/* * Copyright (c) 2017-2020, STMicroelectronics - All Rights Reserved * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #include #include #include #include /* * 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]; static const char *shres2str_id_tbl[STM32MP1_SHRES_COUNT] __unused = { [STM32MP1_SHRES_GPIOZ(0)] = "GPIOZ0", [STM32MP1_SHRES_GPIOZ(1)] = "GPIOZ1", [STM32MP1_SHRES_GPIOZ(2)] = "GPIOZ2", [STM32MP1_SHRES_GPIOZ(3)] = "GPIOZ3", [STM32MP1_SHRES_GPIOZ(4)] = "GPIOZ4", [STM32MP1_SHRES_GPIOZ(5)] = "GPIOZ5", [STM32MP1_SHRES_GPIOZ(6)] = "GPIOZ6", [STM32MP1_SHRES_GPIOZ(7)] = "GPIOZ7", [STM32MP1_SHRES_IWDG1] = "IWDG1", [STM32MP1_SHRES_USART1] = "USART1", [STM32MP1_SHRES_SPI6] = "SPI6", [STM32MP1_SHRES_I2C4] = "I2C4", [STM32MP1_SHRES_RNG1] = "RNG1", [STM32MP1_SHRES_HASH1] = "HASH1", [STM32MP1_SHRES_CRYP1] = "CRYP1", [STM32MP1_SHRES_I2C6] = "I2C6", [STM32MP1_SHRES_RTC] = "RTC", [STM32MP1_SHRES_MCU] = "MCU", [STM32MP1_SHRES_MDMA] = "MDMA", [STM32MP1_SHRES_PLL3] = "PLL3", }; static const char __unused *shres2str_id(enum stm32mp_shres id) { assert(id < ARRAY_SIZE(shres2str_id_tbl)); return shres2str_id_tbl[id]; } static const char __unused *shres2str_state_tbl[] = { [SHRES_UNREGISTERED] = "unregistered", [SHRES_NON_SECURE] = "non-secure", [SHRES_SECURE] = "secure", }; static const char __unused *shres2str_state(unsigned int state) { assert(state < ARRAY_SIZE(shres2str_state_tbl)); return shres2str_state_tbl[state]; } /* 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); } static void register_periph(enum stm32mp_shres id, unsigned int state) { assert((id < STM32MP1_SHRES_COUNT) && ((state == SHRES_SECURE) || (state == SHRES_NON_SECURE))); if (registering_locked) { if (shres_state[id] == state) { return; } panic(); } if ((shres_state[id] != SHRES_UNREGISTERED) && (shres_state[id] != state)) { VERBOSE("Cannot change %s from %s to %s\n", shres2str_id(id), shres2str_state(shres_state[id]), shres2str_state(state)); panic(); } if (shres_state[id] == SHRES_UNREGISTERED) { VERBOSE("Register %s as %s\n", shres2str_id(id), shres2str_state(state)); } if ((id >= STM32MP1_SHRES_GPIOZ(0)) && (id <= STM32MP1_SHRES_GPIOZ(7)) && ((id - STM32MP1_SHRES_GPIOZ(0)) >= get_gpioz_nbpin())) { ERROR("Invalid GPIO pin %u, %u pin(s) available\n", id - STM32MP1_SHRES_GPIOZ(0), get_gpioz_nbpin()); panic(); } shres_state[id] = (uint8_t)state; /* Explore clock tree to lock dependencies */ if (state == SHRES_SECURE) { enum stm32mp_shres clock_res_id; switch (id) { case STM32MP1_SHRES_GPIOZ(0): case STM32MP1_SHRES_GPIOZ(1): case STM32MP1_SHRES_GPIOZ(2): case STM32MP1_SHRES_GPIOZ(3): case STM32MP1_SHRES_GPIOZ(4): case STM32MP1_SHRES_GPIOZ(5): case STM32MP1_SHRES_GPIOZ(6): case STM32MP1_SHRES_GPIOZ(7): clock_res_id = GPIOZ; break; case STM32MP1_SHRES_IWDG1: clock_res_id = IWDG1; break; case STM32MP1_SHRES_USART1: clock_res_id = USART1_K; break; case STM32MP1_SHRES_SPI6: clock_res_id = SPI6_K; break; case STM32MP1_SHRES_I2C4: clock_res_id = I2C4_K; break; case STM32MP1_SHRES_RNG1: clock_res_id = RNG1_K; break; case STM32MP1_SHRES_HASH1: clock_res_id = HASH1; break; case STM32MP1_SHRES_CRYP1: clock_res_id = CRYP1; break; case STM32MP1_SHRES_I2C6: clock_res_id = I2C6_K; break; case STM32MP1_SHRES_RTC: clock_res_id = RTC; break; default: /* No clock resource dependency */ return; } stm32mp1_register_clock_parents_secure(clock_res_id); } } /* Register resource by ID */ void stm32mp_register_secure_periph(enum stm32mp_shres id) { register_periph(id, SHRES_SECURE); } void stm32mp_register_non_secure_periph(enum stm32mp_shres id) { register_periph(id, SHRES_NON_SECURE); } static bool stm32mp_gpio_bank_is_non_secure(unsigned int bank) { unsigned int non_secure = 0U; unsigned int i; lock_registering(); if (bank != GPIO_BANK_Z) { return true; } for (i = 0U; i < get_gpioz_nbpin(); i++) { if (periph_is_non_secure(STM32MP1_SHRES_GPIOZ(i))) { non_secure++; } } return non_secure == get_gpioz_nbpin(); } static bool stm32mp_gpio_bank_is_secure(unsigned int bank) { unsigned int secure = 0U; unsigned int i; lock_registering(); if (bank != GPIO_BANK_Z) { return false; } for (i = 0U; i < get_gpioz_nbpin(); i++) { if (periph_is_secure(STM32MP1_SHRES_GPIOZ(i))) { secure++; } } return secure == get_gpioz_nbpin(); } bool stm32mp_nsec_can_access_clock(unsigned long clock_id) { enum stm32mp_shres shres_id = STM32MP1_SHRES_COUNT; switch (clock_id) { case CK_CSI: case CK_HSE: case CK_HSE_DIV2: case CK_HSI: case CK_LSE: case CK_LSI: case PLL1_P: case PLL1_Q: case PLL1_R: case PLL2_P: case PLL2_Q: case PLL2_R: case PLL3_P: case PLL3_Q: case PLL3_R: case RTCAPB: return true; case GPIOZ: /* Allow clock access if at least one pin is non-secure */ return !stm32mp_gpio_bank_is_secure(GPIO_BANK_Z); case CRYP1: shres_id = STM32MP1_SHRES_CRYP1; break; case HASH1: shres_id = STM32MP1_SHRES_HASH1; break; case I2C4_K: shres_id = STM32MP1_SHRES_I2C4; break; case I2C6_K: shres_id = STM32MP1_SHRES_I2C6; break; case IWDG1: shres_id = STM32MP1_SHRES_IWDG1; break; case RNG1_K: shres_id = STM32MP1_SHRES_RNG1; break; case RTC: shres_id = STM32MP1_SHRES_RTC; break; case SPI6_K: shres_id = STM32MP1_SHRES_SPI6; break; case USART1_K: shres_id = STM32MP1_SHRES_USART1; break; default: return false; } return periph_is_non_secure(shres_id); } bool stm32mp_nsec_can_access_reset(unsigned int reset_id) { enum stm32mp_shres shres_id = STM32MP1_SHRES_COUNT; switch (reset_id) { case CRYP1_R: shres_id = STM32MP1_SHRES_CRYP1; break; case GPIOZ_R: /* GPIOZ reset mandates all pins are non-secure */ return stm32mp_gpio_bank_is_non_secure(GPIO_BANK_Z); case HASH1_R: shres_id = STM32MP1_SHRES_HASH1; break; case I2C4_R: shres_id = STM32MP1_SHRES_I2C4; break; case I2C6_R: shres_id = STM32MP1_SHRES_I2C6; break; case MCU_R: shres_id = STM32MP1_SHRES_MCU; break; case MDMA_R: shres_id = STM32MP1_SHRES_MDMA; break; case RNG1_R: shres_id = STM32MP1_SHRES_RNG1; break; case SPI6_R: shres_id = STM32MP1_SHRES_SPI6; break; case USART1_R: shres_id = STM32MP1_SHRES_USART1; break; default: return false; } return periph_is_non_secure(shres_id); } 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 %s secure\n", secure ? "secure" : "non-secure", mckprot ? "set" : "not set", shres2str_id(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 %s is secure\n", shres2str_id(id)); break; case SHRES_NON_SECURE: case SHRES_UNREGISTERED: VERBOSE("stm32mp %s is non-secure\n", shres2str_id(id)); break; default: VERBOSE("stm32mp %s is invalid\n", shres2str_id(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(); }