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git01.mediatek.com / filogic / atf / 7a4a34f2711dbc5174e1aaa2b5d6f465c0a4c21d / . / plat / st / stm32mp1 / stm32mp1_shared_resources.c
blob: 268aa52c351c6a5ad1d52edc886a80f1312ac54b [file] [log] [blame]
/*
* Copyright (c) 2017-2020, STMicroelectronics - All Rights Reserved
*
* SPDX-License-Identifier: BSD-3-Clause
*/
#include <assert.h>
#include <stdint.h>
#include <platform_def.h>
#include <common/debug.h>
#include <drivers/st/etzpc.h>
#include <drivers/st/stm32_gpio.h>
#include <stm32mp_shared_resources.h>
/*
* Once one starts to get the resource registering state, one cannot register
* new resources. This ensures resource state cannot change.
*/
static bool registering_locked;
/*
* Shared peripherals and resources registration
*
* Each resource assignation is stored in a table. The state defaults
* to PERIPH_UNREGISTERED if the resource is not explicitly assigned.
*
* Resource driver that as not embedded (a.k.a their related CFG_xxx build
* directive is disabled) are assigned to the non-secure world.
*
* Each pin of the GPIOZ bank can be secure or non-secure.
*
* It is the platform responsibility the ensure resource assignation
* matches the access permission firewalls configuration.
*/
enum shres_state {
SHRES_UNREGISTERED = 0,
SHRES_SECURE,
SHRES_NON_SECURE,
};
/* Force uint8_t array for array of enum shres_state for size considerations */
static uint8_t shres_state[STM32MP1_SHRES_COUNT];
/* Get resource state: these accesses lock the registering support */
static void lock_registering(void)
{
registering_locked = true;
}
static bool periph_is_non_secure(enum stm32mp_shres id)
{
lock_registering();
return (shres_state[id] == SHRES_NON_SECURE) ||
(shres_state[id] == SHRES_UNREGISTERED);
}
static bool periph_is_secure(enum stm32mp_shres id)
{
return !periph_is_non_secure(id);
}
/* GPIOZ pin count is saved in RAM to prevent parsing FDT several times */
static int8_t gpioz_nbpin = -1;
static unsigned int get_gpio_nbpin(unsigned int bank)
{
if (bank != GPIO_BANK_Z) {
int count = fdt_get_gpio_bank_pin_count(bank);
assert((count >= 0) || (count <= (GPIO_PIN_MAX + 1)));
return (unsigned int)count;
}
if (gpioz_nbpin < 0) {
int count = fdt_get_gpio_bank_pin_count(GPIO_BANK_Z);
assert((count == 0) || (count == STM32MP_GPIOZ_PIN_MAX_COUNT));
gpioz_nbpin = count;
}
return (unsigned int)gpioz_nbpin;
}
static unsigned int get_gpioz_nbpin(void)
{
return get_gpio_nbpin(GPIO_BANK_Z);
}
/* Currently allow full access by non-secure to platform clock services */
bool stm32mp_nsec_can_access_clock(unsigned long clock_id)
{
return true;
}
/* Currently allow full access by non-secure to platform reset services */
bool stm32mp_nsec_can_access_reset(unsigned int reset_id)
{
return true;
}
static bool mckprot_protects_periph(enum stm32mp_shres id)
{
switch (id) {
case STM32MP1_SHRES_MCU:
case STM32MP1_SHRES_PLL3:
return true;
default:
return false;
}
}
/* ETZPC configuration at drivers initialization completion */
static enum etzpc_decprot_attributes shres2decprot_attr(enum stm32mp_shres id)
{
assert((id < STM32MP1_SHRES_GPIOZ(0)) ||
(id > STM32MP1_SHRES_GPIOZ(7)));
if (periph_is_non_secure(id)) {
return ETZPC_DECPROT_NS_RW;
}
return ETZPC_DECPROT_S_RW;
}
static void set_etzpc_secure_configuration(void)
{
/* Some system peripherals shall be secure */
etzpc_configure_decprot(STM32MP1_ETZPC_STGENC_ID, ETZPC_DECPROT_S_RW);
etzpc_configure_decprot(STM32MP1_ETZPC_BKPSRAM_ID, ETZPC_DECPROT_S_RW);
etzpc_configure_decprot(STM32MP1_ETZPC_DDRCTRL_ID,
ETZPC_DECPROT_NS_R_S_W);
etzpc_configure_decprot(STM32MP1_ETZPC_DDRPHYC_ID,
ETZPC_DECPROT_NS_R_S_W);
/* Configure ETZPC with peripheral registering */
etzpc_configure_decprot(STM32MP1_ETZPC_CRYP1_ID,
shres2decprot_attr(STM32MP1_SHRES_CRYP1));
etzpc_configure_decprot(STM32MP1_ETZPC_HASH1_ID,
shres2decprot_attr(STM32MP1_SHRES_HASH1));
etzpc_configure_decprot(STM32MP1_ETZPC_I2C4_ID,
shres2decprot_attr(STM32MP1_SHRES_I2C4));
etzpc_configure_decprot(STM32MP1_ETZPC_I2C6_ID,
shres2decprot_attr(STM32MP1_SHRES_I2C6));
etzpc_configure_decprot(STM32MP1_ETZPC_IWDG1_ID,
shres2decprot_attr(STM32MP1_SHRES_IWDG1));
etzpc_configure_decprot(STM32MP1_ETZPC_RNG1_ID,
shres2decprot_attr(STM32MP1_SHRES_RNG1));
etzpc_configure_decprot(STM32MP1_ETZPC_USART1_ID,
shres2decprot_attr(STM32MP1_SHRES_USART1));
etzpc_configure_decprot(STM32MP1_ETZPC_SPI6_ID,
shres2decprot_attr(STM32MP1_SHRES_SPI6));
}
static void check_rcc_secure_configuration(void)
{
uint32_t n;
uint32_t error = 0U;
bool mckprot = stm32mp1_rcc_is_mckprot();
bool secure = stm32mp1_rcc_is_secure();
for (n = 0U; n < ARRAY_SIZE(shres_state); n++) {
if (shres_state[n] != SHRES_SECURE) {
continue;
}
if (!secure || (mckprot_protects_periph(n) && (!mckprot))) {
ERROR("RCC %s MCKPROT %s and %u secure\n",
secure ? "secure" : "non-secure",
mckprot ? "set" : "not set",
n);
error++;
}
}
if (error != 0U) {
panic();
}
}
static void set_gpio_secure_configuration(void)
{
uint32_t pin;
for (pin = 0U; pin < get_gpioz_nbpin(); pin++) {
bool secure_state = periph_is_secure(STM32MP1_SHRES_GPIOZ(pin));
set_gpio_secure_cfg(GPIO_BANK_Z, pin, secure_state);
}
}
static void print_shared_resources_state(void)
{
unsigned int id;
for (id = 0U; id < STM32MP1_SHRES_COUNT; id++) {
switch (shres_state[id]) {
case SHRES_SECURE:
INFO("stm32mp1 %u is secure\n", id);
break;
case SHRES_NON_SECURE:
case SHRES_UNREGISTERED:
VERBOSE("stm32mp %u is non-secure\n", id);
break;
default:
VERBOSE("stm32mp %u is invalid\n", id);
panic();
}
}
}
void stm32mp_lock_periph_registering(void)
{
registering_locked = true;
print_shared_resources_state();
check_rcc_secure_configuration();
set_etzpc_secure_configuration();
set_gpio_secure_configuration();
}