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/*
* This file is part of the coreboot project.
*
* Copyright (C) 2017-2018 Intel Corporation.
*
* 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 <arch/cpu.h>
#include <console/console.h>
#include <device/pci.h>
#include <cpu/x86/lapic.h>
#include <cpu/x86/mp.h>
#include <cpu/x86/msr.h>
#include <cpu/intel/smm_reloc.h>
#include <cpu/intel/turbo.h>
#include <intelblocks/cpulib.h>
#include <intelblocks/mp_init.h>
#include <romstage_handoff.h>
#include <soc/cpu.h>
#include <soc/msr.h>
#include <soc/pci_devs.h>
#include <soc/pm.h>
#include <soc/systemagent.h>
#include <cpu/x86/mtrr.h>
#include <cpu/intel/microcode.h>
#include <cpu/intel/common/common.h>
#include "chip.h"
/* Convert time in seconds to POWER_LIMIT_1_TIME MSR value */
static const u8 power_limit_time_sec_to_msr[] = {
[0] = 0x00,
[1] = 0x0a,
[2] = 0x0b,
[3] = 0x4b,
[4] = 0x0c,
[5] = 0x2c,
[6] = 0x4c,
[7] = 0x6c,
[8] = 0x0d,
[10] = 0x2d,
[12] = 0x4d,
[14] = 0x6d,
[16] = 0x0e,
[20] = 0x2e,
[24] = 0x4e,
[28] = 0x6e,
[32] = 0x0f,
[40] = 0x2f,
[48] = 0x4f,
[56] = 0x6f,
[64] = 0x10,
[80] = 0x30,
[96] = 0x50,
[112] = 0x70,
[128] = 0x11,
};
/* Convert POWER_LIMIT_1_TIME MSR value to seconds */
static const u8 power_limit_time_msr_to_sec[] = {
[0x00] = 0,
[0x0a] = 1,
[0x0b] = 2,
[0x4b] = 3,
[0x0c] = 4,
[0x2c] = 5,
[0x4c] = 6,
[0x6c] = 7,
[0x0d] = 8,
[0x2d] = 10,
[0x4d] = 12,
[0x6d] = 14,
[0x0e] = 16,
[0x2e] = 20,
[0x4e] = 24,
[0x6e] = 28,
[0x0f] = 32,
[0x2f] = 40,
[0x4f] = 48,
[0x6f] = 56,
[0x10] = 64,
[0x30] = 80,
[0x50] = 96,
[0x70] = 112,
[0x11] = 128,
};
/*
* Configure processor power limits if possible
* This must be done AFTER set of BIOS_RESET_CPL
*/
void set_power_limits(u8 power_limit_1_time)
{
msr_t msr = rdmsr(MSR_PLATFORM_INFO);
msr_t limit;
unsigned int power_unit;
unsigned int tdp, min_power, max_power, max_time, tdp_pl2, tdp_pl1;
u8 power_limit_1_val;
config_t *conf = config_of_soc();
if (power_limit_1_time >= ARRAY_SIZE(power_limit_time_sec_to_msr))
power_limit_1_time = ARRAY_SIZE(power_limit_time_sec_to_msr) - 1;
if (!(msr.lo & PLATFORM_INFO_SET_TDP))
return;
/* Get units */
msr = rdmsr(MSR_PKG_POWER_SKU_UNIT);
power_unit = 1 << (msr.lo & 0xf);
/* Get power defaults for this SKU */
msr = rdmsr(MSR_PKG_POWER_SKU);
tdp = msr.lo & 0x7fff;
min_power = (msr.lo >> 16) & 0x7fff;
max_power = msr.hi & 0x7fff;
max_time = (msr.hi >> 16) & 0x7f;
printk(BIOS_DEBUG, "CPU TDP: %u Watts\n", tdp / power_unit);
if (power_limit_time_msr_to_sec[max_time] > power_limit_1_time)
power_limit_1_time = power_limit_time_msr_to_sec[max_time];
if (min_power > 0 && tdp < min_power)
tdp = min_power;
if (max_power > 0 && tdp > max_power)
tdp = max_power;
power_limit_1_val = power_limit_time_sec_to_msr[power_limit_1_time];
/* Set long term power limit to TDP */
limit.lo = 0;
tdp_pl1 = ((conf->tdp_pl1_override == 0) ?
tdp : (conf->tdp_pl1_override * power_unit));
limit.lo |= (tdp_pl1 & PKG_POWER_LIMIT_MASK);
/* Set PL1 Pkg Power clamp bit */
limit.lo |= PKG_POWER_LIMIT_CLAMP;
limit.lo |= PKG_POWER_LIMIT_EN;
limit.lo |= (power_limit_1_val & PKG_POWER_LIMIT_TIME_MASK) <<
PKG_POWER_LIMIT_TIME_SHIFT;
/* Set short term power limit to 1.25 * TDP if no config given */
limit.hi = 0;
tdp_pl2 = (conf->tdp_pl2_override == 0) ?
(tdp * 125) / 100 : (conf->tdp_pl2_override * power_unit);
printk(BIOS_DEBUG, "CPU PL2 = %u Watts\n", tdp_pl2 / power_unit);
limit.hi |= (tdp_pl2) & PKG_POWER_LIMIT_MASK;
limit.hi |= PKG_POWER_LIMIT_CLAMP;
limit.hi |= PKG_POWER_LIMIT_EN;
/* Power limit 2 time is only programmable on server SKU */
wrmsr(MSR_PKG_POWER_LIMIT, limit);
/* Set PL2 power limit values in MCHBAR and disable PL1 */
MCHBAR32(MCH_PKG_POWER_LIMIT_LO) = limit.lo & (~(PKG_POWER_LIMIT_EN));
MCHBAR32(MCH_PKG_POWER_LIMIT_HI) = limit.hi;
/* Set PsysPl2 */
if (conf->tdp_psyspl2) {
limit = rdmsr(MSR_PLATFORM_POWER_LIMIT);
limit.hi = 0;
printk(BIOS_DEBUG, "CPU PsysPL2 = %u Watts\n",
conf->tdp_psyspl2);
limit.hi |= (conf->tdp_psyspl2 * power_unit) &
PKG_POWER_LIMIT_MASK;
limit.hi |= PKG_POWER_LIMIT_CLAMP;
limit.hi |= PKG_POWER_LIMIT_EN;
wrmsr(MSR_PLATFORM_POWER_LIMIT, limit);
}
/* Set PsysPl3 */
if (conf->tdp_psyspl3) {
limit = rdmsr(MSR_PL3_CONTROL);
limit.lo = 0;
printk(BIOS_DEBUG, "CPU PsysPL3 = %u Watts\n",
conf->tdp_psyspl3);
limit.lo |= (conf->tdp_psyspl3 * power_unit) &
PKG_POWER_LIMIT_MASK;
/* Enable PsysPl3 */
limit.lo |= PKG_POWER_LIMIT_EN;
/* set PsysPl3 time window */
limit.lo |= (conf->tdp_psyspl3_time &
PKG_POWER_LIMIT_TIME_MASK) <<
PKG_POWER_LIMIT_TIME_SHIFT;
/* set PsysPl3 duty cycle */
limit.lo |= (conf->tdp_psyspl3_dutycycle &
PKG_POWER_LIMIT_DUTYCYCLE_MASK) <<
PKG_POWER_LIMIT_DUTYCYCLE_SHIFT;
wrmsr(MSR_PL3_CONTROL, limit);
}
/* Set Pl4 */
if (conf->tdp_pl4) {
limit = rdmsr(MSR_VR_CURRENT_CONFIG);
limit.lo = 0;
printk(BIOS_DEBUG, "CPU PL4 = %u Watts\n",
conf->tdp_pl4);
limit.lo |= (conf->tdp_pl4 * power_unit) &
PKG_POWER_LIMIT_MASK;
wrmsr(MSR_VR_CURRENT_CONFIG, limit);
}
/* Set DDR RAPL power limit by copying from MMIO to MSR */
msr.lo = MCHBAR32(MCH_DDR_POWER_LIMIT_LO);
msr.hi = MCHBAR32(MCH_DDR_POWER_LIMIT_HI);
wrmsr(MSR_DDR_RAPL_LIMIT, msr);
/* Use nominal TDP values for CPUs with configurable TDP */
if (cpu_config_tdp_levels()) {
limit.hi = 0;
limit.lo = cpu_get_tdp_nominal_ratio();
wrmsr(MSR_TURBO_ACTIVATION_RATIO, limit);
}
}
static void soc_fsp_load(void)
{
fsps_load(romstage_handoff_is_resume());
}
static void configure_isst(void)
{
config_t *conf = config_of_soc();
msr_t msr;
if (conf->speed_shift_enable) {
/*
* Kernel driver checks CPUID.06h:EAX[Bit 7] to determine if HWP
* is supported or not. coreboot needs to configure MSR 0x1AA
* which is then reflected in the CPUID register.
*/
msr = rdmsr(MSR_MISC_PWR_MGMT);
msr.lo |= MISC_PWR_MGMT_ISST_EN; /* Enable Speed Shift */
msr.lo |= MISC_PWR_MGMT_ISST_EN_INT; /* Enable Interrupt */
msr.lo |= MISC_PWR_MGMT_ISST_EN_EPP; /* Enable EPP */
wrmsr(MSR_MISC_PWR_MGMT, msr);
} else {
msr = rdmsr(MSR_MISC_PWR_MGMT);
msr.lo &= ~MISC_PWR_MGMT_ISST_EN; /* Disable Speed Shift */
msr.lo &= ~MISC_PWR_MGMT_ISST_EN_INT; /* Disable Interrupt */
msr.lo &= ~MISC_PWR_MGMT_ISST_EN_EPP; /* Disable EPP */
wrmsr(MSR_MISC_PWR_MGMT, msr);
}
}
static void configure_misc(void)
{
config_t *conf = config_of_soc();
msr_t msr;
msr = rdmsr(IA32_MISC_ENABLE);
msr.lo |= (1 << 0); /* Fast String enable */
msr.lo |= (1 << 3); /* TM1/TM2/EMTTM enable */
/* Set EIST status */
cpu_set_eist(conf->eist_enable);
wrmsr(IA32_MISC_ENABLE, msr);
/* Disable Thermal interrupts */
msr.lo = 0;
msr.hi = 0;
wrmsr(IA32_THERM_INTERRUPT, msr);
/* Enable package critical interrupt only */
msr.lo = 1 << 4;
msr.hi = 0;
wrmsr(IA32_PACKAGE_THERM_INTERRUPT, msr);
/* Enable PROCHOT */
msr = rdmsr(MSR_POWER_CTL);
msr.lo |= (1 << 0); /* Enable Bi-directional PROCHOT as an input*/
msr.lo |= (1 << 23); /* Lock it */
wrmsr(MSR_POWER_CTL, msr);
}
static void enable_lapic_tpr(void)
{
msr_t msr;
msr = rdmsr(MSR_PIC_MSG_CONTROL);
msr.lo &= ~(1 << 10); /* Enable APIC TPR updates */
wrmsr(MSR_PIC_MSG_CONTROL, msr);
}
static void configure_dca_cap(void)
{
uint32_t feature_flag;
msr_t msr;
/* Check feature flag in CPUID.(EAX=1):ECX[18]==1 */
feature_flag = cpu_get_feature_flags_ecx();
if (feature_flag & CPUID_DCA) {
msr = rdmsr(IA32_PLATFORM_DCA_CAP);
msr.lo |= 1;
wrmsr(IA32_PLATFORM_DCA_CAP, msr);
}
}
static void set_energy_perf_bias(u8 policy)
{
msr_t msr;
int ecx;
/* Determine if energy efficient policy is supported. */
ecx = cpuid_ecx(0x6);
if (!(ecx & (1 << 3)))
return;
/* Energy Policy is bits 3:0 */
msr = rdmsr(IA32_ENERGY_PERF_BIAS);
msr.lo &= ~0xf;
msr.lo |= policy & 0xf;
wrmsr(IA32_ENERGY_PERF_BIAS, msr);
}
static void configure_c_states(void)
{
msr_t msr;
/* C-state Interrupt Response Latency Control 1 - package C6/C7 short */
msr.hi = 0;
msr.lo = IRTL_VALID | IRTL_32768_NS | C_STATE_LATENCY_CONTROL_1_LIMIT;
wrmsr(MSR_C_STATE_LATENCY_CONTROL_1, msr);
/* C-state Interrupt Response Latency Control 2 - package C6/C7 long */
msr.hi = 0;
msr.lo = IRTL_VALID | IRTL_32768_NS | C_STATE_LATENCY_CONTROL_2_LIMIT;
wrmsr(MSR_C_STATE_LATENCY_CONTROL_2, msr);
/* C-state Interrupt Response Latency Control 3 - package C8 */
msr.hi = 0;
msr.lo = IRTL_VALID | IRTL_32768_NS |
C_STATE_LATENCY_CONTROL_3_LIMIT;
wrmsr(MSR_C_STATE_LATENCY_CONTROL_3, msr);
/* C-state Interrupt Response Latency Control 4 - package C9 */
msr.hi = 0;
msr.lo = IRTL_VALID | IRTL_32768_NS |
C_STATE_LATENCY_CONTROL_4_LIMIT;
wrmsr(MSR_C_STATE_LATENCY_CONTROL_4, msr);
/* C-state Interrupt Response Latency Control 5 - package C10 */
msr.hi = 0;
msr.lo = IRTL_VALID | IRTL_32768_NS |
C_STATE_LATENCY_CONTROL_5_LIMIT;
wrmsr(MSR_C_STATE_LATENCY_CONTROL_5, msr);
}
static void configure_thermal_target(void)
{
config_t *conf = config_of_soc();
msr_t msr;
/* Set TCC activation offset if supported */
msr = rdmsr(MSR_PLATFORM_INFO);
if ((msr.lo & (1 << 30)) && conf->tcc_offset) {
msr = rdmsr(MSR_TEMPERATURE_TARGET);
msr.lo &= ~(0xf << 24); /* Bits 27:24 */
msr.lo |= (conf->tcc_offset & 0xf) << 24;
wrmsr(MSR_TEMPERATURE_TARGET, msr);
}
msr = rdmsr(MSR_TEMPERATURE_TARGET);
msr.lo &= ~0x7f; /* Bits 6:0 */
msr.lo |= 0xe6; /* setting 100ms thermal time window */
wrmsr(MSR_TEMPERATURE_TARGET, msr);
}
/*
* The emulated ACPI timer allows replacing of the ACPI timer
* (PM1_TMR) to have no impart on the system.
*/
static void enable_pm_timer_emulation(void)
{
const struct soc_intel_cannonlake_config *config;
msr_t msr;
config = config_of_soc();
/* Enable PM timer emulation only if ACPI PM timer is disabled */
if (!config->PmTimerDisabled)
return;
/*
* The derived frequency is calculated as follows:
* (CTC_FREQ * msr[63:32]) >> 32 = target frequency.
* Back solve the multiplier so the 3.579545MHz ACPI timer
* frequency is used.
*/
msr.hi = (3579545ULL << 32) / CTC_FREQ;
/* Set PM1 timer IO port and enable */
msr.lo = (EMULATE_DELAY_VALUE << EMULATE_DELAY_OFFSET_VALUE) |
EMULATE_PM_TMR_EN | (ACPI_BASE_ADDRESS + PM1_TMR);
wrmsr(MSR_EMULATE_PM_TIMER, msr);
}
/* All CPUs including BSP will run the following function. */
void soc_core_init(struct device *cpu)
{
/* Clear out pending MCEs */
/* TODO(adurbin): This should only be done on a cold boot. Also, some
* of these banks are core vs package scope. For now every CPU clears
* every bank. */
mca_configure();
/* Enable the local CPU apics */
enable_lapic_tpr();
setup_lapic();
/* Configure c-state interrupt response time */
configure_c_states();
/* Configure Enhanced SpeedStep and Thermal Sensors */
configure_misc();
/* Configure Intel Speed Shift */
configure_isst();
/* Enable ACPI Timer Emulation via MSR 0x121 */
enable_pm_timer_emulation();
/* Enable Direct Cache Access */
configure_dca_cap();
/* Set energy policy */
set_energy_perf_bias(ENERGY_POLICY_NORMAL);
/* Enable Turbo */
enable_turbo();
/* Enable Vmx */
set_vmx_and_lock();
}
static void per_cpu_smm_trigger(void)
{
/* Relocate the SMM handler. */
smm_relocate();
}
static void post_mp_init(void)
{
/* Set Max Ratio */
cpu_set_max_ratio();
/*
* Now that all APs have been relocated as well as the BSP let SMIs
* start flowing.
*/
smm_southbridge_enable(GBL_EN);
/* Lock down the SMRAM space. */
smm_lock();
}
static const struct mp_ops mp_ops = {
/*
* Skip Pre MP init MTRR programming as MTRRs are mirrored from BSP,
* that are set prior to ramstage.
* Real MTRRs programming are being done after resource allocation.
*/
.pre_mp_init = soc_fsp_load,
.get_cpu_count = get_cpu_count,
.get_smm_info = smm_info,
.get_microcode_info = get_microcode_info,
.pre_mp_smm_init = smm_initialize,
.per_cpu_smm_trigger = per_cpu_smm_trigger,
.relocation_handler = smm_relocation_handler,
.post_mp_init = post_mp_init,
};
void soc_init_cpus(struct bus *cpu_bus)
{
if (mp_init_with_smm(cpu_bus, &mp_ops))
printk(BIOS_ERR, "MP initialization failure.\n");
/* Thermal throttle activation offset */
configure_thermal_target();
}
int soc_skip_ucode_update(u32 current_patch_id, u32 new_patch_id)
{
msr_t msr1;
msr_t msr2;
/*
* CFL and WHL CPU die are based on KBL CPU so we need to
* have this check, where CNL CPU die is not based on KBL CPU
* so skip this check for CNL.
*/
if (!CONFIG(SOC_INTEL_CANNONLAKE_ALTERNATE_HEADERS))
return 0;
/*
* If PRMRR/SGX is supported the FIT microcode load will set the msr
* 0x08b with the Patch revision id one less than the id in the
* microcode binary. The PRMRR support is indicated in the MSR
* MTRRCAP[12]. If SGX is not enabled, check and avoid reloading the
* same microcode during CPU initialization. If SGX is enabled, as
* part of SGX BIOS initialization steps, the same microcode needs to
* be reloaded after the core PRMRR MSRs are programmed.
*/
msr1 = rdmsr(MTRR_CAP_MSR);
msr2 = rdmsr(MSR_PRMRR_PHYS_BASE);
if (msr2.lo && (current_patch_id == new_patch_id - 1))
return 0;
return (msr1.lo & PRMRR_SUPPORTED) &&
(current_patch_id == new_patch_id - 1);
}
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