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|
/*
* This file is part of the coreboot project.
*
* Copyright (C) 2010-2017 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.
*/
#include <console/console.h>
#include <arch/io.h>
#include <bootstate.h>
#include <cpu/x86/smm.h>
#include <device/device.h>
#include <device/pci.h>
#include <device/pci_ids.h>
#include <device/pci_ops.h>
#include <cbmem.h>
#include <elog.h>
#include <amdblocks/amd_pci_util.h>
#include <amdblocks/agesawrapper.h>
#include <amdblocks/reset.h>
#include <soc/southbridge.h>
#include <soc/smbus.h>
#include <soc/smi.h>
#include <soc/amd_pci_int_defs.h>
#include <delay.h>
#include <soc/pci_devs.h>
#include <agesa_headers.h>
#include <soc/nvs.h>
/*
* Table of devices that need their AOAC registers enabled and waited
* upon (usually about .55 milliseconds). Instead of individual delays
* waiting for each device to become available, a single delay will be
* executed.
*/
const static struct stoneyridge_aoac aoac_devs[] = {
{ (FCH_AOAC_D3_CONTROL_UART0 + CONFIG_UART_FOR_CONSOLE * 2),
(FCH_AOAC_D3_STATE_UART0 + CONFIG_UART_FOR_CONSOLE * 2) },
{ FCH_AOAC_D3_CONTROL_AMBA, FCH_AOAC_D3_STATE_AMBA },
{ FCH_AOAC_D3_CONTROL_I2C0, FCH_AOAC_D3_STATE_I2C0 },
{ FCH_AOAC_D3_CONTROL_I2C1, FCH_AOAC_D3_STATE_I2C1 },
{ FCH_AOAC_D3_CONTROL_I2C2, FCH_AOAC_D3_STATE_I2C2 },
{ FCH_AOAC_D3_CONTROL_I2C3, FCH_AOAC_D3_STATE_I2C3 }
};
static int is_sata_config(void)
{
return !((SataNativeIde == CONFIG_STONEYRIDGE_SATA_MODE)
|| (SataLegacyIde == CONFIG_STONEYRIDGE_SATA_MODE));
}
static inline int sb_sata_enable(void)
{
/* True if IDE or AHCI. */
return (SataNativeIde == CONFIG_STONEYRIDGE_SATA_MODE) ||
(SataAhci == CONFIG_STONEYRIDGE_SATA_MODE);
}
static inline int sb_ide_enable(void)
{
/* True if IDE or LEGACY IDE. */
return (SataNativeIde == CONFIG_STONEYRIDGE_SATA_MODE) ||
(SataLegacyIde == CONFIG_STONEYRIDGE_SATA_MODE);
}
void SetFchResetParams(FCH_RESET_INTERFACE *params)
{
const struct device *dev = pcidev_path_on_root(SATA_DEVFN);
params->Xhci0Enable = IS_ENABLED(CONFIG_STONEYRIDGE_XHCI_ENABLE);
if (dev && dev->enabled) {
params->SataEnable = sb_sata_enable();
params->IdeEnable = sb_ide_enable();
} else {
params->SataEnable = FALSE;
params->IdeEnable = FALSE;
}
}
void SetFchEnvParams(FCH_INTERFACE *params)
{
const struct device *dev = pcidev_path_on_root(SATA_DEVFN);
params->AzaliaController = AzEnable;
params->SataClass = CONFIG_STONEYRIDGE_SATA_MODE;
if (dev && dev->enabled) {
params->SataEnable = is_sata_config();
params->IdeEnable = !params->SataEnable;
params->SataIdeMode = (CONFIG_STONEYRIDGE_SATA_MODE ==
SataLegacyIde);
} else {
params->SataEnable = FALSE;
params->IdeEnable = FALSE;
params->SataIdeMode = FALSE;
}
}
void SetFchMidParams(FCH_INTERFACE *params)
{
SetFchEnvParams(params);
}
/*
* Table of APIC register index and associated IRQ name. Using IDX_XXX_NAME
* provides a visible association with the index, therefore helping
* maintainability of table. If a new index/name is defined in
* amd_pci_int_defs.h, just add the pair at the end of this table.
* Order is not important.
*/
const static struct irq_idx_name irq_association[] = {
{ PIRQ_A, "INTA#" },
{ PIRQ_B, "INTB#" },
{ PIRQ_C, "INTC#" },
{ PIRQ_D, "INTD#" },
{ PIRQ_E, "INTE#" },
{ PIRQ_F, "INTF#" },
{ PIRQ_G, "INTG#" },
{ PIRQ_H, "INTH#" },
{ PIRQ_MISC, "Misc" },
{ PIRQ_MISC0, "Misc0" },
{ PIRQ_MISC1, "Misc1" },
{ PIRQ_MISC2, "Misc2" },
{ PIRQ_SIRQA, "Ser IRQ INTA" },
{ PIRQ_SIRQB, "Ser IRQ INTB" },
{ PIRQ_SIRQC, "Ser IRQ INTC" },
{ PIRQ_SIRQD, "Ser IRQ INTD" },
{ PIRQ_SCI, "SCI" },
{ PIRQ_SMBUS, "SMBUS" },
{ PIRQ_ASF, "ASF" },
{ PIRQ_HDA, "HDA" },
{ PIRQ_FC, "FC" },
{ PIRQ_PMON, "PerMon" },
{ PIRQ_SD, "SD" },
{ PIRQ_SDIO, "SDIOt" },
{ PIRQ_EHCI, "EHCI" },
{ PIRQ_XHCI, "XHCI" },
{ PIRQ_SATA, "SATA" },
{ PIRQ_GPIO, "GPIO" },
{ PIRQ_I2C0, "I2C0" },
{ PIRQ_I2C1, "I2C1" },
{ PIRQ_I2C2, "I2C2" },
{ PIRQ_I2C3, "I2C3" },
{ PIRQ_UART0, "UART0" },
{ PIRQ_UART1, "UART1" },
};
/*
* Structure to simplify code obtaining the total of used wide IO
* registers and the size assigned to each.
*/
static struct wide_io_ioport_and_bits {
uint32_t enable;
uint16_t port;
uint8_t alt;
} wio_io_en[TOTAL_WIDEIO_PORTS] = {
{
LPC_WIDEIO0_ENABLE,
LPC_WIDEIO_GENERIC_PORT,
LPC_ALT_WIDEIO0_ENABLE
},
{
LPC_WIDEIO1_ENABLE,
LPC_WIDEIO1_GENERIC_PORT,
LPC_ALT_WIDEIO1_ENABLE
},
{
LPC_WIDEIO2_ENABLE,
LPC_WIDEIO2_GENERIC_PORT,
LPC_ALT_WIDEIO2_ENABLE
}
};
const struct irq_idx_name *sb_get_apic_reg_association(size_t *size)
{
*size = ARRAY_SIZE(irq_association);
return irq_association;
}
/**
* @brief Find the size of a particular wide IO
*
* @param index = index of desired wide IO
*
* @return size of desired wide IO
*/
uint16_t sb_wideio_size(int index)
{
uint32_t enable_register;
uint16_t size = 0;
uint8_t alternate_register;
if (index >= TOTAL_WIDEIO_PORTS)
return size;
enable_register = pci_read_config32(SOC_LPC_DEV,
LPC_IO_OR_MEM_DECODE_ENABLE);
alternate_register = pci_read_config8(SOC_LPC_DEV,
LPC_ALT_WIDEIO_RANGE_ENABLE);
if (enable_register & wio_io_en[index].enable)
size = (alternate_register & wio_io_en[index].alt) ?
16 : 512;
return size;
}
/**
* @brief Identify if any LPC wide IO is covering the IO range
*
* @param start = start of IO range
* @param size = size of IO range
*
* @return Index of wide IO covering the range or error
*/
int sb_find_wideio_range(uint16_t start, uint16_t size)
{
int i, index = WIDEIO_RANGE_ERROR;
uint16_t end, current_size, start_wideio, end_wideio;
end = start + size;
for (i = 0; i < TOTAL_WIDEIO_PORTS; i++) {
current_size = sb_wideio_size(i);
if (current_size == 0)
continue;
start_wideio = pci_read_config16(SOC_LPC_DEV,
wio_io_en[i].port);
end_wideio = start_wideio + current_size;
if ((start >= start_wideio) && (end <= end_wideio)) {
index = i;
break;
}
}
return index;
}
/**
* @brief Program a LPC wide IO to support an IO range
*
* @param start = start of range to be routed through wide IO
* @param size = size of range to be routed through wide IO
*
* @return Index of wide IO register used or error
*/
int sb_set_wideio_range(uint16_t start, uint16_t size)
{
int i, index = WIDEIO_RANGE_ERROR;
uint32_t enable_register;
uint8_t alternate_register;
enable_register = pci_read_config32(SOC_LPC_DEV,
LPC_IO_OR_MEM_DECODE_ENABLE);
alternate_register = pci_read_config8(SOC_LPC_DEV,
LPC_ALT_WIDEIO_RANGE_ENABLE);
for (i = 0; i < TOTAL_WIDEIO_PORTS; i++) {
if (enable_register & wio_io_en[i].enable)
continue;
index = i;
pci_write_config16(SOC_LPC_DEV, wio_io_en[i].port, start);
enable_register |= wio_io_en[i].enable;
pci_write_config32(SOC_LPC_DEV, LPC_IO_OR_MEM_DECODE_ENABLE,
enable_register);
if (size <= 16)
alternate_register |= wio_io_en[i].alt;
else
alternate_register &= ~wio_io_en[i].alt;
pci_write_config8(SOC_LPC_DEV,
LPC_ALT_WIDEIO_RANGE_ENABLE,
alternate_register);
break;
}
return index;
}
static void power_on_aoac_device(int aoac_device_control_register)
{
uint8_t byte;
uint8_t *register_pointer = (uint8_t *)(uintptr_t)AOAC_MMIO_BASE
+ aoac_device_control_register;
/* Power on the UART and AMBA devices */
byte = read8(register_pointer);
byte |= FCH_AOAC_PWR_ON_DEV;
write8(register_pointer, byte);
}
static bool is_aoac_device_enabled(int aoac_device_status_register)
{
uint8_t byte;
byte = read8((uint8_t *)(uintptr_t)AOAC_MMIO_BASE
+ aoac_device_status_register);
byte &= (FCH_AOAC_PWR_RST_STATE | FCH_AOAC_RST_CLK_OK_STATE);
if (byte == (FCH_AOAC_PWR_RST_STATE | FCH_AOAC_RST_CLK_OK_STATE))
return true;
else
return false;
}
void enable_aoac_devices(void)
{
bool status;
int i;
for (i = 0; i < ARRAY_SIZE(aoac_devs); i++)
power_on_aoac_device(aoac_devs[i].enable);
/* Wait for AOAC devices to indicate power and clock OK */
do {
udelay(100);
status = true;
for (i = 0; i < ARRAY_SIZE(aoac_devs); i++)
status &= is_aoac_device_enabled(aoac_devs[i].status);
} while (!status);
}
void sb_pci_port80(void)
{
u8 byte;
byte = pci_read_config8(SOC_LPC_DEV, LPC_IO_OR_MEM_DEC_EN_HIGH);
byte &= ~DECODE_IO_PORT_ENABLE4_H; /* disable lpc port 80 */
pci_write_config8(SOC_LPC_DEV, LPC_IO_OR_MEM_DEC_EN_HIGH, byte);
}
void sb_lpc_port80(void)
{
u8 byte;
/* Enable LPC controller */
outb(PM_LPC_GATING, PM_INDEX);
byte = inb(PM_DATA);
byte |= PM_LPC_ENABLE;
outb(PM_LPC_GATING, PM_INDEX);
outb(byte, PM_DATA);
/* Enable port 80 LPC decode in pci function 3 configuration space. */
byte = pci_read_config8(SOC_LPC_DEV, LPC_IO_OR_MEM_DEC_EN_HIGH);
byte |= DECODE_IO_PORT_ENABLE4_H; /* enable port 80 */
pci_write_config8(SOC_LPC_DEV, LPC_IO_OR_MEM_DEC_EN_HIGH, byte);
}
void sb_lpc_decode(void)
{
u32 tmp = 0;
/* Enable I/O decode to LPC bus */
tmp = DECODE_ENABLE_PARALLEL_PORT0 | DECODE_ENABLE_PARALLEL_PORT2
| DECODE_ENABLE_PARALLEL_PORT4 | DECODE_ENABLE_SERIAL_PORT0
| DECODE_ENABLE_SERIAL_PORT1 | DECODE_ENABLE_SERIAL_PORT2
| DECODE_ENABLE_SERIAL_PORT3 | DECODE_ENABLE_SERIAL_PORT4
| DECODE_ENABLE_SERIAL_PORT5 | DECODE_ENABLE_SERIAL_PORT6
| DECODE_ENABLE_SERIAL_PORT7 | DECODE_ENABLE_AUDIO_PORT0
| DECODE_ENABLE_AUDIO_PORT1 | DECODE_ENABLE_AUDIO_PORT2
| DECODE_ENABLE_AUDIO_PORT3 | DECODE_ENABLE_MSS_PORT2
| DECODE_ENABLE_MSS_PORT3 | DECODE_ENABLE_FDC_PORT0
| DECODE_ENABLE_FDC_PORT1 | DECODE_ENABLE_GAME_PORT
| DECODE_ENABLE_KBC_PORT | DECODE_ENABLE_ACPIUC_PORT
| DECODE_ENABLE_ADLIB_PORT;
pci_write_config32(SOC_LPC_DEV, LPC_IO_PORT_DECODE_ENABLE, tmp);
}
void sb_acpi_mmio_decode(void)
{
uint8_t byte;
/* Enable ACPI MMIO range 0xfed80000 - 0xfed81fff */
outb(PM_ISA_CONTROL, PM_INDEX);
byte = inb(PM_DATA);
byte |= MMIO_EN;
outb(PM_ISA_CONTROL, PM_INDEX);
outb(byte, PM_DATA);
}
static void sb_enable_cf9_io(void)
{
uint32_t reg = pm_read32(PM_DECODE_EN);
pm_write32(PM_DECODE_EN, reg | CF9_IO_EN);
}
static void sb_enable_legacy_io(void)
{
uint32_t reg = pm_read32(PM_DECODE_EN);
pm_write32(PM_DECODE_EN, reg | LEGACY_IO_EN);
}
void sb_clk_output_48Mhz(void)
{
u32 ctrl;
u32 *misc_clk_cntl_1_ptr = (u32 *)(uintptr_t)(MISC_MMIO_BASE
+ MISC_CLK_CNTL1);
/*
* Enable the X14M_25M_48M_OSC pin and leaving it at it's default so
* 48Mhz will be on ball AP13 (FT3b package)
*/
ctrl = read32(misc_clk_cntl_1_ptr);
/* clear the OSCOUT1_ClkOutputEnb to enable the 48 Mhz clock */
ctrl &= ~OSCOUT1_CLK_OUTPUT_ENB;
write32(misc_clk_cntl_1_ptr, ctrl);
}
static uintptr_t sb_spibase(void)
{
u32 base, enables;
/* Make sure the base address is predictable */
base = pci_read_config32(SOC_LPC_DEV, SPIROM_BASE_ADDRESS_REGISTER);
enables = base & SPI_PRESERVE_BITS;
base &= ~(SPI_PRESERVE_BITS | SPI_BASE_RESERVED);
if (!base) {
base = SPI_BASE_ADDRESS;
pci_write_config32(SOC_LPC_DEV, SPIROM_BASE_ADDRESS_REGISTER,
base | enables | SPI_ROM_ENABLE);
/* PCI_COMMAND_MEMORY is read-only and enabled. */
}
return (uintptr_t)base;
}
void sb_set_spi100(u16 norm, u16 fast, u16 alt, u16 tpm)
{
uintptr_t base = sb_spibase();
write16((void *)(base + SPI100_SPEED_CONFIG),
(norm << SPI_NORM_SPEED_NEW_SH) |
(fast << SPI_FAST_SPEED_NEW_SH) |
(alt << SPI_ALT_SPEED_NEW_SH) |
(tpm << SPI_TPM_SPEED_NEW_SH));
write16((void *)(base + SPI100_ENABLE), SPI_USE_SPI100);
}
void sb_disable_4dw_burst(void)
{
uintptr_t base = sb_spibase();
write16((void *)(base + SPI100_HOST_PREF_CONFIG),
read16((void *)(base + SPI100_HOST_PREF_CONFIG))
& ~SPI_RD4DW_EN_HOST);
}
void sb_read_mode(u32 mode)
{
uintptr_t base = sb_spibase();
write32((void *)(base + SPI_CNTRL0),
(read32((void *)(base + SPI_CNTRL0))
& ~SPI_READ_MODE_MASK) | mode);
}
/*
* Enable FCH to decode TPM associated Memory and IO regions
*
* Enable decoding of TPM cycles defined in TPM 1.2 spec
* Enable decoding of legacy TPM addresses: IO addresses 0x7f-
* 0x7e and 0xef-0xee.
* This function should be called if TPM is connected in any way to the FCH and
* conforms to the regions decoded.
* Absent any other routing configuration the TPM cycles will be claimed by the
* LPC bus
*/
void sb_tpm_decode(void)
{
u32 value;
value = pci_read_config32(SOC_LPC_DEV, LPC_TRUSTED_PLATFORM_MODULE);
value |= TPM_12_EN | TPM_LEGACY_EN;
pci_write_config32(SOC_LPC_DEV, LPC_TRUSTED_PLATFORM_MODULE, value);
}
/*
* Enable FCH to decode TPM associated Memory and IO regions to SPI
*
* This should be used if TPM is connected to SPI bus.
* Assumes SPI address space is already configured via a call to sb_spibase().
*/
void sb_tpm_decode_spi(void)
{
/* Enable TPM decoding to FCH */
sb_tpm_decode();
/* Route TPM accesses to SPI */
u32 spibase = pci_read_config32(SOC_LPC_DEV,
SPIROM_BASE_ADDRESS_REGISTER);
pci_write_config32(SOC_LPC_DEV, SPIROM_BASE_ADDRESS_REGISTER, spibase
| ROUTE_TPM_2_SPI);
}
/*
* Enable 4MB (LPC) ROM access at 0xFFC00000 - 0xFFFFFFFF.
*
* Hardware should enable LPC ROM by pin straps. This function does not
* handle the theoretically possible PCI ROM, FWH, or SPI ROM configurations.
*
* The southbridge power-on default is to map 512K ROM space.
*
*/
void sb_enable_rom(void)
{
u8 reg8;
/*
* Decode variable LPC ROM address ranges 1 and 2.
* Bits 3-4 are not defined in any publicly available datasheet
*/
reg8 = pci_read_config8(SOC_LPC_DEV, LPC_IO_OR_MEM_DECODE_ENABLE);
reg8 |= (1 << 3) | (1 << 4);
pci_write_config8(SOC_LPC_DEV, LPC_IO_OR_MEM_DECODE_ENABLE, reg8);
/*
* LPC ROM address range 1:
* Enable LPC ROM range mirroring start at 0x000e(0000).
*/
pci_write_config16(SOC_LPC_DEV, ROM_ADDRESS_RANGE1_START, 0x000e);
/* Enable LPC ROM range mirroring end at 0x000f(ffff). */
pci_write_config16(SOC_LPC_DEV, ROM_ADDRESS_RANGE1_END, 0x000f);
/*
* LPC ROM address range 2:
*
* Enable LPC ROM range start at:
* 0xfff8(0000): 512KB
* 0xfff0(0000): 1MB
* 0xffe0(0000): 2MB
* 0xffc0(0000): 4MB
*/
pci_write_config16(SOC_LPC_DEV, ROM_ADDRESS_RANGE2_START, 0x10000
- (CONFIG_COREBOOT_ROMSIZE_KB >> 6));
/* Enable LPC ROM range end at 0xffff(ffff). */
pci_write_config16(SOC_LPC_DEV, ROM_ADDRESS_RANGE2_END, 0xffff);
}
static void sb_lpc_early_setup(void)
{
uint32_t dword;
/* Enable SPI prefetch */
dword = pci_read_config32(SOC_LPC_DEV, LPC_ROM_DMA_EC_HOST_CONTROL);
dword |= SPI_FROM_HOST_PREFETCH_EN | SPI_FROM_USB_PREFETCH_EN;
pci_write_config32(SOC_LPC_DEV, LPC_ROM_DMA_EC_HOST_CONTROL, dword);
if (IS_ENABLED(CONFIG_STONEYRIDGE_LEGACY_FREE)) {
/* Decode SIOs at 2E/2F and 4E/4F */
dword = pci_read_config32(SOC_LPC_DEV,
LPC_IO_OR_MEM_DECODE_ENABLE);
dword |= DECODE_ALTERNATE_SIO_ENABLE | DECODE_SIO_ENABLE;
pci_write_config32(SOC_LPC_DEV,
LPC_IO_OR_MEM_DECODE_ENABLE, dword);
}
}
static void setup_spread_spectrum(int *reboot)
{
uint16_t rstcfg = pm_read16(PWR_RESET_CFG);
rstcfg &= ~TOGGLE_ALL_PWR_GOOD;
pm_write16(PWR_RESET_CFG, rstcfg);
uint32_t cntl1 = misc_read32(MISC_CLK_CNTL1);
if (cntl1 & CG1PLL_FBDIV_TEST) {
printk(BIOS_DEBUG, "Spread spectrum is ready\n");
misc_write32(MISC_CGPLL_CONFIG1,
misc_read32(MISC_CGPLL_CONFIG1) |
CG1PLL_SPREAD_SPECTRUM_ENABLE);
return;
}
printk(BIOS_DEBUG, "Setting up spread spectrum\n");
uint32_t cfg6 = misc_read32(MISC_CGPLL_CONFIG6);
cfg6 &= ~CG1PLL_LF_MODE_MASK;
cfg6 |= (0x0f8 << CG1PLL_LF_MODE_SHIFT) & CG1PLL_LF_MODE_MASK;
misc_write32(MISC_CGPLL_CONFIG6, cfg6);
uint32_t cfg3 = misc_read32(MISC_CGPLL_CONFIG3);
cfg3 &= ~CG1PLL_REFDIV_MASK;
cfg3 |= (0x003 << CG1PLL_REFDIV_SHIFT) & CG1PLL_REFDIV_MASK;
cfg3 &= ~CG1PLL_FBDIV_MASK;
cfg3 |= (0x04b << CG1PLL_FBDIV_SHIFT) & CG1PLL_FBDIV_MASK;
misc_write32(MISC_CGPLL_CONFIG3, cfg3);
uint32_t cfg5 = misc_read32(MISC_CGPLL_CONFIG5);
cfg5 &= ~SS_AMOUNT_NFRAC_SLIP_MASK;
cfg5 |= (0x2 << SS_AMOUNT_NFRAC_SLIP_SHIFT) & SS_AMOUNT_NFRAC_SLIP_MASK;
misc_write32(MISC_CGPLL_CONFIG5, cfg5);
uint32_t cfg4 = misc_read32(MISC_CGPLL_CONFIG4);
cfg4 &= ~SS_AMOUNT_DSFRAC_MASK;
cfg4 |= (0xd000 << SS_AMOUNT_DSFRAC_SHIFT) & SS_AMOUNT_DSFRAC_MASK;
cfg4 &= ~SS_STEP_SIZE_DSFRAC_MASK;
cfg4 |= (0x02d5 << SS_STEP_SIZE_DSFRAC_SHIFT)
& SS_STEP_SIZE_DSFRAC_MASK;
misc_write32(MISC_CGPLL_CONFIG4, cfg4);
rstcfg |= TOGGLE_ALL_PWR_GOOD;
pm_write16(PWR_RESET_CFG, rstcfg);
cntl1 |= CG1PLL_FBDIV_TEST;
misc_write32(MISC_CLK_CNTL1, cntl1);
*reboot = 1;
}
static void setup_misc(int *reboot)
{
/* Undocumented register */
uint32_t reg = misc_read32(0x50);
if (!(reg & BIT(16))) {
reg |= BIT(16);
misc_write32(0x50, reg);
*reboot = 1;
}
}
static void fch_smbus_init(void)
{
pm_write8(SMB_ASF_IO_BASE, SMB_BASE_ADDR >> 8);
smbus_write8(SMBUS_MMIO_BASE, SMBTIMING, SMB_SPEED_400KHZ);
/* Clear all SMBUS status bits */
smbus_write8(SMBUS_MMIO_BASE, SMBHSTSTAT, SMBHST_STAT_CLEAR);
smbus_write8(SMBUS_MMIO_BASE, SMBSLVSTAT, SMBSLV_STAT_CLEAR);
smbus_write8(ASF_MMIO_BASE, SMBHSTSTAT, SMBHST_STAT_CLEAR);
smbus_write8(ASF_MMIO_BASE, SMBSLVSTAT, SMBSLV_STAT_CLEAR);
}
/* Before console init */
void bootblock_fch_early_init(void)
{
int reboot = 0;
sb_enable_rom();
sb_lpc_port80();
sb_lpc_decode();
sb_lpc_early_setup();
sb_spibase();
sb_disable_4dw_burst(); /* Must be disabled on CZ(ST) */
sb_acpi_mmio_decode();
fch_smbus_init();
sb_enable_cf9_io();
setup_spread_spectrum(&reboot);
setup_misc(&reboot);
if (reboot)
warm_reset();
sb_enable_legacy_io();
enable_aoac_devices();
}
static void print_num_status_bits(int num_bits, uint32_t status,
const char *const bit_names[])
{
int i;
if (!status)
return;
for (i = num_bits - 1; i >= 0; i--) {
if (status & (1 << i)) {
if (bit_names[i])
printk(BIOS_DEBUG, "%s ", bit_names[i]);
else
printk(BIOS_DEBUG, "BIT%d ", i);
}
}
}
static void sb_print_pmxc0_status(void)
{
/* PMxC0 S5/Reset Status shows the source of previous reset. */
uint32_t pmxc0_status = pm_read32(PM_RST_STATUS);
static const char *const pmxc0_status_bits[32] = {
[0] = "ThermalTrip",
[1] = "FourSecondPwrBtn",
[2] = "Shutdown",
[3] = "ThermalTripFromTemp",
[4] = "RemotePowerDownFromASF",
[5] = "ShutDownFan0",
[16] = "UserRst",
[17] = "SoftPciRst",
[18] = "DoInit",
[19] = "DoReset",
[20] = "DoFullReset",
[21] = "SleepReset",
[22] = "KbReset",
[23] = "LtReset",
[24] = "FailBootRst",
[25] = "WatchdogIssueReset",
[26] = "RemoteResetFromASF",
[27] = "SyncFlood",
[28] = "HangReset",
[29] = "EcWatchdogRst",
};
printk(BIOS_DEBUG, "PMxC0 STATUS: 0x%x ", pmxc0_status);
print_num_status_bits(ARRAY_SIZE(pmxc0_status_bits), pmxc0_status,
pmxc0_status_bits);
printk(BIOS_DEBUG, "\n");
}
/* After console init */
void bootblock_fch_init(void)
{
sb_print_pmxc0_status();
}
void sb_enable(struct device *dev)
{
printk(BIOS_DEBUG, "%s\n", __func__);
}
static void sb_init_acpi_ports(void)
{
u32 reg;
/* We use some of these ports in SMM regardless of whether or not
* ACPI tables are generated. Enable these ports indiscriminately.
*/
pm_write16(PM_EVT_BLK, ACPI_PM_EVT_BLK);
pm_write16(PM1_CNT_BLK, ACPI_PM1_CNT_BLK);
pm_write16(PM_TMR_BLK, ACPI_PM_TMR_BLK);
pm_write16(PM_GPE0_BLK, ACPI_GPE0_BLK);
/* CpuControl is in \_PR.CP00, 6 bytes */
pm_write16(PM_CPU_CTRL, ACPI_CPU_CONTROL);
if (IS_ENABLED(CONFIG_HAVE_SMI_HANDLER)) {
/* APMC - SMI Command Port */
pm_write16(PM_ACPI_SMI_CMD, APM_CNT);
configure_smi(SMITYPE_SMI_CMD_PORT, SMI_MODE_SMI);
/* SMI on SlpTyp requires sending SMI before completion
* response of the I/O write. The BKDG also specifies
* clearing ForceStpClkRetry for SMI trapping.
*/
reg = pm_read32(PM_PCI_CTRL);
reg |= FORCE_SLPSTATE_RETRY;
reg &= ~FORCE_STPCLK_RETRY;
pm_write32(PM_PCI_CTRL, reg);
/* Disable SlpTyp feature */
reg = pm_read8(PM_RST_CTRL1);
reg &= ~SLPTYPE_CONTROL_EN;
pm_write8(PM_RST_CTRL1, reg);
configure_smi(SMITYPE_SLP_TYP, SMI_MODE_SMI);
} else {
pm_write16(PM_ACPI_SMI_CMD, 0);
}
/* Decode ACPI registers and enable standard features */
pm_write8(PM_ACPI_CONF, PM_ACPI_DECODE_STD |
PM_ACPI_GLOBAL_EN |
PM_ACPI_RTC_EN_EN |
PM_ACPI_TIMER_EN_EN);
}
static uint16_t reset_pm1_status(void)
{
uint16_t pm1_sts = acpi_read16(MMIO_ACPI_PM1_STS);
acpi_write16(MMIO_ACPI_PM1_STS, pm1_sts);
return pm1_sts;
}
static uint16_t print_pm1_status(uint16_t pm1_sts)
{
static const char *const pm1_sts_bits[16] = {
[0] = "TMROF",
[4] = "BMSTATUS",
[5] = "GBL",
[8] = "PWRBTN",
[10] = "RTC",
[14] = "PCIEXPWAK",
[15] = "WAK",
};
if (!pm1_sts)
return 0;
printk(BIOS_DEBUG, "PM1_STS: ");
print_num_status_bits(ARRAY_SIZE(pm1_sts_bits), pm1_sts, pm1_sts_bits);
printk(BIOS_DEBUG, "\n");
return pm1_sts;
}
static void sb_log_pm1_status(uint16_t pm1_sts)
{
if (!IS_ENABLED(CONFIG_ELOG))
return;
if (pm1_sts & WAK_STS)
elog_add_event_byte(ELOG_TYPE_ACPI_WAKE,
acpi_is_wakeup_s3() ? ACPI_S3 : ACPI_S5);
if (pm1_sts & PWRBTN_STS)
elog_add_event_wake(ELOG_WAKE_SOURCE_PWRBTN, 0);
if (pm1_sts & RTC_STS)
elog_add_event_wake(ELOG_WAKE_SOURCE_RTC, 0);
if (pm1_sts & PCIEXPWAK_STS)
elog_add_event_wake(ELOG_WAKE_SOURCE_PCIE, 0);
}
static void sb_save_sws(uint16_t pm1_status)
{
struct soc_power_reg *sws;
uint32_t reg32;
uint16_t reg16;
sws = cbmem_add(CBMEM_ID_POWER_STATE, sizeof(struct soc_power_reg));
if (sws == NULL)
return;
sws->pm1_sts = pm1_status;
sws->pm1_en = acpi_read16(MMIO_ACPI_PM1_EN);
reg32 = acpi_read32(MMIO_ACPI_GPE0_STS);
acpi_write32(MMIO_ACPI_GPE0_STS, reg32);
sws->gpe0_sts = reg32;
sws->gpe0_en = acpi_read32(MMIO_ACPI_GPE0_EN);
reg16 = acpi_read16(MMIO_ACPI_PM1_CNT_BLK);
reg16 &= SLP_TYP;
sws->wake_from = reg16 >> SLP_TYP_SHIFT;
}
static void sb_clear_pm1_status(void)
{
uint16_t pm1_sts = reset_pm1_status();
sb_save_sws(pm1_sts);
sb_log_pm1_status(pm1_sts);
print_pm1_status(pm1_sts);
}
static int get_index_bit(uint32_t value, uint16_t limit)
{
uint16_t i;
uint32_t t;
if (limit >= TOTAL_BITS(uint32_t))
return -1;
/* get a mask of valid bits. Ex limit = 3, set bits 0-2 */
t = (1 << limit) - 1;
if ((value & t) == 0)
return -1;
t = 1;
for (i = 0; i < limit; i++) {
if (value & t)
break;
t <<= 1;
}
return i;
}
static void set_nvs_sws(void *unused)
{
struct soc_power_reg *sws;
struct global_nvs_t *gnvs;
int index;
sws = cbmem_find(CBMEM_ID_POWER_STATE);
if (sws == NULL)
return;
gnvs = cbmem_find(CBMEM_ID_ACPI_GNVS);
if (gnvs == NULL)
return;
index = get_index_bit(sws->pm1_sts & sws->pm1_en, PM1_LIMIT);
if (index < 0)
gnvs->pm1i = ~0ULL;
else
gnvs->pm1i = index;
index = get_index_bit(sws->gpe0_sts & sws->gpe0_en, GPE0_LIMIT);
if (index < 0)
gnvs->gpei = ~0ULL;
else
gnvs->gpei = index;
}
BOOT_STATE_INIT_ENTRY(BS_OS_RESUME, BS_ON_ENTRY, set_nvs_sws, NULL);
void southbridge_init(void *chip_info)
{
sb_init_acpi_ports();
sb_clear_pm1_status();
}
static void set_sb_final_nvs(void)
{
uintptr_t amdfw_rom;
uintptr_t xhci_fw;
uintptr_t fwaddr;
size_t fwsize;
const struct device *sd, *sata;
struct global_nvs_t *gnvs = cbmem_find(CBMEM_ID_ACPI_GNVS);
if (gnvs == NULL)
return;
gnvs->aoac.ic0e = is_aoac_device_enabled(FCH_AOAC_D3_STATE_I2C0);
gnvs->aoac.ic1e = is_aoac_device_enabled(FCH_AOAC_D3_STATE_I2C1);
gnvs->aoac.ic2e = is_aoac_device_enabled(FCH_AOAC_D3_STATE_I2C2);
gnvs->aoac.ic3e = is_aoac_device_enabled(FCH_AOAC_D3_STATE_I2C3);
gnvs->aoac.ut0e = is_aoac_device_enabled(FCH_AOAC_D3_STATE_UART0);
gnvs->aoac.ut1e = is_aoac_device_enabled(FCH_AOAC_D3_STATE_UART1);
gnvs->aoac.ehce = is_aoac_device_enabled(FCH_AOAC_D3_STATE_USB2);
gnvs->aoac.xhce = is_aoac_device_enabled(FCH_AOAC_D3_STATE_USB3);
/* Rely on these being in sync with devicetree */
sd = pcidev_path_on_root(SD_DEVFN);
gnvs->aoac.st_e = sd && sd->enabled ? 1 : 0;
sata = pcidev_path_on_root(SATA_DEVFN);
gnvs->aoac.sd_e = sata && sata->enabled ? 1 : 0;
gnvs->aoac.espi = 1;
amdfw_rom = 0x20000 - (0x80000 << CONFIG_AMD_FWM_POSITION_INDEX);
xhci_fw = read32((void *)(amdfw_rom + XHCI_FW_SIG_OFFSET));
fwaddr = 2 + read16((void *)(xhci_fw + XHCI_FW_ADDR_OFFSET
+ XHCI_FW_BOOTRAM_SIZE));
fwsize = read16((void *)(xhci_fw + XHCI_FW_SIZE_OFFSET
+ XHCI_FW_BOOTRAM_SIZE));
gnvs->fw00 = 0;
gnvs->fw01 = ((32 * KiB) << 16) + 0;
gnvs->fw02 = fwaddr + XHCI_FW_BOOTRAM_SIZE;
gnvs->fw03 = fwsize << 16;
gnvs->eh10 = pci_read_config32(SOC_EHCI1_DEV, PCI_BASE_ADDRESS_0)
& ~PCI_BASE_ADDRESS_MEM_ATTR_MASK;
}
void southbridge_final(void *chip_info)
{
uint8_t restored_power = PM_S5_AT_POWER_RECOVERY;
if (IS_ENABLED(CONFIG_MAINBOARD_POWER_RESTORE))
restored_power = PM_RESTORE_S0_IF_PREV_S0;
pm_write8(PM_RTC_SHADOW, restored_power);
set_sb_final_nvs();
}
/*
* Update the PCI devices with a valid IRQ number
* that is set in the mainboard PCI_IRQ structures.
*/
static void set_pci_irqs(void *unused)
{
/* Write PCI_INTR regs 0xC00/0xC01 */
write_pci_int_table();
/* Write IRQs for all devicetree enabled devices */
write_pci_cfg_irqs();
}
/*
* Hook this function into the PCI state machine
* on entry into BS_DEV_ENABLE.
*/
BOOT_STATE_INIT_ENTRY(BS_DEV_ENABLE, BS_ON_ENTRY, set_pci_irqs, NULL);
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