arch/x86/core/x86_mmu.c - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2011-2014 Wind River Systems, Inc.
  * Copyright (c) 2017 Intel Corporation
  *
  * SPDX-License-Identifier: Apache-2.0
  */
 #include <kernel.h>
 #include <mmustructs.h>
 #include <linker/linker-defs.h>

 /* Common regions for all x86 processors.
  * Peripheral I/O ranges configured at the SOC level
  */

 /* Mark text and rodata as read-only.
  * Userspace may read all text and rodata.
  */
 MMU_BOOT_REGION((u32_t)&_image_rom_start, (u32_t)&_image_rom_size,
 		MMU_ENTRY_READ | MMU_ENTRY_USER);

 #ifdef CONFIG_APPLICATION_MEMORY
 /* User threads by default can read/write app-level memory. */
 MMU_BOOT_REGION((u32_t)&__app_ram_start, (u32_t)&__app_ram_size,
 		MMU_ENTRY_WRITE | MMU_ENTRY_USER | MMU_ENTRY_EXECUTE_DISABLE);
 #endif

 /* __kernel_ram_size includes all unused memory, which is used for heaps.
  * User threads cannot access this unless granted at runtime. This is done
  * automatically for stacks.
  */
 MMU_BOOT_REGION((u32_t)&__kernel_ram_start, (u32_t)&__kernel_ram_size,
 		MMU_ENTRY_WRITE |
 		MMU_ENTRY_RUNTIME_USER |
 		MMU_ENTRY_EXECUTE_DISABLE);


 void _x86_mmu_get_flags(void *addr,
 			x86_page_entry_data_t *pde_flags,
 			x86_page_entry_data_t *pte_flags)
 {
 	*pde_flags = (x86_page_entry_data_t)(X86_MMU_GET_PDE(addr)->value &
 				~(x86_page_entry_data_t)MMU_PDE_PAGE_TABLE_MASK);

 	if (*pde_flags & MMU_ENTRY_PRESENT) {
 		*pte_flags = (x86_page_entry_data_t)
 			(X86_MMU_GET_PTE(addr)->value &
 			 ~(x86_page_entry_data_t)MMU_PTE_PAGE_MASK);
 	} else {
 		*pte_flags = 0;
 	}
 }


 int _arch_buffer_validate(void *addr, size_t size, int write)
 {
 	u32_t start_pde_num;
 	u32_t end_pde_num;
 	u32_t starting_pte_num;
 	u32_t ending_pte_num;
 	u32_t pde;
 	u32_t pte;
 #ifdef CONFIG_X86_PAE_MODE
 	union x86_mmu_pae_pte pte_value;
 	u32_t start_pdpte_num = MMU_PDPTE_NUM(addr);
 	u32_t end_pdpte_num = MMU_PDPTE_NUM((char *)addr + size - 1);
 	u32_t pdpte;
 #else
 	union x86_mmu_pte pte_value;
 #endif
 	struct x86_mmu_page_table *pte_address;


 	start_pde_num = MMU_PDE_NUM(addr);
 	end_pde_num = MMU_PDE_NUM((char *)addr + size - 1);
 	starting_pte_num = MMU_PAGE_NUM((char *)addr);

 #ifdef CONFIG_X86_PAE_MODE
 	for (pdpte = start_pdpte_num; pdpte <= end_pdpte_num; pdpte++) {
 		if (pdpte != start_pdpte_num) {
 			start_pde_num = 0;
 		}

 		if (pdpte != end_pdpte_num) {
 			end_pde_num = 0;
 		} else {
 			end_pde_num = MMU_PDE_NUM((char *)addr + size - 1);
 		}

 		struct x86_mmu_page_directory *pd_address =
 			X86_MMU_GET_PD_ADDR_INDEX(pdpte);
 #endif
 		/* Iterate for all the pde's the buffer might take up.
 		 * (depends on the size of the buffer and start address
 		 * of the buff)
 		 */
 		for (pde = start_pde_num; pde <= end_pde_num; pde++) {
 #ifdef CONFIG_X86_PAE_MODE
 			union x86_mmu_pae_pde pde_value =
 				pd_address->entry[pde];
 #else
 			union x86_mmu_pde_pt pde_value =
 				X86_MMU_PD->entry[pde].pt;
 #endif

 			if (!pde_value.p ||
 			    !pde_value.us ||
 			    (write && !pde_value.rw)) {
 				return -EPERM;
 			}

 			pte_address = (struct x86_mmu_page_table *)
 				(pde_value.page_table << MMU_PAGE_SHIFT);

 			/* loop over all the possible page tables for the
 			 * required size. If the pde is not the last one
 			 * then the last pte would be 1023. So each pde
 			 * will be using all the page table entires except
 			 * for the last pde. For the last pde, pte is
 			 * calculated using the last memory address
 			 * of the buffer.
 			 */
 			if (pde != end_pde_num) {
 				ending_pte_num = 1023;
 			} else {
 				ending_pte_num =
 					MMU_PAGE_NUM((char *)addr + size - 1);
 			}

 			/* For all the pde's appart from the starting pde,
 			 * will have the start pte number as zero.
 			 */
 			if (pde != start_pde_num) {
 				starting_pte_num = 0;
 			}

 			pte_value.value = 0xFFFFFFFF;

 			/* Bitwise AND all the pte values.
 			 * An optimization done to make sure a compare is
 			 * done only once.
 			 */
 			for (pte = starting_pte_num;
 			     pte <= ending_pte_num;
 			     pte++) {
 				pte_value.value &=
 					pte_address->entry[pte].value;
 			}

 			if (!pte_value.p ||
 			    !pte_value.us ||
 			    (write && !pte_value.rw)) {
 				return -EPERM;
 			}
 		}
 #ifdef CONFIG_X86_PAE_MODE
 	}
 #endif

 	return 0;
 }

 static inline void tlb_flush_page(void *addr)
 {
 	/* Invalidate TLB entries corresponding to the page containing the
 	 * specified address
 	 */
 	char *page = (char *)addr;

 	__asm__ ("invlpg %0" :: "m" (*page));
 }


 void _x86_mmu_set_flags(void *ptr,
 			size_t size,
 			x86_page_entry_data_t flags,
 			x86_page_entry_data_t mask)
 {
 #ifdef CONFIG_X86_PAE_MODE
 	union x86_mmu_pae_pte *pte;
 #else
 	union x86_mmu_pte *pte;
 #endif

 	u32_t addr = (u32_t)ptr;

 	__ASSERT(!(addr & MMU_PAGE_MASK), "unaligned address provided");
 	__ASSERT(!(size & MMU_PAGE_MASK), "unaligned size provided");

 	while (size) {

 #ifdef CONFIG_X86_PAE_MODE
 		/* TODO we're not generating 2MB entries at the moment */
 		__ASSERT(X86_MMU_GET_PDE(addr)->ps != 1, "2MB PDE found");
 #else
 		/* TODO we're not generating 4MB entries at the moment */
 		__ASSERT(X86_MMU_GET_4MB_PDE(addr)->ps != 1, "4MB PDE found");
 #endif
 		pte = X86_MMU_GET_PTE(addr);

 		pte->value = (pte->value & ~mask) | flags;
 		tlb_flush_page((void *)addr);

 		size -= MMU_PAGE_SIZE;
 		addr += MMU_PAGE_SIZE;
 	}
 }

 #ifdef CONFIG_X86_USERSPACE

 /* Helper macros needed to be passed to x86_update_mem_domain_pages */
 #define X86_MEM_DOMAIN_SET_PAGES   (0U)
 #define X86_MEM_DOMAIN_RESET_PAGES (1U)
 /* Pass 1 to page_conf if reset of mem domain pages is needed else pass a 0*/
 static inline void _x86_mem_domain_pages_update(struct k_mem_domain *mem_domain,
 						u32_t page_conf)
 {
 	u32_t partition_index;
 	u32_t total_partitions;
 	struct k_mem_partition partition;
 	u32_t partitions_count;

 	/* If mem_domain doesn't point to a valid location return.*/
 	if (mem_domain == NULL) {
 		goto out;
 	}

 	/* Get the total number of partitions*/
 	total_partitions = mem_domain->num_partitions;

 	/* Iterate over all the partitions for the given mem_domain
 	 * For x86: interate over all the partitions and set the
 	 * required flags in the correct MMU page tables.
 	 */
 	partitions_count = 0;
 	for (partition_index = 0;
 	     partitions_count < total_partitions;
 	     partition_index++) {

 		/* Get the partition info */
 		partition = mem_domain->partitions[partition_index];
 		if (partition.size == 0) {
 			continue;
 		}
 		partitions_count++;
 		if (page_conf == X86_MEM_DOMAIN_SET_PAGES) {
 			/* Set the partition attributes */
 			_x86_mmu_set_flags((void *)partition.start,
 					   partition.size,
 					   partition.attr,
 					   K_MEM_PARTITION_PERM_MASK);
 		} else {
 			/* Reset the pages to supervisor RW only */
 			_x86_mmu_set_flags((void *)partition.start,
 					   partition.size,
 					   K_MEM_PARTITION_P_RW_U_NA,
 					   K_MEM_PARTITION_PERM_MASK);
 		}
 	}
  out:
 	return;
 }


 /* Load the required parttions of the new incoming thread */
 void _x86_mmu_mem_domain_load(struct k_thread *thread)
 {
 	_x86_mem_domain_pages_update(thread->mem_domain_info.mem_domain,
 				     X86_MEM_DOMAIN_SET_PAGES);
 }

 /* Destroy or reset the mmu page tables when necessary.
  * Needed when either swap takes place or k_mem_domain_destroy is called.
  */
 void _arch_mem_domain_destroy(struct k_mem_domain *domain)
 {
 	_x86_mem_domain_pages_update(domain, X86_MEM_DOMAIN_RESET_PAGES);
 }

 /* Reset/destroy one partition spcified in the argument of the API. */
 void _arch_mem_domain_partition_remove(struct k_mem_domain *domain,
 				       u32_t  partition_id)
 {
 	u32_t total_partitions;
 	struct k_mem_partition partition;

 	if (domain == NULL) {
 		goto out;
 	}

 	total_partitions = domain->num_partitions;
 	__ASSERT(partition_id <= total_partitions,
 		 "invalid partitions");

 	partition = domain->partitions[partition_id];

 	_x86_mmu_set_flags((void *)partition.start,
 			   partition.size,
 			   K_MEM_PARTITION_P_RW_U_NA,
 			   K_MEM_PARTITION_PERM_MASK);

  out:
 	return;
 }

 u8_t _arch_mem_domain_max_partitions_get(void)
 {
 	return CONFIG_MAX_DOMAIN_PARTITIONS;
 }

 #endif	/* CONFIG_X86_USERSPACE*/
	/*
	* Copyright (c) 2011-2014 Wind River Systems, Inc.
	* Copyright (c) 2017 Intel Corporation
	*
	* SPDX-License-Identifier: Apache-2.0
	*/
	#include <kernel.h>
	#include <mmustructs.h>
	#include <linker/linker-defs.h>

	/* Common regions for all x86 processors.
	* Peripheral I/O ranges configured at the SOC level
	*/

	/* Mark text and rodata as read-only.
	* Userspace may read all text and rodata.
	*/
	MMU_BOOT_REGION((u32_t)&_image_rom_start, (u32_t)&_image_rom_size,
	MMU_ENTRY_READ \| MMU_ENTRY_USER);

	#ifdef CONFIG_APPLICATION_MEMORY
	/* User threads by default can read/write app-level memory. */
	MMU_BOOT_REGION((u32_t)&__app_ram_start, (u32_t)&__app_ram_size,
	MMU_ENTRY_WRITE \| MMU_ENTRY_USER \| MMU_ENTRY_EXECUTE_DISABLE);
	#endif

	/* __kernel_ram_size includes all unused memory, which is used for heaps.
	* User threads cannot access this unless granted at runtime. This is done
	* automatically for stacks.
	*/
	MMU_BOOT_REGION((u32_t)&__kernel_ram_start, (u32_t)&__kernel_ram_size,
	MMU_ENTRY_WRITE \|
	MMU_ENTRY_RUNTIME_USER \|
	MMU_ENTRY_EXECUTE_DISABLE);


	void _x86_mmu_get_flags(void *addr,
	x86_page_entry_data_t *pde_flags,
	x86_page_entry_data_t *pte_flags)
	{
	*pde_flags = (x86_page_entry_data_t)(X86_MMU_GET_PDE(addr)->value &
	~(x86_page_entry_data_t)MMU_PDE_PAGE_TABLE_MASK);

	if (*pde_flags & MMU_ENTRY_PRESENT) {
	*pte_flags = (x86_page_entry_data_t)
	(X86_MMU_GET_PTE(addr)->value &
	~(x86_page_entry_data_t)MMU_PTE_PAGE_MASK);
	} else {
	*pte_flags = 0;
	}
	}


	int _arch_buffer_validate(void *addr, size_t size, int write)
	{
	u32_t start_pde_num;
	u32_t end_pde_num;
	u32_t starting_pte_num;
	u32_t ending_pte_num;
	u32_t pde;
	u32_t pte;
	#ifdef CONFIG_X86_PAE_MODE
	union x86_mmu_pae_pte pte_value;
	u32_t start_pdpte_num = MMU_PDPTE_NUM(addr);
	u32_t end_pdpte_num = MMU_PDPTE_NUM((char *)addr + size - 1);
	u32_t pdpte;
	#else
	union x86_mmu_pte pte_value;
	#endif
	struct x86_mmu_page_table *pte_address;


	start_pde_num = MMU_PDE_NUM(addr);
	end_pde_num = MMU_PDE_NUM((char *)addr + size - 1);
	starting_pte_num = MMU_PAGE_NUM((char *)addr);

	#ifdef CONFIG_X86_PAE_MODE
	for (pdpte = start_pdpte_num; pdpte <= end_pdpte_num; pdpte++) {
	if (pdpte != start_pdpte_num) {
	start_pde_num = 0;
	}

	if (pdpte != end_pdpte_num) {
	end_pde_num = 0;
	} else {
	end_pde_num = MMU_PDE_NUM((char *)addr + size - 1);
	}

	struct x86_mmu_page_directory *pd_address =
	X86_MMU_GET_PD_ADDR_INDEX(pdpte);
	#endif
	/* Iterate for all the pde's the buffer might take up.
	* (depends on the size of the buffer and start address
	* of the buff)
	*/
	for (pde = start_pde_num; pde <= end_pde_num; pde++) {
	#ifdef CONFIG_X86_PAE_MODE
	union x86_mmu_pae_pde pde_value =
	pd_address->entry[pde];
	#else
	union x86_mmu_pde_pt pde_value =
	X86_MMU_PD->entry[pde].pt;
	#endif

	if (!pde_value.p \|\|
	!pde_value.us \|\|
	(write && !pde_value.rw)) {
	return -EPERM;
	}

	pte_address = (struct x86_mmu_page_table *)
	(pde_value.page_table << MMU_PAGE_SHIFT);

	/* loop over all the possible page tables for the
	* required size. If the pde is not the last one
	* then the last pte would be 1023. So each pde
	* will be using all the page table entires except
	* for the last pde. For the last pde, pte is
	* calculated using the last memory address
	* of the buffer.
	*/
	if (pde != end_pde_num) {
	ending_pte_num = 1023;
	} else {
	ending_pte_num =
	MMU_PAGE_NUM((char *)addr + size - 1);
	}

	/* For all the pde's appart from the starting pde,
	* will have the start pte number as zero.
	*/
	if (pde != start_pde_num) {
	starting_pte_num = 0;
	}

	pte_value.value = 0xFFFFFFFF;

	/* Bitwise AND all the pte values.
	* An optimization done to make sure a compare is
	* done only once.
	*/
	for (pte = starting_pte_num;
	pte <= ending_pte_num;
	pte++) {
	pte_value.value &=
	pte_address->entry[pte].value;
	}

	if (!pte_value.p \|\|
	!pte_value.us \|\|
	(write && !pte_value.rw)) {
	return -EPERM;
	}
	}
	#ifdef CONFIG_X86_PAE_MODE
	}
	#endif

	return 0;
	}

	static inline void tlb_flush_page(void *addr)
	{
	/* Invalidate TLB entries corresponding to the page containing the
	* specified address
	*/
	char page = (char )addr;

	__asm__ ("invlpg %0" :: "m" (*page));
	}


	void _x86_mmu_set_flags(void *ptr,
	size_t size,
	x86_page_entry_data_t flags,
	x86_page_entry_data_t mask)
	{
	#ifdef CONFIG_X86_PAE_MODE
	union x86_mmu_pae_pte *pte;
	#else
	union x86_mmu_pte *pte;
	#endif

	u32_t addr = (u32_t)ptr;

	__ASSERT(!(addr & MMU_PAGE_MASK), "unaligned address provided");
	__ASSERT(!(size & MMU_PAGE_MASK), "unaligned size provided");

	while (size) {

	#ifdef CONFIG_X86_PAE_MODE
	/* TODO we're not generating 2MB entries at the moment */
	__ASSERT(X86_MMU_GET_PDE(addr)->ps != 1, "2MB PDE found");
	#else
	/* TODO we're not generating 4MB entries at the moment */
	__ASSERT(X86_MMU_GET_4MB_PDE(addr)->ps != 1, "4MB PDE found");
	#endif
	pte = X86_MMU_GET_PTE(addr);

	pte->value = (pte->value & ~mask) \| flags;
	tlb_flush_page((void *)addr);

	size -= MMU_PAGE_SIZE;
	addr += MMU_PAGE_SIZE;
	}
	}

	#ifdef CONFIG_X86_USERSPACE

	/* Helper macros needed to be passed to x86_update_mem_domain_pages */
	#define X86_MEM_DOMAIN_SET_PAGES (0U)
	#define X86_MEM_DOMAIN_RESET_PAGES (1U)
	/* Pass 1 to page_conf if reset of mem domain pages is needed else pass a 0*/
	static inline void _x86_mem_domain_pages_update(struct k_mem_domain *mem_domain,
	u32_t page_conf)
	{
	u32_t partition_index;
	u32_t total_partitions;
	struct k_mem_partition partition;
	u32_t partitions_count;

	/* If mem_domain doesn't point to a valid location return.*/
	if (mem_domain == NULL) {
	goto out;
	}

	/* Get the total number of partitions*/
	total_partitions = mem_domain->num_partitions;

	/* Iterate over all the partitions for the given mem_domain
	* For x86: interate over all the partitions and set the
	* required flags in the correct MMU page tables.
	*/
	partitions_count = 0;
	for (partition_index = 0;
	partitions_count < total_partitions;
	partition_index++) {

	/* Get the partition info */
	partition = mem_domain->partitions[partition_index];
	if (partition.size == 0) {
	continue;
	}
	partitions_count++;
	if (page_conf == X86_MEM_DOMAIN_SET_PAGES) {
	/* Set the partition attributes */
	_x86_mmu_set_flags((void *)partition.start,
	partition.size,
	partition.attr,
	K_MEM_PARTITION_PERM_MASK);
	} else {
	/* Reset the pages to supervisor RW only */
	_x86_mmu_set_flags((void *)partition.start,
	partition.size,
	K_MEM_PARTITION_P_RW_U_NA,
	K_MEM_PARTITION_PERM_MASK);
	}
	}
	out:
	return;
	}


	/* Load the required parttions of the new incoming thread */
	void _x86_mmu_mem_domain_load(struct k_thread *thread)
	{
	_x86_mem_domain_pages_update(thread->mem_domain_info.mem_domain,
	X86_MEM_DOMAIN_SET_PAGES);
	}

	/* Destroy or reset the mmu page tables when necessary.
	* Needed when either swap takes place or k_mem_domain_destroy is called.
	*/
	void _arch_mem_domain_destroy(struct k_mem_domain *domain)
	{
	_x86_mem_domain_pages_update(domain, X86_MEM_DOMAIN_RESET_PAGES);
	}

	/* Reset/destroy one partition spcified in the argument of the API. */
	void _arch_mem_domain_partition_remove(struct k_mem_domain *domain,
	u32_t partition_id)
	{
	u32_t total_partitions;
	struct k_mem_partition partition;

	if (domain == NULL) {
	goto out;
	}

	total_partitions = domain->num_partitions;
	__ASSERT(partition_id <= total_partitions,
	"invalid partitions");

	partition = domain->partitions[partition_id];

	_x86_mmu_set_flags((void *)partition.start,
	partition.size,
	K_MEM_PARTITION_P_RW_U_NA,
	K_MEM_PARTITION_PERM_MASK);

	out:
	return;
	}

	u8_t _arch_mem_domain_max_partitions_get(void)
	{
	return CONFIG_MAX_DOMAIN_PARTITIONS;
	}

	#endif /* CONFIG_X86_USERSPACE*/