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/*
* This file is part of the coreboot project.
*
* Copyright 2014 Google Inc.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#include <assert.h>
#include <stdlib.h>
#include <stdint.h>
#include <string.h>
#include <symbols.h>
#include <console/console.h>
#include <arch/mmu.h>
#include <arch/lib_helpers.h>
#include <arch/cache.h>
/* This just caches the next free table slot (okay to do since they fill up from
* bottom to top and can never be freed up again). It will reset to its initial
* value on stage transition, so we still need to check it for UNUSED_DESC. */
static uint64_t *next_free_table = (void *)_ttb;
static void print_tag(int level, uint64_t tag)
{
printk(level, tag & MA_MEM_NC ? "non-cacheable | " :
" cacheable | ");
printk(level, tag & MA_RO ? "read-only | " :
"read-write | ");
printk(level, tag & MA_NS ? "non-secure | " :
" secure | ");
printk(level, tag & MA_MEM ? "normal\n" :
"device\n");
}
/* Func : get_block_attr
* Desc : Get block descriptor attributes based on the value of tag in memrange
* region
*/
static uint64_t get_block_attr(unsigned long tag)
{
uint64_t attr;
attr = (tag & MA_NS)? BLOCK_NS : 0;
attr |= (tag & MA_RO)? BLOCK_AP_RO : BLOCK_AP_RW;
attr |= BLOCK_ACCESS;
if (tag & MA_MEM) {
attr |= BLOCK_SH_INNER_SHAREABLE;
if (tag & MA_MEM_NC)
attr |= BLOCK_INDEX_MEM_NORMAL_NC << BLOCK_INDEX_SHIFT;
else
attr |= BLOCK_INDEX_MEM_NORMAL << BLOCK_INDEX_SHIFT;
} else {
attr |= BLOCK_INDEX_MEM_DEV_NGNRNE << BLOCK_INDEX_SHIFT;
attr |= BLOCK_XN;
}
return attr;
}
/* Func : setup_new_table
* Desc : Get next free table from TTB and set it up to match old parent entry.
*/
static uint64_t *setup_new_table(uint64_t desc, size_t xlat_size)
{
while (next_free_table[0] != UNUSED_DESC) {
next_free_table += GRANULE_SIZE/sizeof(*next_free_table);
if (_ettb - (u8 *)next_free_table <= 0)
die("Ran out of page table space!");
}
void *frame_base = (void *)(desc & XLAT_ADDR_MASK);
printk(BIOS_DEBUG, "Backing address range [%p:%p) with new page"
" table @%p\n", frame_base, frame_base +
(xlat_size << BITS_RESOLVED_PER_LVL), next_free_table);
if (!desc) {
memset(next_free_table, 0, GRANULE_SIZE);
} else {
/* Can reuse old parent entry, but may need to adjust type. */
if (xlat_size == L3_XLAT_SIZE)
desc |= PAGE_DESC;
int i = 0;
for (; i < GRANULE_SIZE/sizeof(*next_free_table); i++) {
next_free_table[i] = desc;
desc += xlat_size;
}
}
return next_free_table;
}
/* Func: get_next_level_table
* Desc: Check if the table entry is a valid descriptor. If not, initialize new
* table, update the entry and return the table addr. If valid, return the addr
*/
static uint64_t *get_next_level_table(uint64_t *ptr, size_t xlat_size)
{
uint64_t desc = *ptr;
if ((desc & DESC_MASK) != TABLE_DESC) {
uint64_t *new_table = setup_new_table(desc, xlat_size);
desc = ((uint64_t)new_table) | TABLE_DESC;
*ptr = desc;
}
return (uint64_t *)(desc & XLAT_ADDR_MASK);
}
/* Func : init_xlat_table
* Desc : Given a base address and size, it identifies the indices within
* different level XLAT tables which map the given base addr. Similar to table
* walk, except that all invalid entries during the walk are updated
* accordingly. On success, it returns the size of the block/page addressed by
* the final table.
*/
static uint64_t init_xlat_table(uint64_t base_addr,
uint64_t size,
uint64_t tag)
{
uint64_t l0_index = (base_addr & L0_ADDR_MASK) >> L0_ADDR_SHIFT;
uint64_t l1_index = (base_addr & L1_ADDR_MASK) >> L1_ADDR_SHIFT;
uint64_t l2_index = (base_addr & L2_ADDR_MASK) >> L2_ADDR_SHIFT;
uint64_t l3_index = (base_addr & L3_ADDR_MASK) >> L3_ADDR_SHIFT;
uint64_t *table = (uint64_t *)_ttb;
uint64_t desc;
uint64_t attr = get_block_attr(tag);
/* L0 entry stores a table descriptor (doesn't support blocks) */
table = get_next_level_table(&table[l0_index], L1_XLAT_SIZE);
/* L1 table lookup */
if ((size >= L1_XLAT_SIZE) &&
IS_ALIGNED(base_addr, (1UL << L1_ADDR_SHIFT))) {
/* If block address is aligned and size is greater than
* or equal to size addressed by each L1 entry, we can
* directly store a block desc */
desc = base_addr | BLOCK_DESC | attr;
table[l1_index] = desc;
/* L2 lookup is not required */
return L1_XLAT_SIZE;
}
/* L1 entry stores a table descriptor */
table = get_next_level_table(&table[l1_index], L2_XLAT_SIZE);
/* L2 table lookup */
if ((size >= L2_XLAT_SIZE) &&
IS_ALIGNED(base_addr, (1UL << L2_ADDR_SHIFT))) {
/* If block address is aligned and size is greater than
* or equal to size addressed by each L2 entry, we can
* directly store a block desc */
desc = base_addr | BLOCK_DESC | attr;
table[l2_index] = desc;
/* L3 lookup is not required */
return L2_XLAT_SIZE;
}
/* L2 entry stores a table descriptor */
table = get_next_level_table(&table[l2_index], L3_XLAT_SIZE);
/* L3 table lookup */
desc = base_addr | PAGE_DESC | attr;
table[l3_index] = desc;
return L3_XLAT_SIZE;
}
/* Func : sanity_check
* Desc : Check address/size alignment of a table or page.
*/
static void sanity_check(uint64_t addr, uint64_t size)
{
assert(!(addr & GRANULE_SIZE_MASK) &&
!(size & GRANULE_SIZE_MASK) &&
(addr + size < (1UL << BITS_PER_VA)) &&
size >= GRANULE_SIZE);
}
/* Func : get_pte
* Desc : Returns the page table entry governing a specific address. */
static uint64_t get_pte(void *addr)
{
int shift = L0_ADDR_SHIFT;
uint64_t *pte = (uint64_t *)_ttb;
while (1) {
int index = ((uintptr_t)addr >> shift) &
((1UL << BITS_RESOLVED_PER_LVL) - 1);
if ((pte[index] & DESC_MASK) != TABLE_DESC ||
shift <= GRANULE_SIZE_SHIFT)
return pte[index];
pte = (uint64_t *)(pte[index] & XLAT_ADDR_MASK);
shift -= BITS_RESOLVED_PER_LVL;
}
}
/* Func : assert_correct_ttb_mapping
* Desc : Asserts that mapping for addr matches the access type used by the
* page table walk (i.e. addr is correctly mapped to be part of the TTB). */
static void assert_correct_ttb_mapping(void *addr)
{
uint64_t pte = get_pte(addr);
assert(((pte >> BLOCK_INDEX_SHIFT) & BLOCK_INDEX_MASK)
== BLOCK_INDEX_MEM_NORMAL && !(pte & BLOCK_NS));
}
/* Func : mmu_config_range
* Desc : This function repeatedly calls init_xlat_table with the base
* address. Based on size returned from init_xlat_table, base_addr is updated
* and subsequent calls are made for initializing the xlat table until the whole
* region is initialized.
*/
void mmu_config_range(void *start, size_t size, uint64_t tag)
{
uint64_t base_addr = (uintptr_t)start;
uint64_t temp_size = size;
printk(BIOS_INFO, "Mapping address range [%p:%p) as ",
start, start + size);
print_tag(BIOS_INFO, tag);
sanity_check(base_addr, temp_size);
while (temp_size)
temp_size -= init_xlat_table(base_addr + (size - temp_size),
temp_size, tag);
/* ARMv8 MMUs snoop L1 data cache, no need to flush it. */
dsb();
tlbiall_el3();
dsb();
isb();
}
/* Func : mmu_init
* Desc : Initialize MMU registers and page table memory region. This must be
* called exactly ONCE PER BOOT before trying to configure any mappings.
*/
void mmu_init(void)
{
/* Initially mark all table slots unused (first PTE == UNUSED_DESC). */
uint64_t *table = (uint64_t *)_ttb;
for (; _ettb - (u8 *)table > 0; table += GRANULE_SIZE/sizeof(*table))
table[0] = UNUSED_DESC;
/* Initialize the root table (L0) to be completely unmapped. */
uint64_t *root = setup_new_table(INVALID_DESC, L0_XLAT_SIZE);
assert((u8 *)root == _ttb);
/* Initialize TTBR */
raw_write_ttbr0_el3((uintptr_t)root);
/* Initialize MAIR indices */
raw_write_mair_el3(MAIR_ATTRIBUTES);
/* Initialize TCR flags */
raw_write_tcr_el3(TCR_TOSZ | TCR_IRGN0_NM_WBWAC | TCR_ORGN0_NM_WBWAC |
TCR_SH0_IS | TCR_TG0_4KB | TCR_PS_256TB |
TCR_TBI_USED);
}
/* Func : mmu_save_context
* Desc : Save mmu context (registers and ttbr base).
*/
void mmu_save_context(struct mmu_context *mmu_context)
{
assert(mmu_context);
/* Back-up MAIR_ATTRIBUTES */
mmu_context->mair = raw_read_mair_el3();
/* Back-up TCR value */
mmu_context->tcr = raw_read_tcr_el3();
}
/* Func : mmu_restore_context
* Desc : Restore mmu context using input backed-up context
*/
void mmu_restore_context(const struct mmu_context *mmu_context)
{
assert(mmu_context);
/* Restore TTBR */
raw_write_ttbr0_el3((uintptr_t)_ttb);
/* Restore MAIR indices */
raw_write_mair_el3(mmu_context->mair);
/* Restore TCR flags */
raw_write_tcr_el3(mmu_context->tcr);
/* invalidate tlb since ttbr is updated. */
tlb_invalidate_all();
}
void mmu_enable(void)
{
assert_correct_ttb_mapping(_ttb);
assert_correct_ttb_mapping(_ettb - 1);
uint32_t sctlr = raw_read_sctlr_el3();
sctlr |= SCTLR_C | SCTLR_M | SCTLR_I;
raw_write_sctlr_el3(sctlr);
isb();
}
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