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Factor out translation table setup in ARM FVP port 

This patch factors out the ARM FVP specific code to create MMU
translation tables so that it is possible for a boot loader stage to
create a different set of tables instead of using the default ones.
The default translation tables are created with the assumption that
the calling boot loader stage executes out of secure SRAM. This might
not be true for the BL3_2 stage in the future.

A boot loader stage can define the `fill_xlation_tables()` function as
per its requirements. It returns a reference to the level 1
translation table which is used by the common platform code to setup
the TTBR_EL3.

This patch is a temporary solution before a larger rework of
translation table creation logic is introduced.

Change-Id: I09a075d5da16822ee32a411a9dbe284718fb4ff6
This commit is contained in:
Achin Gupta 2014-02-09 13:30:38 +00:00 committed by Dan Handley
parent 35ca35119d
commit a0cd989dd5
12 changed files with 522 additions and 388 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

1
Makefile
View File

@ -60,6 +60,7 @@ endif
BL_COMMON_OBJS := misc_helpers.o \
cache_helpers.o \
tlb_helpers.o \
xlat_helpers.o \
std.o \
bl_common.o \
platform_helpers.o \

2
bl1/bl1.ld.S
View File

@ -78,7 +78,7 @@ SECTIONS
} >RAM
/*
* The .xlat_table section is for full, aligned page tables (4K).
* The xlat_table section is for full, aligned page tables (4K).
* Removing them from .bss avoids forcing 4K alignment on
* the .bss section and eliminates the unecessary zero init
*/

1
bl1/bl1.mk
View File

@ -33,6 +33,7 @@ vpath %.c plat/${PLAT} \
common \
lib \
arch/${ARCH} \
lib/arch/${ARCH} \
${PLAT_BL1_C_VPATH}
vpath %.S arch/${ARCH}/cpu \

11
bl2/bl2.ld.S
View File

@ -61,7 +61,7 @@ SECTIONS
} >RAM
/*
* The .xlat_table section is for full, aligned page tables (4K).
* The xlat_table section is for full, aligned page tables (4K).
* Removing them from .bss avoids forcing 4K alignment on
* the .bss section and eliminates the unecessary zero init
*/
@ -92,6 +92,15 @@ SECTIONS
__BSS_END__ = .;
} >RAM
/*
* The .xlat_table section is for full, aligned page tables (4K).
* Removing them from .bss avoids forcing 4K alignment on
* the .bss section and eliminates the unecessary zero init
*/
xlat_table (NOLOAD) : {
*(xlat_table)
} >RAM
/*
* The base address of the coherent memory section must be page-aligned (4K)
* to guarantee that the coherent data are stored on their own pages and

11
bl31/bl31.ld.S
View File

@ -69,7 +69,7 @@ SECTIONS
} >RAM
/*
* The .xlat_table section is for full, aligned page tables (4K).
* The xlat_table section is for full, aligned page tables (4K).
* Removing them from .bss avoids forcing 4K alignment on
* the .bss section and eliminates the unecessary zero init
*/
@ -100,6 +100,15 @@ SECTIONS
__BSS_END__ = .;
} >RAM
/*
* The .xlat_table section is for full, aligned page tables (4K).
* Removing them from .bss avoids forcing 4K alignment on
* the .bss section and eliminates the unecessary zero init
*/
xlat_table (NOLOAD) : {
*(xlat_table)
} >RAM
/*
* The base address of the coherent memory section must be page-aligned (4K)
* to guarantee that the coherent data are stored on their own pages and

1
include/aarch64/arch.h
View File

@ -226,6 +226,7 @@
/* Miscellaneous MMU related constants */
#define NUM_2MB_IN_GB (1 << 9)
#define NUM_4K_IN_2MB (1 << 9)
#define NUM_GB_IN_4GB (1 << 2)
#define TWO_MB_SHIFT 21
#define ONE_GB_SHIFT 30

17
include/aarch64/arch_helpers.h
View File

@ -36,6 +36,23 @@
#ifndef __ASSEMBLY__
#include <stdio.h>
/*******************************************************************************
* Aarch64 translation tables manipulation helper prototypes
******************************************************************************/
extern unsigned long create_table_desc(unsigned long *next_table_ptr);
extern unsigned long create_block_desc(unsigned long desc,
unsigned long addr,
unsigned int level);
extern unsigned long create_device_block(unsigned long output_addr,
unsigned int level,
unsigned int ns);
extern unsigned long create_romem_block(unsigned long output_addr,
unsigned int level,
unsigned int ns);
extern unsigned long create_rwmem_block(unsigned long output_addr,
unsigned int level,
unsigned int ns);
/*******************************************************************************
* TLB maintenance accessor prototypes
******************************************************************************/

128
lib/arch/aarch64/xlat_helpers.c Normal file
View File

@ -0,0 +1,128 @@
/*
* Copyright (c) 2013-2014, ARM Limited and Contributors. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 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.
*
* Neither the name of ARM nor the names of its contributors may be used
* to endorse or promote products derived from this software without specific
* prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS 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 COPYRIGHT HOLDER 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 <string.h>
#include <assert.h>
#include <arch.h>
/*******************************************************************************
* Helper to create a level 1/2 table descriptor which points to a level 2/3
* table.
******************************************************************************/
unsigned long create_table_desc(unsigned long *next_table_ptr)
{
unsigned long desc = (unsigned long) next_table_ptr;
/* Clear the last 12 bits */
desc >>= FOUR_KB_SHIFT;
desc <<= FOUR_KB_SHIFT;
desc |= TABLE_DESC;
return desc;
}
/*******************************************************************************
* Helper to create a level 1/2/3 block descriptor which maps the va to addr
******************************************************************************/
unsigned long create_block_desc(unsigned long desc,
unsigned long addr,
unsigned int level)
{
switch (level) {
case LEVEL1:
desc |= (addr << FIRST_LEVEL_DESC_N) | BLOCK_DESC;
break;
case LEVEL2:
desc |= (addr << SECOND_LEVEL_DESC_N) | BLOCK_DESC;
break;
case LEVEL3:
desc |= (addr << THIRD_LEVEL_DESC_N) | TABLE_DESC;
break;
default:
assert(0);
}
return desc;
}
/*******************************************************************************
* Helper to create a level 1/2/3 block descriptor which maps the va to output_
* addr with Device nGnRE attributes.
******************************************************************************/
unsigned long create_device_block(unsigned long output_addr,
unsigned int level,
unsigned int ns)
{
unsigned long upper_attrs, lower_attrs, desc;
lower_attrs = LOWER_ATTRS(ACCESS_FLAG | OSH | AP_RW);
lower_attrs |= LOWER_ATTRS(ns | ATTR_DEVICE_INDEX);
upper_attrs = UPPER_ATTRS(XN);
desc = upper_attrs | lower_attrs;
return create_block_desc(desc, output_addr, level);
}
/*******************************************************************************
* Helper to create a level 1/2/3 block descriptor which maps the va to output_
* addr with inner-shareable normal wbwa read-only memory attributes.
******************************************************************************/
unsigned long create_romem_block(unsigned long output_addr,
unsigned int level,
unsigned int ns)
{
unsigned long upper_attrs, lower_attrs, desc;
lower_attrs = LOWER_ATTRS(ACCESS_FLAG | ISH | AP_RO);
lower_attrs |= LOWER_ATTRS(ns | ATTR_IWBWA_OWBWA_NTR_INDEX);
upper_attrs = UPPER_ATTRS(0ull);
desc = upper_attrs | lower_attrs;
return create_block_desc(desc, output_addr, level);
}
/*******************************************************************************
* Helper to create a level 1/2/3 block descriptor which maps the va to output_
* addr with inner-shareable normal wbwa read-write memory attributes.
******************************************************************************/
unsigned long create_rwmem_block(unsigned long output_addr,
unsigned int level,
unsigned int ns)
{
unsigned long upper_attrs, lower_attrs, desc;
lower_attrs = LOWER_ATTRS(ACCESS_FLAG | ISH | AP_RW);
lower_attrs |= LOWER_ATTRS(ns | ATTR_IWBWA_OWBWA_NTR_INDEX);
upper_attrs = UPPER_ATTRS(XN);
desc = upper_attrs | lower_attrs;
return create_block_desc(desc, output_addr, level);
}

408
plat/fvp/aarch64/plat_common.c
View File

@ -51,385 +51,11 @@ __attribute__ ((aligned(PLATFORM_CACHE_LINE_SIZE),
static unsigned long platform_config[CONFIG_LIMIT];
/*******************************************************************************
* TODO: Check page table alignment to avoid space wastage
******************************************************************************/
/*******************************************************************************
* Level 1 translation tables need 4 entries for the 4GB address space accessib-
* le by the secure firmware. Input address space will be restricted using the
* T0SZ settings in the TCR.
******************************************************************************/
static unsigned long l1_xlation_table[ADDR_SPACE_SIZE >> 30]
__attribute__ ((aligned((ADDR_SPACE_SIZE >> 30) << 3)));
/*******************************************************************************
* Level 2 translation tables describe the first & second gb of the address
* space needed to address secure peripherals e.g. trusted ROM and RAM.
******************************************************************************/
static unsigned long l2_xlation_table[NUM_L2_PAGETABLES][NUM_2MB_IN_GB]
__attribute__ ((aligned(NUM_2MB_IN_GB << 3), section("xlat_table")));
/*******************************************************************************
* Level 3 translation tables (2 sets) describe the trusted & non-trusted RAM
* regions at a granularity of 4K.
******************************************************************************/
static unsigned long l3_xlation_table[NUM_L3_PAGETABLES][NUM_4K_IN_2MB]
__attribute__ ((aligned(NUM_4K_IN_2MB << 3), section("xlat_table")));
/*******************************************************************************
* Helper to create a level 1/2 table descriptor which points to a level 2/3
* table.
******************************************************************************/
static unsigned long create_table_desc(unsigned long *next_table_ptr)
{
unsigned long desc = (unsigned long) next_table_ptr;
/* Clear the last 12 bits */
desc >>= FOUR_KB_SHIFT;
desc <<= FOUR_KB_SHIFT;
desc |= TABLE_DESC;
return desc;
}
/*******************************************************************************
* Helper to create a level 1/2/3 block descriptor which maps the va to addr
******************************************************************************/
static unsigned long create_block_desc(unsigned long desc,
unsigned long addr,
unsigned int level)
{
switch (level) {
case LEVEL1:
desc |= (addr << FIRST_LEVEL_DESC_N) | BLOCK_DESC;
break;
case LEVEL2:
desc |= (addr << SECOND_LEVEL_DESC_N) | BLOCK_DESC;
break;
case LEVEL3:
desc |= (addr << THIRD_LEVEL_DESC_N) | TABLE_DESC;
break;
default:
assert(0);
}
return desc;
}
/*******************************************************************************
* Helper to create a level 1/2/3 block descriptor which maps the va to output_
* addr with Device nGnRE attributes.
******************************************************************************/
static unsigned long create_device_block(unsigned long output_addr,
unsigned int level,
unsigned int ns)
{
unsigned long upper_attrs, lower_attrs, desc;
lower_attrs = LOWER_ATTRS(ACCESS_FLAG | OSH | AP_RW);
lower_attrs |= LOWER_ATTRS(ns | ATTR_DEVICE_INDEX);
upper_attrs = UPPER_ATTRS(XN);
desc = upper_attrs | lower_attrs;
return create_block_desc(desc, output_addr, level);
}
/*******************************************************************************
* Helper to create a level 1/2/3 block descriptor which maps the va to output_
* addr with inner-shareable normal wbwa read-only memory attributes.
******************************************************************************/
static unsigned long create_romem_block(unsigned long output_addr,
unsigned int level,
unsigned int ns)
{
unsigned long upper_attrs, lower_attrs, desc;
lower_attrs = LOWER_ATTRS(ACCESS_FLAG | ISH | AP_RO);
lower_attrs |= LOWER_ATTRS(ns | ATTR_IWBWA_OWBWA_NTR_INDEX);
upper_attrs = UPPER_ATTRS(0ull);
desc = upper_attrs | lower_attrs;
return create_block_desc(desc, output_addr, level);
}
/*******************************************************************************
* Helper to create a level 1/2/3 block descriptor which maps the va to output_
* addr with inner-shareable normal wbwa read-write memory attributes.
******************************************************************************/
static unsigned long create_rwmem_block(unsigned long output_addr,
unsigned int level,
unsigned int ns)
{
unsigned long upper_attrs, lower_attrs, desc;
lower_attrs = LOWER_ATTRS(ACCESS_FLAG | ISH | AP_RW);
lower_attrs |= LOWER_ATTRS(ns | ATTR_IWBWA_OWBWA_NTR_INDEX);
upper_attrs = UPPER_ATTRS(XN);
desc = upper_attrs | lower_attrs;
return create_block_desc(desc, output_addr, level);
}
/*******************************************************************************
* Create page tables as per the platform memory map. Certain aspects of page
* talble creating have been abstracted in the above routines. This can be impr-
* oved further.
* TODO: Move the page table setup helpers into the arch or lib directory
* An internal global pointer of the level 1 translation tables which should not
* change once setup by the primary cpu during a cold boot.
*******************************************************************************/
static unsigned long fill_xlation_tables(meminfo *tzram_layout,
unsigned long ro_start,
unsigned long ro_limit,
unsigned long coh_start,
unsigned long coh_limit)
{
unsigned long l2_desc, l3_desc;
unsigned long *xt_addr = 0, *pt_addr, off = 0;
unsigned long trom_start_index, trom_end_index;
unsigned long tzram_start_index, tzram_end_index;
unsigned long flash0_start_index, flash0_end_index;
unsigned long flash1_start_index, flash1_end_index;
unsigned long vram_start_index, vram_end_index;
unsigned long nsram_start_index, nsram_end_index;
unsigned long tdram_start_index, tdram_end_index;
unsigned long dram_start_index, dram_end_index;
unsigned long dev0_start_index, dev0_end_index;
unsigned long dev1_start_index, dev1_end_index;
unsigned int idx;
/*****************************************************************
* LEVEL1 PAGETABLE SETUP
*
* Find the start and end indices of the memory peripherals in the
* first level pagetables. These are the main areas we care about.
* Also bump the end index by one if its equal to the start to
* allow for regions which lie completely in a GB.
*****************************************************************/
trom_start_index = ONE_GB_INDEX(TZROM_BASE);
dev0_start_index = ONE_GB_INDEX(TZRNG_BASE);
dram_start_index = ONE_GB_INDEX(DRAM_BASE);
dram_end_index = ONE_GB_INDEX(DRAM_BASE + DRAM_SIZE);
if (dram_end_index == dram_start_index)
dram_end_index++;
/*
* Fill up the level1 translation table first
*/
for (idx = 0; idx < (ADDR_SPACE_SIZE >> 30); idx++) {
/*
* Fill up the entry for the TZROM. This will cover
* everything in the first GB.
*/
if (idx == trom_start_index) {
xt_addr = &l2_xlation_table[GB1_L2_PAGETABLE][0];
l1_xlation_table[idx] = create_table_desc(xt_addr);
continue;
}
/*
* Mark the second gb as device
*/
if (idx == dev0_start_index) {
xt_addr = &l2_xlation_table[GB2_L2_PAGETABLE][0];
l1_xlation_table[idx] = create_table_desc(xt_addr);
continue;
}
/*
* Fill up the block entry for the DRAM with Normal
* inner-WBWA outer-WBWA non-transient attributes.
* This will cover 2-4GB. Note that the acesses are
* marked as non-secure.
*/
if ((idx >= dram_start_index) && (idx < dram_end_index)) {
l1_xlation_table[idx] = create_rwmem_block(idx, LEVEL1,
NS);
continue;
}
assert(0);
}
/*****************************************************************
* LEVEL2 PAGETABLE SETUP
*
* Find the start and end indices of the memory & peripherals in the
* second level pagetables.
******************************************************************/
/* Initializations for the 1st GB */
trom_start_index = TWO_MB_INDEX(TZROM_BASE);
trom_end_index = TWO_MB_INDEX(TZROM_BASE + TZROM_SIZE);
if (trom_end_index == trom_start_index)
trom_end_index++;
tdram_start_index = TWO_MB_INDEX(TZDRAM_BASE);
tdram_end_index = TWO_MB_INDEX(TZDRAM_BASE + TZDRAM_SIZE);
if (tdram_end_index == tdram_start_index)
tdram_end_index++;
flash0_start_index = TWO_MB_INDEX(FLASH0_BASE);
flash0_end_index = TWO_MB_INDEX(FLASH0_BASE + TZROM_SIZE);
if (flash0_end_index == flash0_start_index)
flash0_end_index++;
flash1_start_index = TWO_MB_INDEX(FLASH1_BASE);
flash1_end_index = TWO_MB_INDEX(FLASH1_BASE + FLASH1_SIZE);
if (flash1_end_index == flash1_start_index)
flash1_end_index++;
vram_start_index = TWO_MB_INDEX(VRAM_BASE);
vram_end_index = TWO_MB_INDEX(VRAM_BASE + VRAM_SIZE);
if (vram_end_index == vram_start_index)
vram_end_index++;
dev0_start_index = TWO_MB_INDEX(DEVICE0_BASE);
dev0_end_index = TWO_MB_INDEX(DEVICE0_BASE + DEVICE0_SIZE);
if (dev0_end_index == dev0_start_index)
dev0_end_index++;
dev1_start_index = TWO_MB_INDEX(DEVICE1_BASE);
dev1_end_index = TWO_MB_INDEX(DEVICE1_BASE + DEVICE1_SIZE);
if (dev1_end_index == dev1_start_index)
dev1_end_index++;
/* Since the size is < 2M this is a single index */
tzram_start_index = TWO_MB_INDEX(tzram_layout->total_base);
nsram_start_index = TWO_MB_INDEX(NSRAM_BASE);
/*
* Fill up the level2 translation table for the first GB next
*/
for (idx = 0; idx < NUM_2MB_IN_GB; idx++) {
l2_desc = INVALID_DESC;
xt_addr = &l2_xlation_table[GB1_L2_PAGETABLE][idx];
/* Block entries for 64M of trusted Boot ROM */
if ((idx >= trom_start_index) && (idx < trom_end_index))
l2_desc = create_romem_block(idx, LEVEL2, 0);
/* Single L3 page table entry for 256K of TZRAM */
if (idx == tzram_start_index) {
pt_addr = &l3_xlation_table[TZRAM_PAGETABLE][0];
l2_desc = create_table_desc(pt_addr);
}
/* Block entries for 32M of trusted DRAM */
if ((idx >= tdram_start_index) && (idx <= tdram_end_index))
l2_desc = create_rwmem_block(idx, LEVEL2, 0);
/* Block entries for 64M of aliased trusted Boot ROM */
if ((idx >= flash0_start_index) && (idx < flash0_end_index))
l2_desc = create_romem_block(idx, LEVEL2, 0);
/* Block entries for 64M of flash1 */
if ((idx >= flash1_start_index) && (idx < flash1_end_index))
l2_desc = create_romem_block(idx, LEVEL2, 0);
/* Block entries for 32M of VRAM */
if ((idx >= vram_start_index) && (idx < vram_end_index))
l2_desc = create_rwmem_block(idx, LEVEL2, 0);
/* Block entries for all the devices in the first gb */
if ((idx >= dev0_start_index) && (idx < dev0_end_index))
l2_desc = create_device_block(idx, LEVEL2, 0);
/* Block entries for all the devices in the first gb */
if ((idx >= dev1_start_index) && (idx < dev1_end_index))
l2_desc = create_device_block(idx, LEVEL2, 0);
/* Single L3 page table entry for 64K of NSRAM */
if (idx == nsram_start_index) {
pt_addr = &l3_xlation_table[NSRAM_PAGETABLE][0];
l2_desc = create_table_desc(pt_addr);
}
*xt_addr = l2_desc;
}
/*
* Initializations for the 2nd GB. Mark everything as device
* for the time being as the memory map is not final. Each
* index will need to be offset'ed to allow absolute values
*/
off = NUM_2MB_IN_GB;
for (idx = off; idx < (NUM_2MB_IN_GB + off); idx++) {
l2_desc = create_device_block(idx, LEVEL2, 0);
xt_addr = &l2_xlation_table[GB2_L2_PAGETABLE][idx - off];
*xt_addr = l2_desc;
}
/*****************************************************************
* LEVEL3 PAGETABLE SETUP
*****************************************************************/
/* Fill up the level3 pagetable for the trusted SRAM. */
tzram_start_index = FOUR_KB_INDEX(tzram_layout->total_base);
tzram_end_index = FOUR_KB_INDEX(tzram_layout->total_base +
tzram_layout->total_size);
if (tzram_end_index == tzram_start_index)
tzram_end_index++;
/* Reusing trom* to mark RO memory. */
trom_start_index = FOUR_KB_INDEX(ro_start);
trom_end_index = FOUR_KB_INDEX(ro_limit);
if (trom_end_index == trom_start_index)
trom_end_index++;
/* Reusing dev* to mark coherent device memory. */
dev0_start_index = FOUR_KB_INDEX(coh_start);
dev0_end_index = FOUR_KB_INDEX(coh_limit);
if (dev0_end_index == dev0_start_index)
dev0_end_index++;
/* Each index will need to be offset'ed to allow absolute values */
off = FOUR_KB_INDEX(TZRAM_BASE);
for (idx = off; idx < (NUM_4K_IN_2MB + off); idx++) {
l3_desc = INVALID_DESC;
xt_addr = &l3_xlation_table[TZRAM_PAGETABLE][idx - off];
if (idx >= tzram_start_index && idx < tzram_end_index)
l3_desc = create_rwmem_block(idx, LEVEL3, 0);
if (idx >= trom_start_index && idx < trom_end_index)
l3_desc = create_romem_block(idx, LEVEL3, 0);
if (idx >= dev0_start_index && idx < dev0_end_index)
l3_desc = create_device_block(idx, LEVEL3, 0);
*xt_addr = l3_desc;
}
/* Fill up the level3 pagetable for the non-trusted SRAM. */
nsram_start_index = FOUR_KB_INDEX(NSRAM_BASE);
nsram_end_index = FOUR_KB_INDEX(NSRAM_BASE + NSRAM_SIZE);
if (nsram_end_index == nsram_start_index)
nsram_end_index++;
/* Each index will need to be offset'ed to allow absolute values */
off = FOUR_KB_INDEX(NSRAM_BASE);
for (idx = off; idx < (NUM_4K_IN_2MB + off); idx++) {
l3_desc = INVALID_DESC;
xt_addr = &l3_xlation_table[NSRAM_PAGETABLE][idx - off];
if (idx >= nsram_start_index && idx < nsram_end_index)
l3_desc = create_rwmem_block(idx, LEVEL3, NS);
*xt_addr = l3_desc;
}
return (unsigned long) l1_xlation_table;
}
unsigned long l1_xlation_table __aligned(PLATFORM_CACHE_LINE_SIZE)
__attribute__ ((section("tzfw_coherent_mem")));
/*******************************************************************************
* Enable the MMU assuming that the pagetables have already been created
@ -438,6 +64,10 @@ void enable_mmu()
{
unsigned long mair, tcr, ttbr, sctlr;
unsigned long current_el = read_current_el();
#if DEBUG
unsigned int l1_table_desc_bits;
unsigned int l1_table_align;
#endif
/* Set the attributes in the right indices of the MAIR */
mair = MAIR_ATTR_SET(ATTR_DEVICE, ATTR_DEVICE_INDEX);
@ -461,8 +91,16 @@ void enable_mmu()
write_tcr(tcr);
/* Set TTBR bits as well */
assert(((unsigned long)l1_xlation_table & (sizeof(l1_xlation_table) - 1)) == 0);
/* Set TTBR bits. Ensure the alignment for level 1 page table */
#if DEBUG
#define BITS_PER_4K_L3DESC 12
#define BITS_PER_4K_L2DESC (9 + BITS_PER_4K_L3DESC)
#define BITS_PER_4K_L1DESC (9 + BITS_PER_4K_L2DESC)
l1_table_desc_bits = (64 - TCR_T0SZ_4GB - BITS_PER_4K_L1DESC);
l1_table_align = l1_table_desc_bits + 3;
assert(((unsigned long) l1_xlation_table &
((1 << l1_table_align) - 1)) == 0);
#endif
ttbr = (unsigned long) l1_xlation_table;
write_ttbr0(ttbr);
@ -502,11 +140,11 @@ void configure_mmu(meminfo *mem_layout,
assert(IS_PAGE_ALIGNED(coh_start));
assert(IS_PAGE_ALIGNED(coh_limit));
fill_xlation_tables(mem_layout,
ro_start,
ro_limit,
coh_start,
coh_limit);
l1_xlation_table = fill_xlation_tables(mem_layout,
ro_start,
ro_limit,
coh_start,
coh_limit);
enable_mmu();
return;
}

322
plat/fvp/aarch64/plat_setup_xlat.c Normal file
View File

@ -0,0 +1,322 @@
/*
* Copyright (c) 2013-2014, ARM Limited and Contributors. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 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.
*
* Neither the name of ARM nor the names of its contributors may be used
* to endorse or promote products derived from this software without specific
* prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS 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 COPYRIGHT HOLDER 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 <string.h>
#include <assert.h>
#include <arch_helpers.h>
#include <platform.h>
#include <bl_common.h>
/*******************************************************************************
* TODO: Check page table alignment to avoid space wastage
******************************************************************************/
/*******************************************************************************
* Level 1 translation tables need 4 entries for the 4GB address space accessib-
* le by the secure firmware. Input address space will be restricted using the
* T0SZ settings in the TCR.
******************************************************************************/
static unsigned long l1_xlation_table[NUM_GB_IN_4GB]
__attribute__ ((aligned((NUM_GB_IN_4GB) << 3)));
/*******************************************************************************
* Level 2 translation tables describe the first & second gb of the address
* space needed to address secure peripherals e.g. trusted ROM and RAM.
******************************************************************************/
static unsigned long l2_xlation_table[NUM_L2_PAGETABLES][NUM_2MB_IN_GB]
__attribute__ ((aligned(NUM_2MB_IN_GB << 3),
section("xlat_table")));
/*******************************************************************************
* Level 3 translation tables (2 sets) describe the trusted & non-trusted RAM
* regions at a granularity of 4K.
******************************************************************************/
static unsigned long l3_xlation_table[NUM_L3_PAGETABLES][NUM_4K_IN_2MB]
__attribute__ ((aligned(NUM_4K_IN_2MB << 3),
section("xlat_table")));
/*******************************************************************************
* Create page tables as per the platform memory map. Certain aspects of page
* talble creating have been abstracted in the above routines. This can be impr-
* oved further.
* TODO: Move the page table setup helpers into the arch or lib directory
*******************************************************************************/
unsigned long fill_xlation_tables(meminfo *tzram_layout,
unsigned long ro_start,
unsigned long ro_limit,
unsigned long coh_start,
unsigned long coh_limit)
{
unsigned long l2_desc, l3_desc;
unsigned long *xt_addr = 0, *pt_addr, off = 0;
unsigned long trom_start_index, trom_end_index;
unsigned long tzram_start_index, tzram_end_index;
unsigned long flash0_start_index, flash0_end_index;
unsigned long flash1_start_index, flash1_end_index;
unsigned long vram_start_index, vram_end_index;
unsigned long nsram_start_index, nsram_end_index;
unsigned long tdram_start_index, tdram_end_index;
unsigned long dram_start_index, dram_end_index;
unsigned long dev0_start_index, dev0_end_index;
unsigned long dev1_start_index, dev1_end_index;
unsigned int idx;
/*****************************************************************
* LEVEL1 PAGETABLE SETUP
*
* Find the start and end indices of the memory peripherals in the
* first level pagetables. These are the main areas we care about.
* Also bump the end index by one if its equal to the start to
* allow for regions which lie completely in a GB.
*****************************************************************/
trom_start_index = ONE_GB_INDEX(TZROM_BASE);
dev0_start_index = ONE_GB_INDEX(TZRNG_BASE);
dram_start_index = ONE_GB_INDEX(DRAM_BASE);
dram_end_index = ONE_GB_INDEX(DRAM_BASE + DRAM_SIZE);
if (dram_end_index == dram_start_index)
dram_end_index++;
/*
* Fill up the level1 translation table first
*/
for (idx = 0; idx < NUM_GB_IN_4GB; idx++) {
/*
* Fill up the entry for the TZROM. This will cover
* everything in the first GB.
*/
if (idx == trom_start_index) {
xt_addr = &l2_xlation_table[GB1_L2_PAGETABLE][0];
l1_xlation_table[idx] = create_table_desc(xt_addr);
continue;
}
/*
* Mark the second gb as device
*/
if (idx == dev0_start_index) {
xt_addr = &l2_xlation_table[GB2_L2_PAGETABLE][0];
l1_xlation_table[idx] = create_table_desc(xt_addr);
continue;
}
/*
* Fill up the block entry for the DRAM with Normal
* inner-WBWA outer-WBWA non-transient attributes.
* This will cover 2-4GB. Note that the acesses are
* marked as non-secure.
*/
if ((idx >= dram_start_index) && (idx < dram_end_index)) {
l1_xlation_table[idx] = create_rwmem_block(idx, LEVEL1,
NS);
continue;
}
assert(0);
}
/*****************************************************************
* LEVEL2 PAGETABLE SETUP
*
* Find the start and end indices of the memory & peripherals in the
* second level pagetables.
******************************************************************/
/* Initializations for the 1st GB */
trom_start_index = TWO_MB_INDEX(TZROM_BASE);
trom_end_index = TWO_MB_INDEX(TZROM_BASE + TZROM_SIZE);
if (trom_end_index == trom_start_index)
trom_end_index++;
tdram_start_index = TWO_MB_INDEX(TZDRAM_BASE);
tdram_end_index = TWO_MB_INDEX(TZDRAM_BASE + TZDRAM_SIZE);
if (tdram_end_index == tdram_start_index)
tdram_end_index++;
flash0_start_index = TWO_MB_INDEX(FLASH0_BASE);
flash0_end_index = TWO_MB_INDEX(FLASH0_BASE + TZROM_SIZE);
if (flash0_end_index == flash0_start_index)
flash0_end_index++;
flash1_start_index = TWO_MB_INDEX(FLASH1_BASE);
flash1_end_index = TWO_MB_INDEX(FLASH1_BASE + FLASH1_SIZE);
if (flash1_end_index == flash1_start_index)
flash1_end_index++;
vram_start_index = TWO_MB_INDEX(VRAM_BASE);
vram_end_index = TWO_MB_INDEX(VRAM_BASE + VRAM_SIZE);
if (vram_end_index == vram_start_index)
vram_end_index++;
dev0_start_index = TWO_MB_INDEX(DEVICE0_BASE);
dev0_end_index = TWO_MB_INDEX(DEVICE0_BASE + DEVICE0_SIZE);
if (dev0_end_index == dev0_start_index)
dev0_end_index++;
dev1_start_index = TWO_MB_INDEX(DEVICE1_BASE);
dev1_end_index = TWO_MB_INDEX(DEVICE1_BASE + DEVICE1_SIZE);
if (dev1_end_index == dev1_start_index)
dev1_end_index++;
/* Since the size is < 2M this is a single index */
tzram_start_index = TWO_MB_INDEX(tzram_layout->total_base);
nsram_start_index = TWO_MB_INDEX(NSRAM_BASE);
/*
* Fill up the level2 translation table for the first GB next
*/
for (idx = 0; idx < NUM_2MB_IN_GB; idx++) {
l2_desc = INVALID_DESC;
xt_addr = &l2_xlation_table[GB1_L2_PAGETABLE][idx];
/* Block entries for 64M of trusted Boot ROM */
if ((idx >= trom_start_index) && (idx < trom_end_index))
l2_desc = create_romem_block(idx, LEVEL2, 0);
/* Single L3 page table entry for 256K of TZRAM */
if (idx == tzram_start_index) {
pt_addr = &l3_xlation_table[TZRAM_PAGETABLE][0];
l2_desc = create_table_desc(pt_addr);
}
/* Block entries for 32M of trusted DRAM */
if ((idx >= tdram_start_index) && (idx <= tdram_end_index))
l2_desc = create_rwmem_block(idx, LEVEL2, 0);
/* Block entries for 64M of aliased trusted Boot ROM */
if ((idx >= flash0_start_index) && (idx < flash0_end_index))
l2_desc = create_romem_block(idx, LEVEL2, 0);
/* Block entries for 64M of flash1 */
if ((idx >= flash1_start_index) && (idx < flash1_end_index))
l2_desc = create_romem_block(idx, LEVEL2, 0);
/* Block entries for 32M of VRAM */
if ((idx >= vram_start_index) && (idx < vram_end_index))
l2_desc = create_rwmem_block(idx, LEVEL2, 0);
/* Block entries for all the devices in the first gb */
if ((idx >= dev0_start_index) && (idx < dev0_end_index))
l2_desc = create_device_block(idx, LEVEL2, 0);
/* Block entries for all the devices in the first gb */
if ((idx >= dev1_start_index) && (idx < dev1_end_index))
l2_desc = create_device_block(idx, LEVEL2, 0);
/* Single L3 page table entry for 64K of NSRAM */
if (idx == nsram_start_index) {
pt_addr = &l3_xlation_table[NSRAM_PAGETABLE][0];
l2_desc = create_table_desc(pt_addr);
}
*xt_addr = l2_desc;
}
/*
* Initializations for the 2nd GB. Mark everything as device
* for the time being as the memory map is not final. Each
* index will need to be offset'ed to allow absolute values
*/
off = NUM_2MB_IN_GB;
for (idx = off; idx < (NUM_2MB_IN_GB + off); idx++) {
l2_desc = create_device_block(idx, LEVEL2, 0);
xt_addr = &l2_xlation_table[GB2_L2_PAGETABLE][idx - off];
*xt_addr = l2_desc;
}
/*****************************************************************
* LEVEL3 PAGETABLE SETUP
*****************************************************************/
/* Fill up the level3 pagetable for the trusted SRAM. */
tzram_start_index = FOUR_KB_INDEX(tzram_layout->total_base);
tzram_end_index = FOUR_KB_INDEX(tzram_layout->total_base +
tzram_layout->total_size);
if (tzram_end_index == tzram_start_index)
tzram_end_index++;
/* Reusing trom* to mark RO memory. */
trom_start_index = FOUR_KB_INDEX(ro_start);
trom_end_index = FOUR_KB_INDEX(ro_limit);
if (trom_end_index == trom_start_index)
trom_end_index++;
/* Reusing dev* to mark coherent device memory. */
dev0_start_index = FOUR_KB_INDEX(coh_start);
dev0_end_index = FOUR_KB_INDEX(coh_limit);
if (dev0_end_index == dev0_start_index)
dev0_end_index++;
/* Each index will need to be offset'ed to allow absolute values */
off = FOUR_KB_INDEX(TZRAM_BASE);
for (idx = off; idx < (NUM_4K_IN_2MB + off); idx++) {
l3_desc = INVALID_DESC;
xt_addr = &l3_xlation_table[TZRAM_PAGETABLE][idx - off];
if (idx >= tzram_start_index && idx < tzram_end_index)
l3_desc = create_rwmem_block(idx, LEVEL3, 0);
if (idx >= trom_start_index && idx < trom_end_index)
l3_desc = create_romem_block(idx, LEVEL3, 0);
if (idx >= dev0_start_index && idx < dev0_end_index)
l3_desc = create_device_block(idx, LEVEL3, 0);
*xt_addr = l3_desc;
}
/* Fill up the level3 pagetable for the non-trusted SRAM. */
nsram_start_index = FOUR_KB_INDEX(NSRAM_BASE);
nsram_end_index = FOUR_KB_INDEX(NSRAM_BASE + NSRAM_SIZE);
if (nsram_end_index == nsram_start_index)
nsram_end_index++;
/* Each index will need to be offset'ed to allow absolute values */
off = FOUR_KB_INDEX(NSRAM_BASE);
for (idx = off; idx < (NUM_4K_IN_2MB + off); idx++) {
l3_desc = INVALID_DESC;
xt_addr = &l3_xlation_table[NSRAM_PAGETABLE][idx - off];
if (idx >= nsram_start_index && idx < nsram_end_index)
l3_desc = create_rwmem_block(idx, LEVEL3, NS);
*xt_addr = l3_desc;
}
return (unsigned long) l1_xlation_table;
}

5
plat/fvp/platform.h
View File

@ -341,6 +341,11 @@ extern void bl2_plat_arch_setup(void);
extern void bl31_plat_arch_setup(void);
extern int platform_setup_pm(plat_pm_ops **);
extern unsigned int platform_get_core_pos(unsigned long mpidr);
extern unsigned long fill_xlation_tables(meminfo *memory_layout,
unsigned long ro_start,
unsigned long ro_limit,
unsigned long coh_start,
unsigned long coh_limit);
extern void disable_mmu(void);
extern void enable_mmu(void);
extern void configure_mmu(meminfo *,

3
plat/fvp/platform.mk
View File

@ -71,13 +71,16 @@ BL1_OBJS += bl1_plat_setup.o \
bl1_plat_helpers.o \
plat_helpers.o \
plat_common.o \
plat_setup_xlat.o \
cci400.o
BL2_OBJS += bl2_plat_setup.o \
plat_setup_xlat.o \
plat_common.o
BL31_OBJS += bl31_plat_setup.o \
plat_helpers.o \
plat_setup_xlat.o \
plat_common.o \
plat_pm.o \
plat_topology.o \