arch/x86/core/acpi.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2020 Intel Corporation
  * SPDX-License-Identifier: Apache-2.0
  */
 #include <zephyr/kernel.h>
 #include <zephyr/arch/x86/acpi.h>
 #include <zephyr/arch/x86/efi.h>

 static struct acpi_rsdp *rsdp;
 static bool is_rsdp_searched;

 static struct acpi_dmar *dmar;
 static bool is_dmar_searched;

 static bool check_sum(struct acpi_sdt *t)
 {
 	uint8_t sum = 0U, *p = (uint8_t *)t;

 	for (int i = 0; i < t->length; i++) {
 		sum += p[i];
 	}

 	return sum == 0U;
 }

 static void find_rsdp(void)
 {
 	uint8_t *bda_seg, *zero_page_base;
 	uint64_t *search;
 	uintptr_t search_phys, rsdp_phys = 0U;
 	size_t search_length = 0U, rsdp_length;

 	if (is_rsdp_searched) {
 		/* Looking up for RSDP has already been done */
 		return;
 	}

 	/* Let's first get it from EFI, if enabled */
 	if (IS_ENABLED(CONFIG_X86_EFI)) {
 		rsdp_phys = (uintptr_t)efi_get_acpi_rsdp();
 		if (rsdp_phys != 0UL) {
 			/* See at found label why this is required */
 			search_length = sizeof(struct acpi_rsdp);
 			z_phys_map((uint8_t **)&search, rsdp_phys, search_length, 0);
 			rsdp = (struct acpi_rsdp *)search;

 			goto found;
 		}
 	}

 	/* We never identity map the NULL page, so need to map it before
 	 * it can be accessed.
 	 */
 	z_phys_map(&zero_page_base, 0, 4096, 0);

 	/* Physical (real mode!) address 0000:040e stores a (real
 	 * mode!!) segment descriptor pointing to the 1kb Extended
 	 * BIOS Data Area.
 	 *
 	 * We had to memory map this segment descriptor since it is in
 	 * the NULL page. The remaining structures (EBDA etc) are identity
 	 * mapped somewhere within the minefield of reserved regions in the
 	 * first megabyte and are directly accessible.
 	 */
 	bda_seg = 0x040e + zero_page_base;
 	search_phys = (long)(((int)*(uint16_t *)bda_seg) << 4);

 	/* Unmap after use */
 	z_phys_unmap(zero_page_base, 4096);

 	/* Might be nothing there, check before we inspect.
 	 * Note that EBDA usually is in 0x80000 to 0x100000.
 	 */
 	if ((POINTER_TO_UINT(search_phys) >= 0x80000UL) &&
 	    (POINTER_TO_UINT(search_phys) < 0x100000UL)) {
 		search_length = 1024;
 		z_phys_map((uint8_t **)&search, search_phys, search_length, 0);

 		for (int i = 0; i < 1024/8; i++) {
 			if (search[i] == ACPI_RSDP_SIGNATURE) {
 				rsdp_phys = search_phys + i * 8;
 				rsdp = (void *)&search[i];
 				goto found;
 			}
 		}

 		z_phys_unmap((uint8_t *)search, search_length);
 	}

 	/* If it's not there, then look for it in the last 128kb of
 	 * real mode memory.
 	 */
 	search_phys = 0xe0000;
 	search_length = 128 * 1024;
 	z_phys_map((uint8_t **)&search, search_phys, search_length, 0);

 	rsdp_phys = 0U;
 	for (int i = 0; i < 128*1024/8; i++) {
 		if (search[i] == ACPI_RSDP_SIGNATURE) {
 			rsdp_phys = search_phys + i * 8;
 			rsdp = (void *)&search[i];
 			goto found;
 		}
 	}

 	z_phys_unmap((uint8_t *)search, search_length);

 	rsdp = NULL;

 	is_rsdp_searched = true;

 	return;

 found:
 	/* Determine length of RSDP table.
 	 * ACPI v2 and above uses the length field.
 	 * Otherwise, just the size of struct itself.
 	 */
 	if (rsdp->revision < 2) {
 		rsdp_length = sizeof(*rsdp);
 	} else {
 		rsdp_length = rsdp->length;
 	}

 	/* Need to unmap search since it is still mapped */
 	if (search_length != 0U) {
 		z_phys_unmap((uint8_t *)search, search_length);
 	}

 	/* Now map the RSDP */
 	z_phys_map((uint8_t **)&rsdp, rsdp_phys, rsdp_length, 0);

 	is_rsdp_searched = true;
 }

 void *z_acpi_find_table(uint32_t signature)
 {
 	uint8_t *mapped_tbl;
 	uint32_t length;
 	struct acpi_rsdt *rsdt;
 	struct acpi_xsdt *xsdt;
 	struct acpi_sdt *t;
 	uintptr_t t_phys;
 	bool tbl_found;

 	find_rsdp();

 	if (!rsdp) {
 		return NULL;
 	}

 	if (rsdp->rsdt_ptr != 0U) {
 		z_phys_map((uint8_t **)&rsdt, rsdp->rsdt_ptr, sizeof(*rsdt), 0);
 		tbl_found = false;

 		if (check_sum(&rsdt->sdt)) {
 			/* Remap the memory to the indicated length of RSDT */
 			length = rsdt->sdt.length;
 			z_phys_unmap((uint8_t *)rsdt, sizeof(*rsdt));
 			z_phys_map((uint8_t **)&rsdt, rsdp->rsdt_ptr, length, 0);

 			uint32_t *end = (uint32_t *)((char *)rsdt + rsdt->sdt.length);

 			/* Extra indirection required to avoid
 			 * -Waddress-of-packed-member
 			 */
 			void *table_ptrs = &rsdt->table_ptrs[0];

 			for (uint32_t *tp = table_ptrs; tp < end; tp++) {
 				t_phys = (long)*tp;
 				z_phys_map(&mapped_tbl, t_phys, sizeof(*t), 0);
 				t = (void *)mapped_tbl;

 				if (t->signature == signature && check_sum(t)) {
 					tbl_found = true;
 					break;
 				}

 				z_phys_unmap(mapped_tbl, sizeof(*t));
 			}
 		}

 		z_phys_unmap((uint8_t *)rsdt, sizeof(*rsdt));

 		if (tbl_found) {
 			goto found;
 		}
 	}

 	if (rsdp->revision < 2) {
 		return NULL;
 	}

 	if (rsdp->xsdt_ptr != 0ULL) {
 		z_phys_map((uint8_t **)&xsdt, rsdp->xsdt_ptr, sizeof(*xsdt), 0);

 		tbl_found = false;
 		if (check_sum(&xsdt->sdt)) {
 			/* Remap the memory to the indicated length of RSDT */
 			length = xsdt->sdt.length;
 			z_phys_unmap((uint8_t *)xsdt, sizeof(*xsdt));
 			z_phys_map((uint8_t **)&xsdt, rsdp->xsdt_ptr, length, 0);

 			uint64_t *end = (uint64_t *)((char *)xsdt + xsdt->sdt.length);

 			/* Extra indirection required to avoid
 			 * -Waddress-of-packed-member
 			 */
 			void *table_ptrs = &xsdt->table_ptrs[0];

 			for (uint64_t *tp = table_ptrs; tp < end; tp++) {
 				t_phys = (long)*tp;
 				z_phys_map(&mapped_tbl, t_phys, sizeof(*t), 0);
 				t = (void *)mapped_tbl;

 				if (t->signature == signature && check_sum(t)) {
 					tbl_found = true;
 					break;
 				}

 				z_phys_unmap(mapped_tbl, sizeof(*t));
 			}
 		}

 		z_phys_unmap((uint8_t *)xsdt, sizeof(*xsdt));

 		if (tbl_found) {
 			goto found;
 		}
 	}

 	return NULL;

 found:
 	/* Remap to indicated length of the table */
 	length = t->length;
 	z_phys_unmap(mapped_tbl, sizeof(*t));
 	z_phys_map(&mapped_tbl, t_phys, length, 0);
 	t = (void *)mapped_tbl;

 	return t;
 }

 /*
  * Return the 'n'th CPU entry from the ACPI MADT, or NULL if not available.
  */

 struct acpi_cpu *z_acpi_get_cpu(int n)
 {
 	struct acpi_madt *madt = z_acpi_find_table(ACPI_MADT_SIGNATURE);
 	uintptr_t base = POINTER_TO_UINT(madt);
 	uintptr_t offset;

 	if (!madt) {
 		return NULL;
 	}

 	offset = POINTER_TO_UINT(madt->entries) - base;

 	while (offset < madt->sdt.length) {
 		struct acpi_madt_entry *entry;

 		entry = (struct acpi_madt_entry *)(offset + base);
 		if (entry->type == ACPI_MADT_ENTRY_CPU) {
 			struct acpi_cpu *cpu = (struct acpi_cpu *)entry;

 			if ((cpu->flags & ACPI_CPU_FLAGS_ENABLED) != 0) {
 				if (n == 0) {
 					return cpu;
 				}

 				--n;
 			}
 		}

 		offset += entry->length;
 	}

 	return NULL;
 }

 static void find_dmar(void)
 {
 	if (is_dmar_searched) {
 		return;
 	}

 	dmar = z_acpi_find_table(ACPI_DMAR_SIGNATURE);
 	is_dmar_searched = true;
 }

 struct acpi_dmar *z_acpi_find_dmar(void)
 {
 	find_dmar();
 	return dmar;
 }

 struct acpi_drhd *z_acpi_find_drhds(int *n)
 {
 	struct acpi_drhd *drhds = NULL;
 	uintptr_t offset;
 	uintptr_t base;

 	find_dmar();

 	if (dmar == NULL) {
 		return NULL;
 	}

 	*n = 0;
 	base = POINTER_TO_UINT(dmar);

 	offset = POINTER_TO_UINT(dmar->remap_entries) - base;
 	while (offset < dmar->sdt.length) {
 		struct acpi_dmar_entry *entry;

 		entry = (struct acpi_dmar_entry *)(offset + base);
 		if (entry->type == ACPI_DMAR_TYPE_DRHD) {
 			if (*n == 0) {
 				drhds = (struct acpi_drhd *)entry;
 			}

 			(*n)++;
 		} else {
 			/* DMAR entries are found packed by type so
 			 * if type is not DRHD, we will not encounter one,
 			 * anymore.
 			 */
 			break;
 		}

 		offset += entry->length;
 	}

 	return drhds;
 }

 struct acpi_dmar_dev_scope *z_acpi_get_drhd_dev_scopes(struct acpi_drhd *drhd,
 						       int *n)
 {
 	uintptr_t offset;
 	uintptr_t base;

 	if (drhd->entry.length <= ACPI_DRHD_MIN_SIZE) {
 		return NULL;
 	}

 	*n = 0;
 	base = POINTER_TO_UINT(drhd);

 	offset = POINTER_TO_UINT(drhd->device_scope) - base;
 	while (offset < drhd->entry.length) {
 		struct acpi_dmar_dev_scope *dev_scope;

 		dev_scope = (struct acpi_dmar_dev_scope *)(offset + base);

 		(*n)++;

 		offset += dev_scope->length;
 	}

 	return (*n == 0) ? NULL : drhd->device_scope;
 }

 struct acpi_dmar_dev_path *
 z_acpi_get_dev_scope_paths(struct acpi_dmar_dev_scope *dev_scope, int *n)
 {
 	switch (dev_scope->type) {
 	case ACPI_DRHD_DEV_SCOPE_PCI_EPD:
 		/* Fall through */
 	case ACPI_DRHD_DEV_SCOPE_PCI_SUB_H:
 		/* Fall through */
 	case ACPI_DRHD_DEV_SCOPE_IOAPIC:
 		if (dev_scope->length < (ACPI_DMAR_DEV_SCOPE_MIN_SIZE +
 					 ACPI_DMAR_DEV_PATH_SIZE)) {
 			return NULL;
 		}

 		break;
 	case ACPI_DRHD_DEV_SCOPE_MSI_CAP_HPET:
 		/* Fall through */
 	case ACPI_DRHD_DEV_SCOPE_NAMESPACE_DEV:
 		if (dev_scope->length != (ACPI_DMAR_DEV_SCOPE_MIN_SIZE +
 					  ACPI_DMAR_DEV_PATH_SIZE)) {
 			return NULL;
 		}

 		break;
 	default:
 		return NULL;
 	}

 	*n = (dev_scope->length - ACPI_DMAR_DEV_SCOPE_MIN_SIZE) /
 		ACPI_DMAR_DEV_PATH_SIZE;

 	return dev_scope->path;
 }

 uint16_t z_acpi_get_dev_id_from_dmar(uint8_t dev_scope_type)
 {
 	struct acpi_drhd *drhd;
 	int n_drhd;

 	find_dmar();

 	if (dmar == NULL) {
 		return USHRT_MAX;
 	}

 	drhd = z_acpi_find_drhds(&n_drhd);

 	for (; n_drhd > 0; n_drhd--) {
 		struct acpi_dmar_dev_scope *dev_scope;
 		int n_ds;

 		dev_scope = z_acpi_get_drhd_dev_scopes(drhd, &n_ds);
 		for (; n_ds > 0; n_ds--) {
 			if (dev_scope->type == dev_scope_type) {
 				struct acpi_dmar_dev_path *path;
 				int n_path;

 				path = z_acpi_get_dev_scope_paths(dev_scope,
 								  &n_path);
 				if (n_path > 0) {
 					union acpi_dmar_id id;

 					/* Let's over simplify for now:
 					 * we don't look for secondary bus
 					 * and extra paths. We just stop here.
 					 */

 					id.bits.bus = dev_scope->start_bus_num;
 					id.bits.device = path->device;
 					id.bits.function = path->function;

 					return id.raw;
 				}
 			}

 			dev_scope = (struct acpi_dmar_dev_scope *)(
 				POINTER_TO_UINT(dev_scope) + dev_scope->length);
 		}

 		drhd = (struct acpi_drhd *)(POINTER_TO_UINT(drhd) +
 					    drhd->entry.length);
 	}

 	return USHRT_MAX;
 }
	/*
	* Copyright (c) 2020 Intel Corporation
	* SPDX-License-Identifier: Apache-2.0
	*/
	#include <zephyr/kernel.h>
	#include <zephyr/arch/x86/acpi.h>
	#include <zephyr/arch/x86/efi.h>

	static struct acpi_rsdp *rsdp;
	static bool is_rsdp_searched;

	static struct acpi_dmar *dmar;
	static bool is_dmar_searched;

	static bool check_sum(struct acpi_sdt *t)
	{
	uint8_t sum = 0U, p = (uint8_t )t;

	for (int i = 0; i < t->length; i++) {
	sum += p[i];
	}

	return sum == 0U;
	}

	static void find_rsdp(void)
	{
	uint8_t bda_seg, zero_page_base;
	uint64_t *search;
	uintptr_t search_phys, rsdp_phys = 0U;
	size_t search_length = 0U, rsdp_length;

	if (is_rsdp_searched) {
	/* Looking up for RSDP has already been done */
	return;
	}

	/* Let's first get it from EFI, if enabled */
	if (IS_ENABLED(CONFIG_X86_EFI)) {
	rsdp_phys = (uintptr_t)efi_get_acpi_rsdp();
	if (rsdp_phys != 0UL) {
	/* See at found label why this is required */
	search_length = sizeof(struct acpi_rsdp);
	z_phys_map((uint8_t **)&search, rsdp_phys, search_length, 0);
	rsdp = (struct acpi_rsdp *)search;

	goto found;
	}
	}

	/* We never identity map the NULL page, so need to map it before
	* it can be accessed.
	*/
	z_phys_map(&zero_page_base, 0, 4096, 0);

	/* Physical (real mode!) address 0000:040e stores a (real
	* mode!!) segment descriptor pointing to the 1kb Extended
	* BIOS Data Area.
	*
	* We had to memory map this segment descriptor since it is in
	* the NULL page. The remaining structures (EBDA etc) are identity
	* mapped somewhere within the minefield of reserved regions in the
	* first megabyte and are directly accessible.
	*/
	bda_seg = 0x040e + zero_page_base;
	search_phys = (long)(((int)(uint16_t )bda_seg) << 4);

	/* Unmap after use */
	z_phys_unmap(zero_page_base, 4096);

	/* Might be nothing there, check before we inspect.
	* Note that EBDA usually is in 0x80000 to 0x100000.
	*/
	if ((POINTER_TO_UINT(search_phys) >= 0x80000UL) &&
	(POINTER_TO_UINT(search_phys) < 0x100000UL)) {
	search_length = 1024;
	z_phys_map((uint8_t **)&search, search_phys, search_length, 0);

	for (int i = 0; i < 1024/8; i++) {
	if (search[i] == ACPI_RSDP_SIGNATURE) {
	rsdp_phys = search_phys + i * 8;
	rsdp = (void *)&search[i];
	goto found;
	}
	}

	z_phys_unmap((uint8_t *)search, search_length);
	}

	/* If it's not there, then look for it in the last 128kb of
	* real mode memory.
	*/
	search_phys = 0xe0000;
	search_length = 128 * 1024;
	z_phys_map((uint8_t **)&search, search_phys, search_length, 0);

	rsdp_phys = 0U;
	for (int i = 0; i < 128*1024/8; i++) {
	if (search[i] == ACPI_RSDP_SIGNATURE) {
	rsdp_phys = search_phys + i * 8;
	rsdp = (void *)&search[i];
	goto found;
	}
	}

	z_phys_unmap((uint8_t *)search, search_length);

	rsdp = NULL;

	is_rsdp_searched = true;

	return;

	found:
	/* Determine length of RSDP table.
	* ACPI v2 and above uses the length field.
	* Otherwise, just the size of struct itself.
	*/
	if (rsdp->revision < 2) {
	rsdp_length = sizeof(*rsdp);
	} else {
	rsdp_length = rsdp->length;
	}

	/* Need to unmap search since it is still mapped */
	if (search_length != 0U) {
	z_phys_unmap((uint8_t *)search, search_length);
	}

	/* Now map the RSDP */
	z_phys_map((uint8_t **)&rsdp, rsdp_phys, rsdp_length, 0);

	is_rsdp_searched = true;
	}

	void *z_acpi_find_table(uint32_t signature)
	{
	uint8_t *mapped_tbl;
	uint32_t length;
	struct acpi_rsdt *rsdt;
	struct acpi_xsdt *xsdt;
	struct acpi_sdt *t;
	uintptr_t t_phys;
	bool tbl_found;

	find_rsdp();

	if (!rsdp) {
	return NULL;
	}

	if (rsdp->rsdt_ptr != 0U) {
	z_phys_map((uint8_t *)&rsdt, rsdp->rsdt_ptr, sizeof(rsdt), 0);
	tbl_found = false;

	if (check_sum(&rsdt->sdt)) {
	/* Remap the memory to the indicated length of RSDT */
	length = rsdt->sdt.length;
	z_phys_unmap((uint8_t )rsdt, sizeof(rsdt));
	z_phys_map((uint8_t **)&rsdt, rsdp->rsdt_ptr, length, 0);

	uint32_t end = (uint32_t )((char *)rsdt + rsdt->sdt.length);

	/* Extra indirection required to avoid
	* -Waddress-of-packed-member
	*/
	void *table_ptrs = &rsdt->table_ptrs[0];

	for (uint32_t *tp = table_ptrs; tp < end; tp++) {
	t_phys = (long)*tp;
	z_phys_map(&mapped_tbl, t_phys, sizeof(*t), 0);
	t = (void *)mapped_tbl;

	if (t->signature == signature && check_sum(t)) {
	tbl_found = true;
	break;
	}

	z_phys_unmap(mapped_tbl, sizeof(*t));
	}
	}

	z_phys_unmap((uint8_t )rsdt, sizeof(rsdt));

	if (tbl_found) {
	goto found;
	}
	}

	if (rsdp->revision < 2) {
	return NULL;
	}

	if (rsdp->xsdt_ptr != 0ULL) {
	z_phys_map((uint8_t *)&xsdt, rsdp->xsdt_ptr, sizeof(xsdt), 0);

	tbl_found = false;
	if (check_sum(&xsdt->sdt)) {
	/* Remap the memory to the indicated length of RSDT */
	length = xsdt->sdt.length;
	z_phys_unmap((uint8_t )xsdt, sizeof(xsdt));
	z_phys_map((uint8_t **)&xsdt, rsdp->xsdt_ptr, length, 0);

	uint64_t end = (uint64_t )((char *)xsdt + xsdt->sdt.length);

	/* Extra indirection required to avoid
	* -Waddress-of-packed-member
	*/
	void *table_ptrs = &xsdt->table_ptrs[0];

	for (uint64_t *tp = table_ptrs; tp < end; tp++) {
	t_phys = (long)*tp;
	z_phys_map(&mapped_tbl, t_phys, sizeof(*t), 0);
	t = (void *)mapped_tbl;

	if (t->signature == signature && check_sum(t)) {
	tbl_found = true;
	break;
	}

	z_phys_unmap(mapped_tbl, sizeof(*t));
	}
	}

	z_phys_unmap((uint8_t )xsdt, sizeof(xsdt));

	if (tbl_found) {
	goto found;
	}
	}

	return NULL;

	found:
	/* Remap to indicated length of the table */
	length = t->length;
	z_phys_unmap(mapped_tbl, sizeof(*t));
	z_phys_map(&mapped_tbl, t_phys, length, 0);
	t = (void *)mapped_tbl;

	return t;
	}

	/*
	* Return the 'n'th CPU entry from the ACPI MADT, or NULL if not available.
	*/

	struct acpi_cpu *z_acpi_get_cpu(int n)
	{
	struct acpi_madt *madt = z_acpi_find_table(ACPI_MADT_SIGNATURE);
	uintptr_t base = POINTER_TO_UINT(madt);
	uintptr_t offset;

	if (!madt) {
	return NULL;
	}

	offset = POINTER_TO_UINT(madt->entries) - base;

	while (offset < madt->sdt.length) {
	struct acpi_madt_entry *entry;

	entry = (struct acpi_madt_entry *)(offset + base);
	if (entry->type == ACPI_MADT_ENTRY_CPU) {
	struct acpi_cpu cpu = (struct acpi_cpu )entry;

	if ((cpu->flags & ACPI_CPU_FLAGS_ENABLED) != 0) {
	if (n == 0) {
	return cpu;
	}

	--n;
	}
	}

	offset += entry->length;
	}

	return NULL;
	}

	static void find_dmar(void)
	{
	if (is_dmar_searched) {
	return;
	}

	dmar = z_acpi_find_table(ACPI_DMAR_SIGNATURE);
	is_dmar_searched = true;
	}

	struct acpi_dmar *z_acpi_find_dmar(void)
	{
	find_dmar();
	return dmar;
	}

	struct acpi_drhd z_acpi_find_drhds(int n)
	{
	struct acpi_drhd *drhds = NULL;
	uintptr_t offset;
	uintptr_t base;

	find_dmar();

	if (dmar == NULL) {
	return NULL;
	}

	*n = 0;
	base = POINTER_TO_UINT(dmar);

	offset = POINTER_TO_UINT(dmar->remap_entries) - base;
	while (offset < dmar->sdt.length) {
	struct acpi_dmar_entry *entry;

	entry = (struct acpi_dmar_entry *)(offset + base);
	if (entry->type == ACPI_DMAR_TYPE_DRHD) {
	if (*n == 0) {
	drhds = (struct acpi_drhd *)entry;
	}

	(*n)++;
	} else {
	/* DMAR entries are found packed by type so
	* if type is not DRHD, we will not encounter one,
	* anymore.
	*/
	break;
	}

	offset += entry->length;
	}

	return drhds;
	}

	struct acpi_dmar_dev_scope z_acpi_get_drhd_dev_scopes(struct acpi_drhd drhd,
	int *n)
	{
	uintptr_t offset;
	uintptr_t base;

	if (drhd->entry.length <= ACPI_DRHD_MIN_SIZE) {
	return NULL;
	}

	*n = 0;
	base = POINTER_TO_UINT(drhd);

	offset = POINTER_TO_UINT(drhd->device_scope) - base;
	while (offset < drhd->entry.length) {
	struct acpi_dmar_dev_scope *dev_scope;

	dev_scope = (struct acpi_dmar_dev_scope *)(offset + base);

	(*n)++;

	offset += dev_scope->length;
	}

	return (*n == 0) ? NULL : drhd->device_scope;
	}

	struct acpi_dmar_dev_path *
	z_acpi_get_dev_scope_paths(struct acpi_dmar_dev_scope dev_scope, int n)
	{
	switch (dev_scope->type) {
	case ACPI_DRHD_DEV_SCOPE_PCI_EPD:
	/* Fall through */
	case ACPI_DRHD_DEV_SCOPE_PCI_SUB_H:
	/* Fall through */
	case ACPI_DRHD_DEV_SCOPE_IOAPIC:
	if (dev_scope->length < (ACPI_DMAR_DEV_SCOPE_MIN_SIZE +
	ACPI_DMAR_DEV_PATH_SIZE)) {
	return NULL;
	}

	break;
	case ACPI_DRHD_DEV_SCOPE_MSI_CAP_HPET:
	/* Fall through */
	case ACPI_DRHD_DEV_SCOPE_NAMESPACE_DEV:
	if (dev_scope->length != (ACPI_DMAR_DEV_SCOPE_MIN_SIZE +
	ACPI_DMAR_DEV_PATH_SIZE)) {
	return NULL;
	}

	break;
	default:
	return NULL;
	}

	*n = (dev_scope->length - ACPI_DMAR_DEV_SCOPE_MIN_SIZE) /
	ACPI_DMAR_DEV_PATH_SIZE;

	return dev_scope->path;
	}

	uint16_t z_acpi_get_dev_id_from_dmar(uint8_t dev_scope_type)
	{
	struct acpi_drhd *drhd;
	int n_drhd;

	find_dmar();

	if (dmar == NULL) {
	return USHRT_MAX;
	}

	drhd = z_acpi_find_drhds(&n_drhd);

	for (; n_drhd > 0; n_drhd--) {
	struct acpi_dmar_dev_scope *dev_scope;
	int n_ds;

	dev_scope = z_acpi_get_drhd_dev_scopes(drhd, &n_ds);
	for (; n_ds > 0; n_ds--) {
	if (dev_scope->type == dev_scope_type) {
	struct acpi_dmar_dev_path *path;
	int n_path;

	path = z_acpi_get_dev_scope_paths(dev_scope,
	&n_path);
	if (n_path > 0) {
	union acpi_dmar_id id;

	/* Let's over simplify for now:
	* we don't look for secondary bus
	* and extra paths. We just stop here.
	*/

	id.bits.bus = dev_scope->start_bus_num;
	id.bits.device = path->device;
	id.bits.function = path->function;

	return id.raw;
	}
	}

	dev_scope = (struct acpi_dmar_dev_scope *)(
	POINTER_TO_UINT(dev_scope) + dev_scope->length);
	}

	drhd = (struct acpi_drhd *)(POINTER_TO_UINT(drhd) +
	drhd->entry.length);
	}

	return USHRT_MAX;
	}