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#include <console/console.h>
#include <device/device.h>
#include <device/pci.h>
#include <device/pci_ids.h>
#include <device/pci_ops.h>
#include <cpu/x86/msr.h>
#include <part/hard_reset.h>
#include <device/smbus.h>
#include <delay.h>
#include <arch/io.h>
#include "../../../northbridge/amd/amdk8/northbridge.h"
#include <cpu/amd/model_fxx_rev.h>
#include "chip.h"
#include "pc80/mc146818rtc.h"
#undef DEBUG
#define DEBUG 0
#if DEBUG
static void debug_init(device_t dev)
{
unsigned bus;
unsigned devfn;
#if 0
for(bus = 0; bus < 256; bus++) {
for(devfn = 0; devfn < 256; devfn++) {
int i;
dev = dev_find_slot(bus, devfn);
if (!dev) {
continue;
}
if (!dev->enabled) {
continue;
}
printk_info("%02x:%02x.%0x aka %s\n",
bus, devfn >> 3, devfn & 7, dev_path(dev));
for(i = 0; i < 256; i++) {
if ((i & 0x0f) == 0) {
printk_info("%02x:", i);
}
printk_info(" %02x", pci_read_config8(dev, i));
if ((i & 0x0f) == 0xf) {
printk_info("\n");
}
}
printk_info("\n");
}
}
#endif
#if 0
msr_t msr;
unsigned index;
unsigned eax, ebx, ecx, edx;
index = 0x80000007;
printk_debug("calling cpuid 0x%08x\n", index);
asm volatile(
"cpuid"
: "=a" (eax), "=b" (ebx), "=c" (ecx), "=d" (edx)
: "a" (index)
);
printk_debug("cpuid[%08x]: %08x %08x %08x %08x\n",
index, eax, ebx, ecx, edx);
if (edx & (3 << 1)) {
index = 0xC0010042;
printk_debug("Reading msr: 0x%08x\n", index);
msr = rdmsr(index);
printk_debug("msr[0x%08x]: 0x%08x%08x\n",
index, msr.hi, msr.hi);
}
#endif
}
static void debug_noop(device_t dummy)
{
}
static struct device_operations debug_operations = {
.read_resources = debug_noop,
.set_resources = debug_noop,
.enable_resources = debug_noop,
.init = debug_init,
};
static unsigned int scan_root_bus(device_t root, unsigned int max)
{
struct device_path path;
device_t debug;
max = root_dev_scan_bus(root, max);
path.type = DEVICE_PATH_PNP;
path.u.pnp.port = 0;
path.u.pnp.device = 0;
debug = alloc_dev(&root->link[1], &path);
debug->ops = &debug_operations;
return max;
}
#endif
#if 1
static void handle_smbus_error(int value, const char *msg)
{
if (value >= 0) {
return;
}
switch(value) {
case SMBUS_WAIT_UNTIL_READY_TIMEOUT:
printk_emerg("SMBUS wait until ready timed out - resetting...");
hard_reset();
break;
case SMBUS_WAIT_UNTIL_DONE_TIMEOUT:
printk_emerg("SMBUS wait until done timed out - resetting...");
hard_reset();
break;
default:
die(msg);
break;
}
}
#define ADM1026_DEVICE 0x2d /* Either 0x2c, 0x2d or 0x2e. */
#define ADM1026_REG_CONFIG1 0x00
#define CFG1_MONITOR 0x01
#define CFG1_INT_ENABLE 0x02
#define CFG1_INT_CLEAR 0x04
#define CFG1_AIN8_9 0x08
#define CFG1_THERM_HOT 0x10
#define CFT1_DAC_AFC 0x20
#define CFG1_PWM_AFC 0x40
#define CFG1_RESET 0x80
#define ADM1026_REG_CONFIG2 0x01
#define ADM1026_REG_CONFIG3 0x07
#define BILLION 1000000000UL
static void verify_cpu_voltage(const char *name,
device_t dev, unsigned int reg,
unsigned factor, unsigned cpu_volts, unsigned delta)
{
unsigned nvolts_lo, nvolts_hi;
unsigned cpuvolts_hi, cpuvolts_lo;
int value;
int loops;
loops = 1000;
do {
value = smbus_read_byte(dev, reg);
handle_smbus_error(value, "SMBUS read byte failed");
} while ((--loops > 0) && value == 0);
/* Convert the byte value to nanoVolts.
* My accuracy is nowhere near that good but I don't
* have to round so the math is simple.
* I can only go up to about 4.2 Volts this way so my range is
* limited.
*/
nvolts_lo = ((unsigned)value * factor);
nvolts_hi = nvolts_lo + factor - 1;
/* Get the range of acceptable cpu voltage values */
cpuvolts_lo = cpu_volts - delta;
cpuvolts_hi = cpu_volts + delta;
if ((nvolts_lo < cpuvolts_lo) || (nvolts_hi > cpuvolts_hi)) {
printk_emerg("%s at (%u.%09u-%u.%09u)Volts expected %u.%09u+/-%u.%09uVolts\n",
name,
nvolts_lo/BILLION, nvolts_lo%BILLION,
nvolts_hi/BILLION, nvolts_hi%BILLION,
cpu_volts/BILLION, cpu_volts%BILLION,
delta/BILLION, delta%BILLION);
die("");
}
printk_info("%s at (%u.%09u-%u.%09u)Volts\n",
name,
nvolts_lo/BILLION, nvolts_lo%BILLION,
nvolts_hi/BILLION, nvolts_hi%BILLION);
}
static void adm1026_enable_monitoring(device_t dev)
{
int result;
result = smbus_read_byte(dev, ADM1026_REG_CONFIG1);
handle_smbus_error(result, "ADM1026: cannot read config1");
result = (result | CFG1_MONITOR) & ~(CFG1_INT_CLEAR | CFG1_RESET);
result = smbus_write_byte(dev, ADM1026_REG_CONFIG1, result);
handle_smbus_error(result, "ADM1026: cannot write to config1");
result = smbus_read_byte(dev, ADM1026_REG_CONFIG1);
handle_smbus_error(result, "ADM1026: cannot reread config1");
if (!(result & CFG1_MONITOR)) {
die("ADM1026: monitoring would not enable");
}
}
static unsigned k8_cpu_volts(void)
{
unsigned volts = ~0;
if (is_cpu_c0()) {
volts = 1500000000;
}
if (is_cpu_b3()) {
volts = 1550000000;
}
return volts;
}
static void verify_cpu_voltages(device_t dev)
{
unsigned cpu_volts;
unsigned delta;
#if 0
delta = 50000000;
#else
delta = 75000000;
#endif
cpu_volts = k8_cpu_volts();
if (cpu_volts == ~0) {
printk_info("Required cpu voltage unknwon not checking\n");
return;
}
/* I need to read registers 0x37 == Ain7CPU1 core 0x2d == VcppCPU0 core */
/* CPU1 core
* The sensor has a range of 0-2.5V and reports in
* 256 distinct steps.
*/
verify_cpu_voltage("CPU1 Vcore", dev, 0x37, 9765625,
cpu_volts, delta);
/* CPU0 core
* The sensor has range of 0-3.0V and reports in
* 256 distinct steps.
*/
verify_cpu_voltage("CPU0 Vcore", dev, 0x2d, 11718750,
cpu_volts, delta);
}
#define SMBUS_MUX 0x71
static void do_verify_cpu_voltages(void)
{
device_t smbus_dev;
device_t mux, sensor;
struct device_path mux_path, sensor_path;
int result;
int mux_setting;
/* Find the smbus controller */
smbus_dev = dev_find_device(0x1022, 0x746b, 0);
if (!smbus_dev) {
die("SMBUS controller not found\n");
}
/* Find the smbus mux */
mux_path.type = DEVICE_PATH_I2C;
mux_path.u.i2c.device = SMBUS_MUX;
mux = find_dev_path(smbus_dev, &mux_path);
if (!mux) {
die("SMBUS mux not found\n");
}
/* Find the adm1026 sensor */
sensor_path.type = DEVICE_PATH_I2C;
sensor_path.u.i2c.device = ADM1026_DEVICE;
sensor = find_dev_path(mux, &sensor_path);
if (!sensor) {
die("ADM1026 not found\n");
}
/* Set the mux to see the temperature sensors */
mux_setting = 1;
result = smbus_send_byte(mux, mux_setting);
handle_smbus_error(result, "SMBUS send byte failed\n");
result = smbus_recv_byte(mux);
handle_smbus_error(result, "SMBUS recv byte failed\n");
if (result != mux_setting) {
printk_emerg("SMBUS mux would not set to %d\n", mux_setting);
die("");
}
adm1026_enable_monitoring(sensor);
/* It takes 11.38ms to read a new voltage sensor value */
mdelay(12);
/* Read the cpu voltages and make certain everything looks sane */
verify_cpu_voltages(sensor);
}
#else
#define do_verify_cpu_voltages() do {} while(0)
#endif
static void fixup_aruma(void)
{
msr_t msr;
/* bit 6 (0x40) in MSR 0xC0010015
* disables the TLB cache flush filter
*/
msr=rdmsr(0xC0010015);
msr.lo |= 0x40;
wrmsr(0xC0010015, msr);
}
static void mainboard_init(device_t dev)
{
root_dev_init(dev);
printk_info("Initializing mainboard components... ");
// do_verify_cpu_voltages();
printk_info("ok\n");
printk_info("Initializing mainboard specific functions... ");
fixup_aruma();
printk_info("ok\n");
}
static void enable_dev(struct device *dev)
{
dev->ops->init = mainboard_init;
}
struct chip_operations mainboard_agami_aruma_ops = {
CHIP_NAME("AGAMI Aruma Mainboard")
.enable_dev = enable_dev,
};
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