src/soc/amd/common/block/acpi/ivrs.c - coreboot - Gitiles

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

 #include <acpi/acpi_ivrs.h>
 #include <amdblocks/acpi.h>
 #include <amdblocks/cpu.h>
 #include <amdblocks/data_fabric.h>
 #include <amdblocks/ioapic.h>
 #include <arch/ioapic.h>
 #include <console/console.h>
 #include <cpu/amd/cpuid.h>
 #include <device/device.h>
 #include <device/mmio.h>
 #include <device/pci_def.h>
 #include <device/pci_ops.h>
 #include <soc/acpi.h>
 #include <soc/data_fabric.h>
 #include <soc/iomap.h>
 #include <soc/pci_devs.h>

 static unsigned long acpi_fill_ivrs_ioapic(unsigned long current, void *ioapic_base,
 					    uint16_t src_devid, uint8_t dte_setting)
 {
 	ivrs_ivhd_special_t *ivhd_ioapic = (ivrs_ivhd_special_t *)current;
 	memset(ivhd_ioapic, 0, sizeof(*ivhd_ioapic));

 	ivhd_ioapic->type = IVHD_DEV_8_BYTE_EXT_SPECIAL_DEV;
 	ivhd_ioapic->dte_setting = dte_setting;
 	ivhd_ioapic->handle = get_ioapic_id(ioapic_base);
 	ivhd_ioapic->source_dev_id = src_devid;
 	ivhd_ioapic->variety = IVHD_SPECIAL_DEV_IOAPIC;
 	current += sizeof(ivrs_ivhd_special_t);

 	return current;
 }

 static unsigned long ivhd_describe_hpet(unsigned long current, uint8_t hndl, uint16_t src_devid)
 {
 	ivrs_ivhd_special_t *ivhd_hpet = (ivrs_ivhd_special_t *)current;

 	ivhd_hpet->type = IVHD_DEV_8_BYTE_EXT_SPECIAL_DEV;
 	ivhd_hpet->reserved = 0x0000;
 	ivhd_hpet->dte_setting = 0x00;
 	ivhd_hpet->handle = hndl;
 	ivhd_hpet->source_dev_id = src_devid; /* function 0 of FCH PCI device */
 	ivhd_hpet->variety = IVHD_SPECIAL_DEV_HPET;
 	current += sizeof(ivrs_ivhd_special_t);

 	return current;
 }

 static unsigned long ivhd_describe_f0_device(unsigned long current,
 						uint16_t dev_id, uint8_t datasetting)
 {
 	ivrs_ivhd_f0_entry_t *ivhd_f0 = (ivrs_ivhd_f0_entry_t *)current;

 	ivhd_f0->type = IVHD_DEV_VARIABLE;
 	ivhd_f0->dev_id = dev_id;
 	ivhd_f0->dte_setting = datasetting;
 	ivhd_f0->hardware_id[0] = 'A';
 	ivhd_f0->hardware_id[1] = 'M';
 	ivhd_f0->hardware_id[2] = 'D';
 	ivhd_f0->hardware_id[3] = 'I';
 	ivhd_f0->hardware_id[4] = '0';
 	ivhd_f0->hardware_id[5] = '0';
 	ivhd_f0->hardware_id[6] = '4';
 	ivhd_f0->hardware_id[7] = '0';

 	memset(ivhd_f0->compatible_id, 0, sizeof(ivhd_f0->compatible_id));

 	ivhd_f0->uuid_format = 0;
 	ivhd_f0->uuid_length = 0;

 	current += sizeof(ivrs_ivhd_f0_entry_t);
 	return current;
 }

 static unsigned long ivhd_dev_range(unsigned long current, uint16_t start_devid,
 				    uint16_t end_devid, uint8_t setting)
 {
 	/* 4-byte IVHD structures must be aligned to the 4-byte boundary. */
 	current = ALIGN_UP(current, 4);
 	ivrs_ivhd_generic_t *ivhd_range = (ivrs_ivhd_generic_t *)current;

 	/* Create the start range IVHD entry */
 	ivhd_range->type = IVHD_DEV_4_BYTE_START_RANGE;
 	ivhd_range->dev_id = start_devid;
 	ivhd_range->dte_setting = setting;
 	current += sizeof(ivrs_ivhd_generic_t);

 	/* Create the end range IVHD entry */
 	ivhd_range = (ivrs_ivhd_generic_t *)current;
 	ivhd_range->type = IVHD_DEV_4_BYTE_END_RANGE;
 	ivhd_range->dev_id = end_devid;
 	ivhd_range->dte_setting = setting;
 	current += sizeof(ivrs_ivhd_generic_t);

 	return current;
 }

 static unsigned long add_ivhd_dev_entry(struct device *parent, struct device *dev,
 					unsigned long *current, uint8_t type, uint8_t data)
 {
 	if (type == IVHD_DEV_4_BYTE_SELECT) {
 		/* 4-byte IVHD structures must be aligned to the 4-byte boundary. */
 		*current = ALIGN_UP(*current, 4);
 		ivrs_ivhd_generic_t *ivhd_entry = (ivrs_ivhd_generic_t *)*current;

 		ivhd_entry->type = type;
 		ivhd_entry->dev_id = dev->path.pci.devfn | (dev->bus->secondary << 8);
 		ivhd_entry->dte_setting = data;
 		*current += sizeof(ivrs_ivhd_generic_t);
 	} else if (type == IVHD_DEV_8_BYTE_ALIAS_SELECT) {
 		ivrs_ivhd_alias_t *ivhd_entry = (ivrs_ivhd_alias_t *)*current;

 		ivhd_entry->type = type;
 		ivhd_entry->dev_id = dev->path.pci.devfn | (dev->bus->secondary << 8);
 		ivhd_entry->dte_setting = data;
 		ivhd_entry->reserved1 = 0;
 		ivhd_entry->reserved2 = 0;
 		ivhd_entry->source_dev_id = parent->path.pci.devfn |
 					    (parent->bus->secondary << 8);
 		*current += sizeof(ivrs_ivhd_alias_t);
 	}

 	return *current;
 }

 static void ivrs_add_device_or_bridge(struct device *parent, struct device *dev,
 				      unsigned long *current)
 {
 	unsigned int header_type, is_pcie;

 	header_type = dev->hdr_type & 0x7f;
 	is_pcie = pci_find_capability(dev, PCI_CAP_ID_PCIE);

 	if (((header_type == PCI_HEADER_TYPE_NORMAL) ||
 	     (header_type == PCI_HEADER_TYPE_BRIDGE)) && is_pcie) {
 		/* Device or Bridge is PCIe */
 		add_ivhd_dev_entry(parent, dev, current, IVHD_DEV_4_BYTE_SELECT, 0x0);
 	} else if ((header_type == PCI_HEADER_TYPE_NORMAL) && !is_pcie) {
 		/* Device is legacy PCI or PCI-X */
 		add_ivhd_dev_entry(parent, dev, current, IVHD_DEV_8_BYTE_ALIAS_SELECT, 0x0);

 	}
 }

 static void add_ivhd_device_entries(struct device *parent, struct device *dev,
 				    unsigned int depth, int linknum, int8_t *root_level,
 				    unsigned long *current, uint16_t nb_bus)
 {
 	struct device *sibling;
 	struct bus *link;

 	if (!root_level)
 		return;

 	if (dev->path.type == DEVICE_PATH_PCI) {
 		if ((dev->bus->secondary == nb_bus) &&
 		    (dev->path.pci.devfn == 0x0))
 			*root_level = depth;

 		if ((*root_level != -1) && (dev->enabled))
 			if (depth != *root_level)
 				ivrs_add_device_or_bridge(parent, dev, current);
 	}

 	for (link = dev->link_list; link; link = link->next)
 		for (sibling = link->children; sibling; sibling =
 		     sibling->sibling)
 			add_ivhd_device_entries(dev, sibling, depth + 1, depth, root_level,
 						current, nb_bus);
 }

 static unsigned long acpi_ivhd_misc(unsigned long current, struct device *dev)
 {
 	u8 dte_setting = IVHD_DTE_LINT_1_PASS | IVHD_DTE_LINT_0_PASS |
 		       IVHD_DTE_SYS_MGT_NO_TRANS | IVHD_DTE_NMI_PASS |
 		       IVHD_DTE_EXT_INT_PASS | IVHD_DTE_INIT_PASS;
 	int8_t root_level = -1;
 	struct resource *res;

 	/*
 	 * Add all possible PCI devices in the domain that can generate transactions
 	 * processed by IOMMU. Start with device <bus>:01.0
 	*/
 	current = ivhd_dev_range(current, PCI_DEVFN(0, 3) | (dev->link_list->secondary << 8),
 				 0xff | (dev->link_list->subordinate << 8), 0);

 	add_ivhd_device_entries(NULL, dev, 0, -1, &root_level,
 		&current, dev->link_list->secondary);

 	res = probe_resource(dev, IOMMU_IOAPIC_IDX);
 	if (res) {
 		/* Describe IOAPIC associated with the IOMMU */
 		current = acpi_fill_ivrs_ioapic(current, (u8 *)(uintptr_t)res->base,
 				      PCI_DEVFN(0, 1) | (dev->link_list->secondary << 8), 0);
 	}

 	/* If the domain has secondary bus as zero then associate HPET & FCH IOAPIC */
 	if (dev->link_list->secondary == 0) {
 		/* Describe HPET */
 		current = ivhd_describe_hpet(current, 0x00, SMBUS_DEVFN);
 		/* Describe FCH IOAPICs */
 		current = acpi_fill_ivrs_ioapic(current, VIO_APIC_VADDR,
 				      SMBUS_DEVFN, dte_setting);
 	}

 	return current;
 }

 static unsigned long acpi_fill_ivrs40(unsigned long current, acpi_ivrs_ivhd_t *ivhd,
 				       struct device *nb_dev, struct device *iommu_dev)
 {
 	acpi_ivrs_ivhd40_t *ivhd_40;
 	unsigned long current_backup;

 	memset((void *)current, 0, sizeof(acpi_ivrs_ivhd40_t));
 	ivhd_40 = (acpi_ivrs_ivhd40_t *)current;

 	/* Enable EFR */
 	ivhd_40->type = IVHD_BLOCK_TYPE_FULL__ACPI_HID;
 	/* For type 40h bits 6 and 7 are reserved */
 	ivhd_40->flags = ivhd->flags & 0x3f;
 	ivhd_40->length = sizeof(struct acpi_ivrs_ivhd_40);
 	/* BDF <bus>:00.2 */
 	ivhd_40->device_id = 0x02 | (nb_dev->bus->secondary << 8);
 	ivhd_40->capability_offset = pci_find_capability(iommu_dev, IOMMU_CAP_ID);
 	ivhd_40->iommu_base_low = ivhd->iommu_base_low;
 	ivhd_40->iommu_base_high = ivhd->iommu_base_high;
 	ivhd_40->pci_segment_group = 0x0000;
 	ivhd_40->iommu_info = ivhd->iommu_info;
 	/* For type 40h bits 31:28 and 12:0 are reserved */
 	ivhd_40->iommu_attributes = ivhd->iommu_feature_info & 0xfffe000;

 	if (pci_read_config32(iommu_dev, ivhd_40->capability_offset) & EFR_FEATURE_SUP) {
 		ivhd_40->efr_reg_image_low  = read32p(ivhd_40->iommu_base_low + 0x30);
 		ivhd_40->efr_reg_image_high = read32p(ivhd_40->iommu_base_low + 0x34);
 	}

 	current += sizeof(acpi_ivrs_ivhd40_t);

 	/* Now repeat all the device entries from type 10h */
 	current_backup = current;
 	current = acpi_ivhd_misc(current, nb_dev->bus->dev);

 	if (nb_dev->bus->secondary == 0) {
 		/* Describe EMMC */
 		current = ivhd_describe_f0_device(current, PCI_DEVFN(0x13, 1),
 					IVHD_DTE_LINT_1_PASS | IVHD_DTE_LINT_0_PASS |
 					IVHD_DTE_SYS_MGT_TRANS   | IVHD_DTE_NMI_PASS |
 					IVHD_DTE_EXT_INT_PASS | IVHD_DTE_INIT_PASS);
 	}
 	ivhd_40->length += (current - current_backup);

 	return current;
 }

 static unsigned long acpi_fill_ivrs11(unsigned long current, acpi_ivrs_ivhd_t *ivhd,
 				       struct device *nb_dev, struct device *iommu_dev)
 {
 	acpi_ivrs_ivhd11_t *ivhd_11;
 	ivhd11_iommu_attr_t *ivhd11_attr_ptr;
 	unsigned long current_backup;

 	/*
 	 * In order to utilize all features, firmware should expose type 11h
 	 * IVHD which supersedes the type 10h.
 	 */
 	memset((void *)current, 0, sizeof(acpi_ivrs_ivhd11_t));
 	ivhd_11 = (acpi_ivrs_ivhd11_t *)current;

 	/* Enable EFR */
 	ivhd_11->type = IVHD_BLOCK_TYPE_FULL__FIXED;
 	/* For type 11h bits 6 and 7 are reserved */
 	ivhd_11->flags = ivhd->flags & 0x3f;
 	ivhd_11->length = sizeof(struct acpi_ivrs_ivhd_11);
 	/* BDF <bus>:00.2 */
 	ivhd_11->device_id = 0x02 | (nb_dev->bus->secondary << 8);
 	ivhd_11->capability_offset = pci_find_capability(iommu_dev, IOMMU_CAP_ID);
 	ivhd_11->iommu_base_low = ivhd->iommu_base_low;
 	ivhd_11->iommu_base_high = ivhd->iommu_base_high;
 	ivhd_11->pci_segment_group = 0x0000;
 	ivhd_11->iommu_info = ivhd->iommu_info;
 	ivhd11_attr_ptr = (ivhd11_iommu_attr_t *)&ivhd->iommu_feature_info;
 	ivhd_11->iommu_attributes.perf_counters = ivhd11_attr_ptr->perf_counters;
 	ivhd_11->iommu_attributes.perf_counter_banks = ivhd11_attr_ptr->perf_counter_banks;
 	ivhd_11->iommu_attributes.msi_num_ppr = ivhd11_attr_ptr->msi_num_ppr;

 	if (pci_read_config32(iommu_dev, ivhd_11->capability_offset) & EFR_FEATURE_SUP) {
 		ivhd_11->efr_reg_image_low  = read32p(ivhd_11->iommu_base_low + 0x30);
 		ivhd_11->efr_reg_image_high = read32p(ivhd_11->iommu_base_low + 0x34);
 	}

 	current += sizeof(acpi_ivrs_ivhd11_t);

 	/* Now repeat all the device entries from type 10h */
 	current_backup = current;
 	current = acpi_ivhd_misc(current, nb_dev->bus->dev);
 	ivhd_11->length += (current - current_backup);

 	return acpi_fill_ivrs40(current, ivhd, nb_dev, iommu_dev);
 }

 unsigned long acpi_fill_ivrs(acpi_ivrs_t *ivrs, unsigned long current)
 {
 	unsigned long current_backup;
 	uint64_t mmio_x30_value;
 	uint64_t mmio_x18_value;
 	uint64_t mmio_x4000_value;
 	uint32_t cap_offset_0;
 	uint32_t cap_offset_10;
 	struct acpi_ivrs_ivhd *ivhd;
 	struct device *iommu_dev;
 	struct device *nb_dev;
 	struct device *dev = NULL;

 	ivhd = &ivrs->ivhd;

 	while ((dev = dev_find_path(dev, DEVICE_PATH_DOMAIN)) != NULL) {

 		nb_dev = pcidev_path_behind(dev->link_list, PCI_DEVFN(0, 0));
 		iommu_dev = pcidev_path_behind(dev->link_list, PCI_DEVFN(0, 2));
 		if (!nb_dev) {
 			printk(BIOS_WARNING, "%s: Northbridge device not present!\n", __func__);
 			printk(BIOS_WARNING, "%s: IVRS table not generated...\n", __func__);
 			return (unsigned long)ivrs;
 		}

 		if (!iommu_dev) {
 			printk(BIOS_WARNING, "%s: IOMMU device not found\n", __func__);
 			return (unsigned long)ivrs;
 		}

 		ivhd->type = IVHD_BLOCK_TYPE_LEGACY__FIXED;
 		ivhd->length = sizeof(struct acpi_ivrs_ivhd);

 		/* BDF <bus>:00.2 */
 		ivhd->device_id = 0x02 | (nb_dev->bus->secondary << 8);
 		ivhd->capability_offset = pci_find_capability(iommu_dev, IOMMU_CAP_ID);
 		ivhd->iommu_base_low = pci_read_config32(iommu_dev, 0x44) & 0xffffc000;
 		ivhd->iommu_base_high = pci_read_config32(iommu_dev, 0x48);

 		cap_offset_0 = pci_read_config32(iommu_dev, ivhd->capability_offset);
 		cap_offset_10 = pci_read_config32(iommu_dev,
 						ivhd->capability_offset + 0x10);
 		mmio_x18_value = read64p(ivhd->iommu_base_low + 0x18);
 		mmio_x30_value = read64p(ivhd->iommu_base_low + 0x30);
 		mmio_x4000_value = read64p(ivhd->iommu_base_low + 0x4000);

 		ivhd->flags |= ((mmio_x30_value & MMIO_EXT_FEATURE_PPR_SUP) ?
 							IVHD_FLAG_PPE_SUP : 0);
 		ivhd->flags |= ((mmio_x30_value & MMIO_EXT_FEATURE_PRE_F_SUP) ?
 							IVHD_FLAG_PREF_SUP : 0);
 		ivhd->flags |= ((mmio_x18_value & MMIO_CTRL_COHERENT) ?
 							IVHD_FLAG_COHERENT : 0);
 		ivhd->flags |= ((cap_offset_0 & CAP_OFFSET_0_IOTLB_SP) ?
 							IVHD_FLAG_IOTLB_SUP : 0);
 		ivhd->flags |= ((mmio_x18_value & MMIO_CTRL_ISOC) ?
 							IVHD_FLAG_ISOC : 0);
 		ivhd->flags |= ((mmio_x18_value & MMIO_CTRL_RES_PASS_PW) ?
 							IVHD_FLAG_RES_PASS_PW : 0);
 		ivhd->flags |= ((mmio_x18_value & MMIO_CTRL_PASS_PW) ?
 							IVHD_FLAG_PASS_PW : 0);
 		ivhd->flags |= ((mmio_x18_value & MMIO_CTRL_HT_TUN_EN) ?
 							IVHD_FLAG_HT_TUN_EN : 0);

 		ivhd->pci_segment_group = 0x0000;

 		ivhd->iommu_info = pci_read_config16(iommu_dev,
 			ivhd->capability_offset + 0x10) & 0x1F;
 		ivhd->iommu_info |= (pci_read_config16(iommu_dev,
 			ivhd->capability_offset + 0xC) & 0x1F) << IOMMU_INFO_UNIT_ID_SHIFT;

 		ivhd->iommu_feature_info = 0;
 		ivhd->iommu_feature_info |= (mmio_x30_value & MMIO_EXT_FEATURE_HATS_MASK)
 			<< (IOMMU_FEATURE_HATS_SHIFT - MMIO_EXT_FEATURE_HATS_SHIFT);

 		ivhd->iommu_feature_info |= (mmio_x30_value & MMIO_EXT_FEATURE_GATS_MASK)
 			<< (IOMMU_FEATURE_GATS_SHIFT - MMIO_EXT_FEATURE_GATS_SHIFT);

 		ivhd->iommu_feature_info |= (cap_offset_10 & CAP_OFFSET_10_MSI_NUM_PPR)
 			>> (CAP_OFFSET_10_MSI_NUM_PPR_SHIFT
 				- IOMMU_FEATURE_MSI_NUM_PPR_SHIFT);

 		ivhd->iommu_feature_info |= (mmio_x4000_value &
 			MMIO_CNT_CFG_N_COUNTER_BANKS)
 			<< (IOMMU_FEATURE_PN_BANKS_SHIFT - MMIO_CNT_CFG_N_CNT_BANKS_SHIFT);

 		ivhd->iommu_feature_info |= (mmio_x4000_value & MMIO_CNT_CFG_N_COUNTER)
 			<< (IOMMU_FEATURE_PN_COUNTERS_SHIFT - MMIO_CNT_CFG_N_COUNTER_SHIFT);
 		ivhd->iommu_feature_info |= (mmio_x30_value &
 			MMIO_EXT_FEATURE_PAS_MAX_MASK)
 			>> (MMIO_EXT_FEATURE_PAS_MAX_SHIFT - IOMMU_FEATURE_PA_SMAX_SHIFT);
 		ivhd->iommu_feature_info |= ((mmio_x30_value & MMIO_EXT_FEATURE_HE_SUP)
 			? IOMMU_FEATURE_HE_SUP : 0);
 		ivhd->iommu_feature_info |= ((mmio_x30_value & MMIO_EXT_FEATURE_GA_SUP)
 			? IOMMU_FEATURE_GA_SUP : 0);
 		ivhd->iommu_feature_info |= ((mmio_x30_value & MMIO_EXT_FEATURE_IA_SUP)
 			? IOMMU_FEATURE_IA_SUP : 0);
 		ivhd->iommu_feature_info |= (mmio_x30_value &
 			MMIO_EXT_FEATURE_GLX_SUP_MASK)
 			>> (MMIO_EXT_FEATURE_GLX_SHIFT - IOMMU_FEATURE_GLX_SHIFT);
 		ivhd->iommu_feature_info |= ((mmio_x30_value & MMIO_EXT_FEATURE_GT_SUP)
 			? IOMMU_FEATURE_GT_SUP : 0);
 		ivhd->iommu_feature_info |= ((mmio_x30_value & MMIO_EXT_FEATURE_NX_SUP)
 			? IOMMU_FEATURE_NX_SUP : 0);
 		ivhd->iommu_feature_info |= ((mmio_x30_value & MMIO_EXT_FEATURE_XT_SUP)
 			? IOMMU_FEATURE_XT_SUP : 0);

 		/* Enable EFR if supported */
 		ivrs->iv_info = pci_read_config32(iommu_dev,
 					ivhd->capability_offset + 0x10) & 0x007fffe0;
 		if (pci_read_config32(iommu_dev,
 					ivhd->capability_offset) & EFR_FEATURE_SUP)
 			ivrs->iv_info |= IVINFO_EFR_SUPPORTED;


 		current_backup = current;
 		current = acpi_ivhd_misc(current, dev);
 		ivhd->length += (current - current_backup);

 		/* If EFR is not supported, IVHD type 11h is reserved */
 		if (!(ivrs->iv_info & IVINFO_EFR_SUPPORTED))
 			return current;

 		current = acpi_fill_ivrs11(current, ivhd, nb_dev, iommu_dev);

 		ivhd = (struct acpi_ivrs_ivhd *)current;
 		current += sizeof(struct acpi_ivrs_ivhd);
 	}
 	current -= sizeof(struct acpi_ivrs_ivhd);

 	return current;
 }
	/* SPDX-License-Identifier: GPL-2.0-only */

	#include <acpi/acpi_ivrs.h>
	#include <amdblocks/acpi.h>
	#include <amdblocks/cpu.h>
	#include <amdblocks/data_fabric.h>
	#include <amdblocks/ioapic.h>
	#include <arch/ioapic.h>
	#include <console/console.h>
	#include <cpu/amd/cpuid.h>
	#include <device/device.h>
	#include <device/mmio.h>
	#include <device/pci_def.h>
	#include <device/pci_ops.h>
	#include <soc/acpi.h>
	#include <soc/data_fabric.h>
	#include <soc/iomap.h>
	#include <soc/pci_devs.h>

	static unsigned long acpi_fill_ivrs_ioapic(unsigned long current, void *ioapic_base,
	uint16_t src_devid, uint8_t dte_setting)
	{
	ivrs_ivhd_special_t ivhd_ioapic = (ivrs_ivhd_special_t )current;
	memset(ivhd_ioapic, 0, sizeof(*ivhd_ioapic));

	ivhd_ioapic->type = IVHD_DEV_8_BYTE_EXT_SPECIAL_DEV;
	ivhd_ioapic->dte_setting = dte_setting;
	ivhd_ioapic->handle = get_ioapic_id(ioapic_base);
	ivhd_ioapic->source_dev_id = src_devid;
	ivhd_ioapic->variety = IVHD_SPECIAL_DEV_IOAPIC;
	current += sizeof(ivrs_ivhd_special_t);

	return current;
	}

	static unsigned long ivhd_describe_hpet(unsigned long current, uint8_t hndl, uint16_t src_devid)
	{
	ivrs_ivhd_special_t ivhd_hpet = (ivrs_ivhd_special_t )current;

	ivhd_hpet->type = IVHD_DEV_8_BYTE_EXT_SPECIAL_DEV;
	ivhd_hpet->reserved = 0x0000;
	ivhd_hpet->dte_setting = 0x00;
	ivhd_hpet->handle = hndl;
	ivhd_hpet->source_dev_id = src_devid; /* function 0 of FCH PCI device */
	ivhd_hpet->variety = IVHD_SPECIAL_DEV_HPET;
	current += sizeof(ivrs_ivhd_special_t);

	return current;
	}

	static unsigned long ivhd_describe_f0_device(unsigned long current,
	uint16_t dev_id, uint8_t datasetting)
	{
	ivrs_ivhd_f0_entry_t ivhd_f0 = (ivrs_ivhd_f0_entry_t )current;

	ivhd_f0->type = IVHD_DEV_VARIABLE;
	ivhd_f0->dev_id = dev_id;
	ivhd_f0->dte_setting = datasetting;
	ivhd_f0->hardware_id[0] = 'A';
	ivhd_f0->hardware_id[1] = 'M';
	ivhd_f0->hardware_id[2] = 'D';
	ivhd_f0->hardware_id[3] = 'I';
	ivhd_f0->hardware_id[4] = '0';
	ivhd_f0->hardware_id[5] = '0';
	ivhd_f0->hardware_id[6] = '4';
	ivhd_f0->hardware_id[7] = '0';

	memset(ivhd_f0->compatible_id, 0, sizeof(ivhd_f0->compatible_id));

	ivhd_f0->uuid_format = 0;
	ivhd_f0->uuid_length = 0;

	current += sizeof(ivrs_ivhd_f0_entry_t);
	return current;
	}

	static unsigned long ivhd_dev_range(unsigned long current, uint16_t start_devid,
	uint16_t end_devid, uint8_t setting)
	{
	/* 4-byte IVHD structures must be aligned to the 4-byte boundary. */
	current = ALIGN_UP(current, 4);
	ivrs_ivhd_generic_t ivhd_range = (ivrs_ivhd_generic_t )current;

	/* Create the start range IVHD entry */
	ivhd_range->type = IVHD_DEV_4_BYTE_START_RANGE;
	ivhd_range->dev_id = start_devid;
	ivhd_range->dte_setting = setting;
	current += sizeof(ivrs_ivhd_generic_t);

	/* Create the end range IVHD entry */
	ivhd_range = (ivrs_ivhd_generic_t *)current;
	ivhd_range->type = IVHD_DEV_4_BYTE_END_RANGE;
	ivhd_range->dev_id = end_devid;
	ivhd_range->dte_setting = setting;
	current += sizeof(ivrs_ivhd_generic_t);

	return current;
	}

	static unsigned long add_ivhd_dev_entry(struct device parent, struct device dev,
	unsigned long *current, uint8_t type, uint8_t data)
	{
	if (type == IVHD_DEV_4_BYTE_SELECT) {
	/* 4-byte IVHD structures must be aligned to the 4-byte boundary. */
	current = ALIGN_UP(current, 4);
	ivrs_ivhd_generic_t ivhd_entry = (ivrs_ivhd_generic_t )*current;

	ivhd_entry->type = type;
	ivhd_entry->dev_id = dev->path.pci.devfn \| (dev->bus->secondary << 8);
	ivhd_entry->dte_setting = data;
	*current += sizeof(ivrs_ivhd_generic_t);
	} else if (type == IVHD_DEV_8_BYTE_ALIAS_SELECT) {
	ivrs_ivhd_alias_t ivhd_entry = (ivrs_ivhd_alias_t )*current;

	ivhd_entry->type = type;
	ivhd_entry->dev_id = dev->path.pci.devfn \| (dev->bus->secondary << 8);
	ivhd_entry->dte_setting = data;
	ivhd_entry->reserved1 = 0;
	ivhd_entry->reserved2 = 0;
	ivhd_entry->source_dev_id = parent->path.pci.devfn \|
	(parent->bus->secondary << 8);
	*current += sizeof(ivrs_ivhd_alias_t);
	}

	return *current;
	}

	static void ivrs_add_device_or_bridge(struct device parent, struct device dev,
	unsigned long *current)
	{
	unsigned int header_type, is_pcie;

	header_type = dev->hdr_type & 0x7f;
	is_pcie = pci_find_capability(dev, PCI_CAP_ID_PCIE);

	if (((header_type == PCI_HEADER_TYPE_NORMAL) \|\|
	(header_type == PCI_HEADER_TYPE_BRIDGE)) && is_pcie) {
	/* Device or Bridge is PCIe */
	add_ivhd_dev_entry(parent, dev, current, IVHD_DEV_4_BYTE_SELECT, 0x0);
	} else if ((header_type == PCI_HEADER_TYPE_NORMAL) && !is_pcie) {
	/* Device is legacy PCI or PCI-X */
	add_ivhd_dev_entry(parent, dev, current, IVHD_DEV_8_BYTE_ALIAS_SELECT, 0x0);

	}
	}

	static void add_ivhd_device_entries(struct device parent, struct device dev,
	unsigned int depth, int linknum, int8_t *root_level,
	unsigned long *current, uint16_t nb_bus)
	{
	struct device *sibling;
	struct bus *link;

	if (!root_level)
	return;

	if (dev->path.type == DEVICE_PATH_PCI) {
	if ((dev->bus->secondary == nb_bus) &&
	(dev->path.pci.devfn == 0x0))
	*root_level = depth;

	if ((*root_level != -1) && (dev->enabled))
	if (depth != *root_level)
	ivrs_add_device_or_bridge(parent, dev, current);
	}

	for (link = dev->link_list; link; link = link->next)
	for (sibling = link->children; sibling; sibling =
	sibling->sibling)
	add_ivhd_device_entries(dev, sibling, depth + 1, depth, root_level,
	current, nb_bus);
	}

	static unsigned long acpi_ivhd_misc(unsigned long current, struct device *dev)
	{
	u8 dte_setting = IVHD_DTE_LINT_1_PASS \| IVHD_DTE_LINT_0_PASS \|
	IVHD_DTE_SYS_MGT_NO_TRANS \| IVHD_DTE_NMI_PASS \|
	IVHD_DTE_EXT_INT_PASS \| IVHD_DTE_INIT_PASS;
	int8_t root_level = -1;
	struct resource *res;

	/*
	* Add all possible PCI devices in the domain that can generate transactions
	* processed by IOMMU. Start with device <bus>:01.0
	*/
	current = ivhd_dev_range(current, PCI_DEVFN(0, 3) \| (dev->link_list->secondary << 8),
	0xff \| (dev->link_list->subordinate << 8), 0);

	add_ivhd_device_entries(NULL, dev, 0, -1, &root_level,
	&current, dev->link_list->secondary);

	res = probe_resource(dev, IOMMU_IOAPIC_IDX);
	if (res) {
	/* Describe IOAPIC associated with the IOMMU */
	current = acpi_fill_ivrs_ioapic(current, (u8 *)(uintptr_t)res->base,
	PCI_DEVFN(0, 1) \| (dev->link_list->secondary << 8), 0);
	}

	/* If the domain has secondary bus as zero then associate HPET & FCH IOAPIC */
	if (dev->link_list->secondary == 0) {
	/* Describe HPET */
	current = ivhd_describe_hpet(current, 0x00, SMBUS_DEVFN);
	/* Describe FCH IOAPICs */
	current = acpi_fill_ivrs_ioapic(current, VIO_APIC_VADDR,
	SMBUS_DEVFN, dte_setting);
	}

	return current;
	}

	static unsigned long acpi_fill_ivrs40(unsigned long current, acpi_ivrs_ivhd_t *ivhd,
	struct device nb_dev, struct device iommu_dev)
	{
	acpi_ivrs_ivhd40_t *ivhd_40;
	unsigned long current_backup;

	memset((void *)current, 0, sizeof(acpi_ivrs_ivhd40_t));
	ivhd_40 = (acpi_ivrs_ivhd40_t *)current;

	/* Enable EFR */
	ivhd_40->type = IVHD_BLOCK_TYPE_FULL__ACPI_HID;
	/* For type 40h bits 6 and 7 are reserved */
	ivhd_40->flags = ivhd->flags & 0x3f;
	ivhd_40->length = sizeof(struct acpi_ivrs_ivhd_40);
	/* BDF <bus>:00.2 */
	ivhd_40->device_id = 0x02 \| (nb_dev->bus->secondary << 8);
	ivhd_40->capability_offset = pci_find_capability(iommu_dev, IOMMU_CAP_ID);
	ivhd_40->iommu_base_low = ivhd->iommu_base_low;
	ivhd_40->iommu_base_high = ivhd->iommu_base_high;
	ivhd_40->pci_segment_group = 0x0000;
	ivhd_40->iommu_info = ivhd->iommu_info;
	/* For type 40h bits 31:28 and 12:0 are reserved */
	ivhd_40->iommu_attributes = ivhd->iommu_feature_info & 0xfffe000;

	if (pci_read_config32(iommu_dev, ivhd_40->capability_offset) & EFR_FEATURE_SUP) {
	ivhd_40->efr_reg_image_low = read32p(ivhd_40->iommu_base_low + 0x30);
	ivhd_40->efr_reg_image_high = read32p(ivhd_40->iommu_base_low + 0x34);
	}

	current += sizeof(acpi_ivrs_ivhd40_t);

	/* Now repeat all the device entries from type 10h */
	current_backup = current;
	current = acpi_ivhd_misc(current, nb_dev->bus->dev);

	if (nb_dev->bus->secondary == 0) {
	/* Describe EMMC */
	current = ivhd_describe_f0_device(current, PCI_DEVFN(0x13, 1),
	IVHD_DTE_LINT_1_PASS \| IVHD_DTE_LINT_0_PASS \|
	IVHD_DTE_SYS_MGT_TRANS \| IVHD_DTE_NMI_PASS \|
	IVHD_DTE_EXT_INT_PASS \| IVHD_DTE_INIT_PASS);
	}
	ivhd_40->length += (current - current_backup);

	return current;
	}

	static unsigned long acpi_fill_ivrs11(unsigned long current, acpi_ivrs_ivhd_t *ivhd,
	struct device nb_dev, struct device iommu_dev)
	{
	acpi_ivrs_ivhd11_t *ivhd_11;
	ivhd11_iommu_attr_t *ivhd11_attr_ptr;
	unsigned long current_backup;

	/*
	* In order to utilize all features, firmware should expose type 11h
	* IVHD which supersedes the type 10h.
	*/
	memset((void *)current, 0, sizeof(acpi_ivrs_ivhd11_t));
	ivhd_11 = (acpi_ivrs_ivhd11_t *)current;

	/* Enable EFR */
	ivhd_11->type = IVHD_BLOCK_TYPE_FULL__FIXED;
	/* For type 11h bits 6 and 7 are reserved */
	ivhd_11->flags = ivhd->flags & 0x3f;
	ivhd_11->length = sizeof(struct acpi_ivrs_ivhd_11);
	/* BDF <bus>:00.2 */
	ivhd_11->device_id = 0x02 \| (nb_dev->bus->secondary << 8);
	ivhd_11->capability_offset = pci_find_capability(iommu_dev, IOMMU_CAP_ID);
	ivhd_11->iommu_base_low = ivhd->iommu_base_low;
	ivhd_11->iommu_base_high = ivhd->iommu_base_high;
	ivhd_11->pci_segment_group = 0x0000;
	ivhd_11->iommu_info = ivhd->iommu_info;
	ivhd11_attr_ptr = (ivhd11_iommu_attr_t *)&ivhd->iommu_feature_info;
	ivhd_11->iommu_attributes.perf_counters = ivhd11_attr_ptr->perf_counters;
	ivhd_11->iommu_attributes.perf_counter_banks = ivhd11_attr_ptr->perf_counter_banks;
	ivhd_11->iommu_attributes.msi_num_ppr = ivhd11_attr_ptr->msi_num_ppr;

	if (pci_read_config32(iommu_dev, ivhd_11->capability_offset) & EFR_FEATURE_SUP) {
	ivhd_11->efr_reg_image_low = read32p(ivhd_11->iommu_base_low + 0x30);
	ivhd_11->efr_reg_image_high = read32p(ivhd_11->iommu_base_low + 0x34);
	}

	current += sizeof(acpi_ivrs_ivhd11_t);

	/* Now repeat all the device entries from type 10h */
	current_backup = current;
	current = acpi_ivhd_misc(current, nb_dev->bus->dev);
	ivhd_11->length += (current - current_backup);

	return acpi_fill_ivrs40(current, ivhd, nb_dev, iommu_dev);
	}

	unsigned long acpi_fill_ivrs(acpi_ivrs_t *ivrs, unsigned long current)
	{
	unsigned long current_backup;
	uint64_t mmio_x30_value;
	uint64_t mmio_x18_value;
	uint64_t mmio_x4000_value;
	uint32_t cap_offset_0;
	uint32_t cap_offset_10;
	struct acpi_ivrs_ivhd *ivhd;
	struct device *iommu_dev;
	struct device *nb_dev;
	struct device *dev = NULL;

	ivhd = &ivrs->ivhd;

	while ((dev = dev_find_path(dev, DEVICE_PATH_DOMAIN)) != NULL) {

	nb_dev = pcidev_path_behind(dev->link_list, PCI_DEVFN(0, 0));
	iommu_dev = pcidev_path_behind(dev->link_list, PCI_DEVFN(0, 2));
	if (!nb_dev) {
	printk(BIOS_WARNING, "%s: Northbridge device not present!\n", __func__);
	printk(BIOS_WARNING, "%s: IVRS table not generated...\n", __func__);
	return (unsigned long)ivrs;
	}

	if (!iommu_dev) {
	printk(BIOS_WARNING, "%s: IOMMU device not found\n", __func__);
	return (unsigned long)ivrs;
	}

	ivhd->type = IVHD_BLOCK_TYPE_LEGACY__FIXED;
	ivhd->length = sizeof(struct acpi_ivrs_ivhd);

	/* BDF <bus>:00.2 */
	ivhd->device_id = 0x02 \| (nb_dev->bus->secondary << 8);
	ivhd->capability_offset = pci_find_capability(iommu_dev, IOMMU_CAP_ID);
	ivhd->iommu_base_low = pci_read_config32(iommu_dev, 0x44) & 0xffffc000;
	ivhd->iommu_base_high = pci_read_config32(iommu_dev, 0x48);

	cap_offset_0 = pci_read_config32(iommu_dev, ivhd->capability_offset);
	cap_offset_10 = pci_read_config32(iommu_dev,
	ivhd->capability_offset + 0x10);
	mmio_x18_value = read64p(ivhd->iommu_base_low + 0x18);
	mmio_x30_value = read64p(ivhd->iommu_base_low + 0x30);
	mmio_x4000_value = read64p(ivhd->iommu_base_low + 0x4000);

	ivhd->flags \|= ((mmio_x30_value & MMIO_EXT_FEATURE_PPR_SUP) ?
	IVHD_FLAG_PPE_SUP : 0);
	ivhd->flags \|= ((mmio_x30_value & MMIO_EXT_FEATURE_PRE_F_SUP) ?
	IVHD_FLAG_PREF_SUP : 0);
	ivhd->flags \|= ((mmio_x18_value & MMIO_CTRL_COHERENT) ?
	IVHD_FLAG_COHERENT : 0);
	ivhd->flags \|= ((cap_offset_0 & CAP_OFFSET_0_IOTLB_SP) ?
	IVHD_FLAG_IOTLB_SUP : 0);
	ivhd->flags \|= ((mmio_x18_value & MMIO_CTRL_ISOC) ?
	IVHD_FLAG_ISOC : 0);
	ivhd->flags \|= ((mmio_x18_value & MMIO_CTRL_RES_PASS_PW) ?
	IVHD_FLAG_RES_PASS_PW : 0);
	ivhd->flags \|= ((mmio_x18_value & MMIO_CTRL_PASS_PW) ?
	IVHD_FLAG_PASS_PW : 0);
	ivhd->flags \|= ((mmio_x18_value & MMIO_CTRL_HT_TUN_EN) ?
	IVHD_FLAG_HT_TUN_EN : 0);

	ivhd->pci_segment_group = 0x0000;

	ivhd->iommu_info = pci_read_config16(iommu_dev,
	ivhd->capability_offset + 0x10) & 0x1F;
	ivhd->iommu_info \|= (pci_read_config16(iommu_dev,
	ivhd->capability_offset + 0xC) & 0x1F) << IOMMU_INFO_UNIT_ID_SHIFT;

	ivhd->iommu_feature_info = 0;
	ivhd->iommu_feature_info \|= (mmio_x30_value & MMIO_EXT_FEATURE_HATS_MASK)
	<< (IOMMU_FEATURE_HATS_SHIFT - MMIO_EXT_FEATURE_HATS_SHIFT);

	ivhd->iommu_feature_info \|= (mmio_x30_value & MMIO_EXT_FEATURE_GATS_MASK)
	<< (IOMMU_FEATURE_GATS_SHIFT - MMIO_EXT_FEATURE_GATS_SHIFT);

	ivhd->iommu_feature_info \|= (cap_offset_10 & CAP_OFFSET_10_MSI_NUM_PPR)
	>> (CAP_OFFSET_10_MSI_NUM_PPR_SHIFT
	- IOMMU_FEATURE_MSI_NUM_PPR_SHIFT);

	ivhd->iommu_feature_info \|= (mmio_x4000_value &
	MMIO_CNT_CFG_N_COUNTER_BANKS)
	<< (IOMMU_FEATURE_PN_BANKS_SHIFT - MMIO_CNT_CFG_N_CNT_BANKS_SHIFT);

	ivhd->iommu_feature_info \|= (mmio_x4000_value & MMIO_CNT_CFG_N_COUNTER)
	<< (IOMMU_FEATURE_PN_COUNTERS_SHIFT - MMIO_CNT_CFG_N_COUNTER_SHIFT);
	ivhd->iommu_feature_info \|= (mmio_x30_value &
	MMIO_EXT_FEATURE_PAS_MAX_MASK)
	>> (MMIO_EXT_FEATURE_PAS_MAX_SHIFT - IOMMU_FEATURE_PA_SMAX_SHIFT);
	ivhd->iommu_feature_info \|= ((mmio_x30_value & MMIO_EXT_FEATURE_HE_SUP)
	? IOMMU_FEATURE_HE_SUP : 0);
	ivhd->iommu_feature_info \|= ((mmio_x30_value & MMIO_EXT_FEATURE_GA_SUP)
	? IOMMU_FEATURE_GA_SUP : 0);
	ivhd->iommu_feature_info \|= ((mmio_x30_value & MMIO_EXT_FEATURE_IA_SUP)
	? IOMMU_FEATURE_IA_SUP : 0);
	ivhd->iommu_feature_info \|= (mmio_x30_value &
	MMIO_EXT_FEATURE_GLX_SUP_MASK)
	>> (MMIO_EXT_FEATURE_GLX_SHIFT - IOMMU_FEATURE_GLX_SHIFT);
	ivhd->iommu_feature_info \|= ((mmio_x30_value & MMIO_EXT_FEATURE_GT_SUP)
	? IOMMU_FEATURE_GT_SUP : 0);
	ivhd->iommu_feature_info \|= ((mmio_x30_value & MMIO_EXT_FEATURE_NX_SUP)
	? IOMMU_FEATURE_NX_SUP : 0);
	ivhd->iommu_feature_info \|= ((mmio_x30_value & MMIO_EXT_FEATURE_XT_SUP)
	? IOMMU_FEATURE_XT_SUP : 0);

	/* Enable EFR if supported */
	ivrs->iv_info = pci_read_config32(iommu_dev,
	ivhd->capability_offset + 0x10) & 0x007fffe0;
	if (pci_read_config32(iommu_dev,
	ivhd->capability_offset) & EFR_FEATURE_SUP)
	ivrs->iv_info \|= IVINFO_EFR_SUPPORTED;


	current_backup = current;
	current = acpi_ivhd_misc(current, dev);
	ivhd->length += (current - current_backup);

	/* If EFR is not supported, IVHD type 11h is reserved */
	if (!(ivrs->iv_info & IVINFO_EFR_SUPPORTED))
	return current;

	current = acpi_fill_ivrs11(current, ivhd, nb_dev, iommu_dev);

	ivhd = (struct acpi_ivrs_ivhd *)current;
	current += sizeof(struct acpi_ivrs_ivhd);
	}
	current -= sizeof(struct acpi_ivrs_ivhd);

	return current;
	}