include/lib/xlat_tables/xlat_tables_v2.h - filogic/atf - Gitiles

 /*
  * Copyright (c) 2017-2021, ARM Limited and Contributors. All rights reserved.
  *
  * SPDX-License-Identifier: BSD-3-Clause
  */

 #ifndef XLAT_TABLES_V2_H
 #define XLAT_TABLES_V2_H

 #include <lib/xlat_tables/xlat_tables_defs.h>
 #include <lib/xlat_tables/xlat_tables_v2_helpers.h>

 #ifndef __ASSEMBLER__
 #include <stddef.h>
 #include <stdint.h>

 #include <lib/xlat_tables/xlat_mmu_helpers.h>

 /*
  * Default granularity size for an mmap_region_t.
  * Useful when no specific granularity is required.
  *
  * By default, choose the biggest possible block size allowed by the
  * architectural state and granule size in order to minimize the number of page
  * tables required for the mapping.
  */
 #define REGION_DEFAULT_GRANULARITY	XLAT_BLOCK_SIZE(MIN_LVL_BLOCK_DESC)

 /* Helper macro to define an mmap_region_t. */
 #define MAP_REGION(_pa, _va, _sz, _attr)	\
 	MAP_REGION_FULL_SPEC(_pa, _va, _sz, _attr, REGION_DEFAULT_GRANULARITY)

 /* Helper macro to define an mmap_region_t with an identity mapping. */
 #define MAP_REGION_FLAT(_adr, _sz, _attr)			\
 	MAP_REGION(_adr, _adr, _sz, _attr)

 /*
  * Helper macro to define entries for mmap_region_t. It allows to define 'pa'
  * and sets 'va' to 0 for each region. To be used with mmap_add_alloc_va().
  */
 #define MAP_REGION_ALLOC_VA(pa, sz, attr)	MAP_REGION(pa, 0, sz, attr)

 /*
  * Helper macro to define an mmap_region_t to map with the desired granularity
  * of translation tables.
  *
  * The granularity value passed to this macro must be a valid block or page
  * size. When using a 4KB translation granule, this might be 4KB, 2MB or 1GB.
  * Passing REGION_DEFAULT_GRANULARITY is also allowed and means that the library
  * is free to choose the granularity for this region. In this case, it is
  * equivalent to the MAP_REGION() macro.
  */
 #define MAP_REGION2(_pa, _va, _sz, _attr, _gr)			\
 	MAP_REGION_FULL_SPEC(_pa, _va, _sz, _attr, _gr)

 /*
  * Shifts and masks to access fields of an mmap attribute
  */
 #define MT_TYPE_MASK		U(0x7)
 #define MT_TYPE(_attr)		((_attr) & MT_TYPE_MASK)
 /* Access permissions (RO/RW) */
 #define MT_PERM_SHIFT		U(3)

 /* Physical address space (SECURE/NS/Root/Realm) */
 #define	MT_PAS_SHIFT		U(4)
 #define MT_PAS_MASK		(U(3) << MT_PAS_SHIFT)
 #define MT_PAS(_attr)		((_attr) & MT_PAS_MASK)

 /* Access permissions for instruction execution (EXECUTE/EXECUTE_NEVER) */
 #define MT_EXECUTE_SHIFT	U(6)
 /* In the EL1&0 translation regime, User (EL0) or Privileged (EL1). */
 #define MT_USER_SHIFT		U(7)

 /* Shareability attribute for the memory region */
 #define MT_SHAREABILITY_SHIFT	U(8)
 #define MT_SHAREABILITY_MASK	(U(3) << MT_SHAREABILITY_SHIFT)
 #define MT_SHAREABILITY(_attr)	((_attr) & MT_SHAREABILITY_MASK)

 /* All other bits are reserved */

 /*
  * Memory mapping attributes
  */

 /*
  * Memory types supported.
  * These are organised so that, going down the list, the memory types are
  * getting weaker; conversely going up the list the memory types are getting
  * stronger.
  */
 #define MT_DEVICE		U(0)
 #define MT_NON_CACHEABLE	U(1)
 #define MT_MEMORY		U(2)
 /* Values up to 7 are reserved to add new memory types in the future */

 #define MT_RO			(U(0) << MT_PERM_SHIFT)
 #define MT_RW			(U(1) << MT_PERM_SHIFT)

 #define MT_SECURE		(U(0) << MT_PAS_SHIFT)
 #define MT_NS			(U(1) << MT_PAS_SHIFT)
 #define MT_ROOT			(U(2) << MT_PAS_SHIFT)
 #define MT_REALM		(U(3) << MT_PAS_SHIFT)

 /*
  * Access permissions for instruction execution are only relevant for normal
  * read-only memory, i.e. MT_MEMORY | MT_RO. They are ignored (and potentially
  * overridden) otherwise:
  *  - Device memory is always marked as execute-never.
  *  - Read-write normal memory is always marked as execute-never.
  */
 #define MT_EXECUTE		(U(0) << MT_EXECUTE_SHIFT)
 #define MT_EXECUTE_NEVER	(U(1) << MT_EXECUTE_SHIFT)

 /*
  * When mapping a region at EL0 or EL1, this attribute will be used to determine
  * if a User mapping (EL0) will be created or a Privileged mapping (EL1).
  */
 #define MT_USER			(U(1) << MT_USER_SHIFT)
 #define MT_PRIVILEGED		(U(0) << MT_USER_SHIFT)

 /*
  * Shareability defines the visibility of any cache changes to
  * all masters belonging to a shareable domain.
  *
  * MT_SHAREABILITY_ISH: For inner shareable domain
  * MT_SHAREABILITY_OSH: For outer shareable domain
  * MT_SHAREABILITY_NSH: For non shareable domain
  */
 #define MT_SHAREABILITY_ISH	(U(1) << MT_SHAREABILITY_SHIFT)
 #define MT_SHAREABILITY_OSH	(U(2) << MT_SHAREABILITY_SHIFT)
 #define MT_SHAREABILITY_NSH	(U(3) << MT_SHAREABILITY_SHIFT)

 /* Compound attributes for most common usages */
 #define MT_CODE			(MT_MEMORY | MT_RO | MT_EXECUTE)
 #define MT_RO_DATA		(MT_MEMORY | MT_RO | MT_EXECUTE_NEVER)
 #define MT_RW_DATA		(MT_MEMORY | MT_RW | MT_EXECUTE_NEVER)

 /*
  * Structure for specifying a single region of memory.
  */
 typedef struct mmap_region {
 	unsigned long long	base_pa;
 	uintptr_t		base_va;
 	size_t			size;
 	unsigned int		attr;
 	/* Desired granularity. See the MAP_REGION2() macro for more details. */
 	size_t			granularity;
 } mmap_region_t;

 /*
  * Translation regimes supported by this library. EL_REGIME_INVALID tells the
  * library to detect it at runtime.
  */
 #define EL1_EL0_REGIME		1
 #define EL2_REGIME		2
 #define EL3_REGIME		3
 #define EL_REGIME_INVALID	-1

 /* Memory type for EL3 regions. With RME, EL3 is in ROOT PAS */
 #if ENABLE_RME
 #define EL3_PAS			MT_ROOT
 #else
 #define EL3_PAS			MT_SECURE
 #endif /* ENABLE_RME */

 /*
  * Declare the translation context type.
  * Its definition is private.
  */
 typedef struct xlat_ctx xlat_ctx_t;

 /*
  * Statically allocate a translation context and associated structures. Also
  * initialize them.
  *
  * _ctx_name:
  *   Prefix for the translation context variable.
  *   E.g. If _ctx_name is 'foo', the variable will be called 'foo_xlat_ctx'.
  *   Useful to distinguish multiple contexts from one another.
  *
  * _mmap_count:
  *   Number of mmap_region_t to allocate.
  *   Would typically be MAX_MMAP_REGIONS for the translation context describing
  *   the BL image currently executing.
  *
  * _xlat_tables_count:
  *   Number of sub-translation tables to allocate.
  *   Would typically be MAX_XLAT_TABLES for the translation context describing
  *   the BL image currently executing.
  *   Note that this is only for sub-tables ; at the initial lookup level, there
  *   is always a single table.
  *
  * _virt_addr_space_size, _phy_addr_space_size:
  *   Size (in bytes) of the virtual (resp. physical) address space.
  *   Would typically be PLAT_VIRT_ADDR_SPACE_SIZE
  *   (resp. PLAT_PHY_ADDR_SPACE_SIZE) for the translation context describing the
  *   BL image currently executing.
  */
 #define REGISTER_XLAT_CONTEXT(_ctx_name, _mmap_count, _xlat_tables_count, \
 			      _virt_addr_space_size, _phy_addr_space_size) \
 	REGISTER_XLAT_CONTEXT_FULL_SPEC(_ctx_name, (_mmap_count),	\
 					 (_xlat_tables_count),		\
 					 (_virt_addr_space_size),	\
 					 (_phy_addr_space_size),	\
 					 EL_REGIME_INVALID,		\
 					 "xlat_table", "base_xlat_table")

 /*
  * Same as REGISTER_XLAT_CONTEXT plus the additional parameters:
  *
  * _xlat_regime:
  *   Specify the translation regime managed by this xlat_ctx_t instance. The
  *   values are the one from the EL*_REGIME definitions.
  *
  * _section_name:
  *   Specify the name of the section where the translation tables have to be
  *   placed by the linker.
  *
  * _base_table_section_name:
  *   Specify the name of the section where the base translation tables have to
  *   be placed by the linker.
  */
 #define REGISTER_XLAT_CONTEXT2(_ctx_name, _mmap_count, _xlat_tables_count, \
 			_virt_addr_space_size, _phy_addr_space_size,	\
 			_xlat_regime, _section_name, _base_table_section_name) \
 	REGISTER_XLAT_CONTEXT_FULL_SPEC(_ctx_name, (_mmap_count),	\
 					 (_xlat_tables_count),		\
 					 (_virt_addr_space_size),	\
 					 (_phy_addr_space_size),	\
 					 (_xlat_regime),		\
 					 (_section_name), (_base_table_section_name) \
 )

 /******************************************************************************
  * Generic translation table APIs.
  * Each API comes in 2 variants:
  * - one that acts on the current translation context for this BL image
  * - another that acts on the given translation context instead. This variant
  *   is named after the 1st version, with an additional '_ctx' suffix.
  *****************************************************************************/

 /*
  * Initialize translation tables from the current list of mmap regions. Calling
  * this function marks the transition point after which static regions can no
  * longer be added.
  */
 void init_xlat_tables(void);
 void init_xlat_tables_ctx(xlat_ctx_t *ctx);

 /*
  * Fill all fields of a dynamic translation tables context. It must be done
  * either statically with REGISTER_XLAT_CONTEXT() or at runtime with this
  * function.
  */
 void xlat_setup_dynamic_ctx(xlat_ctx_t *ctx, unsigned long long pa_max,
 			    uintptr_t va_max, struct mmap_region *mmap,
 			    unsigned int mmap_num, uint64_t **tables,
 			    unsigned int tables_num, uint64_t *base_table,
 			    int xlat_regime, int *mapped_regions);

 /*
  * Add a static region with defined base PA and base VA. This function can only
  * be used before initializing the translation tables. The region cannot be
  * removed afterwards.
  */
 void mmap_add_region(unsigned long long base_pa, uintptr_t base_va,
 		     size_t size, unsigned int attr);
 void mmap_add_region_ctx(xlat_ctx_t *ctx, const mmap_region_t *mm);

 /*
  * Add an array of static regions with defined base PA and base VA. This
  * function can only be used before initializing the translation tables. The
  * regions cannot be removed afterwards.
  */
 void mmap_add(const mmap_region_t *mm);
 void mmap_add_ctx(xlat_ctx_t *ctx, const mmap_region_t *mm);

 /*
  * Add a region with defined base PA. Returns base VA calculated using the
  * highest existing region in the mmap array even if it fails to allocate the
  * region.
  */
 void mmap_add_region_alloc_va(unsigned long long base_pa, uintptr_t *base_va,
 			      size_t size, unsigned int attr);
 void mmap_add_region_alloc_va_ctx(xlat_ctx_t *ctx, mmap_region_t *mm);

 /*
  * Add an array of static regions with defined base PA, and fill the base VA
  * field on the array of structs. This function can only be used before
  * initializing the translation tables. The regions cannot be removed afterwards.
  */
 void mmap_add_alloc_va(mmap_region_t *mm);

 #if PLAT_XLAT_TABLES_DYNAMIC
 /*
  * Add a dynamic region with defined base PA and base VA. This type of region
  * can be added and removed even after the translation tables are initialized.
  *
  * Returns:
  *        0: Success.
  *   EINVAL: Invalid values were used as arguments.
  *   ERANGE: Memory limits were surpassed.
  *   ENOMEM: Not enough space in the mmap array or not enough free xlat tables.
  *    EPERM: It overlaps another region in an invalid way.
  */
 int mmap_add_dynamic_region(unsigned long long base_pa, uintptr_t base_va,
 			    size_t size, unsigned int attr);
 int mmap_add_dynamic_region_ctx(xlat_ctx_t *ctx, mmap_region_t *mm);

 /*
  * Add a dynamic region with defined base PA. Returns base VA calculated using
  * the highest existing region in the mmap array even if it fails to allocate
  * the region.
  *
  * mmap_add_dynamic_region_alloc_va() returns the allocated VA in 'base_va'.
  * mmap_add_dynamic_region_alloc_va_ctx() returns it in 'mm->base_va'.
  *
  * It returns the same error values as mmap_add_dynamic_region().
  */
 int mmap_add_dynamic_region_alloc_va(unsigned long long base_pa,
 				     uintptr_t *base_va,
 				     size_t size, unsigned int attr);
 int mmap_add_dynamic_region_alloc_va_ctx(xlat_ctx_t *ctx, mmap_region_t *mm);

 /*
  * Remove a region with the specified base VA and size. Only dynamic regions can
  * be removed, and they can be removed even if the translation tables are
  * initialized.
  *
  * Returns:
  *        0: Success.
  *   EINVAL: The specified region wasn't found.
  *    EPERM: Trying to remove a static region.
  */
 int mmap_remove_dynamic_region(uintptr_t base_va, size_t size);
 int mmap_remove_dynamic_region_ctx(xlat_ctx_t *ctx,
 				uintptr_t base_va,
 				size_t size);

 #endif /* PLAT_XLAT_TABLES_DYNAMIC */

 /*
  * Change the memory attributes of the memory region starting from a given
  * virtual address in a set of translation tables.
  *
  * This function can only be used after the translation tables have been
  * initialized.
  *
  * The base address of the memory region must be aligned on a page boundary.
  * The size of this memory region must be a multiple of a page size.
  * The memory region must be already mapped by the given translation tables
  * and it must be mapped at the granularity of a page.
  *
  * Return 0 on success, a negative value on error.
  *
  * In case of error, the memory attributes remain unchanged and this function
  * has no effect.
  *
  * ctx
  *   Translation context to work on.
  * base_va:
  *   Virtual address of the 1st page to change the attributes of.
  * size:
  *   Size in bytes of the memory region.
  * attr:
  *   New attributes of the page tables. The attributes that can be changed are
  *   data access (MT_RO/MT_RW), instruction access (MT_EXECUTE_NEVER/MT_EXECUTE)
  *   and user/privileged access (MT_USER/MT_PRIVILEGED) in the case of contexts
  *   that are used in the EL1&0 translation regime. Also, note that this
  *   function doesn't allow to remap a region as RW and executable, or to remap
  *   device memory as executable.
  *
  * NOTE: The caller of this function must be able to write to the translation
  * tables, i.e. the memory where they are stored must be mapped with read-write
  * access permissions. This function assumes it is the case. If this is not
  * the case then this function might trigger a data abort exception.
  *
  * NOTE2: The caller is responsible for making sure that the targeted
  * translation tables are not modified by any other code while this function is
  * executing.
  */
 int xlat_change_mem_attributes_ctx(const xlat_ctx_t *ctx, uintptr_t base_va,
 				   size_t size, uint32_t attr);
 int xlat_change_mem_attributes(uintptr_t base_va, size_t size, uint32_t attr);

 #if PLAT_RO_XLAT_TABLES
 /*
  * Change the memory attributes of the memory region encompassing the higher
  * level translation tables to secure read-only data.
  *
  * Return 0 on success, a negative error code on error.
  */
 int xlat_make_tables_readonly(void);
 #endif

 /*
  * Query the memory attributes of a memory page in a set of translation tables.
  *
  * Return 0 on success, a negative error code on error.
  * On success, the attributes are stored into *attr.
  *
  * ctx
  *   Translation context to work on.
  * base_va
  *   Virtual address of the page to get the attributes of.
  *   There are no alignment restrictions on this address. The attributes of the
  *   memory page it lies within are returned.
  * attr
  *   Output parameter where to store the attributes of the targeted memory page.
  */
 int xlat_get_mem_attributes_ctx(const xlat_ctx_t *ctx, uintptr_t base_va,
 				uint32_t *attr);
 int xlat_get_mem_attributes(uintptr_t base_va, uint32_t *attr);

 #endif /*__ASSEMBLER__*/
 #endif /* XLAT_TABLES_V2_H */
	/*
	* Copyright (c) 2017-2021, ARM Limited and Contributors. All rights reserved.
	*
	* SPDX-License-Identifier: BSD-3-Clause
	*/

	#ifndef XLAT_TABLES_V2_H
	#define XLAT_TABLES_V2_H

	#include <lib/xlat_tables/xlat_tables_defs.h>
	#include <lib/xlat_tables/xlat_tables_v2_helpers.h>

	#ifndef __ASSEMBLER__
	#include <stddef.h>
	#include <stdint.h>

	#include <lib/xlat_tables/xlat_mmu_helpers.h>

	/*
	* Default granularity size for an mmap_region_t.
	* Useful when no specific granularity is required.
	*
	* By default, choose the biggest possible block size allowed by the
	* architectural state and granule size in order to minimize the number of page
	* tables required for the mapping.
	*/
	#define REGION_DEFAULT_GRANULARITY XLAT_BLOCK_SIZE(MIN_LVL_BLOCK_DESC)

	/* Helper macro to define an mmap_region_t. */
	#define MAP_REGION(_pa, _va, _sz, _attr) \
	MAP_REGION_FULL_SPEC(_pa, _va, _sz, _attr, REGION_DEFAULT_GRANULARITY)

	/* Helper macro to define an mmap_region_t with an identity mapping. */
	#define MAP_REGION_FLAT(_adr, _sz, _attr) \
	MAP_REGION(_adr, _adr, _sz, _attr)

	/*
	* Helper macro to define entries for mmap_region_t. It allows to define 'pa'
	* and sets 'va' to 0 for each region. To be used with mmap_add_alloc_va().
	*/
	#define MAP_REGION_ALLOC_VA(pa, sz, attr) MAP_REGION(pa, 0, sz, attr)

	/*
	* Helper macro to define an mmap_region_t to map with the desired granularity
	* of translation tables.
	*
	* The granularity value passed to this macro must be a valid block or page
	* size. When using a 4KB translation granule, this might be 4KB, 2MB or 1GB.
	* Passing REGION_DEFAULT_GRANULARITY is also allowed and means that the library
	* is free to choose the granularity for this region. In this case, it is
	* equivalent to the MAP_REGION() macro.
	*/
	#define MAP_REGION2(_pa, _va, _sz, _attr, _gr) \
	MAP_REGION_FULL_SPEC(_pa, _va, _sz, _attr, _gr)

	/*
	* Shifts and masks to access fields of an mmap attribute
	*/
	#define MT_TYPE_MASK U(0x7)
	#define MT_TYPE(_attr) ((_attr) & MT_TYPE_MASK)
	/* Access permissions (RO/RW) */
	#define MT_PERM_SHIFT U(3)

	/* Physical address space (SECURE/NS/Root/Realm) */
	#define MT_PAS_SHIFT U(4)
	#define MT_PAS_MASK (U(3) << MT_PAS_SHIFT)
	#define MT_PAS(_attr) ((_attr) & MT_PAS_MASK)

	/* Access permissions for instruction execution (EXECUTE/EXECUTE_NEVER) */
	#define MT_EXECUTE_SHIFT U(6)
	/* In the EL1&0 translation regime, User (EL0) or Privileged (EL1). */
	#define MT_USER_SHIFT U(7)

	/* Shareability attribute for the memory region */
	#define MT_SHAREABILITY_SHIFT U(8)
	#define MT_SHAREABILITY_MASK (U(3) << MT_SHAREABILITY_SHIFT)
	#define MT_SHAREABILITY(_attr) ((_attr) & MT_SHAREABILITY_MASK)

	/* All other bits are reserved */

	/*
	* Memory mapping attributes
	*/

	/*
	* Memory types supported.
	* These are organised so that, going down the list, the memory types are
	* getting weaker; conversely going up the list the memory types are getting
	* stronger.
	*/
	#define MT_DEVICE U(0)
	#define MT_NON_CACHEABLE U(1)
	#define MT_MEMORY U(2)
	/* Values up to 7 are reserved to add new memory types in the future */

	#define MT_RO (U(0) << MT_PERM_SHIFT)
	#define MT_RW (U(1) << MT_PERM_SHIFT)

	#define MT_SECURE (U(0) << MT_PAS_SHIFT)
	#define MT_NS (U(1) << MT_PAS_SHIFT)
	#define MT_ROOT (U(2) << MT_PAS_SHIFT)
	#define MT_REALM (U(3) << MT_PAS_SHIFT)

	/*
	* Access permissions for instruction execution are only relevant for normal
	* read-only memory, i.e. MT_MEMORY \| MT_RO. They are ignored (and potentially
	* overridden) otherwise:
	* - Device memory is always marked as execute-never.
	* - Read-write normal memory is always marked as execute-never.
	*/
	#define MT_EXECUTE (U(0) << MT_EXECUTE_SHIFT)
	#define MT_EXECUTE_NEVER (U(1) << MT_EXECUTE_SHIFT)

	/*
	* When mapping a region at EL0 or EL1, this attribute will be used to determine
	* if a User mapping (EL0) will be created or a Privileged mapping (EL1).
	*/
	#define MT_USER (U(1) << MT_USER_SHIFT)
	#define MT_PRIVILEGED (U(0) << MT_USER_SHIFT)

	/*
	* Shareability defines the visibility of any cache changes to
	* all masters belonging to a shareable domain.
	*
	* MT_SHAREABILITY_ISH: For inner shareable domain
	* MT_SHAREABILITY_OSH: For outer shareable domain
	* MT_SHAREABILITY_NSH: For non shareable domain
	*/
	#define MT_SHAREABILITY_ISH (U(1) << MT_SHAREABILITY_SHIFT)
	#define MT_SHAREABILITY_OSH (U(2) << MT_SHAREABILITY_SHIFT)
	#define MT_SHAREABILITY_NSH (U(3) << MT_SHAREABILITY_SHIFT)

	/* Compound attributes for most common usages */
	#define MT_CODE (MT_MEMORY \| MT_RO \| MT_EXECUTE)
	#define MT_RO_DATA (MT_MEMORY \| MT_RO \| MT_EXECUTE_NEVER)
	#define MT_RW_DATA (MT_MEMORY \| MT_RW \| MT_EXECUTE_NEVER)

	/*
	* Structure for specifying a single region of memory.
	*/
	typedef struct mmap_region {
	unsigned long long base_pa;
	uintptr_t base_va;
	size_t size;
	unsigned int attr;
	/* Desired granularity. See the MAP_REGION2() macro for more details. */
	size_t granularity;
	} mmap_region_t;

	/*
	* Translation regimes supported by this library. EL_REGIME_INVALID tells the
	* library to detect it at runtime.
	*/
	#define EL1_EL0_REGIME 1
	#define EL2_REGIME 2
	#define EL3_REGIME 3
	#define EL_REGIME_INVALID -1

	/* Memory type for EL3 regions. With RME, EL3 is in ROOT PAS */
	#if ENABLE_RME
	#define EL3_PAS MT_ROOT
	#else
	#define EL3_PAS MT_SECURE
	#endif /* ENABLE_RME */

	/*
	* Declare the translation context type.
	* Its definition is private.
	*/
	typedef struct xlat_ctx xlat_ctx_t;

	/*
	* Statically allocate a translation context and associated structures. Also
	* initialize them.
	*
	* _ctx_name:
	* Prefix for the translation context variable.
	* E.g. If _ctx_name is 'foo', the variable will be called 'foo_xlat_ctx'.
	* Useful to distinguish multiple contexts from one another.
	*
	* _mmap_count:
	* Number of mmap_region_t to allocate.
	* Would typically be MAX_MMAP_REGIONS for the translation context describing
	* the BL image currently executing.
	*
	* _xlat_tables_count:
	* Number of sub-translation tables to allocate.
	* Would typically be MAX_XLAT_TABLES for the translation context describing
	* the BL image currently executing.
	* Note that this is only for sub-tables ; at the initial lookup level, there
	* is always a single table.
	*
	* _virt_addr_space_size, _phy_addr_space_size:
	* Size (in bytes) of the virtual (resp. physical) address space.
	* Would typically be PLAT_VIRT_ADDR_SPACE_SIZE
	* (resp. PLAT_PHY_ADDR_SPACE_SIZE) for the translation context describing the
	* BL image currently executing.
	*/
	#define REGISTER_XLAT_CONTEXT(_ctx_name, _mmap_count, _xlat_tables_count, \
	_virt_addr_space_size, _phy_addr_space_size) \
	REGISTER_XLAT_CONTEXT_FULL_SPEC(_ctx_name, (_mmap_count), \
	(_xlat_tables_count), \
	(_virt_addr_space_size), \
	(_phy_addr_space_size), \
	EL_REGIME_INVALID, \
	"xlat_table", "base_xlat_table")

	/*
	* Same as REGISTER_XLAT_CONTEXT plus the additional parameters:
	*
	* _xlat_regime:
	* Specify the translation regime managed by this xlat_ctx_t instance. The
	* values are the one from the EL*_REGIME definitions.
	*
	* _section_name:
	* Specify the name of the section where the translation tables have to be
	* placed by the linker.
	*
	* _base_table_section_name:
	* Specify the name of the section where the base translation tables have to
	* be placed by the linker.
	*/
	#define REGISTER_XLAT_CONTEXT2(_ctx_name, _mmap_count, _xlat_tables_count, \
	_virt_addr_space_size, _phy_addr_space_size, \
	_xlat_regime, _section_name, _base_table_section_name) \
	REGISTER_XLAT_CONTEXT_FULL_SPEC(_ctx_name, (_mmap_count), \
	(_xlat_tables_count), \
	(_virt_addr_space_size), \
	(_phy_addr_space_size), \
	(_xlat_regime), \
	(_section_name), (_base_table_section_name) \
	)

	/******************************************************************************
	* Generic translation table APIs.
	* Each API comes in 2 variants:
	* - one that acts on the current translation context for this BL image
	* - another that acts on the given translation context instead. This variant
	* is named after the 1st version, with an additional '_ctx' suffix.
	*****************************************************************************/

	/*
	* Initialize translation tables from the current list of mmap regions. Calling
	* this function marks the transition point after which static regions can no
	* longer be added.
	*/
	void init_xlat_tables(void);
	void init_xlat_tables_ctx(xlat_ctx_t *ctx);

	/*
	* Fill all fields of a dynamic translation tables context. It must be done
	* either statically with REGISTER_XLAT_CONTEXT() or at runtime with this
	* function.
	*/
	void xlat_setup_dynamic_ctx(xlat_ctx_t *ctx, unsigned long long pa_max,
	uintptr_t va_max, struct mmap_region *mmap,
	unsigned int mmap_num, uint64_t **tables,
	unsigned int tables_num, uint64_t *base_table,
	int xlat_regime, int *mapped_regions);

	/*
	* Add a static region with defined base PA and base VA. This function can only
	* be used before initializing the translation tables. The region cannot be
	* removed afterwards.
	*/
	void mmap_add_region(unsigned long long base_pa, uintptr_t base_va,
	size_t size, unsigned int attr);
	void mmap_add_region_ctx(xlat_ctx_t ctx, const mmap_region_t mm);

	/*
	* Add an array of static regions with defined base PA and base VA. This
	* function can only be used before initializing the translation tables. The
	* regions cannot be removed afterwards.
	*/
	void mmap_add(const mmap_region_t *mm);
	void mmap_add_ctx(xlat_ctx_t ctx, const mmap_region_t mm);

	/*
	* Add a region with defined base PA. Returns base VA calculated using the
	* highest existing region in the mmap array even if it fails to allocate the
	* region.
	*/
	void mmap_add_region_alloc_va(unsigned long long base_pa, uintptr_t *base_va,
	size_t size, unsigned int attr);
	void mmap_add_region_alloc_va_ctx(xlat_ctx_t ctx, mmap_region_t mm);

	/*
	* Add an array of static regions with defined base PA, and fill the base VA
	* field on the array of structs. This function can only be used before
	* initializing the translation tables. The regions cannot be removed afterwards.
	*/
	void mmap_add_alloc_va(mmap_region_t *mm);

	#if PLAT_XLAT_TABLES_DYNAMIC
	/*
	* Add a dynamic region with defined base PA and base VA. This type of region
	* can be added and removed even after the translation tables are initialized.
	*
	* Returns:
	* 0: Success.
	* EINVAL: Invalid values were used as arguments.
	* ERANGE: Memory limits were surpassed.
	* ENOMEM: Not enough space in the mmap array or not enough free xlat tables.
	* EPERM: It overlaps another region in an invalid way.
	*/
	int mmap_add_dynamic_region(unsigned long long base_pa, uintptr_t base_va,
	size_t size, unsigned int attr);
	int mmap_add_dynamic_region_ctx(xlat_ctx_t ctx, mmap_region_t mm);

	/*
	* Add a dynamic region with defined base PA. Returns base VA calculated using
	* the highest existing region in the mmap array even if it fails to allocate
	* the region.
	*
	* mmap_add_dynamic_region_alloc_va() returns the allocated VA in 'base_va'.
	* mmap_add_dynamic_region_alloc_va_ctx() returns it in 'mm->base_va'.
	*
	* It returns the same error values as mmap_add_dynamic_region().
	*/
	int mmap_add_dynamic_region_alloc_va(unsigned long long base_pa,
	uintptr_t *base_va,
	size_t size, unsigned int attr);
	int mmap_add_dynamic_region_alloc_va_ctx(xlat_ctx_t ctx, mmap_region_t mm);

	/*
	* Remove a region with the specified base VA and size. Only dynamic regions can
	* be removed, and they can be removed even if the translation tables are
	* initialized.
	*
	* Returns:
	* 0: Success.
	* EINVAL: The specified region wasn't found.
	* EPERM: Trying to remove a static region.
	*/
	int mmap_remove_dynamic_region(uintptr_t base_va, size_t size);
	int mmap_remove_dynamic_region_ctx(xlat_ctx_t *ctx,
	uintptr_t base_va,
	size_t size);

	#endif /* PLAT_XLAT_TABLES_DYNAMIC */

	/*
	* Change the memory attributes of the memory region starting from a given
	* virtual address in a set of translation tables.
	*
	* This function can only be used after the translation tables have been
	* initialized.
	*
	* The base address of the memory region must be aligned on a page boundary.
	* The size of this memory region must be a multiple of a page size.
	* The memory region must be already mapped by the given translation tables
	* and it must be mapped at the granularity of a page.
	*
	* Return 0 on success, a negative value on error.
	*
	* In case of error, the memory attributes remain unchanged and this function
	* has no effect.
	*
	* ctx
	* Translation context to work on.
	* base_va:
	* Virtual address of the 1st page to change the attributes of.
	* size:
	* Size in bytes of the memory region.
	* attr:
	* New attributes of the page tables. The attributes that can be changed are
	* data access (MT_RO/MT_RW), instruction access (MT_EXECUTE_NEVER/MT_EXECUTE)
	* and user/privileged access (MT_USER/MT_PRIVILEGED) in the case of contexts
	* that are used in the EL1&0 translation regime. Also, note that this
	* function doesn't allow to remap a region as RW and executable, or to remap
	* device memory as executable.
	*
	* NOTE: The caller of this function must be able to write to the translation
	* tables, i.e. the memory where they are stored must be mapped with read-write
	* access permissions. This function assumes it is the case. If this is not
	* the case then this function might trigger a data abort exception.
	*
	* NOTE2: The caller is responsible for making sure that the targeted
	* translation tables are not modified by any other code while this function is
	* executing.
	*/
	int xlat_change_mem_attributes_ctx(const xlat_ctx_t *ctx, uintptr_t base_va,
	size_t size, uint32_t attr);
	int xlat_change_mem_attributes(uintptr_t base_va, size_t size, uint32_t attr);

	#if PLAT_RO_XLAT_TABLES
	/*
	* Change the memory attributes of the memory region encompassing the higher
	* level translation tables to secure read-only data.
	*
	* Return 0 on success, a negative error code on error.
	*/
	int xlat_make_tables_readonly(void);
	#endif

	/*
	* Query the memory attributes of a memory page in a set of translation tables.
	*
	* Return 0 on success, a negative error code on error.
	* On success, the attributes are stored into *attr.
	*
	* ctx
	* Translation context to work on.
	* base_va
	* Virtual address of the page to get the attributes of.
	* There are no alignment restrictions on this address. The attributes of the
	* memory page it lies within are returned.
	* attr
	* Output parameter where to store the attributes of the targeted memory page.
	*/
	int xlat_get_mem_attributes_ctx(const xlat_ctx_t *ctx, uintptr_t base_va,
	uint32_t *attr);
	int xlat_get_mem_attributes(uintptr_t base_va, uint32_t *attr);

	#endif /__ASSEMBLER__/
	#endif /* XLAT_TABLES_V2_H */