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|
/*
* This file is part of the coreboot project.
*
* Copyright (C) 2007-2009 coresystems GmbH
* Copyright (C) 2013 Google Inc.
* Copyright (C) 2015-2016 Intel Corp.
* Copyright (C) 2016-2018 Siemens AG
*
* 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 <string.h>
#include <types.h>
#include <arch/acpigen.h>
#include <arch/cpu.h>
#include <arch/io.h>
#include <arch/smp/mpspec.h>
#include <console/console.h>
#include <cpu/x86/msr.h>
#include <cpu/intel/speedstep.h>
#include <cpu/intel/turbo.h>
#include <device/device.h>
#include <device/pci.h>
#include <device/pci_ids.h>
#include <soc/acpi.h>
#include <soc/iomap.h>
#include <soc/irq.h>
#include <soc/lpc.h>
#include <soc/msr.h>
#include <soc/pattrs.h>
#include <soc/pci_devs.h>
#include <soc/broadwell_de.h>
#include <chip.h>
uint16_t get_pmbase(void)
{
return ACPI_BASE_ADDRESS;
}
#define MWAIT_RES(state, sub_state) \
{ \
.addrl = (((state) << 4) | (sub_state)), \
.space_id = ACPI_ADDRESS_SPACE_FIXED, \
.bit_width = ACPI_FFIXEDHW_VENDOR_INTEL, \
.bit_offset = ACPI_FFIXEDHW_CLASS_MWAIT, \
.access_size = ACPI_FFIXEDHW_FLAG_HW_COORD, \
}
/* C-state map */
static acpi_cstate_t cstate_map[] = {
{
/* C1 */
.ctype = 1, /* ACPI C1 */
.latency = 1,
.power = 1000,
.resource = MWAIT_RES(0, 0),
},
{
/* C3 */
.ctype = 2, /* ACPI C2 */
.latency = 15,
.power = 500,
.resource = MWAIT_RES(1, 0),
},
{
/* C6 */
.ctype = 3, /* ACPI C3 */
.latency = 41,
.power = 350,
.resource = MWAIT_RES(2, 0),
}
};
static int acpi_sci_irq(void)
{
uint8_t actl = 0;
static uint8_t sci_irq = 0;
struct device *dev = dev_find_slot(0, PCI_DEVFN(LPC_DEV, LPC_FUNC));
/* If this function was already called, just return the stored value. */
if (sci_irq)
return sci_irq;
/* Get contents of ACPI control register. */
actl = pci_read_config8(dev, ACPI_CNTL_OFFSET) & SCIS_MASK;
/* Determine how SCI is routed. */
switch (actl) {
case SCIS_IRQ9:
case SCIS_IRQ10:
case SCIS_IRQ11:
sci_irq = actl + 9;
break;
case SCIS_IRQ20:
case SCIS_IRQ21:
case SCIS_IRQ22:
case SCIS_IRQ23:
sci_irq = actl - 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;
}
void acpi_create_intel_hpet(acpi_hpet_t *hpet)
{
acpi_header_t *header = &(hpet->header);
acpi_addr_t *addr = &(hpet->addr);
memset((void *) hpet, 0, sizeof(acpi_hpet_t));
/* fill out header fields */
memcpy(header->signature, "HPET", 4);
memcpy(header->oem_id, OEM_ID, 6);
memcpy(header->oem_table_id, ACPI_TABLE_CREATOR, 8);
memcpy(header->asl_compiler_id, ASLC, 4);
header->length = sizeof(acpi_hpet_t);
header->revision = get_acpi_table_revision(HPET);
/* fill out HPET address */
addr->space_id = 0; /* Memory */
addr->bit_width = 64;
addr->bit_offset = 0;
addr->addrl = (unsigned long long)HPET_BASE_ADDRESS & 0xffffffff;
addr->addrh = (unsigned long long)HPET_BASE_ADDRESS >> 32;
hpet->id = 0x8086a201; /* Intel */
hpet->number = 0x00;
hpet->min_tick = 0x0080;
header->checksum = acpi_checksum((void *) hpet, sizeof(acpi_hpet_t));
}
unsigned long acpi_fill_mcfg(unsigned long current)
{
current += acpi_create_mcfg_mmconfig((acpi_mcfg_mmconfig_t *)current,
MCFG_BASE_ADDRESS, 0, 0, 255);
return current;
}
/**
* Fill in the fadt with generic values that can be overridden later.
*/
void acpi_fill_in_fadt(acpi_fadt_t *fadt, acpi_facs_t *facs, void *dsdt)
{
acpi_header_t *header = &(fadt->header);
u16 pmbase = get_pmbase();
memset((void *) fadt, 0, sizeof(acpi_fadt_t));
/*
* Reference section 5.2.9 Fixed ACPI Description Table (FADT)
* in the ACPI 3.0b specification.
*/
/* FADT Header Structure */
memcpy(header->signature, "FACP", 4);
header->length = sizeof(acpi_fadt_t);
header->revision = get_acpi_table_revision(FADT);
memcpy(header->oem_id, OEM_ID, 6);
memcpy(header->oem_table_id, ACPI_TABLE_CREATOR, 8);
memcpy(header->asl_compiler_id, ASLC, 4);
header->asl_compiler_revision = 1;
/* ACPI Pointers */
fadt->firmware_ctrl = (unsigned long) facs;
fadt->dsdt = (unsigned long) dsdt;
fadt->model = 0; /* reserved, should be 0 ACPI 3.0 */
fadt->preferred_pm_profile = 0;
fadt->sci_int = acpi_sci_irq();
/* System Management */
fadt->smi_cmd = 0x00; /* disable SMM */
fadt->acpi_enable = 0x00; /* unused if SMI_CMD = 0 */
fadt->acpi_disable = 0x00; /* unused if SMI_CMD = 0 */
/* Enable ACPI */
outl(inl(pmbase + 4) | 0x01, pmbase + 4);
/* Power Control */
fadt->s4bios_req = 0x00;
fadt->pstate_cnt = 0x00;
/* Control Registers - Base Address */
fadt->pm1a_evt_blk = pmbase + PM1_STS;
fadt->pm1b_evt_blk = 0x00; /* Not Used */
fadt->pm1a_cnt_blk = pmbase + PM1_CNT;
fadt->pm1b_cnt_blk = 0x00; /* Not Used */
fadt->pm2_cnt_blk = pmbase + PM2A_CNT_BLK;
fadt->pm_tmr_blk = pmbase + PM1_TMR;
fadt->gpe0_blk = pmbase + GPE0_STS;
fadt->gpe1_blk = 0x00; /* Not Used */
/* Control Registers - Length */
fadt->pm1_evt_len = 4; /* 32 bits */
fadt->pm1_cnt_len = 2; /* 32 bit register, 16 bits used */
fadt->pm2_cnt_len = 1; /* 8 bits */
fadt->pm_tmr_len = 4; /* 32 bits */
fadt->gpe0_blk_len = 8; /* 64 bits */
fadt->gpe1_blk_len = 0;
fadt->gpe1_base = 0;
fadt->cst_cnt = 0;
fadt->p_lvl2_lat = ACPI_FADT_C2_NOT_SUPPORTED;
fadt->p_lvl3_lat = ACPI_FADT_C3_NOT_SUPPORTED;
fadt->flush_size = 0; /* set to 0 if WBINVD is 1 in flags */
fadt->flush_stride = 0; /* set to 0 if WBINVD is 1 in flags */
fadt->duty_offset = 1;
fadt->duty_width = 0;
/* RTC Registers */
fadt->day_alrm = 0x0D;
fadt->mon_alrm = 0x00;
fadt->century = 0x00;
fadt->iapc_boot_arch = 0;
fadt->flags = ACPI_FADT_WBINVD | ACPI_FADT_C1_SUPPORTED |
ACPI_FADT_C2_MP_SUPPORTED | ACPI_FADT_SLEEP_BUTTON |
ACPI_FADT_RESET_REGISTER | ACPI_FADT_SLEEP_TYPE |
ACPI_FADT_S4_RTC_WAKE | ACPI_FADT_PLATFORM_CLOCK;
/* Reset Register */
fadt->reset_reg.space_id = ACPI_ADDRESS_SPACE_IO;
fadt->reset_reg.bit_width = 8;
fadt->reset_reg.bit_offset = 0;
fadt->reset_reg.access_size = ACPI_ACCESS_SIZE_BYTE_ACCESS;
fadt->reset_reg.addrl = 0xCF9;
fadt->reset_reg.addrh = 0x00;
fadt->reset_value = 6;
/* Reserved Bits */
fadt->res3 = 0x00; /* reserved, MUST be 0 ACPI 3.0 */
fadt->res4 = 0x00; /* reserved, MUST be 0 ACPI 3.0 */
fadt->res5 = 0x00; /* reserved, MUST be 0 ACPI 3.0 */
/* Extended ACPI Pointers */
fadt->x_firmware_ctl_l = (unsigned long)facs;
fadt->x_firmware_ctl_h = 0x00;
fadt->x_dsdt_l = (unsigned long)dsdt;
fadt->x_dsdt_h = 0x00;
/* PM1 Status & PM1 Enable */
fadt->x_pm1a_evt_blk.space_id = ACPI_ADDRESS_SPACE_IO;
fadt->x_pm1a_evt_blk.bit_width = fadt->pm1_evt_len * 8;
fadt->x_pm1a_evt_blk.bit_offset = 0;
fadt->x_pm1a_evt_blk.access_size = ACPI_ACCESS_SIZE_DWORD_ACCESS;
fadt->x_pm1a_evt_blk.addrl = fadt->pm1a_evt_blk;
fadt->x_pm1a_evt_blk.addrh = 0x00;
fadt->x_pm1b_evt_blk.space_id = ACPI_ADDRESS_SPACE_IO;
fadt->x_pm1b_evt_blk.bit_width = 0;
fadt->x_pm1b_evt_blk.bit_offset = 0;
fadt->x_pm1b_evt_blk.access_size = 0;
fadt->x_pm1b_evt_blk.addrl = fadt->pm1b_evt_blk;
fadt->x_pm1b_evt_blk.addrh = 0x00;
/* PM1 Control Registers */
fadt->x_pm1a_cnt_blk.space_id = ACPI_ADDRESS_SPACE_IO;
fadt->x_pm1a_cnt_blk.bit_width = 16;
fadt->x_pm1a_cnt_blk.bit_offset = 0;
fadt->x_pm1a_cnt_blk.access_size = ACPI_ACCESS_SIZE_WORD_ACCESS;
fadt->x_pm1a_cnt_blk.addrl = fadt->pm1a_cnt_blk;
fadt->x_pm1a_cnt_blk.addrh = 0x00;
fadt->x_pm1b_cnt_blk.space_id = ACPI_ADDRESS_SPACE_IO;
fadt->x_pm1b_cnt_blk.bit_width = 0;
fadt->x_pm1b_cnt_blk.bit_offset = 0;
fadt->x_pm1b_cnt_blk.access_size = 0;
fadt->x_pm1b_cnt_blk.addrl = fadt->pm1b_cnt_blk;
fadt->x_pm1b_cnt_blk.addrh = 0x00;
/* PM2 Control Registers */
fadt->x_pm2_cnt_blk.space_id = ACPI_ADDRESS_SPACE_IO;
fadt->x_pm2_cnt_blk.bit_width = 8;
fadt->x_pm2_cnt_blk.bit_offset = 0;
fadt->x_pm2_cnt_blk.access_size = ACPI_ACCESS_SIZE_BYTE_ACCESS;
fadt->x_pm2_cnt_blk.addrl = fadt->pm2_cnt_blk;
fadt->x_pm2_cnt_blk.addrh = 0x00;
/* PM1 Timer Register */
fadt->x_pm_tmr_blk.space_id = ACPI_ADDRESS_SPACE_IO;
fadt->x_pm_tmr_blk.bit_width = 32;
fadt->x_pm_tmr_blk.bit_offset = 0;
fadt->x_pm_tmr_blk.access_size = ACPI_ACCESS_SIZE_DWORD_ACCESS;
fadt->x_pm_tmr_blk.addrl = fadt->pm_tmr_blk;
fadt->x_pm_tmr_blk.addrh = 0x00;
/* General-Purpose Event Registers */
fadt->x_gpe0_blk.space_id = ACPI_ADDRESS_SPACE_IO;
fadt->x_gpe0_blk.bit_width = 64; /* EventStatus + EventEnable */
fadt->x_gpe0_blk.bit_offset = 0;
fadt->x_gpe0_blk.access_size = ACPI_ACCESS_SIZE_DWORD_ACCESS;
fadt->x_gpe0_blk.addrl = fadt->gpe0_blk;
fadt->x_gpe0_blk.addrh = 0x00;
fadt->x_gpe1_blk.space_id = ACPI_ADDRESS_SPACE_IO;
fadt->x_gpe1_blk.bit_width = 0;
fadt->x_gpe1_blk.bit_offset = 0;
fadt->x_gpe1_blk.access_size = 0;
fadt->x_gpe1_blk.addrl = fadt->gpe1_blk;
fadt->x_gpe1_blk.addrh = 0x00;
header->checksum = acpi_checksum((void *) fadt, sizeof(acpi_fadt_t));
}
static unsigned long acpi_fill_dmar(unsigned long current)
{
uint32_t vtbar, tmp = current;
struct device *dev = dev_find_slot(0, VTD_DEV_FUNC);
uint16_t bdf, hpet_bdf[8];
uint8_t i, j;
if (!dev)
return current;
vtbar = pci_read_config32(dev, VTBAR_OFFSET) & VTBAR_MASK;
if (!vtbar)
return current;
current += acpi_create_dmar_drhd(current,
DRHD_INCLUDE_PCI_ALL, 0, vtbar);
/* The IIO I/O APIC is fixed on PCI 00:05.4 on Broadwell-DE */
current += acpi_create_dmar_ds_ioapic(current,
9, 0, 5, 4);
/* Get the PCI BDF for the PCH I/O APIC */
dev = dev_find_slot(0, LPC_DEV_FUNC);
bdf = pci_read_config16(dev, 0x6c);
current += acpi_create_dmar_ds_ioapic(current,
8, (bdf >> 8), PCI_SLOT(bdf), PCI_FUNC(bdf));
/*
* Check if there are different PCI paths for the 8 HPET timers
* and add every different PCI path as a separate HPET entry.
* Although the DMAR specification talks about HPET block for this
* entry, it is possible to assign a unique PCI BDF to every single
* timer within a HPET block which will result in different source
* IDs reported by a generated MSI.
* In default configuration every single timer will have the same
* PCI BDF which will result in a single HPET entry in DMAR table.
* I have checked several different systems and all of them had one
* single entry for HPET in DMAR.
*/
memset(hpet_bdf, 0, sizeof(hpet_bdf));
/* Get all unique HPET paths. */
for (i = 0; i < ARRAY_SIZE(hpet_bdf); i++) {
bdf = pci_read_config16(dev, 0x70 + (i * 2));
for (j = 0; j < i; j++) {
if (hpet_bdf[j] == bdf)
break;
}
if (j == i)
hpet_bdf[i] = bdf;
}
/* Create one HPET entry in DMAR for every unique HPET PCI path. */
for (i = 0; i < ARRAY_SIZE(hpet_bdf); i++) {
if (hpet_bdf[i])
current += acpi_create_dmar_ds_msi_hpet(current,
0, (hpet_bdf[i] >> 8), PCI_SLOT(hpet_bdf[i]),
PCI_FUNC(hpet_bdf[i]));
}
acpi_dmar_drhd_fixup(tmp, current);
/* Create root port ATSR capability */
tmp = current;
current += acpi_create_dmar_atsr(current, 0, 0);
/* Add one entry to ATSR for each PCI root port */
dev = all_devices;
do {
dev = dev_find_class(PCI_CLASS_BRIDGE_PCI << 8, dev);
if (dev && dev->bus->secondary == 0 &&
PCI_SLOT(dev->path.pci.devfn) <= 3)
current += acpi_create_dmar_ds_pci_br(current,
dev->bus->secondary,
PCI_SLOT(dev->path.pci.devfn),
PCI_FUNC(dev->path.pci.devfn));
} while (dev);
acpi_dmar_atsr_fixup(tmp, current);
return current;
}
unsigned long vtd_write_acpi_tables(struct device *const dev,
unsigned long current,
struct acpi_rsdp *const rsdp)
{
acpi_dmar_t *const dmar = (acpi_dmar_t *)current;
/* Create DMAR table only if virtualization is enabled */
if (!(pci_read_config32(dev, VTBAR_OFFSET) & VTBAR_ENABLED))
return current;
printk(BIOS_DEBUG, "ACPI: * DMAR\n");
acpi_create_dmar(dmar, DMAR_INTR_REMAP, acpi_fill_dmar);
current += dmar->header.length;
current = acpi_align_current(current);
acpi_add_table(rsdp, dmar);
current = acpi_align_current(current);
return current;
}
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 (int)power;
}
static void generate_P_state_entries(int core, int cores_per_package)
{
int ratio_min, ratio_max, ratio_step;
int coord_type, power_max, power_unit, num_entries;
int ratio, power, clock, clock_max;
int turbo;
u32 control_status;
msr_t msr;
/* Hardware coordination of P-states */
coord_type = HW_ALL;
/* Check for Turbo Mode */
turbo = get_turbo_state() == TURBO_ENABLED;
/* CPU attributes */
msr = rdmsr(MSR_PLATFORM_INFO);
ratio_min = (msr.hi >> 8) & 0xff; // LFM
ratio_max = (msr.lo >> 8) & 0xff; // HFM
clock_max = (ratio_max * 100);
/* Calculate CPU TDP in mW */
msr = rdmsr(MSR_PKG_POWER_SKU_UNIT);
power_unit = 1 << (msr.lo & 0xf);
msr = rdmsr(MSR_PKG_POWER_LIMIT);
power_max = ((msr.lo & 0x7fff) / power_unit) * 1000;
/* Write _PCT indicating use of FFixedHW */
acpigen_write_empty_PCT();
/* Write _PPC starting from first supported P-state */
acpigen_write_PPC(0);
/* 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 */
/* Note: There should be at most 16 performance states. If Turbo Mode
is enabled, the Max Turbo Ratio will occupy one of these states. */
ratio_step = 1;
num_entries = (ratio_max - ratio_min) / ratio_step;
while (num_entries > (15-turbo)) {
ratio_step <<= 1;
num_entries >>= 1;
}
if (turbo) {
/* _PSS package count (with turbo) */
acpigen_write_package(num_entries + 2);
/* Get Max Turbo Ratio */
msr = rdmsr(MSR_TURBO_RATIO_LIMIT);
ratio = msr.lo & 0xff;
acpigen_write_PSS_package(
ratio * 100, /* MHz */
power_max, /* mW */
10, /* lat1 */
10, /* lat2 */
ratio << 8, /* control */
ratio << 8); /* status */
} else {
/* _PSS package count (without turbo) */
acpigen_write_package(num_entries + 1);
}
/* Generate the _PSS entries */
for (ratio = ratio_min + (num_entries * ratio_step);
ratio >= ratio_min; ratio -= ratio_step) {
/* Calculate power at this ratio */
power = calculate_power(power_max, ratio_max, ratio);
clock = ratio * 100;
control_status = ratio << 8;
acpigen_write_PSS_package(
clock, /* MHz */
power, /* mW */
10, /* lat1 */
10, /* lat2 */
control_status, /* control */
control_status); /* status */
}
/* Fix package length */
acpigen_pop_len();
}
void generate_cpu_entries(struct device *device)
{
int core;
int pcontrol_blk = get_pmbase(), plen = 6;
const struct pattrs *pattrs = pattrs_get();
for (core = 0; core < pattrs->num_cpus; core++) {
if (core > 0) {
pcontrol_blk = 0;
plen = 0;
}
/* Generate processor \_PR.CP0x */
acpigen_write_processor(core, pcontrol_blk, plen);
/* Generate P-state tables */
generate_P_state_entries(core, pattrs->num_cpus);
/* Generate C-state tables */
acpigen_write_CST_package(cstate_map, ARRAY_SIZE(cstate_map));
acpigen_pop_len();
}
}
unsigned long acpi_madt_irq_overrides(unsigned long current)
{
int sci_irq = acpi_sci_irq();
acpi_madt_irqoverride_t *irqovr;
uint16_t sci_flags = MP_IRQ_TRIGGER_LEVEL;
/* INT_SRC_OVR */
irqovr = (void *)current;
current += acpi_create_madt_irqoverride(irqovr, 0, 0, 2, 0);
if (sci_irq >= 20)
sci_flags |= MP_IRQ_POLARITY_LOW;
else
sci_flags |= MP_IRQ_POLARITY_HIGH;
irqovr = (void *)current;
current += acpi_create_madt_irqoverride(irqovr, 0, sci_irq, sci_irq,
sci_flags);
return current;
}
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