xlat_tables_internal.c 43.4 KB
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/*
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 * Copyright (c) 2017-2018, ARM Limited and Contributors. All rights reserved.
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 *
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 * SPDX-License-Identifier: BSD-3-Clause
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 */

#include <arch.h>
#include <arch_helpers.h>
#include <assert.h>
#include <common_def.h>
#include <debug.h>
#include <errno.h>
#include <platform_def.h>
#include <string.h>
#include <types.h>
#include <utils.h>
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#include <xlat_tables_arch_private.h>
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#include <xlat_tables_defs.h>
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#include <xlat_tables_v2.h>
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#include "xlat_tables_private.h"

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/*
 * Each platform can define the size of its physical and virtual address spaces.
 * If the platform hasn't defined one or both of them, default to
 * ADDR_SPACE_SIZE. The latter is deprecated, though.
 */
#if ERROR_DEPRECATED
# ifdef ADDR_SPACE_SIZE
#  error "ADDR_SPACE_SIZE is deprecated. Use PLAT_xxx_ADDR_SPACE_SIZE instead."
# endif
#elif defined(ADDR_SPACE_SIZE)
# ifndef PLAT_PHY_ADDR_SPACE_SIZE
#  define PLAT_PHY_ADDR_SPACE_SIZE	ADDR_SPACE_SIZE
# endif
# ifndef PLAT_VIRT_ADDR_SPACE_SIZE
#  define PLAT_VIRT_ADDR_SPACE_SIZE	ADDR_SPACE_SIZE
# endif
#endif

/*
 * Allocate and initialise the default translation context for the BL image
 * currently executing.
 */
REGISTER_XLAT_CONTEXT(tf, MAX_MMAP_REGIONS, MAX_XLAT_TABLES,
		PLAT_VIRT_ADDR_SPACE_SIZE, PLAT_PHY_ADDR_SPACE_SIZE);

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#if PLAT_XLAT_TABLES_DYNAMIC

/*
 * The following functions assume that they will be called using subtables only.
 * The base table can't be unmapped, so it is not needed to do any special
 * handling for it.
 */

/*
 * Returns the index of the array corresponding to the specified translation
 * table.
 */
static int xlat_table_get_index(xlat_ctx_t *ctx, const uint64_t *table)
{
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	for (unsigned int i = 0; i < ctx->tables_num; i++)
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		if (ctx->tables[i] == table)
			return i;

	/*
	 * Maybe we were asked to get the index of the base level table, which
	 * should never happen.
	 */
	assert(0);

	return -1;
}

/* Returns a pointer to an empty translation table. */
static uint64_t *xlat_table_get_empty(xlat_ctx_t *ctx)
{
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	for (unsigned int i = 0; i < ctx->tables_num; i++)
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		if (ctx->tables_mapped_regions[i] == 0)
			return ctx->tables[i];

	return NULL;
}

/* Increments region count for a given table. */
static void xlat_table_inc_regions_count(xlat_ctx_t *ctx, const uint64_t *table)
{
	ctx->tables_mapped_regions[xlat_table_get_index(ctx, table)]++;
}

/* Decrements region count for a given table. */
static void xlat_table_dec_regions_count(xlat_ctx_t *ctx, const uint64_t *table)
{
	ctx->tables_mapped_regions[xlat_table_get_index(ctx, table)]--;
}

/* Returns 0 if the speficied table isn't empty, otherwise 1. */
static int xlat_table_is_empty(xlat_ctx_t *ctx, const uint64_t *table)
{
	return !ctx->tables_mapped_regions[xlat_table_get_index(ctx, table)];
}

#else /* PLAT_XLAT_TABLES_DYNAMIC */

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/* Returns a pointer to the first empty translation table. */
static uint64_t *xlat_table_get_empty(xlat_ctx_t *ctx)
{
	assert(ctx->next_table < ctx->tables_num);

	return ctx->tables[ctx->next_table++];
}

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#endif /* PLAT_XLAT_TABLES_DYNAMIC */

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/*
 * Returns a block/page table descriptor for the given level and attributes.
 */
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static uint64_t xlat_desc(const xlat_ctx_t *ctx, uint32_t attr,
			  unsigned long long addr_pa, int level)
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{
	uint64_t desc;
	int mem_type;

	/* Make sure that the granularity is fine enough to map this address. */
	assert((addr_pa & XLAT_BLOCK_MASK(level)) == 0);

	desc = addr_pa;
	/*
	 * There are different translation table descriptors for level 3 and the
	 * rest.
	 */
	desc |= (level == XLAT_TABLE_LEVEL_MAX) ? PAGE_DESC : BLOCK_DESC;
	/*
	 * Always set the access flag, as TF doesn't manage access flag faults.
	 * Deduce other fields of the descriptor based on the MT_NS and MT_RW
	 * memory region attributes.
	 */
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	desc |= LOWER_ATTRS(ACCESS_FLAG);

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	desc |= (attr & MT_NS) ? LOWER_ATTRS(NS) : 0;
	desc |= (attr & MT_RW) ? LOWER_ATTRS(AP_RW) : LOWER_ATTRS(AP_RO);
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	/*
	 * Do not allow unprivileged access when the mapping is for a privileged
	 * EL. For translation regimes that do not have mappings for access for
	 * lower exception levels, set AP[2] to AP_NO_ACCESS_UNPRIVILEGED.
	 */
	if (ctx->xlat_regime == EL1_EL0_REGIME) {
		if (attr & MT_USER) {
			/* EL0 mapping requested, so we give User access */
			desc |= LOWER_ATTRS(AP_ACCESS_UNPRIVILEGED);
		} else {
			/* EL1 mapping requested, no User access granted */
			desc |= LOWER_ATTRS(AP_NO_ACCESS_UNPRIVILEGED);
		}
	} else {
		assert(ctx->xlat_regime == EL3_REGIME);
		desc |= LOWER_ATTRS(AP_NO_ACCESS_UNPRIVILEGED);
	}
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	/*
	 * Deduce shareability domain and executability of the memory region
	 * from the memory type of the attributes (MT_TYPE).
	 *
	 * Data accesses to device memory and non-cacheable normal memory are
	 * coherent for all observers in the system, and correspondingly are
	 * always treated as being Outer Shareable. Therefore, for these 2 types
	 * of memory, it is not strictly needed to set the shareability field
	 * in the translation tables.
	 */
	mem_type = MT_TYPE(attr);
	if (mem_type == MT_DEVICE) {
		desc |= LOWER_ATTRS(ATTR_DEVICE_INDEX | OSH);
		/*
		 * Always map device memory as execute-never.
		 * This is to avoid the possibility of a speculative instruction
		 * fetch, which could be an issue if this memory region
		 * corresponds to a read-sensitive peripheral.
		 */
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		desc |= xlat_arch_regime_get_xn_desc(ctx->xlat_regime);
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	} else { /* Normal memory */
		/*
		 * Always map read-write normal memory as execute-never.
		 * (Trusted Firmware doesn't self-modify its code, therefore
		 * R/W memory is reserved for data storage, which must not be
		 * executable.)
		 * Note that setting the XN bit here is for consistency only.
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		 * The function that enables the MMU sets the SCTLR_ELx.WXN bit,
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		 * which makes any writable memory region to be treated as
		 * execute-never, regardless of the value of the XN bit in the
		 * translation table.
		 *
		 * For read-only memory, rely on the MT_EXECUTE/MT_EXECUTE_NEVER
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		 * attribute to figure out the value of the XN bit.  The actual
		 * XN bit(s) to set in the descriptor depends on the context's
		 * translation regime and the policy applied in
		 * xlat_arch_regime_get_xn_desc().
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		 */
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		if ((attr & MT_RW) || (attr & MT_EXECUTE_NEVER)) {
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			desc |= xlat_arch_regime_get_xn_desc(ctx->xlat_regime);
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		}
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		if (mem_type == MT_MEMORY) {
			desc |= LOWER_ATTRS(ATTR_IWBWA_OWBWA_NTR_INDEX | ISH);
		} else {
			assert(mem_type == MT_NON_CACHEABLE);
			desc |= LOWER_ATTRS(ATTR_NON_CACHEABLE_INDEX | OSH);
		}
	}

	return desc;
}

/*
 * Enumeration of actions that can be made when mapping table entries depending
 * on the previous value in that entry and information about the region being
 * mapped.
 */
typedef enum {

	/* Do nothing */
	ACTION_NONE,

	/* Write a block (or page, if in level 3) entry. */
	ACTION_WRITE_BLOCK_ENTRY,

	/*
	 * Create a new table and write a table entry pointing to it. Recurse
	 * into it for further processing.
	 */
	ACTION_CREATE_NEW_TABLE,

	/*
	 * There is a table descriptor in this entry, read it and recurse into
	 * that table for further processing.
	 */
	ACTION_RECURSE_INTO_TABLE,

} action_t;

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#if PLAT_XLAT_TABLES_DYNAMIC

/*
 * Recursive function that writes to the translation tables and unmaps the
 * specified region.
 */
static void xlat_tables_unmap_region(xlat_ctx_t *ctx, mmap_region_t *mm,
				     const uintptr_t table_base_va,
				     uint64_t *const table_base,
				     const int table_entries,
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				     const unsigned int level)
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{
	assert(level >= ctx->base_level && level <= XLAT_TABLE_LEVEL_MAX);

	uint64_t *subtable;
	uint64_t desc;

	uintptr_t table_idx_va;
	uintptr_t table_idx_end_va; /* End VA of this entry */

	uintptr_t region_end_va = mm->base_va + mm->size - 1;

	int table_idx;

	if (mm->base_va > table_base_va) {
		/* Find the first index of the table affected by the region. */
		table_idx_va = mm->base_va & ~XLAT_BLOCK_MASK(level);

		table_idx = (table_idx_va - table_base_va) >>
			    XLAT_ADDR_SHIFT(level);

		assert(table_idx < table_entries);
	} else {
		/* Start from the beginning of the table. */
		table_idx_va = table_base_va;
		table_idx = 0;
	}

	while (table_idx < table_entries) {

		table_idx_end_va = table_idx_va + XLAT_BLOCK_SIZE(level) - 1;

		desc = table_base[table_idx];
		uint64_t desc_type = desc & DESC_MASK;

		action_t action = ACTION_NONE;

		if ((mm->base_va <= table_idx_va) &&
		    (region_end_va >= table_idx_end_va)) {

			/* Region covers all block */

			if (level == 3) {
				/*
				 * Last level, only page descriptors allowed,
				 * erase it.
				 */
				assert(desc_type == PAGE_DESC);

				action = ACTION_WRITE_BLOCK_ENTRY;
			} else {
				/*
				 * Other levels can have table descriptors. If
				 * so, recurse into it and erase descriptors
				 * inside it as needed. If there is a block
				 * descriptor, just erase it. If an invalid
				 * descriptor is found, this table isn't
				 * actually mapped, which shouldn't happen.
				 */
				if (desc_type == TABLE_DESC) {
					action = ACTION_RECURSE_INTO_TABLE;
				} else {
					assert(desc_type == BLOCK_DESC);
					action = ACTION_WRITE_BLOCK_ENTRY;
				}
			}

		} else if ((mm->base_va <= table_idx_end_va) ||
			   (region_end_va >= table_idx_va)) {

			/*
			 * Region partially covers block.
			 *
			 * It can't happen in level 3.
			 *
			 * There must be a table descriptor here, if not there
			 * was a problem when mapping the region.
			 */

			assert(level < 3);

			assert(desc_type == TABLE_DESC);

			action = ACTION_RECURSE_INTO_TABLE;
		}

		if (action == ACTION_WRITE_BLOCK_ENTRY) {

			table_base[table_idx] = INVALID_DESC;
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			xlat_arch_tlbi_va_regime(table_idx_va, ctx->xlat_regime);
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		} else if (action == ACTION_RECURSE_INTO_TABLE) {

			subtable = (uint64_t *)(uintptr_t)(desc & TABLE_ADDR_MASK);

			/* Recurse to write into subtable */
			xlat_tables_unmap_region(ctx, mm, table_idx_va,
						 subtable, XLAT_TABLE_ENTRIES,
						 level + 1);

			/*
			 * If the subtable is now empty, remove its reference.
			 */
			if (xlat_table_is_empty(ctx, subtable)) {
				table_base[table_idx] = INVALID_DESC;
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				xlat_arch_tlbi_va_regime(table_idx_va,
						ctx->xlat_regime);
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			}

		} else {
			assert(action == ACTION_NONE);
		}

		table_idx++;
		table_idx_va += XLAT_BLOCK_SIZE(level);

		/* If reached the end of the region, exit */
		if (region_end_va <= table_idx_va)
			break;
	}

	if (level > ctx->base_level)
		xlat_table_dec_regions_count(ctx, table_base);
}

#endif /* PLAT_XLAT_TABLES_DYNAMIC */

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/*
 * From the given arguments, it decides which action to take when mapping the
 * specified region.
 */
static action_t xlat_tables_map_region_action(const mmap_region_t *mm,
		const int desc_type, const unsigned long long dest_pa,
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		const uintptr_t table_entry_base_va, const unsigned int level)
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{
	uintptr_t mm_end_va = mm->base_va + mm->size - 1;
	uintptr_t table_entry_end_va =
			table_entry_base_va + XLAT_BLOCK_SIZE(level) - 1;

	/*
	 * The descriptor types allowed depend on the current table level.
	 */

	if ((mm->base_va <= table_entry_base_va) &&
	    (mm_end_va >= table_entry_end_va)) {

		/*
		 * Table entry is covered by region
		 * --------------------------------
		 *
		 * This means that this table entry can describe the whole
		 * translation with this granularity in principle.
		 */

		if (level == 3) {
			/*
			 * Last level, only page descriptors are allowed.
			 */
			if (desc_type == PAGE_DESC) {
				/*
				 * There's another region mapped here, don't
				 * overwrite.
				 */
				return ACTION_NONE;
			} else {
				assert(desc_type == INVALID_DESC);
				return ACTION_WRITE_BLOCK_ENTRY;
			}

		} else {

			/*
			 * Other levels. Table descriptors are allowed. Block
			 * descriptors too, but they have some limitations.
			 */

			if (desc_type == TABLE_DESC) {
				/* There's already a table, recurse into it. */
				return ACTION_RECURSE_INTO_TABLE;

			} else if (desc_type == INVALID_DESC) {
				/*
				 * There's nothing mapped here, create a new
				 * entry.
				 *
				 * Check if the destination granularity allows
				 * us to use a block descriptor or we need a
				 * finer table for it.
				 *
				 * Also, check if the current level allows block
				 * descriptors. If not, create a table instead.
				 */
				if ((dest_pa & XLAT_BLOCK_MASK(level)) ||
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				    (level < MIN_LVL_BLOCK_DESC) ||
				    (mm->granularity < XLAT_BLOCK_SIZE(level)))
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					return ACTION_CREATE_NEW_TABLE;
				else
					return ACTION_WRITE_BLOCK_ENTRY;

			} else {
				/*
				 * There's another region mapped here, don't
				 * overwrite.
				 */
				assert(desc_type == BLOCK_DESC);

				return ACTION_NONE;
			}
		}

	} else if ((mm->base_va <= table_entry_end_va) ||
		   (mm_end_va >= table_entry_base_va)) {

		/*
		 * Region partially covers table entry
		 * -----------------------------------
		 *
		 * This means that this table entry can't describe the whole
		 * translation, a finer table is needed.

		 * There cannot be partial block overlaps in level 3. If that
		 * happens, some of the preliminary checks when adding the
		 * mmap region failed to detect that PA and VA must at least be
		 * aligned to PAGE_SIZE.
		 */
		assert(level < 3);

		if (desc_type == INVALID_DESC) {
			/*
			 * The block is not fully covered by the region. Create
			 * a new table, recurse into it and try to map the
			 * region with finer granularity.
			 */
			return ACTION_CREATE_NEW_TABLE;

		} else {
			assert(desc_type == TABLE_DESC);
			/*
			 * The block is not fully covered by the region, but
			 * there is already a table here. Recurse into it and
			 * try to map with finer granularity.
			 *
			 * PAGE_DESC for level 3 has the same value as
			 * TABLE_DESC, but this code can't run on a level 3
			 * table because there can't be overlaps in level 3.
			 */
			return ACTION_RECURSE_INTO_TABLE;
		}
	}

	/*
	 * This table entry is outside of the region specified in the arguments,
	 * don't write anything to it.
	 */
	return ACTION_NONE;
}

/*
 * Recursive function that writes to the translation tables and maps the
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 * specified region. On success, it returns the VA of the last byte that was
 * succesfully mapped. On error, it returns the VA of the next entry that
 * should have been mapped.
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 */
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static uintptr_t xlat_tables_map_region(xlat_ctx_t *ctx, mmap_region_t *mm,
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				   const uintptr_t table_base_va,
				   uint64_t *const table_base,
				   const int table_entries,
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				   const unsigned int level)
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{
	assert(level >= ctx->base_level && level <= XLAT_TABLE_LEVEL_MAX);

	uintptr_t mm_end_va = mm->base_va + mm->size - 1;

	uintptr_t table_idx_va;
	unsigned long long table_idx_pa;

	uint64_t *subtable;
	uint64_t desc;

	int table_idx;

	if (mm->base_va > table_base_va) {
		/* Find the first index of the table affected by the region. */
		table_idx_va = mm->base_va & ~XLAT_BLOCK_MASK(level);

		table_idx = (table_idx_va - table_base_va) >>
			    XLAT_ADDR_SHIFT(level);

		assert(table_idx < table_entries);
	} else {
		/* Start from the beginning of the table. */
		table_idx_va = table_base_va;
		table_idx = 0;
	}

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#if PLAT_XLAT_TABLES_DYNAMIC
	if (level > ctx->base_level)
		xlat_table_inc_regions_count(ctx, table_base);
#endif

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	while (table_idx < table_entries) {

		desc = table_base[table_idx];

		table_idx_pa = mm->base_pa + table_idx_va - mm->base_va;

		action_t action = xlat_tables_map_region_action(mm,
			desc & DESC_MASK, table_idx_pa, table_idx_va, level);

		if (action == ACTION_WRITE_BLOCK_ENTRY) {

			table_base[table_idx] =
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				xlat_desc(ctx, (uint32_t)mm->attr, table_idx_pa,
					  level);
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		} else if (action == ACTION_CREATE_NEW_TABLE) {

			subtable = xlat_table_get_empty(ctx);
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			if (subtable == NULL) {
				/* Not enough free tables to map this region */
				return table_idx_va;
			}

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			/* Point to new subtable from this one. */
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			table_base[table_idx] = TABLE_DESC | (unsigned long)subtable;

			/* Recurse to write into subtable */
			uintptr_t end_va = xlat_tables_map_region(ctx, mm, table_idx_va,
					       subtable, XLAT_TABLE_ENTRIES,
					       level + 1);
			if (end_va != table_idx_va + XLAT_BLOCK_SIZE(level) - 1)
				return end_va;
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		} else if (action == ACTION_RECURSE_INTO_TABLE) {

			subtable = (uint64_t *)(uintptr_t)(desc & TABLE_ADDR_MASK);
			/* Recurse to write into subtable */
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			uintptr_t end_va =  xlat_tables_map_region(ctx, mm, table_idx_va,
					       subtable, XLAT_TABLE_ENTRIES,
					       level + 1);
			if (end_va != table_idx_va + XLAT_BLOCK_SIZE(level) - 1)
				return end_va;
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		} else {

			assert(action == ACTION_NONE);

		}

		table_idx++;
		table_idx_va += XLAT_BLOCK_SIZE(level);

		/* If reached the end of the region, exit */
		if (mm_end_va <= table_idx_va)
			break;
	}
608
609

	return table_idx_va - 1;
610
611
612
613
614
615
616
617
618
}

void print_mmap(mmap_region_t *const mmap)
{
#if LOG_LEVEL >= LOG_LEVEL_VERBOSE
	tf_printf("mmap:\n");
	mmap_region_t *mm = mmap;

	while (mm->size) {
619
		tf_printf(" VA:%p  PA:0x%llx  size:0x%zx  attr:0x%x",
620
621
				(void *)mm->base_va, mm->base_pa,
				mm->size, mm->attr);
622
		tf_printf(" granularity:0x%zx\n", mm->granularity);
623
624
625
626
627
628
629
630
631
632
633
634
635
636
637
		++mm;
	};
	tf_printf("\n");
#endif
}

/*
 * Function that verifies that a region can be mapped.
 * Returns:
 *        0: Success, the mapping is allowed.
 *   EINVAL: Invalid values were used as arguments.
 *   ERANGE: The memory limits were surpassed.
 *   ENOMEM: There is not enough memory in the mmap array.
 *    EPERM: Region overlaps another one in an invalid way.
 */
638
static int mmap_add_region_check(xlat_ctx_t *ctx, const mmap_region_t *mm)
639
{
640
641
642
	unsigned long long base_pa = mm->base_pa;
	uintptr_t base_va = mm->base_va;
	size_t size = mm->size;
643
	size_t granularity = mm->granularity;
644

645
646
647
648
649
650
651
	unsigned long long end_pa = base_pa + size - 1;
	uintptr_t end_va = base_va + size - 1;

	if (!IS_PAGE_ALIGNED(base_pa) || !IS_PAGE_ALIGNED(base_va) ||
			!IS_PAGE_ALIGNED(size))
		return -EINVAL;

652
653
654
655
656
657
	if ((granularity != XLAT_BLOCK_SIZE(1)) &&
		(granularity != XLAT_BLOCK_SIZE(2)) &&
		(granularity != XLAT_BLOCK_SIZE(3))) {
		return -EINVAL;
	}

658
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660
661
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664
665
666
667
	/* Check for overflows */
	if ((base_pa > end_pa) || (base_va > end_va))
		return -ERANGE;

	if ((base_va + (uintptr_t)size - (uintptr_t)1) > ctx->va_max_address)
		return -ERANGE;

	if ((base_pa + (unsigned long long)size - 1ULL) > ctx->pa_max_address)
		return -ERANGE;

668
	/* Check that there is space in the ctx->mmap array */
669
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671
672
	if (ctx->mmap[ctx->mmap_num - 1].size != 0)
		return -ENOMEM;

	/* Check for PAs and VAs overlaps with all other regions */
673
674
	for (mmap_region_t *mm_cursor = ctx->mmap;
						mm_cursor->size; ++mm_cursor) {
675

676
677
		uintptr_t mm_cursor_end_va = mm_cursor->base_va
							+ mm_cursor->size - 1;
678
679
680
681
682
683

		/*
		 * Check if one of the regions is completely inside the other
		 * one.
		 */
		int fully_overlapped_va =
684
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686
687
688
			((base_va >= mm_cursor->base_va) &&
					(end_va <= mm_cursor_end_va)) ||

			((mm_cursor->base_va >= base_va) &&
						(mm_cursor_end_va <= end_va));
689
690
691
692
693

		/*
		 * Full VA overlaps are only allowed if both regions are
		 * identity mapped (zero offset) or have the same VA to PA
		 * offset. Also, make sure that it's not the exact same area.
694
		 * This can only be done with static regions.
695
696
697
		 */
		if (fully_overlapped_va) {

698
#if PLAT_XLAT_TABLES_DYNAMIC
699
			if ((mm->attr & MT_DYNAMIC) ||
700
						(mm_cursor->attr & MT_DYNAMIC))
701
702
				return -EPERM;
#endif /* PLAT_XLAT_TABLES_DYNAMIC */
703
704
			if ((mm_cursor->base_va - mm_cursor->base_pa) !=
							(base_va - base_pa))
705
706
				return -EPERM;

707
708
			if ((base_va == mm_cursor->base_va) &&
						(size == mm_cursor->size))
709
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711
712
713
714
715
716
717
				return -EPERM;

		} else {
			/*
			 * If the regions do not have fully overlapping VAs,
			 * then they must have fully separated VAs and PAs.
			 * Partial overlaps are not allowed
			 */

718
719
			unsigned long long mm_cursor_end_pa =
				     mm_cursor->base_pa + mm_cursor->size - 1;
720
721

			int separated_pa =
722
723
				(end_pa < mm_cursor->base_pa) ||
				(base_pa > mm_cursor_end_pa);
724
			int separated_va =
725
726
				(end_va < mm_cursor->base_va) ||
				(base_va > mm_cursor_end_va);
727
728
729
730
731
732
733
734
735

			if (!(separated_va && separated_pa))
				return -EPERM;
		}
	}

	return 0;
}

736
void mmap_add_region_ctx(xlat_ctx_t *ctx, const mmap_region_t *mm)
737
738
{
	mmap_region_t *mm_cursor = ctx->mmap;
739
740
	const mmap_region_t *mm_end = ctx->mmap + ctx->mmap_num;
	mmap_region_t *mm_last;
741
742
743
744
745
746
747
748
	unsigned long long end_pa = mm->base_pa + mm->size - 1;
	uintptr_t end_va = mm->base_va + mm->size - 1;
	int ret;

	/* Ignore empty regions */
	if (!mm->size)
		return;

749
750
751
	/* Static regions must be added before initializing the xlat tables. */
	assert(!ctx->initialized);

752
	ret = mmap_add_region_check(ctx, mm);
753
754
755
756
757
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761
762
763
764
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766
767
768
769
770
771
772
773
774
775
776
777
778
	if (ret != 0) {
		ERROR("mmap_add_region_check() failed. error %d\n", ret);
		assert(0);
		return;
	}

	/*
	 * Find correct place in mmap to insert new region.
	 *
	 * 1 - Lower region VA end first.
	 * 2 - Smaller region size first.
	 *
	 * VA  0                                   0xFF
	 *
	 * 1st |------|
	 * 2nd |------------|
	 * 3rd                 |------|
	 * 4th                            |---|
	 * 5th                                   |---|
	 * 6th                            |----------|
	 * 7th |-------------------------------------|
	 *
	 * This is required for overlapping regions only. It simplifies adding
	 * regions with the loop in xlat_tables_init_internal because the outer
	 * ones won't overwrite block or page descriptors of regions added
	 * previously.
779
780
	 *
	 * Overlapping is only allowed for static regions.
781
782
783
784
785
786
787
788
789
790
	 */

	while ((mm_cursor->base_va + mm_cursor->size - 1) < end_va
	       && mm_cursor->size)
		++mm_cursor;

	while ((mm_cursor->base_va + mm_cursor->size - 1 == end_va)
	       && (mm_cursor->size < mm->size))
		++mm_cursor;

791
792
793
794
795
796
797
798
799
800
801
802
803
804
805
	/*
	 * Find the last entry marker in the mmap
	 */
	mm_last = ctx->mmap;
	while ((mm_last->size != 0U) && (mm_last < mm_end)) {
		++mm_last;
	}

	/*
	 * Check if we have enough space in the memory mapping table.
	 * This shouldn't happen as we have checked in mmap_add_region_check
	 * that there is free space.
	 */
	assert(mm_last->size == 0U);

806
807
808
809
810
811
812
813
814
	/* Make room for new region by moving other regions up by one place */
	memmove(mm_cursor + 1, mm_cursor,
		(uintptr_t)mm_last - (uintptr_t)mm_cursor);

	/*
	 * Check we haven't lost the empty sentinel from the end of the array.
	 * This shouldn't happen as we have checked in mmap_add_region_check
	 * that there is free space.
	 */
815
	assert(mm_end->size == 0U);
816

817
	*mm_cursor = *mm;
818
819
820
821
822
823
824

	if (end_pa > ctx->max_pa)
		ctx->max_pa = end_pa;
	if (end_va > ctx->max_va)
		ctx->max_va = end_va;
}

825
826
827
828
829
void mmap_add_region(unsigned long long base_pa,
				uintptr_t base_va,
				size_t size,
				mmap_attr_t attr)
{
830
	mmap_region_t mm = MAP_REGION(base_pa, base_va, size, attr);
831
832
833
834
835
836
837
838
839
840
841
842
843
844
845
846
847
	mmap_add_region_ctx(&tf_xlat_ctx, &mm);
}


void mmap_add_ctx(xlat_ctx_t *ctx, const mmap_region_t *mm)
{
	while (mm->size) {
		mmap_add_region_ctx(ctx, mm);
		mm++;
	}
}

void mmap_add(const mmap_region_t *mm)
{
	mmap_add_ctx(&tf_xlat_ctx, mm);
}

848
849
850
851
852
853
854
855
856
857
858
859
860
861
#if PLAT_XLAT_TABLES_DYNAMIC

int mmap_add_dynamic_region_ctx(xlat_ctx_t *ctx, mmap_region_t *mm)
{
	mmap_region_t *mm_cursor = ctx->mmap;
	mmap_region_t *mm_last = mm_cursor + ctx->mmap_num;
	unsigned long long end_pa = mm->base_pa + mm->size - 1;
	uintptr_t end_va = mm->base_va + mm->size - 1;
	int ret;

	/* Nothing to do */
	if (!mm->size)
		return 0;

862
863
864
865
	/* Now this region is a dynamic one */
	mm->attr |= MT_DYNAMIC;

	ret = mmap_add_region_check(ctx, mm);
866
867
868
869
870
871
872
873
	if (ret != 0)
		return ret;

	/*
	 * Find the adequate entry in the mmap array in the same way done for
	 * static regions in mmap_add_region_ctx().
	 */

874
875
	while ((mm_cursor->base_va + mm_cursor->size - 1)
					< end_va && mm_cursor->size)
876
877
		++mm_cursor;

878
879
	while ((mm_cursor->base_va + mm_cursor->size - 1 == end_va)
				&& (mm_cursor->size < mm->size))
880
881
882
		++mm_cursor;

	/* Make room for new region by moving other regions up by one place */
883
884
	memmove(mm_cursor + 1, mm_cursor,
		     (uintptr_t)mm_last - (uintptr_t)mm_cursor);
885
886
887
888
889
890
891
892

	/*
	 * Check we haven't lost the empty sentinal from the end of the array.
	 * This shouldn't happen as we have checked in mmap_add_region_check
	 * that there is free space.
	 */
	assert(mm_last->size == 0);

893
	*mm_cursor = *mm;
894
895
896
897
898
899

	/*
	 * Update the translation tables if the xlat tables are initialized. If
	 * not, this region will be mapped when they are initialized.
	 */
	if (ctx->initialized) {
900
901
902
		uintptr_t end_va = xlat_tables_map_region(ctx, mm_cursor,
				0, ctx->base_table, ctx->base_table_entries,
				ctx->base_level);
903
904
905

		/* Failed to map, remove mmap entry, unmap and return error. */
		if (end_va != mm_cursor->base_va + mm_cursor->size - 1) {
906
907
			memmove(mm_cursor, mm_cursor + 1,
				(uintptr_t)mm_last - (uintptr_t)mm_cursor);
908
909
910
911
912

			/*
			 * Check if the mapping function actually managed to map
			 * anything. If not, just return now.
			 */
913
			if (mm->base_va >= end_va)
914
915
916
				return -ENOMEM;

			/*
917
918
			 * Something went wrong after mapping some table
			 * entries, undo every change done up to this point.
919
920
921
922
923
924
925
			 */
			mmap_region_t unmap_mm = {
					.base_pa = 0,
					.base_va = mm->base_va,
					.size = end_va - mm->base_va,
					.attr = 0
			};
926
927
			xlat_tables_unmap_region(ctx, &unmap_mm, 0, ctx->base_table,
							ctx->base_table_entries, ctx->base_level);
928
929
930
931
932
933
934
935
936
937
938
939
940
941
942
943
944
945
946
947
948

			return -ENOMEM;
		}

		/*
		 * Make sure that all entries are written to the memory. There
		 * is no need to invalidate entries when mapping dynamic regions
		 * because new table/block/page descriptors only replace old
		 * invalid descriptors, that aren't TLB cached.
		 */
		dsbishst();
	}

	if (end_pa > ctx->max_pa)
		ctx->max_pa = end_pa;
	if (end_va > ctx->max_va)
		ctx->max_va = end_va;

	return 0;
}

949
950
951
int mmap_add_dynamic_region(unsigned long long base_pa,
			    uintptr_t base_va, size_t size, mmap_attr_t attr)
{
952
	mmap_region_t mm = MAP_REGION(base_pa, base_va, size, attr);
953
954
955
	return mmap_add_dynamic_region_ctx(&tf_xlat_ctx, &mm);
}

956
957
958
959
960
961
962
963
964
965
966
967
968
969
970
971
972
973
974
975
976
977
978
979
980
981
982
983
984
985
986
987
988
989
990
991
992
993
994
995
996
997
998
999
1000
1001
1002
1003
1004
1005
1006
1007
1008
1009
1010
1011
1012
1013
1014
1015
1016
1017
1018
1019
1020
1021
1022
1023
1024
1025
1026
1027
1028
1029
1030
/*
 * Removes the region with given base Virtual Address and size from the given
 * context.
 *
 * Returns:
 *        0: Success.
 *   EINVAL: Invalid values were used as arguments (region not found).
 *    EPERM: Tried to remove a static region.
 */
int mmap_remove_dynamic_region_ctx(xlat_ctx_t *ctx, uintptr_t base_va,
				   size_t size)
{
	mmap_region_t *mm = ctx->mmap;
	mmap_region_t *mm_last = mm + ctx->mmap_num;
	int update_max_va_needed = 0;
	int update_max_pa_needed = 0;

	/* Check sanity of mmap array. */
	assert(mm[ctx->mmap_num].size == 0);

	while (mm->size) {
		if ((mm->base_va == base_va) && (mm->size == size))
			break;
		++mm;
	}

	/* Check that the region was found */
	if (mm->size == 0)
		return -EINVAL;

	/* If the region is static it can't be removed */
	if (!(mm->attr & MT_DYNAMIC))
		return -EPERM;

	/* Check if this region is using the top VAs or PAs. */
	if ((mm->base_va + mm->size - 1) == ctx->max_va)
		update_max_va_needed = 1;
	if ((mm->base_pa + mm->size - 1) == ctx->max_pa)
		update_max_pa_needed = 1;

	/* Update the translation tables if needed */
	if (ctx->initialized) {
		xlat_tables_unmap_region(ctx, mm, 0, ctx->base_table,
					 ctx->base_table_entries,
					 ctx->base_level);
		xlat_arch_tlbi_va_sync();
	}

	/* Remove this region by moving the rest down by one place. */
	memmove(mm, mm + 1, (uintptr_t)mm_last - (uintptr_t)mm);

	/* Check if we need to update the max VAs and PAs */
	if (update_max_va_needed) {
		ctx->max_va = 0;
		mm = ctx->mmap;
		while (mm->size) {
			if ((mm->base_va + mm->size - 1) > ctx->max_va)
				ctx->max_va = mm->base_va + mm->size - 1;
			++mm;
		}
	}

	if (update_max_pa_needed) {
		ctx->max_pa = 0;
		mm = ctx->mmap;
		while (mm->size) {
			if ((mm->base_pa + mm->size - 1) > ctx->max_pa)
				ctx->max_pa = mm->base_pa + mm->size - 1;
			++mm;
		}
	}

	return 0;
}

1031
1032
1033
1034
1035
1036
int mmap_remove_dynamic_region(uintptr_t base_va, size_t size)
{
	return mmap_remove_dynamic_region_ctx(&tf_xlat_ctx,
					base_va, size);
}

1037
1038
#endif /* PLAT_XLAT_TABLES_DYNAMIC */

1039
1040
1041
#if LOG_LEVEL >= LOG_LEVEL_VERBOSE

/* Print the attributes of the specified block descriptor. */
1042
static void xlat_desc_print(const xlat_ctx_t *ctx, uint64_t desc)
1043
1044
{
	int mem_type_index = ATTR_INDEX_GET(desc);
1045
	xlat_regime_t xlat_regime = ctx->xlat_regime;
1046
1047
1048
1049
1050
1051
1052
1053
1054
1055

	if (mem_type_index == ATTR_IWBWA_OWBWA_NTR_INDEX) {
		tf_printf("MEM");
	} else if (mem_type_index == ATTR_NON_CACHEABLE_INDEX) {
		tf_printf("NC");
	} else {
		assert(mem_type_index == ATTR_DEVICE_INDEX);
		tf_printf("DEV");
	}

1056
1057
1058
1059
1060
1061
1062
1063
1064
1065
1066
1067
1068
1069
1070
1071
1072
1073
1074
1075
1076
1077
1078
1079
1080
1081
1082
1083
1084
1085
1086
1087
1088
1089
1090
1091
1092
1093
1094
1095
1096
1097
	const char *priv_str = "(PRIV)";
	const char *user_str = "(USER)";

	/*
	 * Showing Privileged vs Unprivileged only makes sense for EL1&0
	 * mappings
	 */
	const char *ro_str = "-RO";
	const char *rw_str = "-RW";
	const char *no_access_str = "-NOACCESS";

	if (xlat_regime == EL3_REGIME) {
		/* For EL3, the AP[2] bit is all what matters */
		tf_printf((desc & LOWER_ATTRS(AP_RO)) ? ro_str : rw_str);
	} else {
		const char *ap_str = (desc & LOWER_ATTRS(AP_RO)) ? ro_str : rw_str;
		tf_printf(ap_str);
		tf_printf(priv_str);
		/*
		 * EL0 can only have the same permissions as EL1 or no
		 * permissions at all.
		 */
		tf_printf((desc & LOWER_ATTRS(AP_ACCESS_UNPRIVILEGED))
			  ? ap_str : no_access_str);
		tf_printf(user_str);
	}

	const char *xn_str = "-XN";
	const char *exec_str = "-EXEC";

	if (xlat_regime == EL3_REGIME) {
		/* For EL3, the XN bit is all what matters */
		tf_printf(LOWER_ATTRS(XN) & desc ? xn_str : exec_str);
	} else {
		/* For EL0 and EL1, we need to know who has which rights */
		tf_printf(LOWER_ATTRS(PXN) & desc ? xn_str : exec_str);
		tf_printf(priv_str);

		tf_printf(LOWER_ATTRS(UXN) & desc ? xn_str : exec_str);
		tf_printf(user_str);
	}

1098
1099
1100
1101
	tf_printf(LOWER_ATTRS(NS) & desc ? "-NS" : "-S");
}

static const char * const level_spacers[] = {
1102
1103
1104
1105
	"[LV0] ",
	"  [LV1] ",
	"    [LV2] ",
	"      [LV3] "
1106
1107
};

1108
1109
1110
static const char *invalid_descriptors_ommited =
		"%s(%d invalid descriptors omitted)\n";

1111
1112
1113
1114
/*
 * Recursive function that reads the translation tables passed as an argument
 * and prints their status.
 */
1115
1116
static void xlat_tables_print_internal(xlat_ctx_t *ctx,
		const uintptr_t table_base_va,
1117
		uint64_t *const table_base, const int table_entries,
1118
		const unsigned int level)
1119
1120
1121
1122
1123
1124
1125
1126
1127
{
	assert(level <= XLAT_TABLE_LEVEL_MAX);

	uint64_t desc;
	uintptr_t table_idx_va = table_base_va;
	int table_idx = 0;

	size_t level_size = XLAT_BLOCK_SIZE(level);

1128
1129
1130
1131
1132
1133
1134
1135
	/*
	 * Keep track of how many invalid descriptors are counted in a row.
	 * Whenever multiple invalid descriptors are found, only the first one
	 * is printed, and a line is added to inform about how many descriptors
	 * have been omitted.
	 */
	int invalid_row_count = 0;

1136
1137
1138
1139
1140
1141
	while (table_idx < table_entries) {

		desc = table_base[table_idx];

		if ((desc & DESC_MASK) == INVALID_DESC) {

1142
1143
1144
1145
1146
1147
			if (invalid_row_count == 0) {
				tf_printf("%sVA:%p size:0x%zx\n",
					  level_spacers[level],
					  (void *)table_idx_va, level_size);
			}
			invalid_row_count++;
1148
1149
1150

		} else {

1151
1152
1153
1154
1155
1156
1157
			if (invalid_row_count > 1) {
				tf_printf(invalid_descriptors_ommited,
					  level_spacers[level],
					  invalid_row_count - 1);
			}
			invalid_row_count = 0;

1158
1159
1160
1161
1162
1163
1164
1165
1166
1167
1168
1169
1170
1171
1172
1173
1174
1175
1176
			/*
			 * Check if this is a table or a block. Tables are only
			 * allowed in levels other than 3, but DESC_PAGE has the
			 * same value as DESC_TABLE, so we need to check.
			 */
			if (((desc & DESC_MASK) == TABLE_DESC) &&
					(level < XLAT_TABLE_LEVEL_MAX)) {
				/*
				 * Do not print any PA for a table descriptor,
				 * as it doesn't directly map physical memory
				 * but instead points to the next translation
				 * table in the translation table walk.
				 */
				tf_printf("%sVA:%p size:0x%zx\n",
					  level_spacers[level],
					  (void *)table_idx_va, level_size);

				uintptr_t addr_inner = desc & TABLE_ADDR_MASK;

1177
				xlat_tables_print_internal(ctx, table_idx_va,
1178
					(uint64_t *)addr_inner,
1179
					XLAT_TABLE_ENTRIES, level + 1);
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			} else {
				tf_printf("%sVA:%p PA:0x%llx size:0x%zx ",
					  level_spacers[level],
					  (void *)table_idx_va,
					  (unsigned long long)(desc & TABLE_ADDR_MASK),
					  level_size);
1186
				xlat_desc_print(ctx, desc);
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				tf_printf("\n");
			}
		}

		table_idx++;
		table_idx_va += level_size;
	}
1194
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	if (invalid_row_count > 1) {
		tf_printf(invalid_descriptors_ommited,
			  level_spacers[level], invalid_row_count - 1);
	}
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}

#endif /* LOG_LEVEL >= LOG_LEVEL_VERBOSE */

void xlat_tables_print(xlat_ctx_t *ctx)
{
#if LOG_LEVEL >= LOG_LEVEL_VERBOSE
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	const char *xlat_regime_str;
	if (ctx->xlat_regime == EL1_EL0_REGIME) {
		xlat_regime_str = "1&0";
	} else {
		assert(ctx->xlat_regime == EL3_REGIME);
		xlat_regime_str = "3";
	}
1213
	VERBOSE("Translation tables state:\n");
1214
	VERBOSE("  Xlat regime:     EL%s\n", xlat_regime_str);
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	VERBOSE("  Max allowed PA:  0x%llx\n", ctx->pa_max_address);
	VERBOSE("  Max allowed VA:  %p\n", (void *) ctx->va_max_address);
	VERBOSE("  Max mapped PA:   0x%llx\n", ctx->max_pa);
	VERBOSE("  Max mapped VA:   %p\n", (void *) ctx->max_va);

	VERBOSE("  Initial lookup level: %i\n", ctx->base_level);
	VERBOSE("  Entries @initial lookup level: %i\n",
		ctx->base_table_entries);

	int used_page_tables;
#if PLAT_XLAT_TABLES_DYNAMIC
	used_page_tables = 0;
1227
	for (unsigned int i = 0; i < ctx->tables_num; ++i) {
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		if (ctx->tables_mapped_regions[i] != 0)
			++used_page_tables;
	}
#else
	used_page_tables = ctx->next_table;
#endif
	VERBOSE("  Used %i sub-tables out of %i (spare: %i)\n",
		used_page_tables, ctx->tables_num,
		ctx->tables_num - used_page_tables);

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	xlat_tables_print_internal(ctx, 0, ctx->base_table,
				   ctx->base_table_entries, ctx->base_level);
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#endif /* LOG_LEVEL >= LOG_LEVEL_VERBOSE */
}

1243
void init_xlat_tables_ctx(xlat_ctx_t *ctx)
1244
{
1245
	assert(ctx != NULL);
1246
	assert(!ctx->initialized);
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	assert(ctx->xlat_regime == EL3_REGIME || ctx->xlat_regime == EL1_EL0_REGIME);
	assert(!is_mmu_enabled_ctx(ctx));
1249

1250
	mmap_region_t *mm = ctx->mmap;
1251

1252
	print_mmap(mm);
1253

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	/* All tables must be zeroed before mapping any region. */

1256
	for (unsigned int i = 0; i < ctx->base_table_entries; i++)
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		ctx->base_table[i] = INVALID_DESC;

1259
	for (unsigned int j = 0; j < ctx->tables_num; j++) {
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#if PLAT_XLAT_TABLES_DYNAMIC
		ctx->tables_mapped_regions[j] = 0;
#endif
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		for (unsigned int i = 0; i < XLAT_TABLE_ENTRIES; i++)
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			ctx->tables[j][i] = INVALID_DESC;
	}

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	while (mm->size) {
		uintptr_t end_va = xlat_tables_map_region(ctx, mm, 0, ctx->base_table,
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				ctx->base_table_entries, ctx->base_level);

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		if (end_va != mm->base_va + mm->size - 1) {
			ERROR("Not enough memory to map region:\n"
			      " VA:%p  PA:0x%llx  size:0x%zx  attr:0x%x\n",
			      (void *)mm->base_va, mm->base_pa, mm->size, mm->attr);
			panic();
		}

		mm++;
	}

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	assert(ctx->pa_max_address <= xlat_arch_get_max_supported_pa());
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	assert(ctx->max_va <= ctx->va_max_address);
	assert(ctx->max_pa <= ctx->pa_max_address);

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	ctx->initialized = 1;

	xlat_tables_print(ctx);
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}

void init_xlat_tables(void)
{
	init_xlat_tables_ctx(&tf_xlat_ctx);
1293
}
1294

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/*
 * If dynamic allocation of new regions is disabled then by the time we call the
 * function enabling the MMU, we'll have registered all the memory regions to
 * map for the system's lifetime. Therefore, at this point we know the maximum
 * physical address that will ever be mapped.
 *
 * If dynamic allocation is enabled then we can't make any such assumption
 * because the maximum physical address could get pushed while adding a new
 * region. Therefore, in this case we have to assume that the whole address
 * space size might be mapped.
 */
#ifdef PLAT_XLAT_TABLES_DYNAMIC
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#define MAX_PHYS_ADDR	tf_xlat_ctx.pa_max_address
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#else
#define MAX_PHYS_ADDR	tf_xlat_ctx.max_pa
#endif

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#ifdef AARCH32

void enable_mmu_secure(unsigned int flags)
{
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	enable_mmu_arch(flags, tf_xlat_ctx.base_table, MAX_PHYS_ADDR,
			tf_xlat_ctx.va_max_address);
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}

#else

void enable_mmu_el1(unsigned int flags)
{
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	enable_mmu_arch(flags, tf_xlat_ctx.base_table, MAX_PHYS_ADDR,
			tf_xlat_ctx.va_max_address);
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}

void enable_mmu_el3(unsigned int flags)
{
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	enable_mmu_arch(flags, tf_xlat_ctx.base_table, MAX_PHYS_ADDR,
			tf_xlat_ctx.va_max_address);
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}

#endif /* AARCH32 */
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/*
 * Do a translation table walk to find the block or page descriptor that maps
 * virtual_addr.
 *
 * On success, return the address of the descriptor within the translation
 * table. Its lookup level is stored in '*out_level'.
 * On error, return NULL.
 *
 * xlat_table_base
 *   Base address for the initial lookup level.
 * xlat_table_base_entries
 *   Number of entries in the translation table for the initial lookup level.
 * virt_addr_space_size
 *   Size in bytes of the virtual address space.
 */
static uint64_t *find_xlat_table_entry(uintptr_t virtual_addr,
				       void *xlat_table_base,
				       int xlat_table_base_entries,
				       unsigned long long virt_addr_space_size,
				       int *out_level)
{
	unsigned int start_level;
	uint64_t *table;
	int entries;

	VERBOSE("%s(%p)\n", __func__, (void *)virtual_addr);

	start_level = GET_XLAT_TABLE_LEVEL_BASE(virt_addr_space_size);
	VERBOSE("Starting translation table walk from level %i\n", start_level);

	table = xlat_table_base;
	entries = xlat_table_base_entries;

	for (unsigned int level = start_level;
	     level <= XLAT_TABLE_LEVEL_MAX;
	     ++level) {
		int idx;
		uint64_t desc;
		uint64_t desc_type;

		VERBOSE("Table address: %p\n", (void *)table);

		idx = XLAT_TABLE_IDX(virtual_addr, level);
		VERBOSE("Index into level %i table: %i\n", level, idx);
		if (idx >= entries) {
			VERBOSE("Invalid address\n");
			return NULL;
		}

		desc = table[idx];
		desc_type = desc & DESC_MASK;
		VERBOSE("Descriptor at level %i: 0x%llx\n", level,
				(unsigned long long)desc);

		if (desc_type == INVALID_DESC) {
			VERBOSE("Invalid entry (memory not mapped)\n");
			return NULL;
		}

		if (level == XLAT_TABLE_LEVEL_MAX) {
			/*
			 * There can't be table entries at the final lookup
			 * level.
			 */
			assert(desc_type == PAGE_DESC);
			VERBOSE("Descriptor mapping a memory page (size: 0x%llx)\n",
				(unsigned long long)XLAT_BLOCK_SIZE(XLAT_TABLE_LEVEL_MAX));
			*out_level = level;
			return &table[idx];
		}

		if (desc_type == BLOCK_DESC) {
			VERBOSE("Descriptor mapping a memory block (size: 0x%llx)\n",
				(unsigned long long)XLAT_BLOCK_SIZE(level));
			*out_level = level;
			return &table[idx];
		}

		assert(desc_type == TABLE_DESC);
		VERBOSE("Table descriptor, continuing xlat table walk...\n");
		table = (uint64_t *)(uintptr_t)(desc & TABLE_ADDR_MASK);
		entries = XLAT_TABLE_ENTRIES;
	}

	/*
	 * This shouldn't be reached, the translation table walk should end at
	 * most at level XLAT_TABLE_LEVEL_MAX and return from inside the loop.
	 */
	assert(0);

	return NULL;
}


static int get_mem_attributes_internal(const xlat_ctx_t *ctx, uintptr_t base_va,
1431
		uint32_t *attributes, uint64_t **table_entry,
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		unsigned long long *addr_pa, int *table_level)
{
	uint64_t *entry;
	uint64_t desc;
	int level;
	unsigned long long virt_addr_space_size;

	/*
	 * Sanity-check arguments.
	 */
	assert(ctx != NULL);
	assert(ctx->initialized);
	assert(ctx->xlat_regime == EL1_EL0_REGIME || ctx->xlat_regime == EL3_REGIME);

	virt_addr_space_size = (unsigned long long)ctx->va_max_address + 1;
	assert(virt_addr_space_size > 0);

	entry = find_xlat_table_entry(base_va,
				ctx->base_table,
				ctx->base_table_entries,
				virt_addr_space_size,
				&level);
	if (entry == NULL) {
		WARN("Address %p is not mapped.\n", (void *)base_va);
		return -EINVAL;
	}

	if (addr_pa != NULL) {
		*addr_pa = *entry & TABLE_ADDR_MASK;
	}

	if (table_entry != NULL) {
		*table_entry = entry;
	}

	if (table_level != NULL) {
		*table_level = level;
	}

	desc = *entry;

#if LOG_LEVEL >= LOG_LEVEL_VERBOSE
	VERBOSE("Attributes: ");
	xlat_desc_print(ctx, desc);
	tf_printf("\n");
#endif /* LOG_LEVEL >= LOG_LEVEL_VERBOSE */

	assert(attributes != NULL);
	*attributes = 0;

	int attr_index = (desc >> ATTR_INDEX_SHIFT) & ATTR_INDEX_MASK;

	if (attr_index == ATTR_IWBWA_OWBWA_NTR_INDEX) {
		*attributes |= MT_MEMORY;
	} else if (attr_index == ATTR_NON_CACHEABLE_INDEX) {
		*attributes |= MT_NON_CACHEABLE;
	} else {
		assert(attr_index == ATTR_DEVICE_INDEX);
		*attributes |= MT_DEVICE;
	}

	int ap2_bit = (desc >> AP2_SHIFT) & 1;

	if (ap2_bit == AP2_RW)
		*attributes |= MT_RW;

	if (ctx->xlat_regime == EL1_EL0_REGIME) {
		int ap1_bit = (desc >> AP1_SHIFT) & 1;
		if (ap1_bit == AP1_ACCESS_UNPRIVILEGED)
			*attributes |= MT_USER;
	}

	int ns_bit = (desc >> NS_SHIFT) & 1;

	if (ns_bit == 1)
		*attributes |= MT_NS;

	uint64_t xn_mask = xlat_arch_regime_get_xn_desc(ctx->xlat_regime);

	if ((desc & xn_mask) == xn_mask) {
		*attributes |= MT_EXECUTE_NEVER;
	} else {
		assert((desc & xn_mask) == 0);
	}

	return 0;
}


int get_mem_attributes(const xlat_ctx_t *ctx, uintptr_t base_va,
1522
		       uint32_t *attributes)
1523
1524
1525
1526
{
	return get_mem_attributes_internal(ctx, base_va, attributes,
					   NULL, NULL, NULL);
}
1527
1528
1529
1530
1531


int change_mem_attributes(xlat_ctx_t *ctx,
			uintptr_t base_va,
			size_t size,
1532
			uint32_t attr)
1533
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1622
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1624
1625
1626
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1628
{
	/* Note: This implementation isn't optimized. */

	assert(ctx != NULL);
	assert(ctx->initialized);

	unsigned long long virt_addr_space_size =
		(unsigned long long)ctx->va_max_address + 1;
	assert(virt_addr_space_size > 0);

	if (!IS_PAGE_ALIGNED(base_va)) {
		WARN("%s: Address %p is not aligned on a page boundary.\n",
		     __func__, (void *)base_va);
		return -EINVAL;
	}

	if (size == 0) {
		WARN("%s: Size is 0.\n", __func__);
		return -EINVAL;
	}

	if ((size % PAGE_SIZE) != 0) {
		WARN("%s: Size 0x%zx is not a multiple of a page size.\n",
		     __func__, size);
		return -EINVAL;
	}

	if (((attr & MT_EXECUTE_NEVER) == 0) && ((attr & MT_RW) != 0)) {
		WARN("%s() doesn't allow to remap memory as read-write and executable.\n",
		     __func__);
		return -EINVAL;
	}

	int pages_count = size / PAGE_SIZE;

	VERBOSE("Changing memory attributes of %i pages starting from address %p...\n",
		pages_count, (void *)base_va);

	uintptr_t base_va_original = base_va;

	/*
	 * Sanity checks.
	 */
	for (int i = 0; i < pages_count; ++i) {
		uint64_t *entry;
		uint64_t desc;
		int level;

		entry = find_xlat_table_entry(base_va,
					      ctx->base_table,
					      ctx->base_table_entries,
					      virt_addr_space_size,
					      &level);
		if (entry == NULL) {
			WARN("Address %p is not mapped.\n", (void *)base_va);
			return -EINVAL;
		}

		desc = *entry;

		/*
		 * Check that all the required pages are mapped at page
		 * granularity.
		 */
		if (((desc & DESC_MASK) != PAGE_DESC) ||
			(level != XLAT_TABLE_LEVEL_MAX)) {
			WARN("Address %p is not mapped at the right granularity.\n",
			     (void *)base_va);
			WARN("Granularity is 0x%llx, should be 0x%x.\n",
			     (unsigned long long)XLAT_BLOCK_SIZE(level), PAGE_SIZE);
			return -EINVAL;
		}

		/*
		 * If the region type is device, it shouldn't be executable.
		 */
		int attr_index = (desc >> ATTR_INDEX_SHIFT) & ATTR_INDEX_MASK;
		if (attr_index == ATTR_DEVICE_INDEX) {
			if ((attr & MT_EXECUTE_NEVER) == 0) {
				WARN("Setting device memory as executable at address %p.",
				     (void *)base_va);
				return -EINVAL;
			}
		}

		base_va += PAGE_SIZE;
	}

	/* Restore original value. */
	base_va = base_va_original;

	VERBOSE("%s: All pages are mapped, now changing their attributes...\n",
		__func__);

	for (int i = 0; i < pages_count; ++i) {

1629
		uint32_t old_attr, new_attr;
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		uint64_t *entry;
		int level;
		unsigned long long addr_pa;

		get_mem_attributes_internal(ctx, base_va, &old_attr,
					    &entry, &addr_pa, &level);

		VERBOSE("Old attributes: 0x%x\n", old_attr);

		/*
		 * From attr, only MT_RO/MT_RW, MT_EXECUTE/MT_EXECUTE_NEVER and
		 * MT_USER/MT_PRIVILEGED are taken into account. Any other
		 * information is ignored.
		 */

		/* Clean the old attributes so that they can be rebuilt. */
		new_attr = old_attr & ~(MT_RW|MT_EXECUTE_NEVER|MT_USER);

		/*
		 * Update attributes, but filter out the ones this function
		 * isn't allowed to change.
		 */
		new_attr |= attr & (MT_RW|MT_EXECUTE_NEVER|MT_USER);

		VERBOSE("New attributes: 0x%x\n", new_attr);

		/*
		 * The break-before-make sequence requires writing an invalid
		 * descriptor and making sure that the system sees the change
		 * before writing the new descriptor.
		 */
		*entry = INVALID_DESC;

		/* Invalidate any cached copy of this mapping in the TLBs. */
		xlat_arch_tlbi_va_regime(base_va, ctx->xlat_regime);

		/* Ensure completion of the invalidation. */
		xlat_arch_tlbi_va_sync();

		/* Write new descriptor */
		*entry = xlat_desc(ctx, new_attr, addr_pa, level);

		base_va += PAGE_SIZE;
	}

	/* Ensure that the last descriptor writen is seen by the system. */
	dsbish();

	return 0;
}