boot/zephyr/main.c - mirror/mcuboot - TrustedFirmware Git Browser

 /*
  * Copyright (c) 2012-2014 Wind River Systems, Inc.
  * Copyright (c) 2020 Arm Limited
  * Copyright (c) 2021-2023 Nordic Semiconductor ASA
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *     http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include <assert.h>
 #include <zephyr/kernel.h>
 #include <zephyr/devicetree.h>
 #include <zephyr/drivers/gpio.h>
 #include <zephyr/sys/__assert.h>
 #include <zephyr/drivers/flash.h>
 #include <zephyr/drivers/timer/system_timer.h>
 #include <zephyr/usb/usb_device.h>
 #include <soc.h>
 #include <zephyr/linker/linker-defs.h>

 #if defined(CONFIG_CPU_AARCH32_CORTEX_A) || defined(CONFIG_CPU_AARCH32_CORTEX_R)
 #include <zephyr/arch/arm/aarch32/cortex_a_r/cmsis.h>
 #elif defined(CONFIG_CPU_CORTEX_M)
 #include <zephyr/arch/arm/aarch32/cortex_m/cmsis.h>
 #endif

 #include "target.h"

 #include "bootutil/bootutil_log.h"
 #include "bootutil/image.h"
 #include "bootutil/bootutil.h"
 #include "bootutil/fault_injection_hardening.h"
 #include "bootutil/mcuboot_status.h"
 #include "flash_map_backend/flash_map_backend.h"

 /* Check if Espressif target is supported */
 #ifdef CONFIG_SOC_FAMILY_ESP32

 #include <bootloader_init.h>
 #include <esp_loader.h>

 #define IMAGE_INDEX_0   0
 #define IMAGE_INDEX_1   1

 #define PRIMARY_SLOT    0
 #define SECONDARY_SLOT  1

 #define IMAGE0_PRIMARY_START_ADDRESS \
           DT_PROP_BY_IDX(DT_NODE_BY_FIXED_PARTITION_LABEL(image_0), reg, 0)
 #define IMAGE0_PRIMARY_SIZE \
           DT_PROP_BY_IDX(DT_NODE_BY_FIXED_PARTITION_LABEL(image_0), reg, 1)

 #define IMAGE1_PRIMARY_START_ADDRESS \
           DT_PROP_BY_IDX(DT_NODE_BY_FIXED_PARTITION_LABEL(image_1), reg, 0)
 #define IMAGE1_PRIMARY_SIZE \
           DT_PROP_BY_IDX(DT_NODE_BY_FIXED_PARTITION_LABEL(image_1), reg, 1)

 #endif /* CONFIG_SOC_FAMILY_ESP32 */

 #ifdef CONFIG_MCUBOOT_SERIAL
 #include "boot_serial/boot_serial.h"
 #include "serial_adapter/serial_adapter.h"

 const struct boot_uart_funcs boot_funcs = {
     .read = console_read,
     .write = console_write
 };
 #endif

 #ifdef CONFIG_BOOT_SERIAL_BOOT_MODE
 #include <zephyr/retention/bootmode.h>
 #endif

 #if defined(CONFIG_BOOT_USB_DFU_WAIT) || defined(CONFIG_BOOT_USB_DFU_GPIO)
 #include <zephyr/usb/class/usb_dfu.h>
 #endif

 #if CONFIG_MCUBOOT_CLEANUP_ARM_CORE
 #include <arm_cleanup.h>
 #endif

 #ifdef CONFIG_BOOT_SERIAL_PIN_RESET
 #include <zephyr/drivers/hwinfo.h>
 #endif

 /* CONFIG_LOG_MINIMAL is the legacy Kconfig property,
  * replaced by CONFIG_LOG_MODE_MINIMAL.
  */
 #if (defined(CONFIG_LOG_MODE_MINIMAL) || defined(CONFIG_LOG_MINIMAL))
 #define ZEPHYR_LOG_MODE_MINIMAL 1
 #endif

 /* CONFIG_LOG_IMMEDIATE is the legacy Kconfig property,
  * replaced by CONFIG_LOG_MODE_IMMEDIATE.
  */
 #if (defined(CONFIG_LOG_MODE_IMMEDIATE) || defined(CONFIG_LOG_IMMEDIATE))
 #define ZEPHYR_LOG_MODE_IMMEDIATE 1
 #endif

 #if defined(CONFIG_LOG) && !defined(ZEPHYR_LOG_MODE_IMMEDIATE) && \
     !defined(ZEPHYR_LOG_MODE_MINIMAL)
 #ifdef CONFIG_LOG_PROCESS_THREAD
 #warning "The log internal thread for log processing can't transfer the log"\
          "well for MCUBoot."
 #else
 #include <zephyr/logging/log_ctrl.h>

 #define BOOT_LOG_PROCESSING_INTERVAL K_MSEC(30) /* [ms] */

 /* log are processing in custom routine */
 K_THREAD_STACK_DEFINE(boot_log_stack, CONFIG_MCUBOOT_LOG_THREAD_STACK_SIZE);
 struct k_thread boot_log_thread;
 volatile bool boot_log_stop = false;
 K_SEM_DEFINE(boot_log_sem, 1, 1);

 /* log processing need to be initalized by the application */
 #define ZEPHYR_BOOT_LOG_START() zephyr_boot_log_start()
 #define ZEPHYR_BOOT_LOG_STOP() zephyr_boot_log_stop()
 #endif /* CONFIG_LOG_PROCESS_THREAD */
 #else
 /* synchronous log mode doesn't need to be initalized by the application */
 #define ZEPHYR_BOOT_LOG_START() do { } while (false)
 #define ZEPHYR_BOOT_LOG_STOP() do { } while (false)
 #endif /* defined(CONFIG_LOG) && !defined(ZEPHYR_LOG_MODE_IMMEDIATE) && \
         * !defined(ZEPHYR_LOG_MODE_MINIMAL)
 	*/

 #ifdef CONFIG_SOC_FAMILY_NRF
 #include <helpers/nrfx_reset_reason.h>

 static inline bool boot_skip_serial_recovery()
 {
     uint32_t rr = nrfx_reset_reason_get();

     return !(rr == 0 || (rr & NRFX_RESET_REASON_RESETPIN_MASK));
 }
 #else
 static inline bool boot_skip_serial_recovery()
 {
     return false;
 }
 #endif

 BOOT_LOG_MODULE_REGISTER(mcuboot);

 /* Validate serial recovery configuration */
 #ifdef CONFIG_MCUBOOT_SERIAL
 #if !defined(CONFIG_BOOT_SERIAL_ENTRANCE_GPIO) && \
     !defined(CONFIG_BOOT_SERIAL_WAIT_FOR_DFU) && \
     !defined(CONFIG_BOOT_SERIAL_BOOT_MODE) && \
     !defined(CONFIG_BOOT_SERIAL_NO_APPLICATION) && \
     !defined(CONFIG_BOOT_SERIAL_PIN_RESET)
 #error "Serial recovery selected without an entrance mode set"
 #endif
 #endif

 #ifdef CONFIG_MCUBOOT_INDICATION_LED

 /*
  * The led0 devicetree alias is optional. If present, we'll use it
  * to turn on the LED whenever the button is pressed.
  */
 #if DT_NODE_EXISTS(DT_ALIAS(mcuboot_led0))
 #define LED0_NODE DT_ALIAS(mcuboot_led0)
 #elif DT_NODE_EXISTS(DT_ALIAS(bootloader_led0))
 #warning "bootloader-led0 alias is deprecated; use mcuboot-led0 instead"
 #define LED0_NODE DT_ALIAS(bootloader_led0)
 #endif

 #if DT_NODE_HAS_STATUS(LED0_NODE, okay) && DT_NODE_HAS_PROP(LED0_NODE, gpios)
 static const struct gpio_dt_spec led0 = GPIO_DT_SPEC_GET(LED0_NODE, gpios);
 #else
 /* A build error here means your board isn't set up to drive an LED. */
 #error "Unsupported board: led0 devicetree alias is not defined"
 #endif

 void led_init(void)
 {
     if (!device_is_ready(led0.port)) {
         BOOT_LOG_ERR("Didn't find LED device referred by the LED0_NODE\n");
         return;
     }

     gpio_pin_configure_dt(&led0, GPIO_OUTPUT);
     gpio_pin_set_dt(&led0, 0);
 }
 #endif /* CONFIG_MCUBOOT_INDICATION_LED */

 void os_heap_init(void);

 #if defined(CONFIG_ARM)

 #ifdef CONFIG_SW_VECTOR_RELAY
 extern void *_vector_table_pointer;
 #endif

 struct arm_vector_table {
     uint32_t msp;
     uint32_t reset;
 };

 static void do_boot(struct boot_rsp *rsp)
 {
     struct arm_vector_table *vt;

     /* The beginning of the image is the ARM vector table, containing
      * the initial stack pointer address and the reset vector
      * consecutively. Manually set the stack pointer and jump into the
      * reset vector
      */
 #ifdef CONFIG_BOOT_RAM_LOAD
     /* Get ram address for image */
     vt = (struct arm_vector_table *)(rsp->br_hdr->ih_load_addr + rsp->br_hdr->ih_hdr_size);
 #else
     uintptr_t flash_base;
     int rc;

     /* Jump to flash image */
     rc = flash_device_base(rsp->br_flash_dev_id, &flash_base);
     assert(rc == 0);

     vt = (struct arm_vector_table *)(flash_base +
                                      rsp->br_image_off +
                                      rsp->br_hdr->ih_hdr_size);
 #endif

     if (IS_ENABLED(CONFIG_SYSTEM_TIMER_HAS_DISABLE_SUPPORT)) {
         sys_clock_disable();
     }

 #ifdef CONFIG_USB_DEVICE_STACK
     /* Disable the USB to prevent it from firing interrupts */
     usb_disable();
 #endif
 #if CONFIG_MCUBOOT_CLEANUP_ARM_CORE
     cleanup_arm_nvic(); /* cleanup NVIC registers */

 #ifdef CONFIG_CPU_CORTEX_M_HAS_CACHE
     /* Disable instruction cache and data cache before chain-load the application */
     SCB_DisableDCache();
     SCB_DisableICache();
 #endif

 #if CONFIG_CPU_HAS_ARM_MPU || CONFIG_CPU_HAS_NXP_MPU
     z_arm_clear_arm_mpu_config();
 #endif

 #if defined(CONFIG_BUILTIN_STACK_GUARD) && \
     defined(CONFIG_CPU_CORTEX_M_HAS_SPLIM)
     /* Reset limit registers to avoid inflicting stack overflow on image
      * being booted.
      */
     __set_PSPLIM(0);
     __set_MSPLIM(0);
 #endif

 #else
     irq_lock();
 #endif /* CONFIG_MCUBOOT_CLEANUP_ARM_CORE */

 #ifdef CONFIG_BOOT_INTR_VEC_RELOC
 #if defined(CONFIG_SW_VECTOR_RELAY)
     _vector_table_pointer = vt;
 #ifdef CONFIG_CPU_CORTEX_M_HAS_VTOR
     SCB->VTOR = (uint32_t)__vector_relay_table;
 #endif
 #elif defined(CONFIG_CPU_CORTEX_M_HAS_VTOR)
     SCB->VTOR = (uint32_t)vt;
 #endif /* CONFIG_SW_VECTOR_RELAY */
 #else /* CONFIG_BOOT_INTR_VEC_RELOC */
 #if defined(CONFIG_CPU_CORTEX_M_HAS_VTOR) && defined(CONFIG_SW_VECTOR_RELAY)
     _vector_table_pointer = _vector_start;
     SCB->VTOR = (uint32_t)__vector_relay_table;
 #endif
 #endif /* CONFIG_BOOT_INTR_VEC_RELOC */

     __set_MSP(vt->msp);
 #if CONFIG_MCUBOOT_CLEANUP_ARM_CORE
     __set_CONTROL(0x00); /* application will configures core on its own */
     __ISB();
 #endif
     ((void (*)(void))vt->reset)();
 }

 #elif defined(CONFIG_XTENSA) || defined(CONFIG_RISCV)

 #ifndef CONFIG_SOC_FAMILY_ESP32

 #define SRAM_BASE_ADDRESS	0xBE030000

 static void copy_img_to_SRAM(int slot, unsigned int hdr_offset)
 {
     const struct flash_area *fap;
     int area_id;
     int rc;
     unsigned char *dst = (unsigned char *)(SRAM_BASE_ADDRESS + hdr_offset);

     BOOT_LOG_INF("Copying image to SRAM");

     area_id = flash_area_id_from_image_slot(slot);
     rc = flash_area_open(area_id, &fap);
     if (rc != 0) {
         BOOT_LOG_ERR("flash_area_open failed with %d\n", rc);
         goto done;
     }

     rc = flash_area_read(fap, hdr_offset, dst, fap->fa_size - hdr_offset);
     if (rc != 0) {
         BOOT_LOG_ERR("flash_area_read failed with %d\n", rc);
         goto done;
     }

 done:
     flash_area_close(fap);
 }
 #endif /* !CONFIG_SOC_FAMILY_ESP32 */

 /* Entry point (.ResetVector) is at the very beginning of the image.
  * Simply copy the image to a suitable location and jump there.
  */
 static void do_boot(struct boot_rsp *rsp)
 {
     void *start;

     BOOT_LOG_INF("br_image_off = 0x%x\n", rsp->br_image_off);
     BOOT_LOG_INF("ih_hdr_size = 0x%x\n", rsp->br_hdr->ih_hdr_size);

 #ifdef CONFIG_SOC_FAMILY_ESP32
     int slot = (rsp->br_image_off == IMAGE0_PRIMARY_START_ADDRESS) ?
                 PRIMARY_SLOT : SECONDARY_SLOT;
     /* Load memory segments and start from entry point */
     start_cpu0_image(IMAGE_INDEX_0, slot, rsp->br_hdr->ih_hdr_size);
 #else
     /* Copy from the flash to HP SRAM */
     copy_img_to_SRAM(0, rsp->br_hdr->ih_hdr_size);

     /* Jump to entry point */
     start = (void *)(SRAM_BASE_ADDRESS + rsp->br_hdr->ih_hdr_size);
     ((void (*)(void))start)();
 #endif /* CONFIG_SOC_FAMILY_ESP32 */
 }

 #else
 /* Default: Assume entry point is at the very beginning of the image. Simply
  * lock interrupts and jump there. This is the right thing to do for X86 and
  * possibly other platforms.
  */
 static void do_boot(struct boot_rsp *rsp)
 {
     void *start;

 #if defined(MCUBOOT_RAM_LOAD)
     start = (void *)(rsp->br_hdr->ih_load_addr + rsp->br_hdr->ih_hdr_size);
 #else
     uintptr_t flash_base;
     int rc;

     rc = flash_device_base(rsp->br_flash_dev_id, &flash_base);
     assert(rc == 0);

     start = (void *)(flash_base + rsp->br_image_off +
                      rsp->br_hdr->ih_hdr_size);
 #endif

     /* Lock interrupts and dive into the entry point */
     irq_lock();
     ((void (*)(void))start)();
 }
 #endif

 #if defined(CONFIG_LOG) && !defined(ZEPHYR_LOG_MODE_IMMEDIATE) && \
     !defined(CONFIG_LOG_PROCESS_THREAD) && !defined(ZEPHYR_LOG_MODE_MINIMAL)
 /* The log internal thread for log processing can't transfer log well as has too
  * low priority.
  * Dedicated thread for log processing below uses highest application
  * priority. This allows to transmit all logs without adding k_sleep/k_yield
  * anywhere else int the code.
  */

 /* most simple log processing theread */
 void boot_log_thread_func(void *dummy1, void *dummy2, void *dummy3)
 {
     (void)dummy1;
     (void)dummy2;
     (void)dummy3;

     log_init();

     while (1) {
 #if defined(CONFIG_LOG1) || defined(CONFIG_LOG2)
         /* support Zephyr legacy logging implementation before commit c5f2cde */
         if (log_process(false) == false) {
 #else
         if (log_process() == false) {
 #endif
             if (boot_log_stop) {
                 break;
             }
             k_sleep(BOOT_LOG_PROCESSING_INTERVAL);
         }
     }

     k_sem_give(&boot_log_sem);
 }

 void zephyr_boot_log_start(void)
 {
     /* start logging thread */
     k_thread_create(&boot_log_thread, boot_log_stack,
                     K_THREAD_STACK_SIZEOF(boot_log_stack),
                     boot_log_thread_func, NULL, NULL, NULL,
                     K_HIGHEST_APPLICATION_THREAD_PRIO, 0,
                     BOOT_LOG_PROCESSING_INTERVAL);

     k_thread_name_set(&boot_log_thread, "logging");
 }

 void zephyr_boot_log_stop(void)
 {
     boot_log_stop = true;

     /* wait until log procesing thread expired
      * This can be reworked using a thread_join() API once a such will be
      * available in zephyr.
      * see https://github.com/zephyrproject-rtos/zephyr/issues/21500
      */
     (void)k_sem_take(&boot_log_sem, K_FOREVER);
 }
 #endif /* defined(CONFIG_LOG) && !defined(ZEPHYR_LOG_MODE_IMMEDIATE) && \
         * !defined(CONFIG_LOG_PROCESS_THREAD) && !defined(ZEPHYR_LOG_MODE_MINIMAL)
         */

 #if defined(CONFIG_BOOT_SERIAL_ENTRANCE_GPIO) || defined(CONFIG_BOOT_USB_DFU_GPIO)

 #ifdef CONFIG_MCUBOOT_SERIAL
 #define BUTTON_0_DETECT_DELAY CONFIG_BOOT_SERIAL_DETECT_DELAY
 #else
 #define BUTTON_0_DETECT_DELAY CONFIG_BOOT_USB_DFU_DETECT_DELAY
 #endif

 #define BUTTON_0_NODE DT_ALIAS(mcuboot_button0)

 #if DT_NODE_EXISTS(BUTTON_0_NODE) && DT_NODE_HAS_PROP(BUTTON_0_NODE, gpios)
 static const struct gpio_dt_spec button0 = GPIO_DT_SPEC_GET(BUTTON_0_NODE, gpios);
 #else
 #error "Serial recovery/USB DFU button must be declared in device tree as 'mcuboot_button0'"
 #endif

 static bool detect_pin(void)
 {
     int rc;
     int pin_active;

     if (!device_is_ready(button0.port)) {
         __ASSERT(false, "GPIO device is not ready.\n");
         return false;
     }

     rc = gpio_pin_configure_dt(&button0, GPIO_INPUT);
     __ASSERT(rc == 0, "Failed to initialize boot detect pin.\n");

     rc = gpio_pin_get_dt(&button0);
     pin_active = rc;

     __ASSERT(rc >= 0, "Failed to read boot detect pin.\n");

     if (pin_active) {
         if (BUTTON_0_DETECT_DELAY > 0) {
 #ifdef CONFIG_MULTITHREADING
             k_sleep(K_MSEC(50));
 #else
             k_busy_wait(50000);
 #endif

             /* Get the uptime for debounce purposes. */
             int64_t timestamp = k_uptime_get();

             for(;;) {
                 rc = gpio_pin_get_dt(&button0);
                 pin_active = rc;
                 __ASSERT(rc >= 0, "Failed to read boot detect pin.\n");

                 /* Get delta from when this started */
                 uint32_t delta = k_uptime_get() -  timestamp;

                 /* If not pressed OR if pressed > debounce period, stop. */
                 if (delta >= BUTTON_0_DETECT_DELAY || !pin_active) {
                     break;
                 }

                 /* Delay 1 ms */
 #ifdef CONFIG_MULTITHREADING
                 k_sleep(K_MSEC(1));
 #else
                 k_busy_wait(1000);
 #endif
             }
         }
     }

     return (bool)pin_active;
 }
 #endif

 #ifdef CONFIG_MCUBOOT_SERIAL
 static void boot_serial_enter()
 {
     int rc;

 #ifdef CONFIG_MCUBOOT_INDICATION_LED
     gpio_pin_set_dt(&led0, 1);
 #endif

     mcuboot_status_change(MCUBOOT_STATUS_SERIAL_DFU_ENTERED);

     BOOT_LOG_INF("Enter the serial recovery mode");
     rc = boot_console_init();
     __ASSERT(rc == 0, "Error initializing boot console.\n");
     boot_serial_start(&boot_funcs);
     __ASSERT(0, "Bootloader serial process was terminated unexpectedly.\n");
 }
 #endif

 int main(void)
 {
     struct boot_rsp rsp;
     int rc;
     FIH_DECLARE(fih_rc, FIH_FAILURE);

 #ifdef CONFIG_BOOT_SERIAL_BOOT_MODE
     int32_t boot_mode;
 #endif

 #ifdef CONFIG_BOOT_SERIAL_PIN_RESET
     uint32_t reset_cause;
 #endif

     MCUBOOT_WATCHDOG_SETUP();
     MCUBOOT_WATCHDOG_FEED();

 #if !defined(MCUBOOT_DIRECT_XIP)
     BOOT_LOG_INF("Starting bootloader");
 #else
     BOOT_LOG_INF("Starting Direct-XIP bootloader");
 #endif

 #ifdef CONFIG_MCUBOOT_INDICATION_LED
     /* LED init */
     led_init();
 #endif

     os_heap_init();

     ZEPHYR_BOOT_LOG_START();

     (void)rc;

     mcuboot_status_change(MCUBOOT_STATUS_STARTUP);

 #ifdef CONFIG_BOOT_SERIAL_ENTRANCE_GPIO
     if (detect_pin() &&
             !boot_skip_serial_recovery()) {
         boot_serial_enter();
     }
 #endif

 #ifdef CONFIG_BOOT_SERIAL_PIN_RESET
     rc = hwinfo_get_reset_cause(&reset_cause);

     if (rc == 0 && reset_cause == RESET_PIN) {
         (void)hwinfo_clear_reset_cause();
         boot_serial_enter();
     }
 #endif

 #if defined(CONFIG_BOOT_USB_DFU_GPIO)
     if (detect_pin()) {
 #ifdef CONFIG_MCUBOOT_INDICATION_LED
         gpio_pin_set_dt(&led0, 1);
 #endif

         mcuboot_status_change(MCUBOOT_STATUS_USB_DFU_ENTERED);

         rc = usb_enable(NULL);
         if (rc) {
             BOOT_LOG_ERR("Cannot enable USB");
         } else {
             BOOT_LOG_INF("Waiting for USB DFU");
             wait_for_usb_dfu(K_FOREVER);
             BOOT_LOG_INF("USB DFU wait time elapsed");
         }
     }
 #elif defined(CONFIG_BOOT_USB_DFU_WAIT)
     rc = usb_enable(NULL);
     if (rc) {
         BOOT_LOG_ERR("Cannot enable USB");
     } else {
         BOOT_LOG_INF("Waiting for USB DFU");

         mcuboot_status_change(MCUBOOT_STATUS_USB_DFU_WAITING);

         wait_for_usb_dfu(K_MSEC(CONFIG_BOOT_USB_DFU_WAIT_DELAY_MS));
         BOOT_LOG_INF("USB DFU wait time elapsed");

         mcuboot_status_change(MCUBOOT_STATUS_USB_DFU_TIMED_OUT);
     }
 #endif

 #ifdef CONFIG_BOOT_SERIAL_WAIT_FOR_DFU
     /* Initialize the boot console, so we can already fill up our buffers while
      * waiting for the boot image check to finish. This image check, can take
      * some time, so it's better to reuse thistime to already receive the
      * initial mcumgr command(s) into our buffers
      */
     rc = boot_console_init();
     int timeout_in_ms = CONFIG_BOOT_SERIAL_WAIT_FOR_DFU_TIMEOUT;
     uint32_t start = k_uptime_get_32();
 #endif

     FIH_CALL(boot_go, fih_rc, &rsp);

 #ifdef CONFIG_BOOT_SERIAL_BOOT_MODE
     boot_mode = bootmode_check(BOOT_MODE_TYPE_BOOTLOADER);

     if (boot_mode == 1) {
         /* Boot mode to stay in bootloader, clear status and enter serial
          * recovery mode
          */
         bootmode_clear();
         boot_serial_enter();
     }
 #endif

 #ifdef CONFIG_BOOT_SERIAL_WAIT_FOR_DFU
     timeout_in_ms -= (k_uptime_get_32() - start);
     if( timeout_in_ms <= 0 ) {
         /* at least one check if time was expired */
         timeout_in_ms = 1;
     }
     boot_serial_check_start(&boot_funcs,timeout_in_ms);
 #endif

     if (FIH_NOT_EQ(fih_rc, FIH_SUCCESS)) {
         BOOT_LOG_ERR("Unable to find bootable image");

         mcuboot_status_change(MCUBOOT_STATUS_NO_BOOTABLE_IMAGE_FOUND);

 #ifdef CONFIG_BOOT_SERIAL_NO_APPLICATION
         /* No bootable image and configuration set to remain in serial
          * recovery mode
          */
         boot_serial_enter();
 #endif

         FIH_PANIC;
     }

     BOOT_LOG_INF("Bootloader chainload address offset: 0x%x",
                  rsp.br_image_off);

 #if defined(MCUBOOT_DIRECT_XIP)
     BOOT_LOG_INF("Jumping to the image slot");
 #else
     BOOT_LOG_INF("Jumping to the first image slot");
 #endif

     mcuboot_status_change(MCUBOOT_STATUS_BOOTABLE_IMAGE_FOUND);

     ZEPHYR_BOOT_LOG_STOP();
     do_boot(&rsp);

     mcuboot_status_change(MCUBOOT_STATUS_BOOT_FAILED);

     BOOT_LOG_ERR("Never should get here");
     while (1)
         ;
 }
	/*
	* Copyright (c) 2012-2014 Wind River Systems, Inc.
	* Copyright (c) 2020 Arm Limited
	* Copyright (c) 2021-2023 Nordic Semiconductor ASA
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include <assert.h>
	#include <zephyr/kernel.h>
	#include <zephyr/devicetree.h>
	#include <zephyr/drivers/gpio.h>
	#include <zephyr/sys/__assert.h>
	#include <zephyr/drivers/flash.h>
	#include <zephyr/drivers/timer/system_timer.h>
	#include <zephyr/usb/usb_device.h>
	#include <soc.h>
	#include <zephyr/linker/linker-defs.h>

	#if defined(CONFIG_CPU_AARCH32_CORTEX_A) \|\| defined(CONFIG_CPU_AARCH32_CORTEX_R)
	#include <zephyr/arch/arm/aarch32/cortex_a_r/cmsis.h>
	#elif defined(CONFIG_CPU_CORTEX_M)
	#include <zephyr/arch/arm/aarch32/cortex_m/cmsis.h>
	#endif

	#include "target.h"

	#include "bootutil/bootutil_log.h"
	#include "bootutil/image.h"
	#include "bootutil/bootutil.h"
	#include "bootutil/fault_injection_hardening.h"
	#include "bootutil/mcuboot_status.h"
	#include "flash_map_backend/flash_map_backend.h"

	/* Check if Espressif target is supported */
	#ifdef CONFIG_SOC_FAMILY_ESP32

	#include <bootloader_init.h>
	#include <esp_loader.h>

	#define IMAGE_INDEX_0 0
	#define IMAGE_INDEX_1 1

	#define PRIMARY_SLOT 0
	#define SECONDARY_SLOT 1

	#define IMAGE0_PRIMARY_START_ADDRESS \
	DT_PROP_BY_IDX(DT_NODE_BY_FIXED_PARTITION_LABEL(image_0), reg, 0)
	#define IMAGE0_PRIMARY_SIZE \
	DT_PROP_BY_IDX(DT_NODE_BY_FIXED_PARTITION_LABEL(image_0), reg, 1)

	#define IMAGE1_PRIMARY_START_ADDRESS \
	DT_PROP_BY_IDX(DT_NODE_BY_FIXED_PARTITION_LABEL(image_1), reg, 0)
	#define IMAGE1_PRIMARY_SIZE \
	DT_PROP_BY_IDX(DT_NODE_BY_FIXED_PARTITION_LABEL(image_1), reg, 1)

	#endif /* CONFIG_SOC_FAMILY_ESP32 */

	#ifdef CONFIG_MCUBOOT_SERIAL
	#include "boot_serial/boot_serial.h"
	#include "serial_adapter/serial_adapter.h"

	const struct boot_uart_funcs boot_funcs = {
	.read = console_read,
	.write = console_write
	};
	#endif

	#ifdef CONFIG_BOOT_SERIAL_BOOT_MODE
	#include <zephyr/retention/bootmode.h>
	#endif

	#if defined(CONFIG_BOOT_USB_DFU_WAIT) \|\| defined(CONFIG_BOOT_USB_DFU_GPIO)
	#include <zephyr/usb/class/usb_dfu.h>
	#endif

	#if CONFIG_MCUBOOT_CLEANUP_ARM_CORE
	#include <arm_cleanup.h>
	#endif

	#ifdef CONFIG_BOOT_SERIAL_PIN_RESET
	#include <zephyr/drivers/hwinfo.h>
	#endif

	/* CONFIG_LOG_MINIMAL is the legacy Kconfig property,
	* replaced by CONFIG_LOG_MODE_MINIMAL.
	*/
	#if (defined(CONFIG_LOG_MODE_MINIMAL) \|\| defined(CONFIG_LOG_MINIMAL))
	#define ZEPHYR_LOG_MODE_MINIMAL 1
	#endif

	/* CONFIG_LOG_IMMEDIATE is the legacy Kconfig property,
	* replaced by CONFIG_LOG_MODE_IMMEDIATE.
	*/
	#if (defined(CONFIG_LOG_MODE_IMMEDIATE) \|\| defined(CONFIG_LOG_IMMEDIATE))
	#define ZEPHYR_LOG_MODE_IMMEDIATE 1
	#endif

	#if defined(CONFIG_LOG) && !defined(ZEPHYR_LOG_MODE_IMMEDIATE) && \
	!defined(ZEPHYR_LOG_MODE_MINIMAL)
	#ifdef CONFIG_LOG_PROCESS_THREAD
	#warning "The log internal thread for log processing can't transfer the log"\
	"well for MCUBoot."
	#else
	#include <zephyr/logging/log_ctrl.h>

	#define BOOT_LOG_PROCESSING_INTERVAL K_MSEC(30) /* [ms] */

	/* log are processing in custom routine */
	K_THREAD_STACK_DEFINE(boot_log_stack, CONFIG_MCUBOOT_LOG_THREAD_STACK_SIZE);
	struct k_thread boot_log_thread;
	volatile bool boot_log_stop = false;
	K_SEM_DEFINE(boot_log_sem, 1, 1);

	/* log processing need to be initalized by the application */
	#define ZEPHYR_BOOT_LOG_START() zephyr_boot_log_start()
	#define ZEPHYR_BOOT_LOG_STOP() zephyr_boot_log_stop()
	#endif /* CONFIG_LOG_PROCESS_THREAD */
	#else
	/* synchronous log mode doesn't need to be initalized by the application */
	#define ZEPHYR_BOOT_LOG_START() do { } while (false)
	#define ZEPHYR_BOOT_LOG_STOP() do { } while (false)
	#endif /* defined(CONFIG_LOG) && !defined(ZEPHYR_LOG_MODE_IMMEDIATE) && \
	* !defined(ZEPHYR_LOG_MODE_MINIMAL)
	*/

	#ifdef CONFIG_SOC_FAMILY_NRF
	#include <helpers/nrfx_reset_reason.h>

	static inline bool boot_skip_serial_recovery()
	{
	uint32_t rr = nrfx_reset_reason_get();

	return !(rr == 0 \|\| (rr & NRFX_RESET_REASON_RESETPIN_MASK));
	}
	#else
	static inline bool boot_skip_serial_recovery()
	{
	return false;
	}
	#endif

	BOOT_LOG_MODULE_REGISTER(mcuboot);

	/* Validate serial recovery configuration */
	#ifdef CONFIG_MCUBOOT_SERIAL
	#if !defined(CONFIG_BOOT_SERIAL_ENTRANCE_GPIO) && \
	!defined(CONFIG_BOOT_SERIAL_WAIT_FOR_DFU) && \
	!defined(CONFIG_BOOT_SERIAL_BOOT_MODE) && \
	!defined(CONFIG_BOOT_SERIAL_NO_APPLICATION) && \
	!defined(CONFIG_BOOT_SERIAL_PIN_RESET)
	#error "Serial recovery selected without an entrance mode set"
	#endif
	#endif

	#ifdef CONFIG_MCUBOOT_INDICATION_LED

	/*
	* The led0 devicetree alias is optional. If present, we'll use it
	* to turn on the LED whenever the button is pressed.
	*/
	#if DT_NODE_EXISTS(DT_ALIAS(mcuboot_led0))
	#define LED0_NODE DT_ALIAS(mcuboot_led0)
	#elif DT_NODE_EXISTS(DT_ALIAS(bootloader_led0))
	#warning "bootloader-led0 alias is deprecated; use mcuboot-led0 instead"
	#define LED0_NODE DT_ALIAS(bootloader_led0)
	#endif

	#if DT_NODE_HAS_STATUS(LED0_NODE, okay) && DT_NODE_HAS_PROP(LED0_NODE, gpios)
	static const struct gpio_dt_spec led0 = GPIO_DT_SPEC_GET(LED0_NODE, gpios);
	#else
	/* A build error here means your board isn't set up to drive an LED. */
	#error "Unsupported board: led0 devicetree alias is not defined"
	#endif

	void led_init(void)
	{
	if (!device_is_ready(led0.port)) {
	BOOT_LOG_ERR("Didn't find LED device referred by the LED0_NODE\n");
	return;
	}

	gpio_pin_configure_dt(&led0, GPIO_OUTPUT);
	gpio_pin_set_dt(&led0, 0);
	}
	#endif /* CONFIG_MCUBOOT_INDICATION_LED */

	void os_heap_init(void);

	#if defined(CONFIG_ARM)

	#ifdef CONFIG_SW_VECTOR_RELAY
	extern void *_vector_table_pointer;
	#endif

	struct arm_vector_table {
	uint32_t msp;
	uint32_t reset;
	};

	static void do_boot(struct boot_rsp *rsp)
	{
	struct arm_vector_table *vt;

	/* The beginning of the image is the ARM vector table, containing
	* the initial stack pointer address and the reset vector
	* consecutively. Manually set the stack pointer and jump into the
	* reset vector
	*/
	#ifdef CONFIG_BOOT_RAM_LOAD
	/* Get ram address for image */
	vt = (struct arm_vector_table *)(rsp->br_hdr->ih_load_addr + rsp->br_hdr->ih_hdr_size);
	#else
	uintptr_t flash_base;
	int rc;

	/* Jump to flash image */
	rc = flash_device_base(rsp->br_flash_dev_id, &flash_base);
	assert(rc == 0);

	vt = (struct arm_vector_table *)(flash_base +
	rsp->br_image_off +
	rsp->br_hdr->ih_hdr_size);
	#endif

	if (IS_ENABLED(CONFIG_SYSTEM_TIMER_HAS_DISABLE_SUPPORT)) {
	sys_clock_disable();
	}

	#ifdef CONFIG_USB_DEVICE_STACK
	/* Disable the USB to prevent it from firing interrupts */
	usb_disable();
	#endif
	#if CONFIG_MCUBOOT_CLEANUP_ARM_CORE
	cleanup_arm_nvic(); /* cleanup NVIC registers */

	#ifdef CONFIG_CPU_CORTEX_M_HAS_CACHE
	/* Disable instruction cache and data cache before chain-load the application */
	SCB_DisableDCache();
	SCB_DisableICache();
	#endif

	#if CONFIG_CPU_HAS_ARM_MPU \|\| CONFIG_CPU_HAS_NXP_MPU
	z_arm_clear_arm_mpu_config();
	#endif

	#if defined(CONFIG_BUILTIN_STACK_GUARD) && \
	defined(CONFIG_CPU_CORTEX_M_HAS_SPLIM)
	/* Reset limit registers to avoid inflicting stack overflow on image
	* being booted.
	*/
	__set_PSPLIM(0);
	__set_MSPLIM(0);
	#endif

	#else
	irq_lock();
	#endif /* CONFIG_MCUBOOT_CLEANUP_ARM_CORE */

	#ifdef CONFIG_BOOT_INTR_VEC_RELOC
	#if defined(CONFIG_SW_VECTOR_RELAY)
	_vector_table_pointer = vt;
	#ifdef CONFIG_CPU_CORTEX_M_HAS_VTOR
	SCB->VTOR = (uint32_t)__vector_relay_table;
	#endif
	#elif defined(CONFIG_CPU_CORTEX_M_HAS_VTOR)
	SCB->VTOR = (uint32_t)vt;
	#endif /* CONFIG_SW_VECTOR_RELAY */
	#else /* CONFIG_BOOT_INTR_VEC_RELOC */
	#if defined(CONFIG_CPU_CORTEX_M_HAS_VTOR) && defined(CONFIG_SW_VECTOR_RELAY)
	_vector_table_pointer = _vector_start;
	SCB->VTOR = (uint32_t)__vector_relay_table;
	#endif
	#endif /* CONFIG_BOOT_INTR_VEC_RELOC */

	__set_MSP(vt->msp);
	#if CONFIG_MCUBOOT_CLEANUP_ARM_CORE
	__set_CONTROL(0x00); /* application will configures core on its own */
	__ISB();
	#endif
	((void (*)(void))vt->reset)();
	}

	#elif defined(CONFIG_XTENSA) \|\| defined(CONFIG_RISCV)

	#ifndef CONFIG_SOC_FAMILY_ESP32

	#define SRAM_BASE_ADDRESS 0xBE030000

	static void copy_img_to_SRAM(int slot, unsigned int hdr_offset)
	{
	const struct flash_area *fap;
	int area_id;
	int rc;
	unsigned char dst = (unsigned char )(SRAM_BASE_ADDRESS + hdr_offset);

	BOOT_LOG_INF("Copying image to SRAM");

	area_id = flash_area_id_from_image_slot(slot);
	rc = flash_area_open(area_id, &fap);
	if (rc != 0) {
	BOOT_LOG_ERR("flash_area_open failed with %d\n", rc);
	goto done;
	}

	rc = flash_area_read(fap, hdr_offset, dst, fap->fa_size - hdr_offset);
	if (rc != 0) {
	BOOT_LOG_ERR("flash_area_read failed with %d\n", rc);
	goto done;
	}

	done:
	flash_area_close(fap);
	}
	#endif /* !CONFIG_SOC_FAMILY_ESP32 */

	/* Entry point (.ResetVector) is at the very beginning of the image.
	* Simply copy the image to a suitable location and jump there.
	*/
	static void do_boot(struct boot_rsp *rsp)
	{
	void *start;

	BOOT_LOG_INF("br_image_off = 0x%x\n", rsp->br_image_off);
	BOOT_LOG_INF("ih_hdr_size = 0x%x\n", rsp->br_hdr->ih_hdr_size);

	#ifdef CONFIG_SOC_FAMILY_ESP32
	int slot = (rsp->br_image_off == IMAGE0_PRIMARY_START_ADDRESS) ?
	PRIMARY_SLOT : SECONDARY_SLOT;
	/* Load memory segments and start from entry point */
	start_cpu0_image(IMAGE_INDEX_0, slot, rsp->br_hdr->ih_hdr_size);
	#else
	/* Copy from the flash to HP SRAM */
	copy_img_to_SRAM(0, rsp->br_hdr->ih_hdr_size);

	/* Jump to entry point */
	start = (void *)(SRAM_BASE_ADDRESS + rsp->br_hdr->ih_hdr_size);
	((void (*)(void))start)();
	#endif /* CONFIG_SOC_FAMILY_ESP32 */
	}

	#else
	/* Default: Assume entry point is at the very beginning of the image. Simply
	* lock interrupts and jump there. This is the right thing to do for X86 and
	* possibly other platforms.
	*/
	static void do_boot(struct boot_rsp *rsp)
	{
	void *start;

	#if defined(MCUBOOT_RAM_LOAD)
	start = (void *)(rsp->br_hdr->ih_load_addr + rsp->br_hdr->ih_hdr_size);
	#else
	uintptr_t flash_base;
	int rc;

	rc = flash_device_base(rsp->br_flash_dev_id, &flash_base);
	assert(rc == 0);

	start = (void *)(flash_base + rsp->br_image_off +
	rsp->br_hdr->ih_hdr_size);
	#endif

	/* Lock interrupts and dive into the entry point */
	irq_lock();
	((void (*)(void))start)();
	}
	#endif

	#if defined(CONFIG_LOG) && !defined(ZEPHYR_LOG_MODE_IMMEDIATE) && \
	!defined(CONFIG_LOG_PROCESS_THREAD) && !defined(ZEPHYR_LOG_MODE_MINIMAL)
	/* The log internal thread for log processing can't transfer log well as has too
	* low priority.
	* Dedicated thread for log processing below uses highest application
	* priority. This allows to transmit all logs without adding k_sleep/k_yield
	* anywhere else int the code.
	*/

	/* most simple log processing theread */
	void boot_log_thread_func(void dummy1, void dummy2, void *dummy3)
	{
	(void)dummy1;
	(void)dummy2;
	(void)dummy3;

	log_init();

	while (1) {
	#if defined(CONFIG_LOG1) \|\| defined(CONFIG_LOG2)
	/* support Zephyr legacy logging implementation before commit c5f2cde */
	if (log_process(false) == false) {
	#else
	if (log_process() == false) {
	#endif
	if (boot_log_stop) {
	break;
	}
	k_sleep(BOOT_LOG_PROCESSING_INTERVAL);
	}
	}

	k_sem_give(&boot_log_sem);
	}

	void zephyr_boot_log_start(void)
	{
	/* start logging thread */
	k_thread_create(&boot_log_thread, boot_log_stack,
	K_THREAD_STACK_SIZEOF(boot_log_stack),
	boot_log_thread_func, NULL, NULL, NULL,
	K_HIGHEST_APPLICATION_THREAD_PRIO, 0,
	BOOT_LOG_PROCESSING_INTERVAL);

	k_thread_name_set(&boot_log_thread, "logging");
	}

	void zephyr_boot_log_stop(void)
	{
	boot_log_stop = true;

	/* wait until log procesing thread expired
	* This can be reworked using a thread_join() API once a such will be
	* available in zephyr.
	* see https://github.com/zephyrproject-rtos/zephyr/issues/21500
	*/
	(void)k_sem_take(&boot_log_sem, K_FOREVER);
	}
	#endif /* defined(CONFIG_LOG) && !defined(ZEPHYR_LOG_MODE_IMMEDIATE) && \
	* !defined(CONFIG_LOG_PROCESS_THREAD) && !defined(ZEPHYR_LOG_MODE_MINIMAL)
	*/

	#if defined(CONFIG_BOOT_SERIAL_ENTRANCE_GPIO) \|\| defined(CONFIG_BOOT_USB_DFU_GPIO)

	#ifdef CONFIG_MCUBOOT_SERIAL
	#define BUTTON_0_DETECT_DELAY CONFIG_BOOT_SERIAL_DETECT_DELAY
	#else
	#define BUTTON_0_DETECT_DELAY CONFIG_BOOT_USB_DFU_DETECT_DELAY
	#endif

	#define BUTTON_0_NODE DT_ALIAS(mcuboot_button0)

	#if DT_NODE_EXISTS(BUTTON_0_NODE) && DT_NODE_HAS_PROP(BUTTON_0_NODE, gpios)
	static const struct gpio_dt_spec button0 = GPIO_DT_SPEC_GET(BUTTON_0_NODE, gpios);
	#else
	#error "Serial recovery/USB DFU button must be declared in device tree as 'mcuboot_button0'"
	#endif

	static bool detect_pin(void)
	{
	int rc;
	int pin_active;

	if (!device_is_ready(button0.port)) {
	__ASSERT(false, "GPIO device is not ready.\n");
	return false;
	}

	rc = gpio_pin_configure_dt(&button0, GPIO_INPUT);
	__ASSERT(rc == 0, "Failed to initialize boot detect pin.\n");

	rc = gpio_pin_get_dt(&button0);
	pin_active = rc;

	__ASSERT(rc >= 0, "Failed to read boot detect pin.\n");

	if (pin_active) {
	if (BUTTON_0_DETECT_DELAY > 0) {
	#ifdef CONFIG_MULTITHREADING
	k_sleep(K_MSEC(50));
	#else
	k_busy_wait(50000);
	#endif

	/* Get the uptime for debounce purposes. */
	int64_t timestamp = k_uptime_get();

	for(;;) {
	rc = gpio_pin_get_dt(&button0);
	pin_active = rc;
	__ASSERT(rc >= 0, "Failed to read boot detect pin.\n");

	/* Get delta from when this started */
	uint32_t delta = k_uptime_get() - timestamp;

	/* If not pressed OR if pressed > debounce period, stop. */
	if (delta >= BUTTON_0_DETECT_DELAY \|\| !pin_active) {
	break;
	}

	/* Delay 1 ms */
	#ifdef CONFIG_MULTITHREADING
	k_sleep(K_MSEC(1));
	#else
	k_busy_wait(1000);
	#endif
	}
	}
	}

	return (bool)pin_active;
	}
	#endif

	#ifdef CONFIG_MCUBOOT_SERIAL
	static void boot_serial_enter()
	{
	int rc;

	#ifdef CONFIG_MCUBOOT_INDICATION_LED
	gpio_pin_set_dt(&led0, 1);
	#endif

	mcuboot_status_change(MCUBOOT_STATUS_SERIAL_DFU_ENTERED);

	BOOT_LOG_INF("Enter the serial recovery mode");
	rc = boot_console_init();
	__ASSERT(rc == 0, "Error initializing boot console.\n");
	boot_serial_start(&boot_funcs);
	__ASSERT(0, "Bootloader serial process was terminated unexpectedly.\n");
	}
	#endif

	int main(void)
	{
	struct boot_rsp rsp;
	int rc;
	FIH_DECLARE(fih_rc, FIH_FAILURE);

	#ifdef CONFIG_BOOT_SERIAL_BOOT_MODE
	int32_t boot_mode;
	#endif

	#ifdef CONFIG_BOOT_SERIAL_PIN_RESET
	uint32_t reset_cause;
	#endif

	MCUBOOT_WATCHDOG_SETUP();
	MCUBOOT_WATCHDOG_FEED();

	#if !defined(MCUBOOT_DIRECT_XIP)
	BOOT_LOG_INF("Starting bootloader");
	#else
	BOOT_LOG_INF("Starting Direct-XIP bootloader");
	#endif

	#ifdef CONFIG_MCUBOOT_INDICATION_LED
	/* LED init */
	led_init();
	#endif

	os_heap_init();

	ZEPHYR_BOOT_LOG_START();

	(void)rc;

	mcuboot_status_change(MCUBOOT_STATUS_STARTUP);

	#ifdef CONFIG_BOOT_SERIAL_ENTRANCE_GPIO
	if (detect_pin() &&
	!boot_skip_serial_recovery()) {
	boot_serial_enter();
	}
	#endif

	#ifdef CONFIG_BOOT_SERIAL_PIN_RESET
	rc = hwinfo_get_reset_cause(&reset_cause);

	if (rc == 0 && reset_cause == RESET_PIN) {
	(void)hwinfo_clear_reset_cause();
	boot_serial_enter();
	}
	#endif

	#if defined(CONFIG_BOOT_USB_DFU_GPIO)
	if (detect_pin()) {
	#ifdef CONFIG_MCUBOOT_INDICATION_LED
	gpio_pin_set_dt(&led0, 1);
	#endif

	mcuboot_status_change(MCUBOOT_STATUS_USB_DFU_ENTERED);

	rc = usb_enable(NULL);
	if (rc) {
	BOOT_LOG_ERR("Cannot enable USB");
	} else {
	BOOT_LOG_INF("Waiting for USB DFU");
	wait_for_usb_dfu(K_FOREVER);
	BOOT_LOG_INF("USB DFU wait time elapsed");
	}
	}
	#elif defined(CONFIG_BOOT_USB_DFU_WAIT)
	rc = usb_enable(NULL);
	if (rc) {
	BOOT_LOG_ERR("Cannot enable USB");
	} else {
	BOOT_LOG_INF("Waiting for USB DFU");

	mcuboot_status_change(MCUBOOT_STATUS_USB_DFU_WAITING);

	wait_for_usb_dfu(K_MSEC(CONFIG_BOOT_USB_DFU_WAIT_DELAY_MS));
	BOOT_LOG_INF("USB DFU wait time elapsed");

	mcuboot_status_change(MCUBOOT_STATUS_USB_DFU_TIMED_OUT);
	}
	#endif

	#ifdef CONFIG_BOOT_SERIAL_WAIT_FOR_DFU
	/* Initialize the boot console, so we can already fill up our buffers while
	* waiting for the boot image check to finish. This image check, can take
	* some time, so it's better to reuse thistime to already receive the
	* initial mcumgr command(s) into our buffers
	*/
	rc = boot_console_init();
	int timeout_in_ms = CONFIG_BOOT_SERIAL_WAIT_FOR_DFU_TIMEOUT;
	uint32_t start = k_uptime_get_32();
	#endif

	FIH_CALL(boot_go, fih_rc, &rsp);

	#ifdef CONFIG_BOOT_SERIAL_BOOT_MODE
	boot_mode = bootmode_check(BOOT_MODE_TYPE_BOOTLOADER);

	if (boot_mode == 1) {
	/* Boot mode to stay in bootloader, clear status and enter serial
	* recovery mode
	*/
	bootmode_clear();
	boot_serial_enter();
	}
	#endif

	#ifdef CONFIG_BOOT_SERIAL_WAIT_FOR_DFU
	timeout_in_ms -= (k_uptime_get_32() - start);
	if( timeout_in_ms <= 0 ) {
	/* at least one check if time was expired */
	timeout_in_ms = 1;
	}
	boot_serial_check_start(&boot_funcs,timeout_in_ms);
	#endif

	if (FIH_NOT_EQ(fih_rc, FIH_SUCCESS)) {
	BOOT_LOG_ERR("Unable to find bootable image");

	mcuboot_status_change(MCUBOOT_STATUS_NO_BOOTABLE_IMAGE_FOUND);

	#ifdef CONFIG_BOOT_SERIAL_NO_APPLICATION
	/* No bootable image and configuration set to remain in serial
	* recovery mode
	*/
	boot_serial_enter();
	#endif

	FIH_PANIC;
	}

	BOOT_LOG_INF("Bootloader chainload address offset: 0x%x",
	rsp.br_image_off);

	#if defined(MCUBOOT_DIRECT_XIP)
	BOOT_LOG_INF("Jumping to the image slot");
	#else
	BOOT_LOG_INF("Jumping to the first image slot");
	#endif

	mcuboot_status_change(MCUBOOT_STATUS_BOOTABLE_IMAGE_FOUND);

	ZEPHYR_BOOT_LOG_STOP();
	do_boot(&rsp);

	mcuboot_status_change(MCUBOOT_STATUS_BOOT_FAILED);

	BOOT_LOG_ERR("Never should get here");
	while (1)
	;
	}