/* * Copyright (c) 2011-2012, 2014-2015 Wind River Systems, Inc. * * SPDX-License-Identifier: Apache-2.0 */ /** * @file * @brief UART-driven console * * * Serial console driver. * Hooks into the printk and fputc (for printf) modules. Poll driven. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #ifdef CONFIG_UART_CONSOLE_MCUMGR #include "mgmt/serial.h" #endif static struct device *uart_console_dev; #ifdef CONFIG_UART_CONSOLE_DEBUG_SERVER_HOOKS static uart_console_in_debug_hook_t debug_hook_in; void uart_console_in_debug_hook_install(uart_console_in_debug_hook_t hook) { debug_hook_in = hook; } static UART_CONSOLE_OUT_DEBUG_HOOK_SIG(debug_hook_out_nop) { ARG_UNUSED(c); return !UART_CONSOLE_DEBUG_HOOK_HANDLED; } static uart_console_out_debug_hook_t *debug_hook_out = debug_hook_out_nop; void uart_console_out_debug_hook_install(uart_console_out_debug_hook_t *hook) { debug_hook_out = hook; } #define HANDLE_DEBUG_HOOK_OUT(c) \ (debug_hook_out(c) == UART_CONSOLE_DEBUG_HOOK_HANDLED) #endif /* CONFIG_UART_CONSOLE_DEBUG_SERVER_HOOKS */ #if 0 /* NOTUSED */ /** * * @brief Get a character from UART * * @return the character or EOF if nothing present */ static int console_in(void) { unsigned char c; if (uart_poll_in(uart_console_dev, &c) < 0) { return EOF; } else { return (int)c; } } #endif #if defined(CONFIG_PRINTK) || defined(CONFIG_STDOUT_CONSOLE) /** * * @brief Output one character to UART * * Outputs both line feed and carriage return in the case of a '\n'. * * @param c Character to output * * @return The character passed as input. */ static int console_out(int c) { #ifdef CONFIG_UART_CONSOLE_DEBUG_SERVER_HOOKS int handled_by_debug_server = HANDLE_DEBUG_HOOK_OUT(c); if (handled_by_debug_server) { return c; } #endif /* CONFIG_UART_CONSOLE_DEBUG_SERVER_HOOKS */ if ('\n' == c) { uart_poll_out(uart_console_dev, '\r'); } uart_poll_out(uart_console_dev, c); return c; } #endif #if defined(CONFIG_STDOUT_CONSOLE) extern void __stdout_hook_install(int (*hook)(int)); #else #define __stdout_hook_install(x) \ do { /* nothing */ \ } while ((0)) #endif #if defined(CONFIG_PRINTK) extern void __printk_hook_install(int (*fn)(int)); #else #define __printk_hook_install(x) \ do { /* nothing */ \ } while ((0)) #endif #if defined(CONFIG_CONSOLE_HANDLER) static struct k_fifo *avail_queue; static struct k_fifo *lines_queue; static u8_t (*completion_cb)(char *line, u8_t len); /* Control characters */ #define BS 0x08 #define ESC 0x1b #define DEL 0x7f /* ANSI escape sequences */ #define ANSI_ESC '[' #define ANSI_UP 'A' #define ANSI_DOWN 'B' #define ANSI_FORWARD 'C' #define ANSI_BACKWARD 'D' #define ANSI_END 'F' #define ANSI_HOME 'H' #define ANSI_DEL '~' static int read_uart(struct device *uart, u8_t *buf, unsigned int size) { int rx; rx = uart_fifo_read(uart, buf, size); if (rx < 0) { /* Overrun issue. Stop the UART */ uart_irq_rx_disable(uart); return -EIO; } return rx; } static inline void cursor_forward(unsigned int count) { printk("\x1b[%uC", count); } static inline void cursor_backward(unsigned int count) { printk("\x1b[%uD", count); } static inline void cursor_save(void) { printk("\x1b[s"); } static inline void cursor_restore(void) { printk("\x1b[u"); } static void insert_char(char *pos, char c, u8_t end) { char tmp; /* Echo back to console */ uart_poll_out(uart_console_dev, c); if (end == 0U) { *pos = c; return; } tmp = *pos; *(pos++) = c; cursor_save(); while (end-- > 0) { uart_poll_out(uart_console_dev, tmp); c = *pos; *(pos++) = tmp; tmp = c; } /* Move cursor back to right place */ cursor_restore(); } static void del_char(char *pos, u8_t end) { uart_poll_out(uart_console_dev, '\b'); if (end == 0U) { uart_poll_out(uart_console_dev, ' '); uart_poll_out(uart_console_dev, '\b'); return; } cursor_save(); while (end-- > 0) { *pos = *(pos + 1); uart_poll_out(uart_console_dev, *(pos++)); } uart_poll_out(uart_console_dev, ' '); /* Move cursor back to right place */ cursor_restore(); } enum { ESC_ESC, ESC_ANSI, ESC_ANSI_FIRST, ESC_ANSI_VAL, ESC_ANSI_VAL_2, #ifdef CONFIG_UART_CONSOLE_MCUMGR ESC_MCUMGR_PKT_1, ESC_MCUMGR_PKT_2, ESC_MCUMGR_FRAG_1, ESC_MCUMGR_FRAG_2, #endif }; static atomic_t esc_state; static unsigned int ansi_val, ansi_val_2; static u8_t cur, end; static void handle_ansi(u8_t byte, char *line) { if (atomic_test_and_clear_bit(&esc_state, ESC_ANSI_FIRST)) { if (!isdigit(byte)) { ansi_val = 1U; goto ansi_cmd; } atomic_set_bit(&esc_state, ESC_ANSI_VAL); ansi_val = byte - '0'; ansi_val_2 = 0U; return; } if (atomic_test_bit(&esc_state, ESC_ANSI_VAL)) { if (isdigit(byte)) { if (atomic_test_bit(&esc_state, ESC_ANSI_VAL_2)) { ansi_val_2 *= 10U; ansi_val_2 += byte - '0'; } else { ansi_val *= 10U; ansi_val += byte - '0'; } return; } /* Multi value sequence, e.g. Esc[Line;ColumnH */ if (byte == ';' && !atomic_test_and_set_bit(&esc_state, ESC_ANSI_VAL_2)) { return; } atomic_clear_bit(&esc_state, ESC_ANSI_VAL); atomic_clear_bit(&esc_state, ESC_ANSI_VAL_2); } ansi_cmd: switch (byte) { case ANSI_BACKWARD: if (ansi_val > cur) { break; } end += ansi_val; cur -= ansi_val; cursor_backward(ansi_val); break; case ANSI_FORWARD: if (ansi_val > end) { break; } end -= ansi_val; cur += ansi_val; cursor_forward(ansi_val); break; case ANSI_HOME: if (!cur) { break; } cursor_backward(cur); end += cur; cur = 0U; break; case ANSI_END: if (!end) { break; } cursor_forward(end); cur += end; end = 0U; break; case ANSI_DEL: if (!end) { break; } cursor_forward(1); del_char(&line[cur], --end); break; default: break; } atomic_clear_bit(&esc_state, ESC_ANSI); } #ifdef CONFIG_UART_CONSOLE_MCUMGR static void clear_mcumgr(void) { atomic_clear_bit(&esc_state, ESC_MCUMGR_PKT_1); atomic_clear_bit(&esc_state, ESC_MCUMGR_PKT_2); atomic_clear_bit(&esc_state, ESC_MCUMGR_FRAG_1); atomic_clear_bit(&esc_state, ESC_MCUMGR_FRAG_2); } /** * These states indicate whether an mcumgr frame is being received. */ #define CONSOLE_MCUMGR_STATE_NONE 1 #define CONSOLE_MCUMGR_STATE_HEADER 2 #define CONSOLE_MCUMGR_STATE_PAYLOAD 3 static int read_mcumgr_byte(uint8_t byte) { bool frag_1; bool frag_2; bool pkt_1; bool pkt_2; pkt_1 = atomic_test_bit(&esc_state, ESC_MCUMGR_PKT_1); pkt_2 = atomic_test_bit(&esc_state, ESC_MCUMGR_PKT_2); frag_1 = atomic_test_bit(&esc_state, ESC_MCUMGR_FRAG_1); frag_2 = atomic_test_bit(&esc_state, ESC_MCUMGR_FRAG_2); if (pkt_2 || frag_2) { /* Already fully framed. */ return CONSOLE_MCUMGR_STATE_PAYLOAD; } if (pkt_1) { if (byte == MCUMGR_SERIAL_HDR_PKT_2) { /* Final framing byte received. */ atomic_set_bit(&esc_state, ESC_MCUMGR_PKT_2); return CONSOLE_MCUMGR_STATE_PAYLOAD; } } else if (frag_1) { if (byte == MCUMGR_SERIAL_HDR_FRAG_2) { /* Final framing byte received. */ atomic_set_bit(&esc_state, ESC_MCUMGR_FRAG_2); return CONSOLE_MCUMGR_STATE_PAYLOAD; } } else { if (byte == MCUMGR_SERIAL_HDR_PKT_1) { /* First framing byte received. */ atomic_set_bit(&esc_state, ESC_MCUMGR_PKT_1); return CONSOLE_MCUMGR_STATE_HEADER; } else if (byte == MCUMGR_SERIAL_HDR_FRAG_1) { /* First framing byte received. */ atomic_set_bit(&esc_state, ESC_MCUMGR_FRAG_1); return CONSOLE_MCUMGR_STATE_HEADER; } } /* Non-mcumgr byte received. */ return CONSOLE_MCUMGR_STATE_NONE; } /** * @brief Attempts to process a received byte as part of an mcumgr frame. * * @param cmd The console command currently being received. * @param byte The byte just received. * * @return true if the command being received is an mcumgr frame; false if it * is a plain console command. */ static bool handle_mcumgr(struct console_input *cmd, uint8_t byte) { int mcumgr_state; mcumgr_state = read_mcumgr_byte(byte); if (mcumgr_state == CONSOLE_MCUMGR_STATE_NONE) { /* Not an mcumgr command; let the normal console handling * process the byte. */ cmd->is_mcumgr = 0; return false; } /* The received byte is part of an mcumgr command. Process the byte * and return true to indicate that normal console handling should * ignore it. */ if (cur + end < sizeof(cmd->line) - 1) { cmd->line[cur++] = byte; } if (mcumgr_state == CONSOLE_MCUMGR_STATE_PAYLOAD && byte == '\n') { cmd->line[cur + end] = '\0'; cmd->is_mcumgr = 1; k_fifo_put(lines_queue, cmd); clear_mcumgr(); cmd = NULL; cur = 0U; end = 0U; } return true; } #endif /* CONFIG_UART_CONSOLE_MCUMGR */ void uart_console_isr(struct device *unused) { ARG_UNUSED(unused); while (uart_irq_update(uart_console_dev) && uart_irq_is_pending(uart_console_dev)) { static struct console_input *cmd; u8_t byte; int rx; if (!uart_irq_rx_ready(uart_console_dev)) { continue; } /* Character(s) have been received */ rx = read_uart(uart_console_dev, &byte, 1); if (rx < 0) { return; } #ifdef CONFIG_UART_CONSOLE_DEBUG_SERVER_HOOKS if (debug_hook_in != NULL && debug_hook_in(byte) != 0) { /* * The input hook indicates that no further processing * should be done by this handler. */ return; } #endif if (!cmd) { cmd = k_fifo_get(avail_queue, K_NO_WAIT); if (!cmd) { return; } } #ifdef CONFIG_UART_CONSOLE_MCUMGR /* Divert this byte from normal console handling if it is part * of an mcumgr frame. */ if (handle_mcumgr(cmd, byte)) { continue; } #endif /* CONFIG_UART_CONSOLE_MCUMGR */ /* Handle ANSI escape mode */ if (atomic_test_bit(&esc_state, ESC_ANSI)) { handle_ansi(byte, cmd->line); continue; } /* Handle escape mode */ if (atomic_test_and_clear_bit(&esc_state, ESC_ESC)) { if (byte == ANSI_ESC) { atomic_set_bit(&esc_state, ESC_ANSI); atomic_set_bit(&esc_state, ESC_ANSI_FIRST); } continue; } /* Handle special control characters */ if (!isprint(byte)) { switch (byte) { case BS: case DEL: if (cur > 0) { del_char(&cmd->line[--cur], end); } break; case ESC: atomic_set_bit(&esc_state, ESC_ESC); break; case '\r': cmd->line[cur + end] = '\0'; uart_poll_out(uart_console_dev, '\r'); uart_poll_out(uart_console_dev, '\n'); cur = 0U; end = 0U; k_fifo_put(lines_queue, cmd); cmd = NULL; break; case '\t': if (completion_cb && !end) { cur += completion_cb(cmd->line, cur); } break; default: break; } continue; } /* Ignore characters if there's no more buffer space */ if (cur + end < sizeof(cmd->line) - 1) { insert_char(&cmd->line[cur++], byte, end); } } } static void console_input_init(void) { u8_t c; uart_irq_rx_disable(uart_console_dev); uart_irq_tx_disable(uart_console_dev); uart_irq_callback_set(uart_console_dev, uart_console_isr); /* Drain the fifo */ while (uart_irq_rx_ready(uart_console_dev)) { uart_fifo_read(uart_console_dev, &c, 1); } uart_irq_rx_enable(uart_console_dev); } void uart_register_input(struct k_fifo *avail, struct k_fifo *lines, u8_t (*completion)(char *str, u8_t len)) { avail_queue = avail; lines_queue = lines; completion_cb = completion; console_input_init(); } #else #define console_input_init(x) \ do { /* nothing */ \ } while ((0)) #define uart_register_input(x) \ do { /* nothing */ \ } while ((0)) #endif /** * * @brief Install printk/stdout hook for UART console output * * @return N/A */ void uart_console_hook_install(void) { __stdout_hook_install(console_out); __printk_hook_install(console_out); } /** * * @brief Initialize one UART as the console/debug port * * @return 0 if successful, otherwise failed. */ static int uart_console_init(struct device *arg) { ARG_UNUSED(arg); uart_console_dev = device_get_binding(CONFIG_UART_CONSOLE_ON_DEV_NAME); #if defined(CONFIG_USB_UART_CONSOLE) && defined(CONFIG_USB_UART_DTR_WAIT) while (1) { u32_t dtr = 0U; uart_line_ctrl_get(uart_console_dev, LINE_CTRL_DTR, &dtr); if (dtr) { break; } } k_busy_wait(1000000); #endif uart_console_hook_install(); return 0; } /* UART console initializes after the UART device itself */ SYS_INIT(uart_console_init, #if defined(CONFIG_USB_UART_CONSOLE) APPLICATION, #elif defined(CONFIG_EARLY_CONSOLE) PRE_KERNEL_1, #else POST_KERNEL, #endif CONFIG_UART_CONSOLE_INIT_PRIORITY);