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/* SPDX-License-Identifier: GPL-2.0-or-later */
#include <acpi/acpigen.h>
#include <arch/ioapic.h>
#include <arch/smp/mpspec.h>
#include <bootstate.h>
#include <cbmem.h>
#include <cf9_reset.h>
#include <acpi/acpi_gnvs.h>
#include <console/console.h>
#include <cpu/intel/turbo.h>
#include <cpu/x86/msr.h>
#include <cpu/x86/smm.h>
#include <intelblocks/acpi.h>
#include <intelblocks/msr.h>
#include <intelblocks/pmclib.h>
#include <intelblocks/uart.h>
#include <soc/gpio.h>
#include <soc/iomap.h>
#include <soc/nvs.h>
#include <soc/pm.h>
#include <string.h>
__attribute__((weak)) unsigned long acpi_fill_mcfg(unsigned long current)
{
/* PCI Segment Group 0, Start Bus Number 0, End Bus Number is 255 */
current += acpi_create_mcfg_mmconfig((void *)current,
CONFIG_MMCONF_BASE_ADDRESS, 0, 0,
(CONFIG_SA_PCIEX_LENGTH >> 20) - 1);
return current;
}
static int acpi_sci_irq(void)
{
int sci_irq = 9;
uint32_t scis;
scis = soc_read_sci_irq_select();
scis &= SCI_IRQ_SEL;
scis >>= SCI_IRQ_ADJUST;
/* Determine how SCI is routed. */
switch (scis) {
case SCIS_IRQ9:
case SCIS_IRQ10:
case SCIS_IRQ11:
sci_irq = scis - SCIS_IRQ9 + 9;
break;
case SCIS_IRQ20:
case SCIS_IRQ21:
case SCIS_IRQ22:
case SCIS_IRQ23:
sci_irq = scis - SCIS_IRQ20 + 20;
break;
default:
printk(BIOS_DEBUG, "Invalid SCI route! Defaulting to IRQ9.\n");
sci_irq = 9;
break;
}
printk(BIOS_DEBUG, "SCI is IRQ%d\n", sci_irq);
return sci_irq;
}
static unsigned long acpi_madt_irq_overrides(unsigned long current)
{
int sci = acpi_sci_irq();
uint16_t flags = MP_IRQ_TRIGGER_LEVEL;
/* INT_SRC_OVR */
current += acpi_create_madt_irqoverride((void *)current, 0, 0, 2, 0);
flags |= soc_madt_sci_irq_polarity(sci);
/* SCI */
current +=
acpi_create_madt_irqoverride((void *)current, 0, sci, sci, flags);
return current;
}
unsigned long acpi_fill_madt(unsigned long current)
{
/* Local APICs */
current = acpi_create_madt_lapics(current);
/* IOAPIC */
current += acpi_create_madt_ioapic((void *)current, 2, IO_APIC_ADDR, 0);
return acpi_madt_irq_overrides(current);
}
void acpi_fill_fadt(acpi_fadt_t *fadt)
{
const uint16_t pmbase = ACPI_BASE_ADDRESS;
fadt->header.revision = get_acpi_table_revision(FADT);
fadt->sci_int = acpi_sci_irq();
if (permanent_smi_handler()) {
fadt->smi_cmd = APM_CNT;
fadt->acpi_enable = APM_CNT_ACPI_ENABLE;
fadt->acpi_disable = APM_CNT_ACPI_DISABLE;
}
fadt->pm1a_evt_blk = pmbase + PM1_STS;
fadt->pm1b_evt_blk = 0x0;
fadt->pm1a_cnt_blk = pmbase + PM1_CNT;
fadt->pm1b_cnt_blk = 0x0;
fadt->gpe0_blk = pmbase + GPE0_STS(0);
fadt->pm1_evt_len = 4;
fadt->pm1_cnt_len = 2;
/* GPE0 STS/EN pairs each 32 bits wide. */
fadt->gpe0_blk_len = 2 * GPE0_REG_MAX * sizeof(uint32_t);
fadt->flush_size = 0x400; /* twice of cache size */
fadt->flush_stride = 0x10; /* Cache line width */
fadt->duty_offset = 1;
fadt->day_alrm = 0xd;
fadt->flags = ACPI_FADT_WBINVD | ACPI_FADT_C1_SUPPORTED |
ACPI_FADT_C2_MP_SUPPORTED | ACPI_FADT_SLEEP_BUTTON |
ACPI_FADT_RESET_REGISTER | ACPI_FADT_SEALED_CASE |
ACPI_FADT_S4_RTC_WAKE | ACPI_FADT_PLATFORM_CLOCK;
fadt->reset_reg.space_id = 1;
fadt->reset_reg.bit_width = 8;
fadt->reset_reg.addrl = RST_CNT;
fadt->reset_reg.access_size = ACPI_ACCESS_SIZE_BYTE_ACCESS;
fadt->reset_value = RST_CPU | SYS_RST;
fadt->x_pm1a_evt_blk.space_id = 1;
fadt->x_pm1a_evt_blk.bit_width = fadt->pm1_evt_len * 8;
fadt->x_pm1a_evt_blk.addrl = pmbase + PM1_STS;
fadt->x_pm1a_evt_blk.access_size = ACPI_ACCESS_SIZE_DWORD_ACCESS;
fadt->x_pm1b_evt_blk.space_id = 1;
fadt->x_pm1a_cnt_blk.space_id = 1;
fadt->x_pm1a_cnt_blk.bit_width = fadt->pm1_cnt_len * 8;
fadt->x_pm1a_cnt_blk.addrl = pmbase + PM1_CNT;
fadt->x_pm1a_cnt_blk.access_size = ACPI_ACCESS_SIZE_WORD_ACCESS;
fadt->x_pm1b_cnt_blk.space_id = 1;
/*
* Windows 10 requires x_gpe0_blk to be set starting with FADT revision 5.
* The bit_width field intentionally overflows here.
* The OSPM can instead use the values in `fadt->gpe0_blk{,_len}`, which
* seems to work fine on Linux 5.0 and Windows 10.
*/
fadt->x_gpe0_blk.space_id = ACPI_ADDRESS_SPACE_IO;
fadt->x_gpe0_blk.bit_width = fadt->gpe0_blk_len * 8;
fadt->x_gpe0_blk.bit_offset = 0;
fadt->x_gpe0_blk.access_size = ACPI_ACCESS_SIZE_BYTE_ACCESS;
fadt->x_gpe0_blk.addrl = fadt->gpe0_blk;
fadt->x_gpe0_blk.addrh = 0;
fadt->x_gpe1_blk.space_id = 1;
}
unsigned long southbridge_write_acpi_tables(const struct device *device,
unsigned long current,
struct acpi_rsdp *rsdp)
{
current = acpi_write_dbg2_pci_uart(rsdp, current,
uart_get_device(),
ACPI_ACCESS_SIZE_DWORD_ACCESS);
return acpi_write_hpet(device, current, rsdp);
}
__weak
uint32_t acpi_fill_soc_wake(uint32_t generic_pm1_en,
const struct chipset_power_state *ps)
{
return generic_pm1_en;
}
#if CONFIG(SOC_INTEL_COMMON_ACPI_WAKE_SOURCE)
/*
* Save wake source information for calculating ACPI _SWS values
*
* @pm1: PM1_STS register with only enabled events set
* @gpe0: GPE0_STS registers with only enabled events set
*
* return the number of registers in the gpe0 array or -1 if nothing
* is provided by this function.
*/
static int acpi_fill_wake(uint32_t *pm1, uint32_t **gpe0)
{
struct chipset_power_state *ps;
static uint32_t gpe0_sts[GPE0_REG_MAX];
uint32_t pm1_en;
int i;
ps = cbmem_find(CBMEM_ID_POWER_STATE);
if (ps == NULL)
return -1;
/*
* PM1_EN to check the basic wake events which can happen through
* powerbtn or any other wake source like lidopen, key board press etc.
*/
pm1_en = ps->pm1_en;
pm1_en = acpi_fill_soc_wake(pm1_en, ps);
*pm1 = ps->pm1_sts & pm1_en;
/* Mask off GPE0 status bits that are not enabled */
*gpe0 = &gpe0_sts[0];
for (i = 0; i < GPE0_REG_MAX; i++)
gpe0_sts[i] = ps->gpe0_sts[i] & ps->gpe0_en[i];
return GPE0_REG_MAX;
}
#endif
__weak void acpi_create_gnvs(struct global_nvs_t *gnvs)
{
}
void southbridge_inject_dsdt(const struct device *device)
{
struct global_nvs_t *gnvs;
gnvs = cbmem_find(CBMEM_ID_ACPI_GNVS);
if (!gnvs) {
gnvs = cbmem_add(CBMEM_ID_ACPI_GNVS, sizeof(*gnvs));
if (gnvs)
memset(gnvs, 0, sizeof(*gnvs));
}
if (gnvs) {
acpi_create_gnvs(gnvs);
/* And tell SMI about it */
apm_control(APM_CNT_GNVS_UPDATE);
/* Add it to DSDT. */
acpigen_write_scope("\\");
acpigen_write_name_dword("NVSA", (uintptr_t) gnvs);
acpigen_pop_len();
}
}
static int calculate_power(int tdp, int p1_ratio, int ratio)
{
u32 m;
u32 power;
/*
* M = ((1.1 - ((p1_ratio - ratio) * 0.00625)) / 1.1) ^ 2
*
* Power = (ratio / p1_ratio) * m * tdp
*/
m = (110000 - ((p1_ratio - ratio) * 625)) / 11;
m = (m * m) / 1000;
power = ((ratio * 100000 / p1_ratio) / 100);
power *= (m / 100) * (tdp / 1000);
power /= 1000;
return power;
}
static int get_cores_per_package(void)
{
struct cpuinfo_x86 c;
struct cpuid_result result;
int cores = 1;
get_fms(&c, cpuid_eax(1));
if (c.x86 != 6)
return 1;
result = cpuid_ext(0xb, 1);
cores = result.ebx & 0xff;
return cores;
}
static void generate_c_state_entries(void)
{
acpi_cstate_t *c_state_map;
size_t entries;
c_state_map = soc_get_cstate_map(&entries);
/* Generate C-state tables */
acpigen_write_CST_package(c_state_map, entries);
}
void generate_p_state_entries(int core, int cores_per_package)
{
int ratio_min, ratio_max, ratio_turbo, ratio_step;
int coord_type, power_max, num_entries;
int ratio, power, clock, clock_max;
bool turbo;
coord_type = cpu_get_coord_type();
ratio_min = cpu_get_min_ratio();
ratio_max = cpu_get_max_ratio();
clock_max = (ratio_max * cpu_get_bus_clock()) / KHz;
turbo = (get_turbo_state() == TURBO_ENABLED);
/* Calculate CPU TDP in mW */
power_max = cpu_get_power_max();
/* Write _PCT indicating use of FFixedHW */
acpigen_write_empty_PCT();
/* Write _PPC with no limit on supported P-state */
acpigen_write_PPC_NVS();
/* Write PSD indicating configured coordination type */
acpigen_write_PSD_package(core, 1, coord_type);
/* Add P-state entries in _PSS table */
acpigen_write_name("_PSS");
/* Determine ratio points */
ratio_step = PSS_RATIO_STEP;
do {
num_entries = ((ratio_max - ratio_min) / ratio_step) + 1;
if (((ratio_max - ratio_min) % ratio_step) > 0)
num_entries += 1;
if (turbo)
num_entries += 1;
if (num_entries > PSS_MAX_ENTRIES)
ratio_step += 1;
} while (num_entries > PSS_MAX_ENTRIES);
/* _PSS package count depends on Turbo */
acpigen_write_package(num_entries);
/* P[T] is Turbo state if enabled */
if (turbo) {
ratio_turbo = cpu_get_max_turbo_ratio();
/* Add entry for Turbo ratio */
acpigen_write_PSS_package(clock_max + 1, /* MHz */
power_max, /* mW */
PSS_LATENCY_TRANSITION,/* lat1 */
PSS_LATENCY_BUSMASTER,/* lat2 */
ratio_turbo << 8, /* control */
ratio_turbo << 8); /* status */
num_entries -= 1;
}
/* First regular entry is max non-turbo ratio */
acpigen_write_PSS_package(clock_max, /* MHz */
power_max, /* mW */
PSS_LATENCY_TRANSITION,/* lat1 */
PSS_LATENCY_BUSMASTER,/* lat2 */
ratio_max << 8, /* control */
ratio_max << 8); /* status */
num_entries -= 1;
/* Generate the remaining entries */
for (ratio = ratio_min + ((num_entries - 1) * ratio_step);
ratio >= ratio_min; ratio -= ratio_step) {
/* Calculate power at this ratio */
power = calculate_power(power_max, ratio_max, ratio);
clock = (ratio * cpu_get_bus_clock()) / KHz;
acpigen_write_PSS_package(clock, /* MHz */
power, /* mW */
PSS_LATENCY_TRANSITION,/* lat1 */
PSS_LATENCY_BUSMASTER,/* lat2 */
ratio << 8, /* control */
ratio << 8); /* status */
}
/* Fix package length */
acpigen_pop_len();
}
__attribute__ ((weak)) acpi_tstate_t *soc_get_tss_table(int *entries)
{
*entries = 0;
return NULL;
}
void generate_t_state_entries(int core, int cores_per_package)
{
acpi_tstate_t *soc_tss_table;
int entries;
soc_tss_table = soc_get_tss_table(&entries);
if (entries == 0)
return;
/* Indicate SW_ALL coordination for T-states */
acpigen_write_TSD_package(core, cores_per_package, SW_ALL);
/* Indicate FixedHW so OS will use MSR */
acpigen_write_empty_PTC();
/* Set NVS controlled T-state limit */
acpigen_write_TPC("\\TLVL");
/* Write TSS table for MSR access */
acpigen_write_TSS_package(entries, soc_tss_table);
}
__weak void soc_power_states_generation(int core_id,
int cores_per_package)
{
}
void generate_cpu_entries(const struct device *device)
{
int core_id, cpu_id, pcontrol_blk = ACPI_BASE_ADDRESS;
int plen = 6;
int totalcores = dev_count_cpu();
int cores_per_package = get_cores_per_package();
int numcpus = totalcores / cores_per_package;
printk(BIOS_DEBUG, "Found %d CPU(s) with %d core(s) each.\n",
numcpus, cores_per_package);
for (cpu_id = 0; cpu_id < numcpus; cpu_id++) {
for (core_id = 0; core_id < cores_per_package; core_id++) {
if (core_id > 0) {
pcontrol_blk = 0;
plen = 0;
}
/* Generate processor \_SB.CPUx */
acpigen_write_processor((cpu_id) * cores_per_package +
core_id, pcontrol_blk, plen);
/* Generate C-state tables */
generate_c_state_entries();
/* Soc specific power states generation */
soc_power_states_generation(core_id, cores_per_package);
acpigen_pop_len();
}
}
/* PPKG is usually used for thermal management
of the first and only package. */
acpigen_write_processor_package("PPKG", 0, cores_per_package);
/* Add a method to notify processor nodes */
acpigen_write_processor_cnot(cores_per_package);
}
#if CONFIG(SOC_INTEL_COMMON_ACPI_WAKE_SOURCE)
/* Save wake source data for ACPI _SWS methods in NVS */
static void acpi_save_wake_source(void *unused)
{
global_nvs_t *gnvs = acpi_get_gnvs();
uint32_t pm1, *gpe0;
int gpe_reg, gpe_reg_count;
int reg_size = sizeof(uint32_t) * 8;
if (!gnvs)
return;
gnvs->pm1i = -1;
gnvs->gpei = -1;
gpe_reg_count = acpi_fill_wake(&pm1, &gpe0);
if (gpe_reg_count < 0)
return;
/* Scan for first set bit in PM1 */
for (gnvs->pm1i = 0; gnvs->pm1i < reg_size; gnvs->pm1i++) {
if (pm1 & 1)
break;
pm1 >>= 1;
}
/* If unable to determine then return -1 */
if (gnvs->pm1i >= 16)
gnvs->pm1i = -1;
/* Scan for first set bit in GPE registers */
for (gpe_reg = 0; gpe_reg < gpe_reg_count; gpe_reg++) {
uint32_t gpe = gpe0[gpe_reg];
int start = gpe_reg * reg_size;
int end = start + reg_size;
if (gpe == 0) {
if (!gnvs->gpei)
gnvs->gpei = end;
continue;
}
for (gnvs->gpei = start; gnvs->gpei < end; gnvs->gpei++) {
if (gpe & 1)
break;
gpe >>= 1;
}
}
/* If unable to determine then return -1 */
if (gnvs->gpei >= gpe_reg_count * reg_size)
gnvs->gpei = -1;
printk(BIOS_DEBUG, "ACPI _SWS is PM1 Index %lld GPE Index %lld\n",
(long long)gnvs->pm1i, (long long)gnvs->gpei);
}
BOOT_STATE_INIT_ENTRY(BS_OS_RESUME, BS_ON_ENTRY, acpi_save_wake_source, NULL);
#endif
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