/* * Copyright (c) 2021, STMicroelectronics - All Rights Reserved * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* USART bootloader protocol version V4.0 */ #define USART_BL_VERSION 0x40U /* Command definition */ #define GET_CMD_COMMAND 0x00U #define GET_VER_COMMAND 0x01U #define GET_ID_COMMAND 0x02U #define PHASE_COMMAND 0x03U #define READ_PART_COMMAND 0x12U #define START_COMMAND 0x21U #define DOWNLOAD_COMMAND 0x31U /* Answer defines */ #define INIT_BYTE 0x7FU #define ACK_BYTE 0x79U #define NACK_BYTE 0x1FU #define ABORT 0x5FU #define UNDEFINED_DOWN_ADDR U(0xFFFFFFFF) #define PROGRAMMER_TIMEOUT_US 20000U static const uint8_t command_tab[] = { GET_CMD_COMMAND, GET_VER_COMMAND, GET_ID_COMMAND, PHASE_COMMAND, START_COMMAND, DOWNLOAD_COMMAND }; /* STM32CubeProgrammer over UART handle */ struct stm32prog_uart_handle_s { struct stm32_uart_handle_s uart; uint32_t packet; uint8_t *addr; uint32_t len; uint8_t phase; /* Error msg buffer: max 255 in UART protocol, reduced in TF-A */ uint8_t error[64]; } handle; /* Trace and handle unrecoverable UART protocol error */ #define STM32PROG_ERROR(...) \ { \ ERROR(__VA_ARGS__); \ if (handle.phase != PHASE_RESET) { \ snprintf((char *)&handle.error, sizeof(handle.error), __VA_ARGS__); \ handle.phase = PHASE_RESET; \ handle.addr = (uint8_t *)UNDEFINED_DOWN_ADDR; \ handle.len = 0U; \ handle.packet = 0U; \ } \ } static int uart_write(const uint8_t *addr, uint16_t size) { while (size != 0U) { if (stm32_uart_putc(&handle.uart, *addr) != 0) { return -EIO; } size--; addr++; } return 0; } static int uart_write_8(uint8_t byte) { return stm32_uart_putc(&handle.uart, byte); } static int uart_write_32(uint32_t value) { return uart_write((uint8_t *)&value, 4U); } static int uart_read_8(uint8_t *byte) { int ret; uint64_t timeout_ref = timeout_init_us(PROGRAMMER_TIMEOUT_US); do { ret = stm32_uart_getc(&handle.uart); if (ret == -EAGAIN) { if (timeout_elapsed(timeout_ref)) { return -ETIMEDOUT; } } else if (ret < 0) { return ret; } } while (ret == -EAGAIN); *byte = (uint8_t)ret; return 0; } static int uart_send_result(uint8_t byte) { int ret; /* Always flush fifo before to send result = read all pending data */ do { ret = stm32_uart_getc(&handle.uart); } while (ret >= 0); return uart_write_8(byte); } static bool is_valid_header(fip_toc_header_t *header) { return (header->name == TOC_HEADER_NAME) && (header->serial_number != 0U); } static int uart_receive_command(uint8_t *command) { uint8_t byte = 0U; uint8_t xor = 0U; unsigned int count; bool found = false; int ret; /* Repeat read until something is received */ do { stm32_iwdg_refresh(); ret = uart_read_8(&byte); } while (ret == -ETIMEDOUT); if (ret != 0) { return ret; } /* Handle reconnection request */ if (byte == INIT_BYTE) { *command = byte; return 0; } for (count = 0U; count < ARRAY_SIZE(command_tab); count++) { if (command_tab[count] == byte) { found = true; break; } } if (!found) { VERBOSE("UART: Command unknown (byte=0x%x)\n", byte); return -EPROTO; } ret = uart_read_8(&xor); if (ret != 0) { return ret; } if ((byte ^ xor) != 0xFF) { VERBOSE("UART: Command XOR check fail (byte=0x%x, xor=0x%x)\n", byte, xor); return -EPROTO; } *command = byte; return 0; } static int get_cmd_command(void) { const uint8_t msg[2] = { sizeof(command_tab), /* Length of data - 1 */ USART_BL_VERSION }; int ret; ret = uart_write(msg, sizeof(msg)); if (ret != 0) { return ret; } return uart_write(command_tab, sizeof(command_tab)); } static int get_version_command(void) { return uart_write_8(STM32_TF_VERSION); } static int get_id_command(void) { uint8_t msg[3] = { sizeof(msg) - 1 /* Length of data - 1 */ }; uint32_t chip_id = stm32mp_get_chip_dev_id(); be16enc(&msg[1], chip_id); return uart_write(msg, sizeof(msg)); } static int uart_send_phase(uint32_t address) { int ret; uint8_t msg_size = 5U; /* Length of data - 1 */ uint8_t error_size = 0U; /* Additional information only for RESET phase */ if (handle.phase == PHASE_RESET) { error_size = strnlen((char *)&handle.error, sizeof(handle.error)); } ret = uart_write_8(msg_size + error_size); if (ret != 0) { return ret; } /* Send the ID of next partition */ ret = uart_write_8(handle.phase); if (ret != 0) { return ret; } /* Destination address */ ret = uart_write_32(address); if (ret != 0) { return ret; } ret = uart_write_8(error_size); if (ret != 0) { return ret; } /* Additional information: message error */ if (error_size > 0U) { ret = uart_write(handle.error, error_size); } return ret; } static int uart_download_part(void) { uint8_t operation = 0U; uint8_t xor; uint8_t byte = 0U; uint32_t packet_number = 0U; uint32_t packet_size = 0U; uint32_t i = 0U; int ret; /* Get operation number */ ret = uart_read_8(&operation); if (ret != 0) { return ret; } xor = operation; /* Get packet number */ for (i = 3U; i != 0U; i--) { ret = uart_read_8(&byte); if (ret != 0) { return ret; } xor ^= byte; packet_number = (packet_number << 8) | byte; } if (packet_number != handle.packet) { WARN("UART: Bad packet number receive: %u, expected %u\n", packet_number, handle.packet); return -EPROTO; } /* Checksum */ ret = uart_read_8(&byte); if (ret != 0) { return ret; } if (xor != byte) { VERBOSE("UART: Download Command checksum xor: %x, received %x\n", xor, byte); return -EPROTO; } ret = uart_send_result(ACK_BYTE); if (ret != 0) { return ret; } ret = uart_read_8(&byte); if (ret != 0) { return ret; } xor = byte; packet_size = byte + 1U; if (handle.len < packet_size) { STM32PROG_ERROR("Download overflow at %p\n", handle.addr + packet_size); return 0; } for (i = 0U; i < packet_size; i++) { ret = uart_read_8(&byte); if (ret != 0) { return ret; } *(handle.addr + i) = byte; xor ^= byte; } /* Checksum */ ret = uart_read_8(&byte) != 0; if (ret != 0) { return ret; } if (xor != byte) { VERBOSE("UART: Download Data checksum xor: %x, received %x\n", xor, byte); return -EPROTO; } /* Packet treated */ handle.packet++; handle.addr += packet_size; handle.len -= packet_size; return 0; } static int uart_start_cmd(uintptr_t buffer) { uint8_t byte = 0U; uint8_t xor = 0U; uint32_t i; uint32_t start_address = 0U; int ret; /* Get address */ for (i = 4U; i != 0U; i--) { ret = uart_read_8(&byte); if (ret != 0U) { return ret; } xor ^= byte; start_address = (start_address << 8) | byte; } /* Checksum */ ret = uart_read_8(&byte); if (ret != 0) { return ret; } if (xor != byte) { VERBOSE("UART: Start Command checksum xor: %x, received %x\n", xor, byte); return -EPROTO; } if (start_address != UNDEFINED_DOWN_ADDR) { STM32PROG_ERROR("Invalid start at %x, for phase %u\n", start_address, handle.phase); return 0; } if (!is_valid_header((fip_toc_header_t *)buffer)) { STM32PROG_ERROR("FIP Header check failed %lx, for phase %u\n", buffer, handle.phase); return -EIO; } VERBOSE("FIP header looks OK.\n"); return 0; } static int uart_read(uint8_t id, uintptr_t buffer, size_t length) { bool start_done = false; int ret; uint8_t command = 0U; handle.phase = id; handle.packet = 0U; handle.addr = (uint8_t *)buffer; handle.len = length; INFO("UART: read phase %u at 0x%lx size 0x%x\n", id, buffer, length); while (!start_done) { ret = uart_receive_command(&command); if (ret != 0) { /* Delay to wait STM32CubeProgrammer end of transmission */ mdelay(3); ret = uart_send_result(NACK_BYTE); if (ret != 0U) { return ret; } continue; } uart_send_result(ACK_BYTE); switch (command) { case INIT_BYTE: INFO("UART: Connected\n"); /* Nothing to do */ continue; case GET_CMD_COMMAND: ret = get_cmd_command(); break; case GET_VER_COMMAND: ret = get_version_command(); break; case GET_ID_COMMAND: ret = get_id_command(); break; case PHASE_COMMAND: ret = uart_send_phase((uint32_t)buffer); if ((ret == 0) && (handle.phase == PHASE_RESET)) { start_done = true; INFO("UART: Reset\n"); } break; case DOWNLOAD_COMMAND: ret = uart_download_part(); break; case START_COMMAND: ret = uart_start_cmd(buffer); if ((ret == 0) && (handle.phase == id)) { INFO("UART: Start phase %u\n", handle.phase); start_done = true; } break; default: WARN("UART: Unknown command\n"); ret = -EINVAL; break; } if (ret == 0) { ret = uart_send_result(ACK_BYTE); } else { ret = uart_send_result(NACK_BYTE); } if (ret != 0) { return ret; } } return 0; } /* Init UART: 115200, 8bit 1stop parity even and enable FIFO mode */ const struct stm32_uart_init_s init = { .baud_rate = U(115200), .word_length = STM32_UART_WORDLENGTH_9B, .stop_bits = STM32_UART_STOPBITS_1, .parity = STM32_UART_PARITY_EVEN, .hw_flow_control = STM32_UART_HWCONTROL_NONE, .mode = STM32_UART_MODE_TX_RX, .over_sampling = STM32_UART_OVERSAMPLING_16, .fifo_mode = STM32_UART_FIFOMODE_EN, }; int stm32cubeprog_uart_load(uintptr_t instance, uintptr_t base, size_t len) { int ret; if (stm32_uart_init(&handle.uart, instance, &init) != 0) { return -EIO; } /* * The following NACK_BYTE is written because STM32CubeProgrammer has * already sent its command before TF-A has reached this point, and * because FIFO was not configured by BootROM. * The byte in the UART_RX register is then the checksum and not the * command. NACK_BYTE has to be written, so that the programmer will * re-send the good command. */ ret = uart_send_result(NACK_BYTE); if (ret != 0) { return ret; } return uart_read(PHASE_SSBL, base, len); }