src/soc/intel/common/block/systemagent/systemagent.c - coreboot - Gitiles

 /* SPDX-License-Identifier: GPL-2.0-only */

 #include <cbmem.h>
 #include <console/console.h>
 #include <cpu/cpu.h>
 #include <device/device.h>
 #include <device/pci.h>
 #include <device/pci_ids.h>
 #include <intelblocks/acpi.h>
 #include <intelblocks/cfg.h>
 #include <intelblocks/systemagent.h>
 #include <smbios.h>
 #include <soc/iomap.h>
 #include <soc/nvs.h>
 #include <soc/pci_devs.h>
 #include <soc/systemagent.h>
 #include <types.h>
 #include "systemagent_def.h"

 /* SoC override function */
 __weak void soc_systemagent_init(struct device *dev)
 {
 	/* no-op */
 }

 __weak void soc_add_fixed_mmio_resources(struct device *dev,
 		int *resource_cnt)
 {
 	/* no-op */
 }

 __weak int soc_get_uncore_prmmr_base_and_mask(uint64_t *base,
 		uint64_t *mask)
 {
 	/* return failure for this dummy API */
 	return -1;
 }

 __weak unsigned long sa_write_acpi_tables(const struct device *dev,
 					  unsigned long current,
 					  struct acpi_rsdp *rsdp)
 {
 	return current;
 }

 __weak uint32_t soc_systemagent_max_chan_capacity_mib(u8 capid0_a_ddrsz)
 {
 	return 32768;	/* 32 GiB per channel */
 }

 static uint8_t sa_get_ecc_type(const uint32_t capid0_a)
 {
 	return capid0_a & CAPID_ECCDIS ? MEMORY_ARRAY_ECC_NONE : MEMORY_ARRAY_ECC_SINGLE_BIT;
 }

 static size_t sa_slots_per_channel(const uint32_t capid0_a)
 {
 	return !(capid0_a & CAPID_DDPCD) + 1;
 }

 static size_t sa_number_of_channels(const uint32_t capid0_a)
 {
 	return !(capid0_a & CAPID_PDCD) + 1;
 }

 static void sa_soc_systemagent_init(struct device *dev)
 {
 	soc_systemagent_init(dev);

 	struct memory_info *m = cbmem_find(CBMEM_ID_MEMINFO);
 	if (m == NULL)
 		return;

 	const uint32_t capid0_a = pci_read_config32(dev, CAPID0_A);

 	m->ecc_type = sa_get_ecc_type(capid0_a);
 	m->max_capacity_mib = soc_systemagent_max_chan_capacity_mib(CAPID_DDRSZ(capid0_a)) *
 			      sa_number_of_channels(capid0_a);
 	m->number_of_devices = sa_slots_per_channel(capid0_a) *
 			       sa_number_of_channels(capid0_a);
 }

 /*
  * Add all known fixed MMIO ranges that hang off the host bridge/memory
  * controller device.
  */
 void sa_add_fixed_mmio_resources(struct device *dev, int *resource_cnt,
 	const struct sa_mmio_descriptor *sa_fixed_resources, size_t count)
 {
 	int i;
 	int index = *resource_cnt;

 	for (i = 0; i < count; i++) {
 		uintptr_t base;
 		size_t size;

 		size = sa_fixed_resources[i].size;
 		base = sa_fixed_resources[i].base;

 		mmio_resource(dev, index++, base / KiB, size / KiB);
 	}

 	*resource_cnt = index;
 }

 /*
  * DRAM memory mapped register
  *
  * TOUUD: This 64 bit register defines the Top of Upper Usable DRAM
  * TOLUD: This 32 bit register defines the Top of Low Usable DRAM
  * BGSM: This register contains the base address of stolen DRAM memory for GTT
  * TSEG: This register contains the base address of TSEG DRAM memory
  */
 static const struct sa_mem_map_descriptor sa_memory_map[MAX_MAP_ENTRIES] = {
 	{ TOUUD, true, "TOUUD" },
 	{ TOLUD, false, "TOLUD" },
 	{ BGSM, false, "BGSM" },
 	{ TSEG, false, "TSEG" },
 };

 /* Read DRAM memory map register value through PCI configuration space */
 static void sa_read_map_entry(struct device *dev,
 		const struct sa_mem_map_descriptor *entry, uint64_t *result)
 {
 	uint64_t value = 0;

 	if (entry->is_64_bit) {
 		value = pci_read_config32(dev, entry->reg + 4);
 		value <<= 32;
 	}

 	value |= pci_read_config32(dev, entry->reg);
 	/* All registers are on a 1MiB granularity. */
 	value = ALIGN_DOWN(value, 1 * MiB);

 	*result = value;
 }

 /* Fill MMIO resource above 4GB into GNVS */
 void sa_fill_gnvs(struct global_nvs *gnvs)
 {
 	struct device *sa_dev = pcidev_path_on_root(SA_DEVFN_ROOT);

 	sa_read_map_entry(sa_dev, &sa_memory_map[SA_TOUUD_REG], &gnvs->a4gb);
 	gnvs->a4gs = POWER_OF_2(cpu_phys_address_size()) - gnvs->a4gb;
 	printk(BIOS_DEBUG, "PCI space above 4GB MMIO is at 0x%llx, len = 0x%llx\n",
 	       gnvs->a4gb, gnvs->a4gs);
 }

 static void sa_get_mem_map(struct device *dev, uint64_t *values)
 {
 	int i;
 	for (i = 0; i < MAX_MAP_ENTRIES; i++)
 		sa_read_map_entry(dev, &sa_memory_map[i], &values[i]);
 }

 /*
  * These are the host memory ranges that should be added:
  * - 0 -> 0xa0000: cacheable
  * - 0xc0000 -> top_of_ram : cacheable
  * - top_of_ram -> TOLUD: not cacheable with standard MTRRs and reserved
  * - 4GiB -> TOUUD: cacheable
  *
  * The default SMRAM space is reserved so that the range doesn't
  * have to be saved during S3 Resume. Once marked reserved the OS
  * cannot use the memory. This is a bit of an odd place to reserve
  * the region, but the CPU devices don't have dev_ops->read_resources()
  * called on them.
  *
  * The range 0xa0000 -> 0xc0000 does not have any resources
  * associated with it to handle legacy VGA memory. If this range
  * is not omitted the mtrr code will setup the area as cacheable
  * causing VGA access to not work.
  *
  * Don't need to mark the entire top_of_ram till TOLUD range (used
  * for stolen memory like GFX and ME, PTT, DPR, PRMRR, TSEG etc) as
  * cacheable for OS usage as coreboot already done with mpinit w/ smm
  * relocation early.
  *
  * It should be noted that cacheable entry types need to be added in
  * order. The reason is that the current MTRR code assumes this and
  * falls over itself if it isn't.
  *
  * The resource index starts low and should not meet or exceed
  * PCI_BASE_ADDRESS_0.
  */
 static void sa_add_dram_resources(struct device *dev, int *resource_count)
 {
 	uintptr_t base_k, touud_k;
 	size_t size_k;
 	uint64_t sa_map_values[MAX_MAP_ENTRIES];
 	uintptr_t top_of_ram;
 	int index = *resource_count;

 	top_of_ram = (uintptr_t)cbmem_top();

 	/* 0 - > 0xa0000 */
 	base_k = 0;
 	size_k = (0xa0000 / KiB) - base_k;
 	ram_resource(dev, index++, base_k, size_k);

 	/* 0xc0000 -> top_of_ram */
 	base_k = 0xc0000 / KiB;
 	size_k = (top_of_ram / KiB) - base_k;
 	ram_resource(dev, index++, base_k, size_k);

 	sa_get_mem_map(dev, &sa_map_values[0]);

 	/* top_of_ram -> TOLUD */
 	base_k = top_of_ram;
 	size_k = sa_map_values[SA_TOLUD_REG] - base_k;
 	mmio_resource(dev, index++, base_k / KiB, size_k / KiB);

 	/* 4GiB -> TOUUD */
 	base_k = 4 * (GiB / KiB); /* 4GiB */
 	touud_k = sa_map_values[SA_TOUUD_REG] / KiB;
 	size_k = touud_k - base_k;
 	if (touud_k > base_k)
 		ram_resource(dev, index++, base_k, size_k);

 	/*
 	 * Reserve everything between A segment and 1MB:
 	 *
 	 * 0xa0000 - 0xbffff: legacy VGA
 	 * 0xc0000 - 0xfffff: RAM
 	 */
 	mmio_resource(dev, index++, 0xa0000 / KiB, (0xc0000 - 0xa0000) / KiB);
 	reserved_ram_resource(dev, index++, 0xc0000 / KiB,
 			(1*MiB - 0xc0000) / KiB);

 	*resource_count = index;
 }

 static bool is_imr_enabled(uint32_t imr_base_reg)
 {
 	return !!(imr_base_reg & (1 << 31));
 }

 static void imr_resource(struct device *dev, int idx, uint32_t base,
 			 uint32_t mask)
 {
 	uint32_t base_k, size_k;
 	/* Bits 28:0 encode the base address bits 38:10, hence the KiB unit. */
 	base_k = (base & 0x0fffffff);
 	/* Bits 28:0 encode the AND mask used for comparison, in KiB. */
 	size_k = ((~mask & 0x0fffffff) + 1);
 	/*
 	 * IMRs sit in lower DRAM. Mark them cacheable, otherwise we run
 	 * out of MTRRs. Memory reserved by IMRs is not usable for host
 	 * so mark it reserved.
 	 */
 	reserved_ram_resource(dev, idx, base_k, size_k);
 }

 /*
  * Add IMR ranges that hang off the host bridge/memory
  * controller device in case CONFIG(SA_ENABLE_IMR) is selected by SoC.
  */
 static void sa_add_imr_resources(struct device *dev, int *resource_cnt)
 {
 	size_t i, imr_offset;
 	uint32_t base, mask;
 	int index = *resource_cnt;

 	for (i = 0; i < MCH_NUM_IMRS; i++) {
 		imr_offset = i * MCH_IMR_PITCH;
 		base = MCHBAR32(imr_offset + MCH_IMR0_BASE);
 		mask = MCHBAR32(imr_offset + MCH_IMR0_MASK);

 		if (is_imr_enabled(base))
 			imr_resource(dev, index++, base, mask);
 	}

 	*resource_cnt = index;
 }

 static void systemagent_read_resources(struct device *dev)
 {
 	int index = 0;

 	/* Read standard PCI resources. */
 	pci_dev_read_resources(dev);

 	/* Add all fixed MMIO resources. */
 	soc_add_fixed_mmio_resources(dev, &index);
 	/* Calculate and add DRAM resources. */
 	sa_add_dram_resources(dev, &index);
 	if (CONFIG(SA_ENABLE_IMR))
 		/* Add the isolated memory ranges (IMRs). */
 		sa_add_imr_resources(dev, &index);

 	/* Reserve the window used for extended BIOS decoding. */
 	if (CONFIG(FAST_SPI_SUPPORTS_EXT_BIOS_WINDOW))
 		mmio_resource(dev, index++, CONFIG_EXT_BIOS_WIN_BASE / KiB,
 			      CONFIG_EXT_BIOS_WIN_SIZE / KiB);
 }

 void enable_power_aware_intr(void)
 {
 	uint8_t pair;

 	/* Enable Power Aware Interrupt Routing */
 	pair = MCHBAR8(MCH_PAIR);
 	pair &= ~0x7;	/* Clear 2:0 */
 	pair |= 0x4;	/* Fixed Priority */
 	MCHBAR8(MCH_PAIR) = pair;
 }

 void sa_lock_pam(void)
 {
 	const struct device *dev = pcidev_path_on_root(SA_DEVFN_ROOT);
 	if (!dev)
 		return;

 	pci_or_config8(dev, PAM0, PAM_LOCK);
 }

 static struct device_operations systemagent_ops = {
 	.read_resources   = systemagent_read_resources,
 	.set_resources    = pci_dev_set_resources,
 	.enable_resources = pci_dev_enable_resources,
 	.init             = sa_soc_systemagent_init,
 	.ops_pci          = &pci_dev_ops_pci,
 #if CONFIG(HAVE_ACPI_TABLES)
 	.write_acpi_tables = sa_write_acpi_tables,
 #endif
 };

 static const unsigned short systemagent_ids[] = {
 	PCI_DID_INTEL_GLK_NB,
 	PCI_DID_INTEL_APL_NB,
 	PCI_DID_INTEL_CNL_ID_U,
 	PCI_DID_INTEL_CNL_ID_Y,
 	PCI_DID_INTEL_SKL_ID_U,
 	PCI_DID_INTEL_SKL_ID_Y,
 	PCI_DID_INTEL_SKL_ID_ULX,
 	PCI_DID_INTEL_SKL_ID_H_4,
 	PCI_DID_INTEL_SKL_ID_H_2,
 	PCI_DID_INTEL_SKL_ID_S_2,
 	PCI_DID_INTEL_SKL_ID_S_4,
 	PCI_DID_INTEL_WHL_ID_W_2,
 	PCI_DID_INTEL_WHL_ID_W_4,
 	PCI_DID_INTEL_KBL_ID_S,
 	PCI_DID_INTEL_SKL_ID_H_EM,
 	PCI_DID_INTEL_KBL_ID_U,
 	PCI_DID_INTEL_KBL_ID_Y,
 	PCI_DID_INTEL_KBL_ID_H,
 	PCI_DID_INTEL_KBL_U_R,
 	PCI_DID_INTEL_KBL_ID_DT,
 	PCI_DID_INTEL_KBL_ID_DT_2,
 	PCI_DID_INTEL_CFL_ID_U,
 	PCI_DID_INTEL_CFL_ID_U_2,
 	PCI_DID_INTEL_CFL_ID_H,
 	PCI_DID_INTEL_CFL_ID_H_4,
 	PCI_DID_INTEL_CFL_ID_H_8,
 	PCI_DID_INTEL_CFL_ID_S,
 	PCI_DID_INTEL_CFL_ID_S_DT_2,
 	PCI_DID_INTEL_CFL_ID_S_DT_4,
 	PCI_DID_INTEL_CFL_ID_S_DT_8,
 	PCI_DID_INTEL_CFL_ID_S_WS_4,
 	PCI_DID_INTEL_CFL_ID_S_WS_6,
 	PCI_DID_INTEL_CFL_ID_S_WS_8,
 	PCI_DID_INTEL_CFL_ID_S_S_4,
 	PCI_DID_INTEL_CFL_ID_S_S_6,
 	PCI_DID_INTEL_CFL_ID_S_S_8,
 	PCI_DID_INTEL_ICL_ID_U,
 	PCI_DID_INTEL_ICL_ID_U_2_2,
 	PCI_DID_INTEL_ICL_ID_Y,
 	PCI_DID_INTEL_ICL_ID_Y_2,
 	PCI_DID_INTEL_CML_ULT,
 	PCI_DID_INTEL_CML_ULT_2_2,
 	PCI_DID_INTEL_CML_ULT_6_2,
 	PCI_DID_INTEL_CML_ULX,
 	PCI_DID_INTEL_CML_S,
 	PCI_DID_INTEL_CML_S_G0G1_P0P1_6_2,
 	PCI_DID_INTEL_CML_S_P0P1_8_2,
 	PCI_DID_INTEL_CML_S_P0P1_10_2,
 	PCI_DID_INTEL_CML_S_G0G1_4,
 	PCI_DID_INTEL_CML_S_G0G1_2,
 	PCI_DID_INTEL_CML_H,
 	PCI_DID_INTEL_CML_H_4_2,
 	PCI_DID_INTEL_CML_H_8_2,
 	PCI_DID_INTEL_TGL_ID_U_2_2,
 	PCI_DID_INTEL_TGL_ID_U_4_2,
 	PCI_DID_INTEL_TGL_ID_Y_2_2,
 	PCI_DID_INTEL_TGL_ID_Y_4_2,
 	PCI_DID_INTEL_TGL_ID_H_6_1,
 	PCI_DID_INTEL_TGL_ID_H_8_1,
 	PCI_DID_INTEL_EHL_ID_0,
 	PCI_DID_INTEL_EHL_ID_1,
 	PCI_DID_INTEL_EHL_ID_1A,
 	PCI_DID_INTEL_EHL_ID_2,
 	PCI_DID_INTEL_EHL_ID_2_1,
 	PCI_DID_INTEL_EHL_ID_3,
 	PCI_DID_INTEL_EHL_ID_3A,
 	PCI_DID_INTEL_EHL_ID_4,
 	PCI_DID_INTEL_EHL_ID_5,
 	PCI_DID_INTEL_EHL_ID_6,
 	PCI_DID_INTEL_EHL_ID_7,
 	PCI_DID_INTEL_EHL_ID_8,
 	PCI_DID_INTEL_EHL_ID_9,
 	PCI_DID_INTEL_EHL_ID_10,
 	PCI_DID_INTEL_EHL_ID_11,
 	PCI_DID_INTEL_EHL_ID_12,
 	PCI_DID_INTEL_EHL_ID_13,
 	PCI_DID_INTEL_EHL_ID_14,
 	PCI_DID_INTEL_EHL_ID_15,
 	PCI_DID_INTEL_JSL_ID_1,
 	PCI_DID_INTEL_JSL_ID_2,
 	PCI_DID_INTEL_JSL_ID_3,
 	PCI_DID_INTEL_JSL_ID_4,
 	PCI_DID_INTEL_JSL_ID_5,
 	PCI_DID_INTEL_ADL_S_ID_1,
 	PCI_DID_INTEL_ADL_S_ID_2,
 	PCI_DID_INTEL_ADL_S_ID_3,
 	PCI_DID_INTEL_ADL_S_ID_4,
 	PCI_DID_INTEL_ADL_S_ID_5,
 	PCI_DID_INTEL_ADL_S_ID_6,
 	PCI_DID_INTEL_ADL_S_ID_7,
 	PCI_DID_INTEL_ADL_S_ID_8,
 	PCI_DID_INTEL_ADL_S_ID_9,
 	PCI_DID_INTEL_ADL_S_ID_10,
 	PCI_DID_INTEL_ADL_S_ID_11,
 	PCI_DID_INTEL_ADL_S_ID_12,
 	PCI_DID_INTEL_ADL_S_ID_13,
 	PCI_DID_INTEL_ADL_S_ID_14,
 	PCI_DID_INTEL_ADL_S_ID_15,
 	PCI_DID_INTEL_ADL_P_ID_1,
 	PCI_DID_INTEL_ADL_P_ID_3,
 	PCI_DID_INTEL_ADL_P_ID_4,
 	PCI_DID_INTEL_ADL_P_ID_5,
 	PCI_DID_INTEL_ADL_P_ID_6,
 	PCI_DID_INTEL_ADL_P_ID_7,
 	PCI_DID_INTEL_ADL_P_ID_8,
 	PCI_DID_INTEL_ADL_P_ID_9,
 	PCI_DID_INTEL_ADL_P_ID_10,
 	PCI_DID_INTEL_ADL_M_ID_1,
 	PCI_DID_INTEL_ADL_M_ID_2,
 	PCI_DID_INTEL_ADL_N_ID_1,
 	PCI_DID_INTEL_ADL_N_ID_2,
 	PCI_DID_INTEL_ADL_N_ID_3,
 	PCI_DID_INTEL_ADL_N_ID_4,
 	0
 };

 static const struct pci_driver systemagent_driver __pci_driver = {
 	.ops     = &systemagent_ops,
 	.vendor  = PCI_VID_INTEL,
 	.devices = systemagent_ids
 };
	/* SPDX-License-Identifier: GPL-2.0-only */

	#include <cbmem.h>
	#include <console/console.h>
	#include <cpu/cpu.h>
	#include <device/device.h>
	#include <device/pci.h>
	#include <device/pci_ids.h>
	#include <intelblocks/acpi.h>
	#include <intelblocks/cfg.h>
	#include <intelblocks/systemagent.h>
	#include <smbios.h>
	#include <soc/iomap.h>
	#include <soc/nvs.h>
	#include <soc/pci_devs.h>
	#include <soc/systemagent.h>
	#include <types.h>
	#include "systemagent_def.h"

	/* SoC override function */
	__weak void soc_systemagent_init(struct device *dev)
	{
	/* no-op */
	}

	__weak void soc_add_fixed_mmio_resources(struct device *dev,
	int *resource_cnt)
	{
	/* no-op */
	}

	__weak int soc_get_uncore_prmmr_base_and_mask(uint64_t *base,
	uint64_t *mask)
	{
	/* return failure for this dummy API */
	return -1;
	}

	__weak unsigned long sa_write_acpi_tables(const struct device *dev,
	unsigned long current,
	struct acpi_rsdp *rsdp)
	{
	return current;
	}

	__weak uint32_t soc_systemagent_max_chan_capacity_mib(u8 capid0_a_ddrsz)
	{
	return 32768; /* 32 GiB per channel */
	}

	static uint8_t sa_get_ecc_type(const uint32_t capid0_a)
	{
	return capid0_a & CAPID_ECCDIS ? MEMORY_ARRAY_ECC_NONE : MEMORY_ARRAY_ECC_SINGLE_BIT;
	}

	static size_t sa_slots_per_channel(const uint32_t capid0_a)
	{
	return !(capid0_a & CAPID_DDPCD) + 1;
	}

	static size_t sa_number_of_channels(const uint32_t capid0_a)
	{
	return !(capid0_a & CAPID_PDCD) + 1;
	}

	static void sa_soc_systemagent_init(struct device *dev)
	{
	soc_systemagent_init(dev);

	struct memory_info *m = cbmem_find(CBMEM_ID_MEMINFO);
	if (m == NULL)
	return;

	const uint32_t capid0_a = pci_read_config32(dev, CAPID0_A);

	m->ecc_type = sa_get_ecc_type(capid0_a);
	m->max_capacity_mib = soc_systemagent_max_chan_capacity_mib(CAPID_DDRSZ(capid0_a)) *
	sa_number_of_channels(capid0_a);
	m->number_of_devices = sa_slots_per_channel(capid0_a) *
	sa_number_of_channels(capid0_a);
	}

	/*
	* Add all known fixed MMIO ranges that hang off the host bridge/memory
	* controller device.
	*/
	void sa_add_fixed_mmio_resources(struct device dev, int resource_cnt,
	const struct sa_mmio_descriptor *sa_fixed_resources, size_t count)
	{
	int i;
	int index = *resource_cnt;

	for (i = 0; i < count; i++) {
	uintptr_t base;
	size_t size;

	size = sa_fixed_resources[i].size;
	base = sa_fixed_resources[i].base;

	mmio_resource(dev, index++, base / KiB, size / KiB);
	}

	*resource_cnt = index;
	}

	/*
	* DRAM memory mapped register
	*
	* TOUUD: This 64 bit register defines the Top of Upper Usable DRAM
	* TOLUD: This 32 bit register defines the Top of Low Usable DRAM
	* BGSM: This register contains the base address of stolen DRAM memory for GTT
	* TSEG: This register contains the base address of TSEG DRAM memory
	*/
	static const struct sa_mem_map_descriptor sa_memory_map[MAX_MAP_ENTRIES] = {
	{ TOUUD, true, "TOUUD" },
	{ TOLUD, false, "TOLUD" },
	{ BGSM, false, "BGSM" },
	{ TSEG, false, "TSEG" },
	};

	/* Read DRAM memory map register value through PCI configuration space */
	static void sa_read_map_entry(struct device *dev,
	const struct sa_mem_map_descriptor entry, uint64_t result)
	{
	uint64_t value = 0;

	if (entry->is_64_bit) {
	value = pci_read_config32(dev, entry->reg + 4);
	value <<= 32;
	}

	value \|= pci_read_config32(dev, entry->reg);
	/* All registers are on a 1MiB granularity. */
	value = ALIGN_DOWN(value, 1 * MiB);

	*result = value;
	}

	/* Fill MMIO resource above 4GB into GNVS */
	void sa_fill_gnvs(struct global_nvs *gnvs)
	{
	struct device *sa_dev = pcidev_path_on_root(SA_DEVFN_ROOT);

	sa_read_map_entry(sa_dev, &sa_memory_map[SA_TOUUD_REG], &gnvs->a4gb);
	gnvs->a4gs = POWER_OF_2(cpu_phys_address_size()) - gnvs->a4gb;
	printk(BIOS_DEBUG, "PCI space above 4GB MMIO is at 0x%llx, len = 0x%llx\n",
	gnvs->a4gb, gnvs->a4gs);
	}

	static void sa_get_mem_map(struct device dev, uint64_t values)
	{
	int i;
	for (i = 0; i < MAX_MAP_ENTRIES; i++)
	sa_read_map_entry(dev, &sa_memory_map[i], &values[i]);
	}

	/*
	* These are the host memory ranges that should be added:
	* - 0 -> 0xa0000: cacheable
	* - 0xc0000 -> top_of_ram : cacheable
	* - top_of_ram -> TOLUD: not cacheable with standard MTRRs and reserved
	* - 4GiB -> TOUUD: cacheable
	*
	* The default SMRAM space is reserved so that the range doesn't
	* have to be saved during S3 Resume. Once marked reserved the OS
	* cannot use the memory. This is a bit of an odd place to reserve
	* the region, but the CPU devices don't have dev_ops->read_resources()
	* called on them.
	*
	* The range 0xa0000 -> 0xc0000 does not have any resources
	* associated with it to handle legacy VGA memory. If this range
	* is not omitted the mtrr code will setup the area as cacheable
	* causing VGA access to not work.
	*
	* Don't need to mark the entire top_of_ram till TOLUD range (used
	* for stolen memory like GFX and ME, PTT, DPR, PRMRR, TSEG etc) as
	* cacheable for OS usage as coreboot already done with mpinit w/ smm
	* relocation early.
	*
	* It should be noted that cacheable entry types need to be added in
	* order. The reason is that the current MTRR code assumes this and
	* falls over itself if it isn't.
	*
	* The resource index starts low and should not meet or exceed
	* PCI_BASE_ADDRESS_0.
	*/
	static void sa_add_dram_resources(struct device dev, int resource_count)
	{
	uintptr_t base_k, touud_k;
	size_t size_k;
	uint64_t sa_map_values[MAX_MAP_ENTRIES];
	uintptr_t top_of_ram;
	int index = *resource_count;

	top_of_ram = (uintptr_t)cbmem_top();

	/* 0 - > 0xa0000 */
	base_k = 0;
	size_k = (0xa0000 / KiB) - base_k;
	ram_resource(dev, index++, base_k, size_k);

	/* 0xc0000 -> top_of_ram */
	base_k = 0xc0000 / KiB;
	size_k = (top_of_ram / KiB) - base_k;
	ram_resource(dev, index++, base_k, size_k);

	sa_get_mem_map(dev, &sa_map_values[0]);

	/* top_of_ram -> TOLUD */
	base_k = top_of_ram;
	size_k = sa_map_values[SA_TOLUD_REG] - base_k;
	mmio_resource(dev, index++, base_k / KiB, size_k / KiB);

	/* 4GiB -> TOUUD */
	base_k = 4 * (GiB / KiB); /* 4GiB */
	touud_k = sa_map_values[SA_TOUUD_REG] / KiB;
	size_k = touud_k - base_k;
	if (touud_k > base_k)
	ram_resource(dev, index++, base_k, size_k);

	/*
	* Reserve everything between A segment and 1MB:
	*
	* 0xa0000 - 0xbffff: legacy VGA
	* 0xc0000 - 0xfffff: RAM
	*/
	mmio_resource(dev, index++, 0xa0000 / KiB, (0xc0000 - 0xa0000) / KiB);
	reserved_ram_resource(dev, index++, 0xc0000 / KiB,
	(1*MiB - 0xc0000) / KiB);

	*resource_count = index;
	}

	static bool is_imr_enabled(uint32_t imr_base_reg)
	{
	return !!(imr_base_reg & (1 << 31));
	}

	static void imr_resource(struct device *dev, int idx, uint32_t base,
	uint32_t mask)
	{
	uint32_t base_k, size_k;
	/* Bits 28:0 encode the base address bits 38:10, hence the KiB unit. */
	base_k = (base & 0x0fffffff);
	/* Bits 28:0 encode the AND mask used for comparison, in KiB. */
	size_k = ((~mask & 0x0fffffff) + 1);
	/*
	* IMRs sit in lower DRAM. Mark them cacheable, otherwise we run
	* out of MTRRs. Memory reserved by IMRs is not usable for host
	* so mark it reserved.
	*/
	reserved_ram_resource(dev, idx, base_k, size_k);
	}

	/*
	* Add IMR ranges that hang off the host bridge/memory
	* controller device in case CONFIG(SA_ENABLE_IMR) is selected by SoC.
	*/
	static void sa_add_imr_resources(struct device dev, int resource_cnt)
	{
	size_t i, imr_offset;
	uint32_t base, mask;
	int index = *resource_cnt;

	for (i = 0; i < MCH_NUM_IMRS; i++) {
	imr_offset = i * MCH_IMR_PITCH;
	base = MCHBAR32(imr_offset + MCH_IMR0_BASE);
	mask = MCHBAR32(imr_offset + MCH_IMR0_MASK);

	if (is_imr_enabled(base))
	imr_resource(dev, index++, base, mask);
	}

	*resource_cnt = index;
	}

	static void systemagent_read_resources(struct device *dev)
	{
	int index = 0;

	/* Read standard PCI resources. */
	pci_dev_read_resources(dev);

	/* Add all fixed MMIO resources. */
	soc_add_fixed_mmio_resources(dev, &index);
	/* Calculate and add DRAM resources. */
	sa_add_dram_resources(dev, &index);
	if (CONFIG(SA_ENABLE_IMR))
	/* Add the isolated memory ranges (IMRs). */
	sa_add_imr_resources(dev, &index);

	/* Reserve the window used for extended BIOS decoding. */
	if (CONFIG(FAST_SPI_SUPPORTS_EXT_BIOS_WINDOW))
	mmio_resource(dev, index++, CONFIG_EXT_BIOS_WIN_BASE / KiB,
	CONFIG_EXT_BIOS_WIN_SIZE / KiB);
	}

	void enable_power_aware_intr(void)
	{
	uint8_t pair;

	/* Enable Power Aware Interrupt Routing */
	pair = MCHBAR8(MCH_PAIR);
	pair &= ~0x7; /* Clear 2:0 */
	pair \|= 0x4; /* Fixed Priority */
	MCHBAR8(MCH_PAIR) = pair;
	}

	void sa_lock_pam(void)
	{
	const struct device *dev = pcidev_path_on_root(SA_DEVFN_ROOT);
	if (!dev)
	return;

	pci_or_config8(dev, PAM0, PAM_LOCK);
	}

	static struct device_operations systemagent_ops = {
	.read_resources = systemagent_read_resources,
	.set_resources = pci_dev_set_resources,
	.enable_resources = pci_dev_enable_resources,
	.init = sa_soc_systemagent_init,
	.ops_pci = &pci_dev_ops_pci,
	#if CONFIG(HAVE_ACPI_TABLES)
	.write_acpi_tables = sa_write_acpi_tables,
	#endif
	};

	static const unsigned short systemagent_ids[] = {
	PCI_DID_INTEL_GLK_NB,
	PCI_DID_INTEL_APL_NB,
	PCI_DID_INTEL_CNL_ID_U,
	PCI_DID_INTEL_CNL_ID_Y,
	PCI_DID_INTEL_SKL_ID_U,
	PCI_DID_INTEL_SKL_ID_Y,
	PCI_DID_INTEL_SKL_ID_ULX,
	PCI_DID_INTEL_SKL_ID_H_4,
	PCI_DID_INTEL_SKL_ID_H_2,
	PCI_DID_INTEL_SKL_ID_S_2,
	PCI_DID_INTEL_SKL_ID_S_4,
	PCI_DID_INTEL_WHL_ID_W_2,
	PCI_DID_INTEL_WHL_ID_W_4,
	PCI_DID_INTEL_KBL_ID_S,
	PCI_DID_INTEL_SKL_ID_H_EM,
	PCI_DID_INTEL_KBL_ID_U,
	PCI_DID_INTEL_KBL_ID_Y,
	PCI_DID_INTEL_KBL_ID_H,
	PCI_DID_INTEL_KBL_U_R,
	PCI_DID_INTEL_KBL_ID_DT,
	PCI_DID_INTEL_KBL_ID_DT_2,
	PCI_DID_INTEL_CFL_ID_U,
	PCI_DID_INTEL_CFL_ID_U_2,
	PCI_DID_INTEL_CFL_ID_H,
	PCI_DID_INTEL_CFL_ID_H_4,
	PCI_DID_INTEL_CFL_ID_H_8,
	PCI_DID_INTEL_CFL_ID_S,
	PCI_DID_INTEL_CFL_ID_S_DT_2,
	PCI_DID_INTEL_CFL_ID_S_DT_4,
	PCI_DID_INTEL_CFL_ID_S_DT_8,
	PCI_DID_INTEL_CFL_ID_S_WS_4,
	PCI_DID_INTEL_CFL_ID_S_WS_6,
	PCI_DID_INTEL_CFL_ID_S_WS_8,
	PCI_DID_INTEL_CFL_ID_S_S_4,
	PCI_DID_INTEL_CFL_ID_S_S_6,
	PCI_DID_INTEL_CFL_ID_S_S_8,
	PCI_DID_INTEL_ICL_ID_U,
	PCI_DID_INTEL_ICL_ID_U_2_2,
	PCI_DID_INTEL_ICL_ID_Y,
	PCI_DID_INTEL_ICL_ID_Y_2,
	PCI_DID_INTEL_CML_ULT,
	PCI_DID_INTEL_CML_ULT_2_2,
	PCI_DID_INTEL_CML_ULT_6_2,
	PCI_DID_INTEL_CML_ULX,
	PCI_DID_INTEL_CML_S,
	PCI_DID_INTEL_CML_S_G0G1_P0P1_6_2,
	PCI_DID_INTEL_CML_S_P0P1_8_2,
	PCI_DID_INTEL_CML_S_P0P1_10_2,
	PCI_DID_INTEL_CML_S_G0G1_4,
	PCI_DID_INTEL_CML_S_G0G1_2,
	PCI_DID_INTEL_CML_H,
	PCI_DID_INTEL_CML_H_4_2,
	PCI_DID_INTEL_CML_H_8_2,
	PCI_DID_INTEL_TGL_ID_U_2_2,
	PCI_DID_INTEL_TGL_ID_U_4_2,
	PCI_DID_INTEL_TGL_ID_Y_2_2,
	PCI_DID_INTEL_TGL_ID_Y_4_2,
	PCI_DID_INTEL_TGL_ID_H_6_1,
	PCI_DID_INTEL_TGL_ID_H_8_1,
	PCI_DID_INTEL_EHL_ID_0,
	PCI_DID_INTEL_EHL_ID_1,
	PCI_DID_INTEL_EHL_ID_1A,
	PCI_DID_INTEL_EHL_ID_2,
	PCI_DID_INTEL_EHL_ID_2_1,
	PCI_DID_INTEL_EHL_ID_3,
	PCI_DID_INTEL_EHL_ID_3A,
	PCI_DID_INTEL_EHL_ID_4,
	PCI_DID_INTEL_EHL_ID_5,
	PCI_DID_INTEL_EHL_ID_6,
	PCI_DID_INTEL_EHL_ID_7,
	PCI_DID_INTEL_EHL_ID_8,
	PCI_DID_INTEL_EHL_ID_9,
	PCI_DID_INTEL_EHL_ID_10,
	PCI_DID_INTEL_EHL_ID_11,
	PCI_DID_INTEL_EHL_ID_12,
	PCI_DID_INTEL_EHL_ID_13,
	PCI_DID_INTEL_EHL_ID_14,
	PCI_DID_INTEL_EHL_ID_15,
	PCI_DID_INTEL_JSL_ID_1,
	PCI_DID_INTEL_JSL_ID_2,
	PCI_DID_INTEL_JSL_ID_3,
	PCI_DID_INTEL_JSL_ID_4,
	PCI_DID_INTEL_JSL_ID_5,
	PCI_DID_INTEL_ADL_S_ID_1,
	PCI_DID_INTEL_ADL_S_ID_2,
	PCI_DID_INTEL_ADL_S_ID_3,
	PCI_DID_INTEL_ADL_S_ID_4,
	PCI_DID_INTEL_ADL_S_ID_5,
	PCI_DID_INTEL_ADL_S_ID_6,
	PCI_DID_INTEL_ADL_S_ID_7,
	PCI_DID_INTEL_ADL_S_ID_8,
	PCI_DID_INTEL_ADL_S_ID_9,
	PCI_DID_INTEL_ADL_S_ID_10,
	PCI_DID_INTEL_ADL_S_ID_11,
	PCI_DID_INTEL_ADL_S_ID_12,
	PCI_DID_INTEL_ADL_S_ID_13,
	PCI_DID_INTEL_ADL_S_ID_14,
	PCI_DID_INTEL_ADL_S_ID_15,
	PCI_DID_INTEL_ADL_P_ID_1,
	PCI_DID_INTEL_ADL_P_ID_3,
	PCI_DID_INTEL_ADL_P_ID_4,
	PCI_DID_INTEL_ADL_P_ID_5,
	PCI_DID_INTEL_ADL_P_ID_6,
	PCI_DID_INTEL_ADL_P_ID_7,
	PCI_DID_INTEL_ADL_P_ID_8,
	PCI_DID_INTEL_ADL_P_ID_9,
	PCI_DID_INTEL_ADL_P_ID_10,
	PCI_DID_INTEL_ADL_M_ID_1,
	PCI_DID_INTEL_ADL_M_ID_2,
	PCI_DID_INTEL_ADL_N_ID_1,
	PCI_DID_INTEL_ADL_N_ID_2,
	PCI_DID_INTEL_ADL_N_ID_3,
	PCI_DID_INTEL_ADL_N_ID_4,
	0
	};

	static const struct pci_driver systemagent_driver __pci_driver = {
	.ops = &systemagent_ops,
	.vendor = PCI_VID_INTEL,
	.devices = systemagent_ids
	};