/* SPDX-License-Identifier: GPL-2.0-only */
#include <acpi/acpi_pm.h>
#include <arch/io.h>
#include <assert.h>
#include <bootmode.h>
#include <device/mmio.h>
#include <device/pci.h>
#include <cbmem.h>
#include <cpu/x86/smm.h>
#include <console/console.h>
#include <halt.h>
#include <intelblocks/pmc_ipc.h>
#include <intelblocks/pmclib.h>
#include <intelblocks/gpio.h>
#include <intelblocks/tco.h>
#include <option.h>
#include <security/vboot/vboot_common.h>
#include <soc/pci_devs.h>
#include <soc/pm.h>
#include <stdint.h>
#include <string.h>
#include <timer.h>
#define PMC_IPC_BIOS_RST_COMPLETE 0xd0
#define PMC_IPC_BIOS_RST_SUBID_PCI_ENUM_DONE 0
#define PMC_IPC_BIOS_RST_CMPL_STS_PCI_ENUM BIT(0)
static struct chipset_power_state power_state;
/* List of Minimum Assertion durations in microseconds */
enum min_assert_dur {
MinAssertDur0s = 0,
MinAssertDur60us = 60,
MinAssertDur1ms = 1000,
MinAssertDur50ms = 50000,
MinAssertDur98ms = 98000,
MinAssertDur500ms = 500000,
MinAssertDur1s = 1000000,
MinAssertDur2s = 2000000,
MinAssertDur3s = 3000000,
MinAssertDur4s = 4000000,
};
/* Signal Assertion duration values */
struct cfg_assert_dur {
/* Minimum assertion duration of SLP_A signal */
enum min_assert_dur slp_a;
/* Minimum assertion duration of SLP_4 signal */
enum min_assert_dur slp_s4;
/* Minimum assertion duration of SLP_3 signal */
enum min_assert_dur slp_s3;
/* PCH PM Power Cycle duration */
enum min_assert_dur pm_pwr_cyc_dur;
};
/* Default value of PchPmPwrCycDur */
#define PCH_PM_PWR_CYC_DUR 0
struct chipset_power_state *pmc_get_power_state(void)
{
struct chipset_power_state *ptr = NULL;
if (ENV_HAS_CBMEM)
ptr = acpi_get_pm_state();
/* cbmem is online but ptr is not populated yet */
if (ptr == NULL && !(ENV_RAMSTAGE || ENV_POSTCAR))
return &power_state;
return ptr;
}
static void migrate_power_state(int is_recovery)
{
struct chipset_power_state *ps_cbmem;
ps_cbmem = cbmem_add(CBMEM_ID_POWER_STATE, sizeof(*ps_cbmem));
if (ps_cbmem == NULL) {
printk(BIOS_DEBUG, "Not adding power state to cbmem!\n");
return;
}
memcpy(ps_cbmem, &power_state, sizeof(*ps_cbmem));
}
CBMEM_CREATION_HOOK(migrate_power_state);
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);
}
}
}
__weak uint32_t soc_get_smi_status(uint32_t generic_sts)
{
return generic_sts;
}
int acpi_get_sleep_type(void)
{
struct chipset_power_state *ps;
int prev_sleep_state = ACPI_S0;
ps = pmc_get_power_state();
if (ps)
prev_sleep_state = ps->prev_sleep_state;
return prev_sleep_state;
}
static uint32_t pmc_reset_smi_status(void)
{
uint32_t smi_sts = inl(ACPI_BASE_ADDRESS + SMI_STS);
outl(smi_sts, ACPI_BASE_ADDRESS + SMI_STS);
return soc_get_smi_status(smi_sts);
}
static uint32_t print_smi_status(uint32_t smi_sts)
{
size_t array_size;
const char *const *smi_arr;
if (!smi_sts)
return 0;
printk(BIOS_DEBUG, "SMI_STS: ");
smi_arr = soc_smi_sts_array(&array_size);
print_num_status_bits(array_size, smi_sts, smi_arr);
printk(BIOS_DEBUG, "\n");
return smi_sts;
}
/*
* Update supplied events in PM1_EN register. This does not disable any already
* set events.
*/
void pmc_update_pm1_enable(u16 events)
{
u16 pm1_en = pmc_read_pm1_enable();
pm1_en |= events;
pmc_enable_pm1(pm1_en);
}
/* Read events set in PM1_EN register. */
uint16_t pmc_read_pm1_enable(void)
{
return inw(ACPI_BASE_ADDRESS + PM1_EN);
}
uint32_t pmc_clear_smi_status(void)
{
uint32_t sts = pmc_reset_smi_status();
return print_smi_status(sts);
}
uint32_t pmc_get_smi_en(void)
{
return inl(ACPI_BASE_ADDRESS + SMI_EN);
}
void pmc_enable_smi(uint32_t mask)
{
uint32_t smi_en = inl(ACPI_BASE_ADDRESS + SMI_EN);
smi_en |= mask;
outl(smi_en, ACPI_BASE_ADDRESS + SMI_EN);
}
void pmc_disable_smi(uint32_t mask)
{
uint32_t smi_en = inl(ACPI_BASE_ADDRESS + SMI_EN);
smi_en &= ~mask;
outl(smi_en, ACPI_BASE_ADDRESS + SMI_EN);
}
/* PM1 */
void pmc_enable_pm1(uint16_t events)
{
outw(events, ACPI_BASE_ADDRESS + PM1_EN);
}
uint32_t pmc_read_pm1_control(void)
{
return inl(ACPI_BASE_ADDRESS + PM1_CNT);
}
void pmc_write_pm1_control(uint32_t pm1_cnt)
{
outl(pm1_cnt, ACPI_BASE_ADDRESS + PM1_CNT);
}
void pmc_enable_pm1_control(uint32_t mask)
{
uint32_t pm1_cnt = pmc_read_pm1_control();
pm1_cnt |= mask;
pmc_write_pm1_control(pm1_cnt);
}
void pmc_disable_pm1_control(uint32_t mask)
{
uint32_t pm1_cnt = pmc_read_pm1_control();
pm1_cnt &= ~mask;
pmc_write_pm1_control(pm1_cnt);
}
static uint16_t reset_pm1_status(void)
{
uint16_t pm1_sts = inw(ACPI_BASE_ADDRESS + PM1_STS);
outw(pm1_sts, ACPI_BASE_ADDRESS + PM1_STS);
return pm1_sts;
}
static uint16_t print_pm1_status(uint16_t pm1_sts)
{
static const char *const pm1_sts_bits[] = {
[0] = "TMROF",
[5] = "GBL",
[8] = "PWRBTN",
[10] = "RTC",
[11] = "PRBTNOR",
[13] = "USB",
[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;
}
uint16_t pmc_clear_pm1_status(void)
{
return print_pm1_status(reset_pm1_status());
}
/* TCO */
static uint32_t print_tco_status(uint32_t tco_sts)
{
size_t array_size;
const char *const *tco_arr;
if (!tco_sts)
return 0;
printk(BIOS_DEBUG, "TCO_STS: ");
tco_arr = soc_tco_sts_array(&array_size);
print_num_status_bits(array_size, tco_sts, tco_arr);
printk(BIOS_DEBUG, "\n");
return tco_sts;
}
uint32_t pmc_clear_tco_status(void)
{
return print_tco_status(tco_reset_status());
}
/* GPE */
static void pmc_enable_gpe(int gpe, uint32_t mask)
{
uint32_t gpe0_en = inl(ACPI_BASE_ADDRESS + GPE0_EN(gpe));
gpe0_en |= mask;
outl(gpe0_en, ACPI_BASE_ADDRESS + GPE0_EN(gpe));
}
static void pmc_disable_gpe(int gpe, uint32_t mask)
{
uint32_t gpe0_en = inl(ACPI_BASE_ADDRESS + GPE0_EN(gpe));
gpe0_en &= ~mask;
outl(gpe0_en, ACPI_BASE_ADDRESS + GPE0_EN(gpe));
}
void pmc_enable_std_gpe(uint32_t mask)
{
pmc_enable_gpe(GPE_STD, mask);
}
void pmc_disable_std_gpe(uint32_t mask)
{
pmc_disable_gpe(GPE_STD, mask);
}
void pmc_disable_all_gpe(void)
{
int i;
for (i = 0; i < GPE0_REG_MAX; i++)
pmc_disable_gpe(i, ~0);
}
/* Clear the gpio gpe0 status bits in ACPI registers */
static void pmc_clear_gpi_gpe_status(void)
{
int i;
for (i = 0; i < GPE0_REG_MAX; i++) {
/* This is reserved GPE block and specific to chipset */
if (i == GPE_STD)
continue;
uint32_t gpe_sts = inl(ACPI_BASE_ADDRESS + GPE0_STS(i));
outl(gpe_sts, ACPI_BASE_ADDRESS + GPE0_STS(i));
}
}
static uint32_t reset_std_gpe_status(void)
{
uint32_t gpe_sts = inl(ACPI_BASE_ADDRESS + GPE0_STS(GPE_STD));
outl(gpe_sts, ACPI_BASE_ADDRESS + GPE0_STS(GPE_STD));
return gpe_sts;
}
static uint32_t print_std_gpe_sts(uint32_t gpe_sts)
{
size_t array_size;
const char *const *sts_arr;
if (!gpe_sts)
return gpe_sts;
printk(BIOS_DEBUG, "GPE0 STD STS: ");
sts_arr = soc_std_gpe_sts_array(&array_size);
print_num_status_bits(array_size, gpe_sts, sts_arr);
printk(BIOS_DEBUG, "\n");
return gpe_sts;
}
static void pmc_clear_std_gpe_status(void)
{
print_std_gpe_sts(reset_std_gpe_status());
}
void pmc_clear_all_gpe_status(void)
{
pmc_clear_std_gpe_status();
pmc_clear_gpi_gpe_status();
}
__weak
void soc_clear_pm_registers(uintptr_t pmc_bar)
{
}
void pmc_or_mmio32(uint32_t offset, uint32_t ormask)
{
uint32_t reg;
uintptr_t pmc_bar;
pmc_bar = soc_read_pmc_base();
reg = read32p(pmc_bar + offset);
reg |= ormask;
write32p(pmc_bar + offset, reg);
}
void pmc_clear_prsts(void)
{
uint32_t prsts;
uintptr_t pmc_bar;
/* Read PMC base address from soc */
pmc_bar = soc_read_pmc_base();
prsts = read32p(pmc_bar + PRSTS);
write32p(pmc_bar + PRSTS, prsts);
soc_clear_pm_registers(pmc_bar);
}
__weak
int soc_prev_sleep_state(const struct chipset_power_state *ps,
int prev_sleep_state)
{
return prev_sleep_state;
}
/*
* Returns prev_sleep_state and also prints all power management registers.
* Calls soc_prev_sleep_state which may be implemented by SOC.
*/
static int pmc_prev_sleep_state(const struct chipset_power_state *ps)
{
/* Default to S0. */
int prev_sleep_state = ACPI_S0;
if (ps->pm1_sts & WAK_STS) {
switch (acpi_sleep_from_pm1(ps->pm1_cnt)) {
case ACPI_S3:
if (CONFIG(HAVE_ACPI_RESUME))
prev_sleep_state = ACPI_S3;
break;
case ACPI_S4:
prev_sleep_state = ACPI_S4;
break;
case ACPI_S5:
prev_sleep_state = ACPI_S5;
break;
}
/* Clear SLP_TYP. */
pmc_write_pm1_control(ps->pm1_cnt & ~(SLP_TYP));
}
prev_sleep_state = soc_prev_sleep_state(ps, prev_sleep_state);
/* Clear PMC PMCON_x register power failure status bits. */
pmc_clear_pmcon_pwr_failure_sts();
return prev_sleep_state;
}
void pmc_fill_pm_reg_info(struct chipset_power_state *ps)
{
int i;
memset(ps, 0, sizeof(*ps));
ps->pm1_sts = inw(ACPI_BASE_ADDRESS + PM1_STS);
ps->pm1_en = inw(ACPI_BASE_ADDRESS + PM1_EN);
ps->pm1_cnt = pmc_read_pm1_control();
printk(BIOS_DEBUG, "pm1_sts: %04x pm1_en: %04x pm1_cnt: %08x\n",
ps->pm1_sts, ps->pm1_en, ps->pm1_cnt);
for (i = 0; i < GPE0_REG_MAX; i++) {
ps->gpe0_sts[i] = inl(ACPI_BASE_ADDRESS + GPE0_STS(i));
ps->gpe0_en[i] = inl(ACPI_BASE_ADDRESS + GPE0_EN(i));
printk(BIOS_DEBUG, "gpe0_sts[%d]: %08x gpe0_en[%d]: %08x\n",
i, ps->gpe0_sts[i], i, ps->gpe0_en[i]);
}
soc_fill_power_state(ps);
}
/* Reads and prints ACPI specific PM registers */
int pmc_fill_power_state(struct chipset_power_state *ps)
{
/* Define the sleep state string */
static const char * const acpi_sleep_states[] = {
[ACPI_S0] = "S0",
[ACPI_S1] = "S1",
[ACPI_S3] = "S3",
[ACPI_S4] = "S4",
[ACPI_S5] = "S5",
};
pmc_fill_pm_reg_info(ps);
ps->prev_sleep_state = pmc_prev_sleep_state(ps);
if (ps->prev_sleep_state < ARRAY_SIZE(acpi_sleep_states) &&
acpi_sleep_states[ps->prev_sleep_state] != NULL)
printk(BIOS_DEBUG, "prev_sleep_state %d (%s)\n", ps->prev_sleep_state,
acpi_sleep_states[ps->prev_sleep_state]);
else
printk(BIOS_DEBUG, "prev_sleep_state %d (unknown state)\n", ps->prev_sleep_state);
return ps->prev_sleep_state;
}
#if CONFIG(PMC_GLOBAL_RESET_ENABLE_LOCK)
void pmc_global_reset_disable_and_lock(void)
{
uint32_t *etr = soc_pmc_etr_addr();
uint32_t reg;
reg = read32(etr);
reg = (reg & ~CF9_GLB_RST) | CF9_LOCK;
write32(etr, reg);
}
void pmc_global_reset_enable(bool enable)
{
uint32_t *etr = soc_pmc_etr_addr();
uint32_t reg;
reg = read32(etr);
reg = enable ? reg | CF9_GLB_RST : reg & ~CF9_GLB_RST;
write32(etr, reg);
}
#endif // CONFIG_PMC_GLOBAL_RESET_ENABLE_LOCK
int platform_is_resuming(void)
{
/* Read power state from PMC data structure */
if (ENV_RAMSTAGE)
return acpi_get_sleep_type() == ACPI_S3;
/* Read power state from PMC ABASE */
if (!(inw(ACPI_BASE_ADDRESS + PM1_STS) & WAK_STS))
return 0;
return acpi_sleep_from_pm1(pmc_read_pm1_control()) == ACPI_S3;
}
/* Read and clear GPE status (defined in acpi/acpi.h) */
int acpi_get_gpe(int gpe)
{
int bank;
uint32_t mask, sts;
struct stopwatch sw;
int rc = 0;
if (gpe < 0 || gpe > GPE_MAX)
return -1;
bank = gpe / 32;
mask = 1 << (gpe % 32);
/* Wait up to 1ms for GPE status to clear */
stopwatch_init_msecs_expire(&sw, 1);
do {
if (stopwatch_expired(&sw))
return rc;
sts = inl(ACPI_BASE_ADDRESS + GPE0_STS(bank));
if (sts & mask) {
outl(mask, ACPI_BASE_ADDRESS + GPE0_STS(bank));
rc = 1;
}
} while (sts & mask);
return rc;
}
/*
* The PM1 control is set to S5 when vboot requests a reboot because the power
* state code above may not have collected its data yet. Therefore, set it to
* S5 when vboot requests a reboot. That's necessary if vboot fails in the
* resume path and requests a reboot. This prevents a reboot loop where the
* error is continually hit on the failing vboot resume path.
*/
void vboot_platform_prepare_reboot(void)
{
uint32_t pm1_cnt;
pm1_cnt = (pmc_read_pm1_control() & ~(SLP_TYP)) |
(SLP_TYP_S5 << SLP_TYP_SHIFT);
pmc_write_pm1_control(pm1_cnt);
}
void poweroff(void)
{
pmc_enable_pm1_control(SLP_EN | (SLP_TYP_S5 << SLP_TYP_SHIFT));
/*
* Setting SLP_TYP_S5 in PM1 triggers SLP_SMI, which is handled by SMM
* to transition to S5 state. If halt is called in SMM, then it prevents
* the SMI handler from being triggered and system never enters S5.
*/
if (!ENV_SMM)
halt();
}
void pmc_gpe_init(void)
{
uint32_t gpio_cfg = 0;
uint32_t gpio_cfg_reg;
uint8_t dw0 = 0, dw1 = 0, dw2 = 0;
/* Read PMC base address from soc. This is implemented in soc */
uintptr_t pmc_bar = soc_read_pmc_base();
/*
* Get the dwX values for pmc gpe settings.
*/
soc_get_gpi_gpe_configs(&dw0, &dw1, &dw2);
const uint32_t gpio_cfg_mask =
(GPE0_DWX_MASK << GPE0_DW_SHIFT(0)) |
(GPE0_DWX_MASK << GPE0_DW_SHIFT(1)) |
(GPE0_DWX_MASK << GPE0_DW_SHIFT(2));
/* Making sure that bad values don't bleed into the other fields */
dw0 &= GPE0_DWX_MASK;
dw1 &= GPE0_DWX_MASK;
dw2 &= GPE0_DWX_MASK;
/*
* Route the GPIOs to the GPE0 block. Determine that all values
* are different, and if they aren't use the reset values.
*/
if (dw0 == dw1 || dw1 == dw2) {
printk(BIOS_INFO, "PMC: Using default GPE route.\n");
gpio_cfg = read32p(pmc_bar + GPIO_GPE_CFG);
dw0 = (gpio_cfg >> GPE0_DW_SHIFT(0)) & GPE0_DWX_MASK;
dw1 = (gpio_cfg >> GPE0_DW_SHIFT(1)) & GPE0_DWX_MASK;
dw2 = (gpio_cfg >> GPE0_DW_SHIFT(2)) & GPE0_DWX_MASK;
} else {
gpio_cfg |= (uint32_t)dw0 << GPE0_DW_SHIFT(0);
gpio_cfg |= (uint32_t)dw1 << GPE0_DW_SHIFT(1);
gpio_cfg |= (uint32_t)dw2 << GPE0_DW_SHIFT(2);
}
gpio_cfg_reg = read32p(pmc_bar + GPIO_GPE_CFG) & ~gpio_cfg_mask;
gpio_cfg_reg |= gpio_cfg & gpio_cfg_mask;
write32p(pmc_bar + GPIO_GPE_CFG, gpio_cfg_reg);
/* Set the routes in the GPIO communities as well. */
gpio_route_gpe(dw0, dw1, dw2);
}
static void pmc_clear_pmcon_pwr_failure_sts_mmio(void)
{
uint8_t *addr = pmc_mmio_regs();
/*
* Clear PMC GEN_PMCON_A register power failure status bits:
* SUS_PWR_FLR, PWR_FLR bits
* while retaining MS4V write-1-to-clear bit
*
* Note: clearing `GBL_RST_STS` bit earlier than FSP-M/MRC having an adverse effect
* on the PMC sleep type register which results in calculating wrong
* `prev_sleep_state` post a global reset, hence, just clearing the power failure
* status bits rather than clearing the complete PMC PMCON_A register.
*/
clrbits32((addr + GEN_PMCON_A), (MS4V | GBL_RST_STS));
}
static void pmc_clear_pmcon_pwr_failure_sts_pci(void)
{
#if defined(__SIMPLE_DEVICE__)
pci_devfn_t dev = PCI_DEV(0, PCI_SLOT(PCH_DEVFN_PMC), PCI_FUNC(PCH_DEVFN_PMC));
#else
struct device *dev = pcidev_path_on_root(PCH_DEVFN_PMC);
if (!dev)
return;
#endif
pci_or_config32(dev, GEN_PMCON_B, (SUS_PWR_FLR | PWR_FLR));
}
/*
* Clear PMC GEN_PMCON_X register power failure status bits:
* SUS_PWR_FLR, PWR_FLR bits (keep the other bits intact)
*/
void pmc_clear_pmcon_pwr_failure_sts(void)
{
if (CONFIG(SOC_INTEL_MEM_MAPPED_PM_CONFIGURATION))
pmc_clear_pmcon_pwr_failure_sts_mmio();
else
pmc_clear_pmcon_pwr_failure_sts_pci();
}
#if ENV_RAMSTAGE
static void pmc_clear_pmcon_sts_mmio(void)
{
uint8_t *addr = pmc_mmio_regs();
clrbits32((addr + GEN_PMCON_A), MS4V);
}
static void pmc_clear_pmcon_sts_pci(void)
{
struct device *dev = pcidev_path_on_root(PCH_DEVFN_PMC);
if (!dev)
return;
pci_and_config32(dev, GEN_PMCON_A, ~MS4V);
}
/*
* Clear PMC GEN_PMCON_A register status bits:
* SUS_PWR_FLR, GBL_RST_STS, HOST_RST_STS, PWR_FLR bits
* while retaining MS4V write-1-to-clear bit
*/
void pmc_clear_pmcon_sts(void)
{
/*
* Accessing PMC GEN_PMCON_A register differs between different Intel chipsets.
* Typically, there are two possible ways to perform GEN_PMCON_A register programming
* (like `pmc_clear_pmcon_sts()`) as:
* 1. Using PCI configuration space when GEN_PMCON_A is a PCI configuration register.
* 2. Using MMIO access when GEN_PMCON_A is a memory mapped register.
*/
if (CONFIG(SOC_INTEL_MEM_MAPPED_PM_CONFIGURATION))
pmc_clear_pmcon_sts_mmio();
else
pmc_clear_pmcon_sts_pci();
}
#endif
void pmc_set_power_failure_state(const bool target_on)
{
const unsigned int state = get_uint_option("power_on_after_fail",
CONFIG_MAINBOARD_POWER_FAILURE_STATE);
/*
* On the shutdown path (target_on == false), we only need to
* update the register for MAINBOARD_POWER_STATE_PREVIOUS. For
* all other cases, we don't write the register to avoid clob-
* bering the value set on the boot path. This is necessary,
* for instance, when we can't access the option backend in SMM.
*/
switch (state) {
case MAINBOARD_POWER_STATE_OFF:
if (!target_on)
break;
printk(BIOS_INFO, "Set power off after power failure.\n");
pmc_soc_set_afterg3_en(false);
break;
case MAINBOARD_POWER_STATE_ON:
if (!target_on)
break;
printk(BIOS_INFO, "Set power on after power failure.\n");
pmc_soc_set_afterg3_en(true);
break;
case MAINBOARD_POWER_STATE_PREVIOUS:
printk(BIOS_INFO, "Keep power state after power failure.\n");
pmc_soc_set_afterg3_en(target_on);
break;
default:
printk(BIOS_WARNING, "Unknown power-failure state: %d\n", state);
break;
}
}
/* This function returns the highest assertion duration of the SLP_Sx assertion widths */
static enum min_assert_dur get_high_assert_width(const struct cfg_assert_dur *cfg_assert_dur)
{
enum min_assert_dur max_assert_dur = cfg_assert_dur->slp_s4;
if (max_assert_dur < cfg_assert_dur->slp_s3)
max_assert_dur = cfg_assert_dur->slp_s3;
if (max_assert_dur < cfg_assert_dur->slp_a)
max_assert_dur = cfg_assert_dur->slp_a;
return max_assert_dur;
}
/* This function converts assertion durations from register-encoded to microseconds */
static void get_min_assert_dur(uint8_t slp_s4_min_assert, uint8_t slp_s3_min_assert,
uint8_t slp_a_min_assert, uint8_t pm_pwr_cyc_dur,
struct cfg_assert_dur *cfg_assert_dur)
{
/*
* Ensure slp_x_dur_list[] elements in the devicetree config are in sync with
* FSP encoded values.
*/
/* slp_s4_assert_dur_list : 1s, 1s(default), 2s, 3s, 4s */
const enum min_assert_dur slp_s4_assert_dur_list[] = {
MinAssertDur1s, MinAssertDur1s, MinAssertDur2s, MinAssertDur3s, MinAssertDur4s
};
/* slp_s3_assert_dur_list: 50ms, 60us, 1ms, 50ms (Default), 2s */
const enum min_assert_dur slp_s3_assert_dur_list[] = {
MinAssertDur50ms, MinAssertDur60us, MinAssertDur1ms, MinAssertDur50ms,
MinAssertDur2s
};
/* slp_a_assert_dur_list: 2s, 0s, 4s, 98ms, 2s(Default) */
const enum min_assert_dur slp_a_assert_dur_list[] = {
MinAssertDur2s, MinAssertDur0s, MinAssertDur4s, MinAssertDur98ms, MinAssertDur2s
};
/* pm_pwr_cyc_dur_list: 4s(Default), 1s, 2s, 3s, 4s */
const enum min_assert_dur pm_pwr_cyc_dur_list[] = {
MinAssertDur4s, MinAssertDur1s, MinAssertDur2s, MinAssertDur3s, MinAssertDur4s
};
/* Get signal assertion width */
if (slp_s4_min_assert < ARRAY_SIZE(slp_s4_assert_dur_list))
cfg_assert_dur->slp_s4 = slp_s4_assert_dur_list[slp_s4_min_assert];
if (slp_s3_min_assert < ARRAY_SIZE(slp_s3_assert_dur_list))
cfg_assert_dur->slp_s3 = slp_s3_assert_dur_list[slp_s3_min_assert];
if (slp_a_min_assert < ARRAY_SIZE(slp_a_assert_dur_list))
cfg_assert_dur->slp_a = slp_a_assert_dur_list[slp_a_min_assert];
if (pm_pwr_cyc_dur < ARRAY_SIZE(pm_pwr_cyc_dur_list))
cfg_assert_dur->pm_pwr_cyc_dur = pm_pwr_cyc_dur_list[pm_pwr_cyc_dur];
}
/*
* This function ensures that the duration programmed in the PchPmPwrCycDur will never be
* smaller than the SLP_Sx assertion widths.
* If the pm_pwr_cyc_dur is less than any of the SLP_Sx assertion widths then it returns the
* default value PCH_PM_PWR_CYC_DUR.
*/
uint8_t get_pm_pwr_cyc_dur(uint8_t slp_s4_min_assert, uint8_t slp_s3_min_assert,
uint8_t slp_a_min_assert, uint8_t pm_pwr_cyc_dur)
{
/* Set default values for the minimum assertion duration */
struct cfg_assert_dur cfg_assert_dur = {
.slp_a = MinAssertDur2s,
.slp_s4 = MinAssertDur1s,
.slp_s3 = MinAssertDur50ms,
.pm_pwr_cyc_dur = MinAssertDur4s
};
enum min_assert_dur high_assert_width;
/* Convert assertion durations from register-encoded to microseconds */
get_min_assert_dur(slp_s4_min_assert, slp_s3_min_assert, slp_a_min_assert,
pm_pwr_cyc_dur, &cfg_assert_dur);
/* Get the highest assertion duration among PCH EDS specified signals for pwr_cyc_dur */
high_assert_width = get_high_assert_width(&cfg_assert_dur);
if (cfg_assert_dur.pm_pwr_cyc_dur >= high_assert_width)
return pm_pwr_cyc_dur;
printk(BIOS_DEBUG,
"Set PmPwrCycDur to 4s as configured PmPwrCycDur (%d) violates PCH EDS "
"spec\n", pm_pwr_cyc_dur);
return PCH_PM_PWR_CYC_DUR;
}
void pmc_set_acpi_mode(void)
{
if (!CONFIG(NO_SMM) && !acpi_is_wakeup_s3()) {
apm_control(APM_CNT_ACPI_DISABLE);
}
}
enum pch_pmc_xtal pmc_get_xtal_freq(void)
{
if (!CONFIG(SOC_INTEL_COMMON_BLOCK_PMC_EPOC))
dead_code();
uint32_t xtal_freq = 0;
const uint32_t epoc = read32p(soc_read_pmc_base() + PCH_PMC_EPOC);
/* XTAL frequency in bits 21, 20, 17 */
xtal_freq |= !!(epoc & (1 << 21)) << 2;
xtal_freq |= !!(epoc & (1 << 20)) << 1;
xtal_freq |= !!(epoc & (1 << 17)) << 0;
switch (xtal_freq) {
case 0:
return XTAL_24_MHZ;
case 1:
return XTAL_19_2_MHZ;
case 2:
return XTAL_38_4_MHZ;
default:
printk(BIOS_ERR, "Unknown EPOC XTAL frequency setting %u\n", xtal_freq);
return XTAL_UNKNOWN_FREQ;
}
}
void pmc_send_bios_reset_pci_enum_done(void)
{
struct pmc_ipc_buffer req = { 0 };
struct pmc_ipc_buffer rsp;
uint32_t cmd;
req.buf[0] = PMC_IPC_BIOS_RST_CMPL_STS_PCI_ENUM;
cmd = pmc_make_ipc_cmd(PMC_IPC_BIOS_RST_COMPLETE,
PMC_IPC_BIOS_RST_SUBID_PCI_ENUM_DONE, 0);
if (pmc_send_ipc_cmd(cmd, &req, &rsp) != CB_SUCCESS)
printk(BIOS_ERR, "PMC: Failed sending PCI Enumeration Done Command\n");
}