blob: b82c51078074469a3fe3c175696878c13110d021 [file] [log] [blame]
/*
* Copyright (c) 2015-2018, Renesas Electronics Corporation. All rights reserved.
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include <errno.h>
#include <stdint.h>
#include <string.h>
#include <platform_def.h>
#include <arch_helpers.h>
#include <common/bl_common.h>
#include <common/debug.h>
#include <drivers/auth/auth_mod.h>
#include <drivers/io/io_driver.h>
#include <drivers/io/io_storage.h>
#include <lib/mmio.h>
#include <plat/common/platform.h>
#include <tools_share/firmware_image_package.h>
#include <tools_share/uuid.h>
#include "io_rcar.h"
#include "io_common.h"
#include "io_private.h"
extern int32_t plat_get_drv_source(uint32_t id, uintptr_t *dev,
uintptr_t *image_spec);
static int32_t rcar_dev_open(const uintptr_t dev_spec __attribute__ ((unused)),
io_dev_info_t **dev_info);
static int32_t rcar_dev_close(io_dev_info_t *dev_info);
typedef struct {
const int32_t name;
const uint32_t offset;
const uint32_t attr;
} plat_rcar_name_offset_t;
typedef struct {
/* Put position above the struct to allow {0} on static init.
* It is a workaround for a known bug in GCC
* http://gcc.gnu.org/bugzilla/show_bug.cgi?id=53119
*/
uint32_t position;
uint32_t no_load;
uintptr_t offset;
uint32_t size;
uintptr_t dst;
uintptr_t partition; /* for eMMC */
/* RCAR_EMMC_PARTITION_BOOT_0 */
/* RCAR_EMMC_PARTITION_BOOT_1 */
/* RCAR_EMMC_PARTITION_USER */
} file_state_t;
#define RCAR_GET_FLASH_ADR(a, b) ((uint32_t)((0x40000U * (a)) + (b)))
#define RCAR_ATTR_SET_CALCADDR(a) ((a) & 0xF)
#define RCAR_ATTR_SET_ISNOLOAD(a) (((a) & 0x1) << 16U)
#define RCAR_ATTR_SET_CERTOFF(a) (((a) & 0xF) << 8U)
#define RCAR_ATTR_SET_ALL(a, b, c) ((uint32_t)(RCAR_ATTR_SET_CALCADDR(a) |\
RCAR_ATTR_SET_ISNOLOAD(b) | \
RCAR_ATTR_SET_CERTOFF(c)))
#define RCAR_ATTR_GET_CALCADDR(a) ((a) & 0xFU)
#define RCAR_ATTR_GET_ISNOLOAD(a) (((a) >> 16) & 0x1U)
#define RCAR_ATTR_GET_CERTOFF(a) ((uint32_t)(((a) >> 8) & 0xFU))
#define RCAR_MAX_BL3X_IMAGE (8U)
#define RCAR_SECTOR6_CERT_OFFSET (0x400U)
#define RCAR_SDRAM_certESS (0x43F00000U)
#define RCAR_CERT_SIZE (0x800U)
#define RCAR_CERT_INFO_SIZE_OFFSET (0x264U)
#define RCAR_CERT_INFO_DST_OFFSET (0x154U)
#define RCAR_CERT_INFO_SIZE_OFFSET1 (0x364U)
#define RCAR_CERT_INFO_DST_OFFSET1 (0x1D4U)
#define RCAR_CERT_INFO_SIZE_OFFSET2 (0x464U)
#define RCAR_CERT_INFO_DST_OFFSET2 (0x254U)
#define RCAR_CERT_LOAD (1U)
#define RCAR_FLASH_CERT_HEADER RCAR_GET_FLASH_ADR(6U, 0U)
#define RCAR_EMMC_CERT_HEADER (0x00030000U)
#define RCAR_COUNT_LOAD_BL33 (2U)
#define RCAR_COUNT_LOAD_BL33X (3U)
static const plat_rcar_name_offset_t name_offset[] = {
{BL31_IMAGE_ID, 0U, RCAR_ATTR_SET_ALL(0, 0, 0)},
/* BL3-2 is optional in the platform */
{BL32_IMAGE_ID, 0U, RCAR_ATTR_SET_ALL(1, 0, 1)},
{BL33_IMAGE_ID, 0U, RCAR_ATTR_SET_ALL(2, 0, 2)},
{BL332_IMAGE_ID, 0U, RCAR_ATTR_SET_ALL(3, 0, 3)},
{BL333_IMAGE_ID, 0U, RCAR_ATTR_SET_ALL(4, 0, 4)},
{BL334_IMAGE_ID, 0U, RCAR_ATTR_SET_ALL(5, 0, 5)},
{BL335_IMAGE_ID, 0U, RCAR_ATTR_SET_ALL(6, 0, 6)},
{BL336_IMAGE_ID, 0U, RCAR_ATTR_SET_ALL(7, 0, 7)},
{BL337_IMAGE_ID, 0U, RCAR_ATTR_SET_ALL(8, 0, 8)},
{BL338_IMAGE_ID, 0U, RCAR_ATTR_SET_ALL(9, 0, 9)},
};
#if TRUSTED_BOARD_BOOT
static const plat_rcar_name_offset_t cert_offset[] = {
/* Certificates */
{TRUSTED_KEY_CERT_ID, 0U, RCAR_ATTR_SET_ALL(0, 1, 0)},
{SOC_FW_KEY_CERT_ID, 0U, RCAR_ATTR_SET_ALL(0, 1, 0)},
{TRUSTED_OS_FW_KEY_CERT_ID, 0U, RCAR_ATTR_SET_ALL(0, 1, 0)},
{NON_TRUSTED_FW_KEY_CERT_ID, 0U, RCAR_ATTR_SET_ALL(0, 1, 0)},
{SOC_FW_CONTENT_CERT_ID, 0U, RCAR_ATTR_SET_ALL(0, 1, 0)},
{TRUSTED_OS_FW_CONTENT_CERT_ID, 0U, RCAR_ATTR_SET_ALL(0, 1, 1)},
{NON_TRUSTED_FW_CONTENT_CERT_ID, 0U, RCAR_ATTR_SET_ALL(0, 1, 2)},
{BL332_CERT_ID, 0U, RCAR_ATTR_SET_ALL(0, 1, 3)},
{BL333_CERT_ID, 0U, RCAR_ATTR_SET_ALL(0, 1, 4)},
{BL334_CERT_ID, 0U, RCAR_ATTR_SET_ALL(0, 1, 5)},
{BL335_CERT_ID, 0U, RCAR_ATTR_SET_ALL(0, 1, 6)},
{BL336_CERT_ID, 0U, RCAR_ATTR_SET_ALL(0, 1, 7)},
{BL337_CERT_ID, 0U, RCAR_ATTR_SET_ALL(0, 1, 8)},
{BL338_CERT_ID, 0U, RCAR_ATTR_SET_ALL(0, 1, 9)},
};
#endif /* TRUSTED_BOARD_BOOT */
static file_state_t current_file = { 0 };
static uintptr_t rcar_handle, rcar_spec;
static uint64_t rcar_image_header[RCAR_MAX_BL3X_IMAGE + 2U] = { 0U };
static uint64_t rcar_image_header_prttn[RCAR_MAX_BL3X_IMAGE + 2U] = { 0U };
static uint64_t rcar_image_number = { 0U };
static uint32_t rcar_cert_load = { 0U };
static io_type_t device_type_rcar(void)
{
return IO_TYPE_FIRMWARE_IMAGE_PACKAGE;
}
int32_t rcar_get_certificate(const int32_t name, uint32_t *cert)
{
#if TRUSTED_BOARD_BOOT
int32_t i;
for (i = 0; i < ARRAY_SIZE(cert_offset); i++) {
if (name != cert_offset[i].name)
continue;
*cert = RCAR_CERT_SIZE;
*cert *= RCAR_ATTR_GET_CERTOFF(cert_offset[i].attr);
*cert += RCAR_SDRAM_certESS;
return 0;
}
#endif
return -EINVAL;
}
static int32_t file_to_offset(const int32_t name, uintptr_t *offset,
uint32_t *cert, uint32_t *no_load,
uintptr_t *partition)
{
uint32_t addr;
int32_t i;
for (i = 0; i < ARRAY_SIZE(name_offset); i++) {
if (name != name_offset[i].name)
continue;
addr = RCAR_ATTR_GET_CALCADDR(name_offset[i].attr);
if (rcar_image_number + 2 < addr)
continue;
*offset = rcar_image_header[addr];
*cert = RCAR_CERT_SIZE;
*cert *= RCAR_ATTR_GET_CERTOFF(name_offset[i].attr);
*cert += RCAR_SDRAM_certESS;
*no_load = RCAR_ATTR_GET_ISNOLOAD(name_offset[i].attr);
*partition = rcar_image_header_prttn[addr];
return IO_SUCCESS;
}
#if TRUSTED_BOARD_BOOT
for (i = 0; i < ARRAY_SIZE(cert_offset); i++) {
if (name != cert_offset[i].name)
continue;
*no_load = RCAR_ATTR_GET_ISNOLOAD(cert_offset[i].attr);
*partition = 0U;
*offset = 0U;
*cert = 0U;
return IO_SUCCESS;
}
#endif
return -EINVAL;
}
#define RCAR_BOOT_KEY_CERT_NEW (0xE6300F00U)
#define RCAR_CERT_MAGIC_NUM (0xE291F358U)
void rcar_read_certificate(uint64_t cert, uint32_t *len, uintptr_t *dst)
{
uint32_t seed, val, info_1, info_2;
uintptr_t size, dsth, dstl;
cert &= 0xFFFFFFFFU;
seed = mmio_read_32(RCAR_BOOT_KEY_CERT_NEW);
val = mmio_read_32(RCAR_BOOT_KEY_CERT_NEW + 0xC);
info_1 = (val >> 18) & 0x3U;
val = mmio_read_32(cert + 0xC);
info_2 = (val >> 21) & 0x3;
if (seed == RCAR_CERT_MAGIC_NUM) {
if (info_1 != 1) {
ERROR("BL2: Cert is invalid.\n");
*dst = 0;
*len = 0;
return;
}
if (info_2 > 2) {
ERROR("BL2: Cert is invalid.\n");
*dst = 0;
*len = 0;
return;
}
switch (info_2) {
case 2:
size = cert + RCAR_CERT_INFO_SIZE_OFFSET2;
dstl = cert + RCAR_CERT_INFO_DST_OFFSET2;
break;
case 1:
size = cert + RCAR_CERT_INFO_SIZE_OFFSET1;
dstl = cert + RCAR_CERT_INFO_DST_OFFSET1;
break;
case 0:
size = cert + RCAR_CERT_INFO_SIZE_OFFSET;
dstl = cert + RCAR_CERT_INFO_DST_OFFSET;
break;
}
*len = mmio_read_32(size) * 4U;
dsth = dstl + 4U;
*dst = ((uintptr_t) mmio_read_32(dsth) << 32) +
((uintptr_t) mmio_read_32(dstl));
return;
}
size = cert + RCAR_CERT_INFO_SIZE_OFFSET;
*len = mmio_read_32(size) * 4U;
dstl = cert + RCAR_CERT_INFO_DST_OFFSET;
dsth = dstl + 4U;
*dst = ((uintptr_t) mmio_read_32(dsth) << 32) +
((uintptr_t) mmio_read_32(dstl));
}
static int32_t check_load_area(uintptr_t dst, uintptr_t len)
{
uint32_t legacy = dst + len <= UINT32_MAX - 1 ? 1 : 0;
uintptr_t dram_start, dram_end;
uintptr_t prot_start, prot_end;
int32_t result = IO_SUCCESS;
dram_start = legacy ? DRAM1_BASE : DRAM_40BIT_BASE;
dram_end = legacy ? DRAM1_BASE + DRAM1_SIZE :
DRAM_40BIT_BASE + DRAM_40BIT_SIZE;
prot_start = legacy ? DRAM_PROTECTED_BASE : DRAM_40BIT_PROTECTED_BASE;
prot_end = prot_start + DRAM_PROTECTED_SIZE;
if (dst < dram_start || dst > dram_end - len) {
ERROR("BL2: dst address is on the protected area.\n");
result = IO_FAIL;
goto done;
}
/* load image is within SDRAM protected area */
if (dst >= prot_start && dst < prot_end) {
ERROR("BL2: dst address is on the protected area.\n");
result = IO_FAIL;
}
if (dst < prot_start && dst > prot_start - len) {
ERROR("BL2: loaded data is on the protected area.\n");
result = IO_FAIL;
}
done:
if (result == IO_FAIL)
ERROR("BL2: Out of range : dst=0x%lx len=0x%lx\n", dst, len);
return result;
}
static int32_t load_bl33x(void)
{
static int32_t loaded = IO_NOT_SUPPORTED;
uintptr_t dst, partition, handle;
uint32_t noload, cert, len, i;
uintptr_t offset;
int32_t rc;
size_t cnt;
const int32_t img[] = {
BL33_IMAGE_ID,
BL332_IMAGE_ID,
BL333_IMAGE_ID,
BL334_IMAGE_ID,
BL335_IMAGE_ID,
BL336_IMAGE_ID,
BL337_IMAGE_ID,
BL338_IMAGE_ID
};
if (loaded != IO_NOT_SUPPORTED)
return loaded;
for (i = 1; i < rcar_image_number; i++) {
rc = file_to_offset(img[i], &offset, &cert, &noload,
&partition);
if (rc != IO_SUCCESS) {
WARN("load_bl33x: failed to get offset\n");
loaded = IO_FAIL;
return loaded;
}
rcar_read_certificate((uint64_t) cert, &len, &dst);
((io_drv_spec_t *) rcar_spec)->partition = partition;
rc = io_open(rcar_handle, rcar_spec, &handle);
if (rc != IO_SUCCESS) {
WARN("Failed to open FIP (%i)\n", rc);
loaded = IO_FAIL;
return loaded;
}
rc = io_seek(handle, IO_SEEK_SET, offset);
if (rc != IO_SUCCESS) {
WARN("load_bl33x: failed to seek\n");
loaded = IO_FAIL;
return loaded;
}
rc = check_load_area(dst, len);
if (rc != IO_SUCCESS) {
WARN("load_bl33x: check load area\n");
loaded = IO_FAIL;
return loaded;
}
rc = io_read(handle, dst, len, &cnt);
if (rc != IO_SUCCESS) {
WARN("load_bl33x: failed to read\n");
loaded = IO_FAIL;
return loaded;
}
#if TRUSTED_BOARD_BOOT
rc = auth_mod_verify_img(img[i], (void *)dst, len);
if (rc) {
memset((void *)dst, 0x00, len);
loaded = IO_FAIL;
return loaded;
}
#endif
io_close(handle);
}
loaded = IO_SUCCESS;
return loaded;
}
static int32_t rcar_dev_init(io_dev_info_t *dev_info, const uintptr_t name)
{
uint64_t header[64] __aligned(FLASH_TRANS_SIZE_UNIT) = {
0};
uintptr_t handle;
ssize_t offset;
uint32_t i;
int32_t rc;
size_t cnt;
/* Obtain a reference to the image by querying the platform layer */
rc = plat_get_drv_source(name, &rcar_handle, &rcar_spec);
if (rc != IO_SUCCESS) {
WARN("Failed to obtain reference to img %ld (%i)\n", name, rc);
return IO_FAIL;
}
if (RCAR_CERT_LOAD == rcar_cert_load)
return IO_SUCCESS;
rc = io_open(rcar_handle, rcar_spec, &handle);
if (rc != IO_SUCCESS) {
WARN("Failed to access img %ld (%i)\n", name, rc);
return IO_FAIL;
}
/* get start address list */
/* [0] address num */
/* [1] BL33-1 image address */
/* [2] BL33-2 image address */
/* [3] BL33-3 image address */
/* [4] BL33-4 image address */
/* [5] BL33-5 image address */
/* [6] BL33-6 image address */
/* [7] BL33-7 image address */
/* [8] BL33-8 image address */
offset = name == EMMC_DEV_ID ? RCAR_EMMC_CERT_HEADER :
RCAR_FLASH_CERT_HEADER;
rc = io_seek(handle, IO_SEEK_SET, offset);
if (rc != IO_SUCCESS) {
WARN("Firmware Image Package header failed to seek\n");
goto error;
}
#if RCAR_BL2_DCACHE == 1
inv_dcache_range((uint64_t) header, sizeof(header));
#endif
rc = io_read(handle, (uintptr_t) &header, sizeof(header), &cnt);
if (rc != IO_SUCCESS) {
WARN("Firmware Image Package header failed to read\n");
goto error;
}
rcar_image_number = header[0];
for (i = 0; i < rcar_image_number + 2; i++) {
rcar_image_header[i] = header[i * 2 + 1];
rcar_image_header_prttn[i] = header[i * 2 + 2];
}
if (rcar_image_number == 0 || rcar_image_number > RCAR_MAX_BL3X_IMAGE) {
WARN("Firmware Image Package header check failed.\n");
goto error;
}
rc = io_seek(handle, IO_SEEK_SET, offset + RCAR_SECTOR6_CERT_OFFSET);
if (rc != IO_SUCCESS) {
WARN("Firmware Image Package header failed to seek cert\n");
goto error;
}
#if RCAR_BL2_DCACHE == 1
inv_dcache_range(RCAR_SDRAM_certESS,
RCAR_CERT_SIZE * (2 + rcar_image_number));
#endif
rc = io_read(handle, RCAR_SDRAM_certESS,
RCAR_CERT_SIZE * (2 + rcar_image_number), &cnt);
if (rc != IO_SUCCESS) {
WARN("cert file read error.\n");
goto error;
}
rcar_cert_load = RCAR_CERT_LOAD;
error:
if (rc != IO_SUCCESS)
rc = IO_FAIL;
io_close(handle);
return rc;
}
static int32_t rcar_file_open(io_dev_info_t *info, const uintptr_t file_spec,
io_entity_t *entity)
{
const io_drv_spec_t *spec = (io_drv_spec_t *) file_spec;
uintptr_t partition, offset, dst;
uint32_t noload, cert, len;
int32_t rc;
/* Only one file open at a time. We need to track state (ie, file
* cursor position). Since the header lives at * offset zero, this entry
* should never be zero in an active file.
* Once the system supports dynamic memory allocation we will allow more
* than one open file at a time. */
if (current_file.offset != 0U) {
WARN("rcar_file_open : Only one open file at a time.\n");
return IO_RESOURCES_EXHAUSTED;
}
rc = file_to_offset(spec->offset, &offset, &cert, &noload, &partition);
if (rc != IO_SUCCESS) {
WARN("Failed to open file name %ld (%i)\n", spec->offset, rc);
return IO_FAIL;
}
if (noload) {
current_file.offset = 1;
current_file.dst = 0;
current_file.size = 1;
current_file.position = 0;
current_file.no_load = noload;
current_file.partition = 0;
entity->info = (uintptr_t) &current_file;
return IO_SUCCESS;
}
rcar_read_certificate((uint64_t) cert, &len, &dst);
/*----------------*
* Baylibre: HACK *
*----------------*/
if (BL31_IMAGE_ID == spec->offset && len < RCAR_TRUSTED_SRAM_SIZE) {
WARN("r-car ignoring the BL31 size from certificate,"
"using RCAR_TRUSTED_SRAM_SIZE instead\n");
len = RCAR_TRUSTED_SRAM_SIZE;
}
current_file.partition = partition;
current_file.no_load = noload;
current_file.offset = offset;
current_file.position = 0;
current_file.size = len;
current_file.dst = dst;
entity->info = (uintptr_t) &current_file;
return IO_SUCCESS;
}
static int32_t rcar_file_len(io_entity_t *entity, size_t *length)
{
*length = ((file_state_t *) entity->info)->size;
NOTICE("%s: len: 0x%08lx\n", __func__, *length);
return IO_SUCCESS;
}
static int32_t rcar_file_read(io_entity_t *entity, uintptr_t buffer,
size_t length, size_t *cnt)
{
file_state_t *fp = (file_state_t *) entity->info;
ssize_t offset = fp->offset + fp->position;
uintptr_t handle;
int32_t rc;
#ifdef SPD_NONE
static uint32_t load_bl33x_counter = 1;
#else
static uint32_t load_bl33x_counter;
#endif
if (current_file.no_load) {
*cnt = length;
return IO_SUCCESS;
}
((io_drv_spec_t *) rcar_spec)->partition = fp->partition;
rc = io_open(rcar_handle, rcar_spec, &handle);
if (rc != IO_SUCCESS) {
WARN("Failed to open FIP (%i)\n", rc);
return IO_FAIL;
}
rc = io_seek(handle, IO_SEEK_SET, offset);
if (rc != IO_SUCCESS) {
WARN("rcar_file_read: failed to seek\n");
goto error;
}
if (load_bl33x_counter == RCAR_COUNT_LOAD_BL33) {
rc = check_load_area(buffer, length);
if (rc != IO_SUCCESS) {
WARN("rcar_file_read: load area err\n");
goto error;
}
}
rc = io_read(handle, buffer, length, cnt);
if (rc != IO_SUCCESS) {
WARN("Failed to read payload (%i)\n", rc);
goto error;
}
fp->position += *cnt;
io_close(handle);
load_bl33x_counter += 1;
if (load_bl33x_counter == RCAR_COUNT_LOAD_BL33X)
return load_bl33x();
return IO_SUCCESS;
error:
io_close(handle);
return IO_FAIL;
}
static int32_t rcar_file_close(io_entity_t *entity)
{
if (current_file.offset)
memset(&current_file, 0, sizeof(current_file));
entity->info = 0U;
return IO_SUCCESS;
}
static const io_dev_funcs_t rcar_dev_funcs = {
.type = &device_type_rcar,
.open = &rcar_file_open,
.seek = NULL,
.size = &rcar_file_len,
.read = &rcar_file_read,
.write = NULL,
.close = &rcar_file_close,
.dev_init = &rcar_dev_init,
.dev_close = &rcar_dev_close,
};
static const io_dev_info_t rcar_dev_info = {
.funcs = &rcar_dev_funcs,
.info = (uintptr_t) 0
};
static const io_dev_connector_t rcar_dev_connector = {
.dev_open = &rcar_dev_open
};
static int32_t rcar_dev_open(const uintptr_t dev_spec __attribute__ ((unused)),
io_dev_info_t **dev_info)
{
*dev_info = (io_dev_info_t *) &rcar_dev_info;
return IO_SUCCESS;
}
static int32_t rcar_dev_close(io_dev_info_t *dev_info)
{
rcar_handle = 0;
rcar_spec = 0;
return IO_SUCCESS;
}
int32_t rcar_register_io_dev(const io_dev_connector_t **dev_con)
{
int32_t result;
result = io_register_device(&rcar_dev_info);
if (result == IO_SUCCESS)
*dev_con = &rcar_dev_connector;
return result;
}