/* * Copyright (c) 2006-2023, RT-Thread Development Team * * SPDX-License-Identifier: Apache-2.0 * * Change Logs: * Date Author Notes * 2021.12.07 linzhenxing first version */ #include #include #include #include #if defined(RT_USING_POSIX_TERMIOS) #include #endif #include #define DBG_TAG "N_TTY" #ifdef RT_TTY_DEBUG #define DBG_LVL DBG_LOG #else #define DBG_LVL DBG_INFO #endif /* RT_TTY_DEBUG */ #include /* number of characters left in xmit buffer before select has we have room */ #define WAKEUP_CHARS 256 /* * This defines the low- and high-watermarks for throttling and * unthrottling the TTY driver. These watermarks are used for * controlling the space in the read buffer. */ #define TTY_THRESHOLD_THROTTLE 128 /* now based on remaining room */ #define TTY_THRESHOLD_UNTHROTTLE 128 /* * Special byte codes used in the echo buffer to represent operations * or special handling of characters. Bytes in the echo buffer that * are not part of such special blocks are treated as normal character * codes. */ #define ECHO_OP_START 0xff #define ECHO_OP_MOVE_BACK_COL 0x80 #define ECHO_OP_SET_CANON_COL 0x81 #define ECHO_OP_ERASE_TAB 0x82 #define ECHO_COMMIT_WATERMARK 256 #define ECHO_BLOCK 256 #define ECHO_DISCARD_WATERMARK RT_TTY_BUF - (ECHO_BLOCK + 32) struct n_tty_data { /* producer-published */ size_t read_head; size_t commit_head; size_t canon_head; size_t echo_head; size_t echo_commit; size_t echo_mark; unsigned long char_map[256]; /* non-atomic */ rt_bool_t no_room; /* must hold exclusive termios_rwsem to reset these */ unsigned char lnext:1, erasing:1, raw:1, real_raw:1, icanon:1; unsigned char push:1; /* shared by producer and consumer */ char read_buf[RT_TTY_BUF]; unsigned long read_flags[RT_TTY_BUF]; unsigned char echo_buf[RT_TTY_BUF]; /* consumer-published */ size_t read_tail; size_t line_start; /* protected by output lock */ unsigned int column; unsigned int canon_column; size_t echo_tail; rt_mutex_t atomic_read_lock; rt_mutex_t output_lock; }; rt_inline int set_bit(int nr,int *addr) { int mask, retval, level; addr += nr >> 5; mask = 1 << (nr & 0x1f); level = rt_hw_interrupt_disable(); retval = (mask & *addr) != 0; *addr |= mask; rt_hw_interrupt_enable(level); return retval; } rt_inline int clear_bit(int nr, int *addr) { int mask, retval, level; addr += nr >> 5; mask = 1 << (nr & 0x1f); level = rt_hw_interrupt_disable(); retval = (mask & *addr) != 0; *addr &= ~mask; rt_hw_interrupt_enable(level); return retval; } rt_inline int test_bit(int nr, int *addr) { int mask; addr += nr >> 5; mask = 1 << (nr & 0x1f); return ((mask & *addr) != 0); } rt_inline int test_and_clear_bit(int nr, volatile void *addr) { int mask, retval, level; volatile unsigned int *a = addr; a += nr >> 5; mask = 1 << (nr & 0x1f); level = rt_hw_interrupt_disable(); retval = (mask & *a) != 0; *a &= ~mask; rt_hw_interrupt_enable(level); return retval; } rt_inline unsigned long __ffs(unsigned long word) { int num = 0; #if BITS_PER_LONG == 64 if ((word & 0xffffffff) == 0) { num += 32; word >>= 32; } #endif if ((word & 0xffff) == 0) { num += 16; word >>= 16; } if ((word & 0xff) == 0) { num += 8; word >>= 8; } if ((word & 0xf) == 0) { num += 4; word >>= 4; } if ((word & 0x3) == 0) { num += 2; word >>= 2; } if ((word & 0x1) == 0) { num += 1; } return num; } #define BITS_PER_LONG 32 #define BITOP_WORD(nr) ((nr) / BITS_PER_LONG) /* * Find the next set bit in a memory region. */ rt_inline unsigned long find_next_bit(const unsigned long *addr, unsigned long size, unsigned long offset) { const unsigned long *p = addr + BITOP_WORD(offset); unsigned long result = offset & ~(BITS_PER_LONG-1); unsigned long tmp; if (offset >= size) { return size; } size -= result; offset %= BITS_PER_LONG; if (offset) { tmp = *(p++); tmp &= (~0UL << offset); if (size < BITS_PER_LONG) { goto found_first; } if (tmp) { goto found_middle; } size -= BITS_PER_LONG; result += BITS_PER_LONG; } while (size & ~(BITS_PER_LONG-1)) { if ((tmp = *(p++))) { goto found_middle; } result += BITS_PER_LONG; size -= BITS_PER_LONG; } if (!size) { return result; } tmp = *p; found_first: tmp &= (~0UL >> (BITS_PER_LONG - size)); if (tmp == 0UL) /* Are any bits set? */ { return result + size; /* Nope. */ } found_middle: return result + __ffs(tmp); } rt_inline void tty_sigaddset(lwp_sigset_t *set, int _sig) { unsigned long sig = _sig - 1; if (_LWP_NSIG_WORDS == 1) { set->sig[0] |= 1UL << sig; } else { set->sig[sig / _LWP_NSIG_BPW] |= 1UL << (sig % _LWP_NSIG_BPW); } } rt_inline size_t read_cnt(struct n_tty_data *ldata) { return ldata->read_head - ldata->read_tail; } rt_inline char read_buf(struct n_tty_data *ldata, size_t i) { return ldata->read_buf[i & (RT_TTY_BUF - 1)]; } rt_inline char *read_buf_addr(struct n_tty_data *ldata, size_t i) { return &ldata->read_buf[i & (RT_TTY_BUF - 1)]; } rt_inline unsigned char echo_buf(struct n_tty_data *ldata, size_t i) { return ldata->echo_buf[i & (RT_TTY_BUF - 1)]; } rt_inline unsigned char *echo_buf_addr(struct n_tty_data *ldata, size_t i) { return &ldata->echo_buf[i & (RT_TTY_BUF - 1)]; } /** * put_tty_queue - add character to tty * @c: character * @ldata: n_tty data * * Add a character to the tty read_buf queue. * * n_tty_receive_buf()/producer path: * caller holds non-exclusive termios_rwsem */ rt_inline void put_tty_queue(unsigned char c, struct n_tty_data *ldata) { *read_buf_addr(ldata, ldata->read_head) = c; ldata->read_head++; } /** * reset_buffer_flags - reset buffer state * @tty: terminal to reset * * Reset the read buffer counters and clear the flags. * Called from n_tty_open() and n_tty_flush_buffer(). * * Locking: caller holds exclusive termios_rwsem * (or locking is not required) */ static void reset_buffer_flags(struct n_tty_data *ldata) { ldata->read_head = ldata->canon_head = ldata->read_tail = 0; ldata->echo_head = ldata->echo_tail = ldata->echo_commit = 0; ldata->commit_head = 0; ldata->echo_mark = 0; ldata->line_start = 0; ldata->erasing = 0; rt_memset(ldata->read_flags, 0, RT_TTY_BUF); ldata->push = 0; } /** * add_echo_byte - add a byte to the echo buffer * @c: unicode byte to echo * @ldata: n_tty data * * Add a character or operation byte to the echo buffer. */ rt_inline void add_echo_byte(unsigned char c, struct n_tty_data *ldata) { *echo_buf_addr(ldata, ldata->echo_head++) = c; } /** * echo_move_back_col - add operation to move back a column * @ldata: n_tty data * * Add an operation to the echo buffer to move back one column. */ static void echo_move_back_col(struct n_tty_data *ldata) { add_echo_byte(ECHO_OP_START, ldata); add_echo_byte(ECHO_OP_MOVE_BACK_COL, ldata); } /** * echo_set_canon_col - add operation to set the canon column * @ldata: n_tty data * * Add an operation to the echo buffer to set the canon column * to the current column. */ static void echo_set_canon_col(struct n_tty_data *ldata) { add_echo_byte(ECHO_OP_START, ldata); add_echo_byte(ECHO_OP_SET_CANON_COL, ldata); } /** * echo_erase_tab - add operation to erase a tab * @num_chars: number of character columns already used * @after_tab: true if num_chars starts after a previous tab * @ldata: n_tty data * * Add an operation to the echo buffer to erase a tab. * * Called by the eraser function, which knows how many character * columns have been used since either a previous tab or the start * of input. This information will be used later, along with * canon column (if applicable), to go back the correct number * of columns. */ static void echo_erase_tab(unsigned int num_chars, int after_tab, struct n_tty_data *ldata) { add_echo_byte(ECHO_OP_START, ldata); add_echo_byte(ECHO_OP_ERASE_TAB, ldata); /* We only need to know this modulo 8 (tab spacing) */ num_chars &= 7; /* Set the high bit as a flag if num_chars is after a previous tab */ if (after_tab) { num_chars |= 0x80; } add_echo_byte(num_chars, ldata); } /** * echo_char_raw - echo a character raw * @c: unicode byte to echo * @tty: terminal device * * Echo user input back onto the screen. This must be called only when * L_ECHO(tty) is true. Called from the driver receive_buf path. * * This variant does not treat control characters specially. */ static void echo_char_raw(unsigned char c, struct n_tty_data *ldata) { if (c == ECHO_OP_START) { add_echo_byte(ECHO_OP_START, ldata); add_echo_byte(ECHO_OP_START, ldata); } else { add_echo_byte(c, ldata); } } /** * echo_char - echo a character * @c: unicode byte to echo * @tty: terminal device * * Echo user input back onto the screen. This must be called only when * L_ECHO(tty) is true. Called from the driver receive_buf path. * * This variant tags control characters to be echoed as "^X" * (where X is the letter representing the control char). */ static void echo_char(unsigned char c, struct tty_struct *tty) { struct n_tty_data *ldata = tty->disc_data; if (c == ECHO_OP_START) { add_echo_byte(ECHO_OP_START, ldata); add_echo_byte(ECHO_OP_START, ldata); } else { if (L_ECHOCTL(tty) && iscntrl(c) && c != '\t') { add_echo_byte(ECHO_OP_START, ldata); } add_echo_byte(c, ldata); } } /** * finish_erasing - complete erase * @ldata: n_tty data */ rt_inline void finish_erasing(struct n_tty_data *ldata) { if (ldata->erasing) { echo_char_raw('/', ldata); ldata->erasing = 0; } } /** * is_utf8_continuation - utf8 multibyte check * @c: byte to check * * Returns true if the utf8 character 'c' is a multibyte continuation * character. We use this to correctly compute the on screen size * of the character when printing */ rt_inline int is_utf8_continuation(unsigned char c) { return (c & 0xc0) == 0x80; } /** * is_continuation - multibyte check * @c: byte to check * * Returns true if the utf8 character 'c' is a multibyte continuation * character and the terminal is in unicode mode. */ rt_inline int is_continuation(unsigned char c, struct tty_struct *tty) { return I_IUTF8(tty) && is_utf8_continuation(c); } /** * eraser - handle erase function * @c: character input * @tty: terminal device * * Perform erase and necessary output when an erase character is * present in the stream from the driver layer. Handles the complexities * of UTF-8 multibyte symbols. * * n_tty_receive_buf()/producer path: * caller holds non-exclusive termios_rwsem */ static void eraser(unsigned char c, struct tty_struct *tty) { struct n_tty_data *ldata = tty->disc_data; enum { KERASE, WERASE, KILL } kill_type; size_t head = 0; size_t cnt = 0; int seen_alnums = 0; if (ldata->read_head == ldata->canon_head) { /* process_output('\a', tty); */ /* what do you think? */ return; } if (c == ERASE_CHAR(tty)) { kill_type = KERASE; } else if (c == WERASE_CHAR(tty)) { kill_type = WERASE; } else { if (!L_ECHO(tty)) { ldata->read_head = ldata->canon_head; return; } if (!L_ECHOK(tty) || !L_ECHOKE(tty) || !L_ECHOE(tty)) { ldata->read_head = ldata->canon_head; finish_erasing(ldata); echo_char(KILL_CHAR(tty), tty); /* Add a newline if ECHOK is on and ECHOKE is off. */ if (L_ECHOK(tty)) { echo_char_raw('\n', ldata); } return; } kill_type = KILL; } seen_alnums = 0; while (ldata->read_head != ldata->canon_head) { head = ldata->read_head; /* erase a single possibly multibyte character */ do { head--; c = read_buf(ldata, head); } while (is_continuation(c, tty) && head != ldata->canon_head); /* do not partially erase */ if (is_continuation(c, tty)) { break; } if (kill_type == WERASE) { /* Equivalent to BSD's ALTWERASE. */ if (isalnum(c) || c == '_') { seen_alnums++; } else if (seen_alnums) { break; } } cnt = ldata->read_head - head; ldata->read_head = head; if (L_ECHO(tty)) { if (L_ECHOPRT(tty)) { if (!ldata->erasing) { echo_char_raw('\\', ldata); ldata->erasing = 1; } /* if cnt > 1, output a multi-byte character */ echo_char(c, tty); while (--cnt > 0) { head++; echo_char_raw(read_buf(ldata, head), ldata); echo_move_back_col(ldata); } } else if (kill_type == KERASE && !L_ECHOE(tty)) { echo_char(ERASE_CHAR(tty), tty); } else if (c == '\t') { unsigned int num_chars = 0; int after_tab = 0; size_t tail = ldata->read_head; /* * Count the columns used for characters * since the start of input or after a * previous tab. * This info is used to go back the correct * number of columns. */ while (tail != ldata->canon_head) { tail--; c = read_buf(ldata, tail); if (c == '\t') { after_tab = 1; break; } else if (iscntrl(c)) { if (L_ECHOCTL(tty)) { num_chars += 2; } } else if (!is_continuation(c, tty)) { num_chars++; } } echo_erase_tab(num_chars, after_tab, ldata); } else { if (iscntrl(c) && L_ECHOCTL(tty)) { echo_char_raw('\b', ldata); echo_char_raw(' ', ldata); echo_char_raw('\b', ldata); } if (!iscntrl(c) || L_ECHOCTL(tty)) { echo_char_raw('\b', ldata); echo_char_raw(' ', ldata); echo_char_raw('\b', ldata); } } } if (kill_type == KERASE) { break; } } if (ldata->read_head == ldata->canon_head && L_ECHO(tty)) { finish_erasing(ldata); } } /** * isig - handle the ISIG optio * @sig: signal * @tty: terminal * * Called when a signal is being sent due to terminal input. * Called from the driver receive_buf path so serialized. * * Performs input and output flush if !NOFLSH. In this context, the echo * buffer is 'output'. The signal is processed first to alert any current * readers or writers to discontinue and exit their i/o loops. * * Locking: ctrl_lock */ static void __isig(int sig, struct tty_struct *tty) { struct rt_lwp *lwp = tty->foreground; struct tty_ldisc *ld = RT_NULL; struct termios old_termios; struct termios *new_termios = get_old_termios(); if (lwp) { if (sig == SIGTSTP) { struct rt_lwp *old_lwp; rt_memcpy(&old_termios, &(tty->init_termios), sizeof(struct termios)); tty->init_termios = *new_termios; ld = tty->ldisc; if (ld != RT_NULL) { if (ld->ops->set_termios) { ld->ops->set_termios(tty, &old_termios); } } tty_sigaddset(&lwp->signal_mask, SIGTTOU); old_lwp = tty_pop(&tty->head, RT_NULL); tty->foreground = old_lwp; } else { lwp_kill(lwp_to_pid(lwp), sig); } } } static void isig(int sig, struct tty_struct *tty) { struct n_tty_data *ldata = tty->disc_data; if (L_NOFLSH(tty)) { /* signal only */ __isig(sig, tty); } else { /* signal and flush */ __isig(sig, tty); /* clear echo buffer */ ldata->echo_head = ldata->echo_tail = 0; ldata->echo_mark = ldata->echo_commit = 0; /* clear input buffer */ reset_buffer_flags(tty->disc_data); } } /** * do_output_char - output one character * @c: character (or partial unicode symbol) * @tty: terminal device * @space: space available in tty driver write buffer * * This is a helper function that handles one output character * (including special characters like TAB, CR, LF, etc.), * doing OPOST processing and putting the results in the * tty driver's write buffer. * * Note that Linux currently ignores TABDLY, CRDLY, VTDLY, FFDLY * and NLDLY. They simply aren't relevant in the world today. * If you ever need them, add them here. * * Returns the number of bytes of buffer space used or -1 if * no space left. * * Locking: should be called under the output_lock to protect * the column state and space left in the buffer */ static int do_output_char(unsigned char c, struct tty_struct *tty) { struct n_tty_data *ldata = tty->disc_data; int spaces = 0; char *ch = RT_NULL; switch (c) { case '\n': if (O_ONLRET(tty)) { ldata->column = 0; } if (O_ONLCR(tty)) { ldata->canon_column = ldata->column = 0; ch = "\r\n"; rt_device_write((rt_device_t)tty, -1, ch, 2); return 2; } ldata->canon_column = ldata->column; break; case '\r': if (O_ONOCR(tty) && ldata->column == 0) { return 0; } if (O_OCRNL(tty)) { c = '\n'; if (O_ONLRET(tty)) { ldata->canon_column = ldata->column = 0; } break; } ldata->canon_column = ldata->column = 0; break; case '\t': spaces = 8 - (ldata->column & 7); if (O_TABDLY(tty) == XTABS) { ldata->column += spaces; ch = " "; rt_device_write((rt_device_t)tty, -1, &ch, spaces); return spaces; } ldata->column += spaces; break; case '\b': if (ldata->column > 0) { ldata->column--; } ch = "\b \b"; rt_device_write((rt_device_t)tty, -1, ch, strlen(ch)); return 1; default: if (!iscntrl(c)) { if (O_OLCUC(tty)) { c = toupper(c); } if (!is_continuation(c, tty)) { ldata->column++; } } break; } rt_device_write((rt_device_t)tty, -1, &c, 1); return 1; } /** * process_output - output post processor * @c: character (or partial unicode symbol) * @tty: terminal device * * Output one character with OPOST processing. * Returns -1 when the output device is full and the character * must be retried. * * Locking: output_lock to protect column state and space left * (also, this is called from n_tty_write under the * tty layer write lock) */ static int process_output(unsigned char c, struct tty_struct *tty) { int retval = 0; retval = do_output_char(c, tty); if (retval < 0) { return -1; } else { return 0; } } /** * process_output_block - block post processor * @tty: terminal device * @buf: character buffer * @nr: number of bytes to output * * Output a block of characters with OPOST processing. * Returns the number of characters output. * * This path is used to speed up block console writes, among other * things when processing blocks of output data. It handles only * the simple cases normally found and helps to generate blocks of * symbols for the console driver and thus improve performance. * * Locking: output_lock to protect column state and space left * (also, this is called from n_tty_write under the * tty layer write lock) */ static ssize_t process_output_block(struct tty_struct *tty, const char *buf, unsigned int nr) { struct n_tty_data *ldata = tty->disc_data; int i = 0; ssize_t size = 0; const char *cp = RT_NULL; for (i = 0, cp = buf; i < nr; i++, cp++) { char c = *cp; switch (c) { case '\n': if (O_ONLRET(tty)) { ldata->column = 0; } if (O_ONLCR(tty)) { goto break_out; } ldata->canon_column = ldata->column; break; case '\r': if (O_ONOCR(tty) && ldata->column == 0) { goto break_out; } if (O_OCRNL(tty)) { goto break_out; } ldata->canon_column = ldata->column = 0; break; case '\t': goto break_out; case '\b': if (ldata->column > 0) { ldata->column--; } break; default: if (!iscntrl(c)) { if (O_OLCUC(tty)) { goto break_out; } if (!is_continuation(c, tty)) { ldata->column++; } } break; } } break_out: size = rt_device_write((rt_device_t)tty, -1, buf, i); return size; } static size_t __process_echoes(struct tty_struct *tty) { struct n_tty_data *ldata = tty->disc_data; size_t tail = 0; unsigned char c = 0; char ch = 0; unsigned char num_chars = 0, num_bs = 0; tail = ldata->echo_tail; while (ldata->echo_commit != tail) { c = echo_buf(ldata, tail); if (c == ECHO_OP_START) { unsigned char op = 0; /* * If the buffer byte is the start of a multi-byte * operation, get the next byte, which is either the * op code or a control character value. */ op = echo_buf(ldata, tail + 1); switch (op) { case ECHO_OP_ERASE_TAB: num_chars = echo_buf(ldata, tail + 2); /* * Determine how many columns to go back * in order to erase the tab. * This depends on the number of columns * used by other characters within the tab * area. If this (modulo 8) count is from * the start of input rather than from a * previous tab, we offset by canon column. * Otherwise, tab spacing is normal. */ if (!(num_chars & 0x80)) { num_chars += ldata->canon_column; } num_bs = 8 - (num_chars & 7); while (num_bs--) { ch = '\b'; rt_device_write((rt_device_t)tty, -1, &ch, 1); if (ldata->column > 0) { ldata->column--; } } tail += 3; break; case ECHO_OP_SET_CANON_COL: ldata->canon_column = ldata->column; tail += 2; break; case ECHO_OP_MOVE_BACK_COL: if (ldata->column > 0) { ldata->column--; } tail += 2; break; case ECHO_OP_START: ch = ECHO_OP_START; rt_device_write((rt_device_t)tty, -1, &ch, 1); ldata->column++; tail += 2; break; default: /* * If the op is not a special byte code, * it is a ctrl char tagged to be echoed * as "^X" (where X is the letter * representing the control char). * Note that we must ensure there is * enough space for the whole ctrl pair. * */ ch = '^'; rt_device_write((rt_device_t)tty, -1, &ch, 1); ch = op ^ 0100; rt_device_write((rt_device_t)tty, -1, &ch, 1); ldata->column += 2; tail += 2; } } else { if (O_OPOST(tty)) { int retval = do_output_char(c, tty); if (retval < 0) { break; } } else { rt_device_write((rt_device_t)tty, -1, &c, 1); } tail += 1; } } /* If the echo buffer is nearly full (so that the possibility exists * of echo overrun before the next commit), then discard enough * data at the tail to prevent a subsequent overrun */ while (ldata->echo_commit - tail >= ECHO_DISCARD_WATERMARK) { if (echo_buf(ldata, tail) == ECHO_OP_START) { if (echo_buf(ldata, tail + 1) == ECHO_OP_ERASE_TAB) { tail += 3; } else { tail += 2; } } else { tail++; } } ldata->echo_tail = tail; return 0; } static void commit_echoes(struct tty_struct *tty) { struct n_tty_data *ldata = tty->disc_data; size_t nr = 0, old = 0; size_t head = 0; head = ldata->echo_head; ldata->echo_mark = head; old = ldata->echo_commit - ldata->echo_tail; /* Process committed echoes if the accumulated # of bytes * is over the threshold (and try again each time another * block is accumulated) */ nr = head - ldata->echo_tail; if (nr < ECHO_COMMIT_WATERMARK || (nr % ECHO_BLOCK > old % ECHO_BLOCK)) { return; } ldata->echo_commit = head; __process_echoes(tty); } static void process_echoes(struct tty_struct *tty) { struct n_tty_data *ldata = tty->disc_data; if (ldata->echo_mark == ldata->echo_tail) { return; } ldata->echo_commit = ldata->echo_mark; __process_echoes(tty); } /* NB: echo_mark and echo_head should be equivalent here */ static void flush_echoes(struct tty_struct *tty) { struct n_tty_data *ldata = tty->disc_data; if ((!L_ECHO(tty) && !L_ECHONL(tty)) || ldata->echo_commit == ldata->echo_head) { return; } ldata->echo_commit = ldata->echo_head; __process_echoes(tty); } /** * n_tty_set_termios - termios data changed * @tty: terminal * @old: previous data * * Called by the tty layer when the user changes termios flags so * that the line discipline can plan ahead. This function cannot sleep * and is protected from re-entry by the tty layer. The user is * guaranteed that this function will not be re-entered or in progress * when the ldisc is closed. * * Locking: Caller holds tty->termios_rwsem */ static void n_tty_set_termios(struct tty_struct *tty, struct termios *old) { struct n_tty_data *ldata = tty->disc_data; if (!old || (old->c_lflag ^ tty->init_termios.c_lflag) & (ICANON | EXTPROC)) { rt_memset(ldata->read_flags, 0, RT_TTY_BUF); ldata->line_start = ldata->read_tail; if (!L_ICANON(tty) || !read_cnt(ldata)) { ldata->canon_head = ldata->read_tail; ldata->push = 0; } else { set_bit((ldata->read_head - 1) & (RT_TTY_BUF - 1),(int *)ldata->read_flags); ldata->canon_head = ldata->read_head; ldata->push = 1; } ldata->commit_head = ldata->read_head; ldata->erasing = 0; ldata->lnext = 0; } ldata->icanon = (L_ICANON(tty) != 0); if (I_ISTRIP(tty) || I_IUCLC(tty) || I_IGNCR(tty) || I_ICRNL(tty) || I_INLCR(tty) || L_ICANON(tty) || I_IXON(tty) || L_ISIG(tty) || L_ECHO(tty) || I_PARMRK(tty)) { rt_memset(ldata->char_map, 0, 256); if (I_IGNCR(tty) || I_ICRNL(tty)) { set_bit('\r', (int *)ldata->char_map); } if (I_INLCR(tty)) { set_bit('\n', (int *)ldata->char_map); } if (L_ICANON(tty)) { set_bit(ERASE_CHAR(tty), (int *)ldata->char_map); set_bit(KILL_CHAR(tty),(int *) ldata->char_map); set_bit(EOF_CHAR(tty), (int *)ldata->char_map); set_bit('\n',(int *) ldata->char_map); set_bit(EOL_CHAR(tty),(int *) ldata->char_map); if (L_IEXTEN(tty)) { set_bit(WERASE_CHAR(tty), (int *)ldata->char_map); set_bit(LNEXT_CHAR(tty), (int *)ldata->char_map); set_bit(EOL2_CHAR(tty), (int *)ldata->char_map); if (L_ECHO(tty)) { set_bit(REPRINT_CHAR(tty), (int *)ldata->char_map); } } } if (I_IXON(tty)) { set_bit(START_CHAR(tty), (int *)ldata->char_map); set_bit(STOP_CHAR(tty), (int *)ldata->char_map); } if (L_ISIG(tty)) { set_bit(INTR_CHAR(tty), (int *)ldata->char_map); set_bit(QUIT_CHAR(tty), (int *)ldata->char_map); set_bit(SUSP_CHAR(tty), (int *)ldata->char_map); } clear_bit(__DISABLED_CHAR, (int *)ldata->char_map); ldata->raw = 0; ldata->real_raw = 0; } else { ldata->raw = 1; if ((I_IGNBRK(tty) || (!I_BRKINT(tty) && !I_PARMRK(tty))) && (I_IGNPAR(tty) || !I_INPCK(tty))/* && (tty->driver->flags & TTY_DRIVER_REAL_RAW)*/) { ldata->real_raw = 1; } else { ldata->real_raw = 0; } } } void console_ldata_init(struct tty_struct *tty) { struct n_tty_data *ldata = RT_NULL; ldata = rt_malloc(sizeof(struct n_tty_data)); if (ldata == RT_NULL) { LOG_E("console_ldata_init ldata malloc fail"); return; } tty->disc_data = ldata; reset_buffer_flags(ldata); ldata->column = 0; ldata->canon_column = 0; ldata->no_room = 0; ldata->lnext = 0; n_tty_set_termios(tty, RT_NULL); return; } static int n_tty_open(struct dfs_file *fd) { int ret = 0; struct n_tty_data *ldata = RT_NULL; struct tty_struct *tty = (struct tty_struct*)fd->vnode->data; ldata = rt_malloc(sizeof(struct n_tty_data)); if (ldata == RT_NULL) { LOG_E("n_tty_open ldata malloc fail"); return -1; } ldata->atomic_read_lock = rt_mutex_create("atomic_read_lock",RT_IPC_FLAG_FIFO); if(ldata->atomic_read_lock == RT_NULL) { LOG_E("n_tty_open atomic_read_lock create fail"); return -1; } ldata->output_lock = rt_mutex_create("output_lock",RT_IPC_FLAG_FIFO); if(ldata->output_lock == RT_NULL) { LOG_E("n_tty_open output_lock create fail"); return -1; } tty->disc_data = ldata; reset_buffer_flags(ldata); ldata->column = 0; ldata->canon_column = 0; ldata->lnext = 0; n_tty_set_termios(tty, RT_NULL); return ret; } rt_inline int input_available_p(struct tty_struct *tty, int poll) { struct n_tty_data *ldata = tty->disc_data; int amt = poll && !TIME_CHAR(tty) && MIN_CHAR(tty) ? MIN_CHAR(tty) : 1; if (ldata->icanon && !L_EXTPROC(tty)) { return ldata->canon_head != ldata->read_tail; } else { return ldata->commit_head - ldata->read_tail >= amt; } } /** * copy_from_read_buf - copy read data directly * @tty: terminal device * @b: user data * @nr: size of data * * Helper function to speed up n_tty_read. It is only called when * ICANON is off; it copies characters straight from the tty queue to * user space directly. It can be profitably called twice; once to * drain the space from the tail pointer to the (physical) end of the * buffer, and once to drain the space from the (physical) beginning of * the buffer to head pointer. * * Called under the ldata->atomic_read_lock sem * * n_tty_read()/consumer path: * caller holds non-exclusive termios_rwsem * read_tail published */ static int copy_from_read_buf(struct tty_struct *tty,char *b,size_t nr) { struct n_tty_data *ldata = tty->disc_data; size_t n = 0; rt_bool_t is_eof = 0; size_t head = ldata->commit_head; size_t tail = ldata->read_tail & (RT_TTY_BUF - 1); n = min(head - ldata->read_tail, RT_TTY_BUF - tail); n = min(nr, n); if (n) { const char *from = read_buf_addr(ldata, tail); rt_memcpy(b, from, n); is_eof = n == 1 && *from == EOF_CHAR(tty); ldata->read_tail += n; /* Turn single EOF into zero-length read */ if (L_EXTPROC(tty) && ldata->icanon && is_eof && (head == ldata->read_tail)) { n = 0; } } return n; } /** * canon_copy_from_read_buf - copy read data in canonical mode * @tty: terminal device * @b: user data * @nr: size of data * * Helper function for n_tty_read. It is only called when ICANON is on; * it copies one line of input up to and including the line-delimiting * character into the user-space buffer. * * NB: When termios is changed from non-canonical to canonical mode and * the read buffer contains data, n_tty_set_termios() simulates an EOF * push (as if C-d were input) _without_ the DISABLED_CHAR in the buffer. * This causes data already processed as input to be immediately available * as input although a newline has not been received. * * Called under the atomic_read_lock mutex * * n_tty_read()/consumer path: * caller holds non-exclusive termios_rwsem * read_tail published */ static int canon_copy_from_read_buf(struct tty_struct *tty, char *b, size_t nr) { struct n_tty_data *ldata = tty->disc_data; size_t n = 0, size = 0, more = 0, c = 0; size_t eol = 0; size_t tail = 0; int found = 0; /* N.B. avoid overrun if nr == 0 */ if (nr == 0) { return 0; } n = min(nr + 1, ldata->canon_head - ldata->read_tail); tail = ldata->read_tail & (RT_TTY_BUF - 1); size = min(tail + n, RT_TTY_BUF); eol = find_next_bit(ldata->read_flags, size, tail); more = n - (size - tail); if (eol == RT_TTY_BUF && more) { /* scan wrapped without finding set bit */ eol = find_next_bit(ldata->read_flags, more, 0); found = eol != more; } else { found = eol != size; } n = eol - tail; if (n > RT_TTY_BUF) { n += RT_TTY_BUF; } c = n + found; if (!found || read_buf(ldata, eol) != __DISABLED_CHAR) { c = min(nr, c); n = c; } size_t buf_size = RT_TTY_BUF - tail; const void *from = read_buf_addr(ldata, tail); if (n > buf_size) { rt_memcpy(b, from, buf_size); b += buf_size; n -= buf_size; from = ldata->read_buf; } rt_memcpy(b, from, n); if (found) { clear_bit(eol, (int *)ldata->read_flags); } ldata->read_tail = ldata->read_tail + c; if (found) { if (!ldata->push) { ldata->line_start = ldata->read_tail; } else { ldata->push = 0; } } return n; } static int n_tty_close(struct tty_struct *tty) { int ret = 0; struct n_tty_data *ldata = RT_NULL; struct tty_struct *o_tty = RT_NULL; RT_ASSERT(tty != RT_NULL); if (tty->type == TTY_DRIVER_TYPE_PTY && tty->subtype == PTY_TYPE_MASTER) { o_tty = tty->other_struct; } else { o_tty = tty; } ldata = o_tty->disc_data; rt_free(ldata); o_tty->disc_data = RT_NULL; return ret; } static int n_tty_ioctl(struct dfs_file *fd, int cmd, void *args) { int ret = 0; struct tty_struct *real_tty = RT_NULL; struct tty_struct *tty = RT_NULL; tty = (struct tty_struct *)fd->vnode->data; RT_ASSERT(tty != RT_NULL); if (tty->type == TTY_DRIVER_TYPE_PTY && tty->subtype == PTY_TYPE_MASTER) { real_tty = tty->other_struct; } else { real_tty = tty; } switch(cmd) { default: ret = n_tty_ioctl_extend(real_tty, cmd, args); if (ret != -ENOIOCTLCMD) { return ret; } } ret = rt_device_control((rt_device_t)real_tty, cmd, args); if (ret != -ENOIOCTLCMD) { return ret; } return ret; } static void n_tty_receive_signal_char(struct tty_struct *tty, int signal, unsigned char c) { isig(signal, tty); if (L_ECHO(tty)) { echo_char(c, tty); commit_echoes(tty); } else { process_echoes(tty); } return; } /** * n_tty_receive_char - perform processing * @tty: terminal device * @c: character * * Process an individual character of input received from the driver. * This is serialized with respect to itself by the rules for the * driver above. * * n_tty_receive_buf()/producer path: * caller holds non-exclusive termios_rwsem * publishes canon_head if canonical mode is active * * Returns 1 if LNEXT was received, else returns 0 */ static int n_tty_receive_char_special(struct tty_struct *tty, unsigned char c) { struct n_tty_data *ldata = tty->disc_data; if (I_IXON(tty)) { if (c == START_CHAR(tty)) /*ctrl + p realize missing*/ { process_echoes(tty); return 0; } if (c == STOP_CHAR(tty)) /*ctrl + s realize missing*/ { return 0; } } if (L_ISIG(tty)) { if (c == INTR_CHAR(tty)) /*ctrl + c realize missing*/ { n_tty_receive_signal_char(tty, SIGINT, c); return 0; } else if (c == QUIT_CHAR(tty)) /*ctrl + d realize missing*/ { n_tty_receive_signal_char(tty, SIGQUIT, c); return 0; } else if (c == SUSP_CHAR(tty)) /*ctrl + z realize missing*/ { n_tty_receive_signal_char(tty, SIGTSTP, c); return 0; } } if (c == '\r') { if (I_IGNCR(tty)) { return 0; } if (I_ICRNL(tty)) { c = '\n'; } } else if (c == '\n' && I_INLCR(tty)) { c = '\r'; } if (ldata->icanon) { if (c == ERASE_CHAR(tty) || c == KILL_CHAR(tty) || (c == WERASE_CHAR(tty) && L_IEXTEN(tty))) { eraser(c, tty); commit_echoes(tty); return 0; } if (c == LNEXT_CHAR(tty) && L_IEXTEN(tty)) { ldata->lnext = 1; if (L_ECHO(tty)) { finish_erasing(ldata); if (L_ECHOCTL(tty)) { echo_char_raw('^', ldata); echo_char_raw('\b', ldata); commit_echoes(tty); } } return 1; } if (c == REPRINT_CHAR(tty) && L_ECHO(tty) && L_IEXTEN(tty)) { size_t tail = ldata->canon_head; finish_erasing(ldata); echo_char(c, tty); echo_char_raw('\n', ldata); while (tail != ldata->read_head) { echo_char(read_buf(ldata, tail), tty); tail++; } commit_echoes(tty); return 0; } if (c == '\n') { if (L_ECHO(tty) || L_ECHONL(tty)) { echo_char_raw('\n', ldata); commit_echoes(tty); } goto handle_newline; } if (c == EOF_CHAR(tty)) { c = __DISABLED_CHAR; goto handle_newline; } if ((c == EOL_CHAR(tty)) || (c == EOL2_CHAR(tty) && L_IEXTEN(tty))) { /* * XXX are EOL_CHAR and EOL2_CHAR echoed?!? */ if (L_ECHO(tty)) { /* Record the column of first canon char. */ if (ldata->canon_head == ldata->read_head) { echo_set_canon_col(ldata); } echo_char(c, tty); commit_echoes(tty); } /* * XXX does PARMRK doubling happen for * EOL_CHAR and EOL2_CHAR? */ if (c == (unsigned char) '\377' && I_PARMRK(tty)) { put_tty_queue(c, ldata); } handle_newline: set_bit(ldata->read_head & (RT_TTY_BUF - 1), (int *)ldata->read_flags); put_tty_queue(c, ldata); ldata->canon_head = ldata->read_head; tty_wakeup_check(tty); return 0; } } if (L_ECHO(tty)) { finish_erasing(ldata); if (c == '\n') { echo_char_raw('\n', ldata); } else { /* Record the column of first canon char. */ if (ldata->canon_head == ldata->read_head) { echo_set_canon_col(ldata); } echo_char(c, tty); } commit_echoes(tty); } /* PARMRK doubling check */ if (c == (unsigned char) '\377' && I_PARMRK(tty)) { put_tty_queue(c, ldata); } put_tty_queue(c, ldata); return 0; } rt_inline void n_tty_receive_char_inline(struct tty_struct *tty, unsigned char c) { struct n_tty_data *ldata = tty->disc_data; if (L_ECHO(tty)) { finish_erasing(ldata); /* Record the column of first canon char. */ if (ldata->canon_head == ldata->read_head) { echo_set_canon_col(ldata); } echo_char(c, tty); commit_echoes(tty); } /* PARMRK doubling check */ if (c == (unsigned char) '\377' && I_PARMRK(tty)) { put_tty_queue(c, ldata); } put_tty_queue(c, ldata); } static void n_tty_receive_char(struct tty_struct *tty, unsigned char c) { n_tty_receive_char_inline(tty, c); } static void n_tty_receive_char_lnext(struct tty_struct *tty, unsigned char c, char flag) { struct n_tty_data *ldata = tty->disc_data; ldata->lnext = 0; if (flag == TTY_NORMAL) { if (I_ISTRIP(tty)) { c &= 0x7f; } if (I_IUCLC(tty) && L_IEXTEN(tty)) { c = tolower(c); } n_tty_receive_char(tty, c); } else { //n_tty_receive_char_flagged(tty, c, flag); } } static void n_tty_receive_buf_real_raw(struct tty_struct *tty, char *cp, int count) { struct n_tty_data *ldata = tty->disc_data; size_t n = 0, head = 0; head = ldata->read_head & (RT_TTY_BUF - 1); n = min(count, RT_TTY_BUF - head); rt_memcpy(read_buf_addr(ldata, head), cp, n); ldata->read_head += n; cp += n; count -= n; head = ldata->read_head & (RT_TTY_BUF - 1); n = min(count, RT_TTY_BUF - head); rt_memcpy(read_buf_addr(ldata, head), cp, n); ldata->read_head += n; } static void n_tty_receive_buf_raw(struct tty_struct *tty, char *cp, int count) { struct n_tty_data *ldata = tty->disc_data; char flag = TTY_NORMAL; while (count--) { if (flag == TTY_NORMAL) { put_tty_queue(*cp++, ldata); } } } static void n_tty_receive_buf_standard(struct tty_struct *tty, char *cp, int count) { struct n_tty_data *ldata = tty->disc_data; char flag = TTY_NORMAL; while (count--) { char c = *cp++; if (I_ISTRIP(tty)) { c &= 0x7f; } if (I_IUCLC(tty) && L_IEXTEN(tty)) { c = tolower(c); } if (L_EXTPROC(tty)) { put_tty_queue(c, ldata); continue; } if (!test_bit(c, (int *)ldata->char_map)) { n_tty_receive_char_inline(tty, c); } else if (n_tty_receive_char_special(tty, c) && count) { n_tty_receive_char_lnext(tty, *cp++, flag); count--; } } } rt_inline void n_tty_receive_char_fast(struct tty_struct *tty, unsigned char c) { struct n_tty_data *ldata = tty->disc_data; if (L_ECHO(tty)) { finish_erasing(ldata); /* Record the column of first canon char. */ if (ldata->canon_head == ldata->read_head) { echo_set_canon_col(ldata); } echo_char(c, tty); commit_echoes(tty); } put_tty_queue(c, ldata); } static void n_tty_receive_buf_fast(struct tty_struct *tty, char *cp, int count) { struct n_tty_data *ldata = tty->disc_data; char flag = TTY_NORMAL; while (count--) { unsigned char c = *cp++; if (!test_bit(c, (int *)ldata->char_map)) { n_tty_receive_char_fast(tty, c); } else if (n_tty_receive_char_special(tty, c) && count) { n_tty_receive_char_lnext(tty, *cp++, flag); count--; } } } static void __receive_buf(struct tty_struct *tty, char *cp, int count) { struct n_tty_data *ldata = tty->disc_data; rt_bool_t preops = I_ISTRIP(tty) || (I_IUCLC(tty) && L_IEXTEN(tty)); if (ldata->real_raw) { n_tty_receive_buf_real_raw(tty, cp, count); } else if (ldata->raw || (L_EXTPROC(tty) && !preops)) { n_tty_receive_buf_raw(tty, cp, count); } else { if (!preops && !I_PARMRK(tty)) { n_tty_receive_buf_fast(tty, cp, count); } else { n_tty_receive_buf_standard(tty, cp, count); } flush_echoes(tty); } if (ldata->icanon && !L_EXTPROC(tty)) return; /* publish read_head to consumer */ ldata->commit_head = ldata->read_head; if (read_cnt(ldata)) { tty_wakeup_check(tty); } } int n_tty_receive_buf(struct tty_struct *tty,char *cp, int count) { int size = 0; struct n_tty_data *ldata = tty->disc_data; int room = 0, n = 0, rcvd = 0, overflow = 0; size = count; while(1) { size_t tail = ldata->read_tail; room = RT_TTY_BUF - (ldata->read_head - tail); if (I_PARMRK(tty)) { room = (room +2)/3; } room--; if (room <= 0) { overflow = ldata->icanon && ldata->canon_head == tail; if (overflow && room < 0) { ldata->read_head--; } room = overflow; } else { overflow = 0; } n = min(size, room); if (!n) { break; } if (!overflow) { __receive_buf(tty, cp, n); } cp += n; size -= n; rcvd += n; } return count - size; } /** * job_control - check job control * @tty: tty * @file: file handle * * Perform job control management checks on this file/tty descriptor * and if appropriate send any needed signals and return a negative * error code if action should be taken. * * Locking: redirected write test is safe * current->signal->tty check is safe * ctrl_lock to safely reference tty->pgrp */ static int job_control(struct tty_struct *tty) { return __tty_check_change(tty, SIGTTIN); } static int n_tty_read(struct dfs_file *fd, void *buf, size_t count) { int level = 0; char *b = (char *)buf; struct tty_struct *tty = RT_NULL; struct rt_lwp *lwp = RT_NULL; struct rt_wqueue *wq = RT_NULL; int wait_ret = 0; int retval = 0; int c = 0; level = rt_hw_interrupt_disable(); tty = (struct tty_struct *)fd->vnode->data; RT_ASSERT(tty != RT_NULL); c = job_control(tty); if (c < 0) { rt_hw_interrupt_enable(level); return c; } struct n_tty_data *ldata = tty->disc_data; lwp = (struct rt_lwp *)(rt_thread_self()->lwp); wq = wait_queue_get(lwp, tty); while(count) { if ((!input_available_p(tty, 0))) { if (fd->flags & O_NONBLOCK) { retval = -EAGAIN; break; } wait_ret = rt_wqueue_wait_interruptible(wq, 0, RT_WAITING_FOREVER); if (wait_ret != 0) { break; } } if (ldata->icanon && !L_EXTPROC(tty)) { retval = canon_copy_from_read_buf(tty, b, count); } else { retval = copy_from_read_buf(tty, b, count); } if (retval >= 1) { break; } } rt_hw_interrupt_enable(level); return retval; } static int n_tty_write(struct dfs_file *fd, const void *buf, size_t count) { int retval = 0; char *b = (char *)buf; int c = 0; struct tty_struct *tty = RT_NULL; tty = (struct tty_struct *)fd->vnode->data; RT_ASSERT(tty != RT_NULL); retval = tty_check_change(tty); if (retval) { return retval; } process_echoes(tty); retval = count; while(1) { if (O_OPOST(tty)) { while (count > 0) { ssize_t num = process_output_block(tty, b, count); if (num < 0) { if (num == -EAGAIN) { break; } retval = num; goto break_out; } b += num; count -= num; if (count == 0) { break; } c = *b; if (process_output(c, tty) < 0) { break; } b++; count--; } retval -= count; } else { while (count > 0) { c = rt_device_write((rt_device_t)tty, -1, b, count); if (c < 0) { retval = c; goto break_out; } b += c; count -= c; } retval -= count; } if (!count) { break; } if (fd->flags & O_NONBLOCK) { break; } } break_out: return retval; } static int n_tty_flush(struct dfs_file *fd) { return 0; } static int n_tty_lseek(struct dfs_file *fd, off_t offset) { return 0; } static int n_tty_getdents(struct dfs_file *fd, struct dirent *dirp, uint32_t count) { return 0; } static int n_tty_poll(struct dfs_file *fd, struct rt_pollreq *req) { rt_base_t level = 0; int mask = POLLOUT; struct tty_struct *tty = RT_NULL; struct rt_wqueue *wq = RT_NULL; struct rt_lwp *lwp = RT_NULL; tty = (struct tty_struct *)fd->vnode->data; RT_ASSERT(tty != RT_NULL); RT_ASSERT(tty->init_flag == TTY_INIT_FLAG_INITED); lwp = (struct rt_lwp *)(rt_thread_self()->lwp); wq = wait_queue_get(lwp, tty); rt_poll_add(wq, req); level = rt_hw_interrupt_disable(); if (input_available_p(tty, 1)) { mask |= POLLIN; } rt_hw_interrupt_enable(level); return mask; } struct tty_ldisc_ops n_tty_ops = { "n_tty", 0, n_tty_open, n_tty_close, n_tty_ioctl, n_tty_read, n_tty_write, n_tty_flush, n_tty_lseek, n_tty_getdents, n_tty_poll, n_tty_set_termios, n_tty_receive_buf, 0, };