kernel: restore setting KTS_NONE

[minix.git] / commands / mined / mined2.c

/*
 * Part 2 of the mined editor.
 */

/*  ========================================================================  *
 *                              Move Commands                                 * 
 *  ========================================================================  */

#include "mined.h"
#include <string.h>

/*
 * Move one line up.
 */
void UP()
{
  if (y == 0) {         /* Top line of screen. Scroll one line */
        (void) reverse_scroll();
        move_to(x, y);
  }
  else                  /* Move to previous line */
        move_to(x, y - 1);
}

/*
 * Move one line down.
 */
void DN()
{
  if (y == last_y) {    /* Last line of screen. Scroll one line */
        if (bot_line->next == tail && bot_line->text[0] != '\n') {
                dummy_line();           /* Create new empty line */
                DN();
                return;
        }
        else {
                (void) forward_scroll();
                move_to(x, y);
        }
  }
  else                  /* Move to next line */
        move_to(x, y + 1);
}

/*
 * Move left one position.
 */
void LF()
{
  if (x == 0 && get_shift(cur_line->shift_count) == 0) {/* Begin of line */
        if (cur_line->prev != header) {
                UP();                                   /* Move one line up */
                move_to(LINE_END, y);
        }
  }
  else
        move_to(x - 1, y);
}

/*
 * Move right one position.
 */
void RT()
{
  if (*cur_text == '\n') {
        if (cur_line->next != tail) {           /* Last char of file */
                DN();                           /* Move one line down */
                move_to(LINE_START, y);
        }
  }
  else
        move_to(x + 1, y);
}

/*
 * Move to coordinates [0, 0] on screen.
 */
void HIGH()
{
  move_to(0, 0);
}

/*
 * Move to coordinates [0, YMAX] on screen.
 */
void LOW()
{
  move_to(0, last_y);
}

/*
 * Move to begin of line.
 */
void BL()
{
  move_to(LINE_START, y);
}

/*
 * Move to end of line.
 */
void EL()
{
  move_to(LINE_END, y);
}

/*
 * GOTO() prompts for a linenumber and moves to that line.
 */
void GOTO()
{
  int number;
  LINE *line;

  if (get_number("Please enter line number.", &number) == ERRORS)
        return;

  if (number <= 0 || (line = proceed(header->next, number - 1)) == tail)
        error("Illegal line number: ", num_out((long) number));
  else
        move_to(x, find_y(line));
}

/*
 * Scroll forward one page or to eof, whatever comes first. (Bot_line becomes 
 * top_line of display.) Try to leave the cursor on the same line. If this is
 * not possible, leave cursor on the line halfway the page.
 */
void PD()
{
  register int i;

  for (i = 0; i < screenmax; i++)
        if (forward_scroll() == ERRORS)
                break;                  /* EOF reached */
  if (y - i < 0)                                /* Line no longer on screen */
        move_to(0, screenmax >> 1);
  else
        move_to(0, y - i);
}


/*
 * Scroll backwards one page or to top of file, whatever comes first. (Top_line
 * becomes bot_line of display).  The very bottom line (YMAX) is always blank.
 * Try to leave the cursor on the same line. If this is not possible, leave
 * cursor on the line halfway the page.
 */
void PU()
{
  register int i;

  for (i = 0; i < screenmax; i++)
        if (reverse_scroll() == ERRORS)
                break;                  /* Top of file reached */
  set_cursor(0, ymax);                  /* Erase very bottom line */
#ifdef UNIX
  tputs(CE, 0, _putchar);
#else
  string_print(blank_line);
#endif /* UNIX */
  if (y + i > screenmax)                        /* line no longer on screen */
        move_to(0, screenmax >> 1);
  else
        move_to(0, y + i);
}

/*
 * Go to top of file, scrolling if possible, else redrawing screen.
 */
void HO()
{
  if (proceed(top_line, -screenmax) == header)
        PU();                   /* It fits. Let PU do it */
  else {
        reset(header->next, 0);/* Reset top_line, etc. */
        RD();                   /* Display full page */
  }
  move_to(LINE_START, 0);
}

/*
 * Go to last line of file, scrolling if possible, else redrawing screen
 */
void EF()
{
  if (tail->prev->text[0] != '\n')
        dummy_line();
  if (proceed(bot_line, screenmax) == tail)
        PD();                   /* It fits. Let PD do it */
  else {
        reset(proceed(tail->prev, -screenmax), screenmax);
        RD();                   /* Display full page */
  }
  move_to(LINE_START, last_y);
}

/*
 * Scroll one line up. Leave the cursor on the same line (if possible).
 */
void SU()
{
  if (top_line->prev == header) /* Top of file. Can't scroll */
        return;

  (void) reverse_scroll();
  set_cursor(0, ymax);          /* Erase very bottom line */
#ifdef UNIX
  tputs(CE, 0, _putchar);
#else
  string_print(blank_line);
#endif /* UNIX */
  move_to(x, (y == screenmax) ? screenmax : y + 1);
}

/*
 * Scroll one line down. Leave the cursor on the same line (if possible).
 */
void SD()
{
  if (forward_scroll() != ERRORS) 
        move_to(x, (y == 0) ? 0 : y - 1);
  else
        set_cursor(x, y);
}

/*
 * Perform a forward scroll. It returns ERRORS if we're at the last line of the
 * file.
 */
int forward_scroll()
{
  if (bot_line->next == tail)           /* Last line of file. No dice */
        return ERRORS;
  top_line = top_line->next;
  bot_line = bot_line->next;
  cur_line = cur_line->next;
  set_cursor(0, ymax);
  line_print(bot_line);

  return FINE;
}

/*
 * Perform a backwards scroll. It returns ERRORS if we're at the first line
 * of the file.
 */
int reverse_scroll()
{
  if (top_line->prev == header)
        return ERRORS;          /* Top of file. Can't scroll */

  if (last_y != screenmax)      /* Reset last_y if necessary */
        last_y++;
  else
        bot_line = bot_line->prev;      /* Else adjust bot_line */
  top_line = top_line->prev;
  cur_line = cur_line->prev;

/* Perform the scroll */
  set_cursor(0, 0);
#ifdef UNIX
  tputs(AL, 0, _putchar);
#else
  string_print(rev_scroll);
#endif /* UNIX */
  set_cursor(0, 0);
  line_print(top_line);

  return FINE;
}

/*
 * A word is defined as a number of non-blank characters separated by tabs
 * spaces or linefeeds.
 */

/*
 * MP() moves to the start of the previous word. A word is defined as a
 * number of non-blank characters separated by tabs spaces or linefeeds.
 */
void MP()
{
  move_previous_word(NO_DELETE);
}

void move_previous_word(remove)
FLAG remove;
{
  register char *begin_line;
  register char *textp;
  char start_char = *cur_text;
  char *start_pos = cur_text;

/* Fist check if we're at the beginning of line. */
  if (cur_text == cur_line->text) {
        if (cur_line->prev == header)
                return;
        start_char = '\0';
  }

  LF();

  begin_line = cur_line->text;
  textp = cur_text;

/* Check if we're in the middle of a word. */
  if (!alpha(*textp) || !alpha(start_char)) {
        while (textp != begin_line && (white_space(*textp) || *textp == '\n'))
                textp--;
  }

/* Now we're at the end of previous word. Skip non-blanks until a blank comes */
  while (textp != begin_line && alpha(*textp))
        textp--;

/* Go to the next char if we're not at the beginning of the line */
  if (textp != begin_line && *textp != '\n')
        textp++;

/* Find the x-coordinate of this address, and move to it */
  move_address(textp);
  if (remove == DELETE)
        delete(cur_line, textp, cur_line, start_pos);
}

/*
 * MN() moves to the start of the next word. A word is defined as a number of
 * non-blank characters separated by tabs spaces or linefeeds. Always keep in
 * mind that the pointer shouldn't pass the '\n'.
 */
void MN()
{
  move_next_word(NO_DELETE);
}

void move_next_word(remove)
FLAG remove;
{
  register char *textp = cur_text;

/* Move to the end of the current word. */
  while (*textp != '\n' && alpha(*textp))
        textp++;

/* Skip all white spaces */
  while (*textp != '\n' && white_space(*textp))
        textp++;
/* If we're deleting. delete the text in between */
  if (remove == DELETE) {
        delete(cur_line, cur_text, cur_line, textp);
        return;
  }

/* If we're at end of line. move to the first word on the next line. */
  if (*textp == '\n' && cur_line->next != tail) {
        DN();
        move_to(LINE_START, y);
        textp = cur_text;
        while (*textp != '\n' && white_space(*textp))
                textp++;
  }
  move_address(textp);
}

/*  ========================================================================  *
 *                              Modify Commands                               *
 *  ========================================================================  */

/*
 * DCC deletes the character under the cursor.  If this character is a '\n' the
 * current line is joined with the next one.
 * If this character is the only character of the line, the current line will
 * be deleted.
 */
void DCC()
{
  if (*cur_text == '\n')
        delete(cur_line,cur_text, cur_line->next,cur_line->next->text);
  else
        delete(cur_line, cur_text, cur_line, cur_text + 1);
}

/*
 * DPC deletes the character on the left side of the cursor.  If the cursor is
 * at the beginning of the line, the last character if the previous line is
 * deleted. 
 */
void DPC()
{
  if (x == 0 && cur_line->prev == header)
        return;                 /* Top of file */
  
  LF();                         /* Move one left */
  DCC();                                /* Delete character under cursor */
}

/*
 * DLN deletes all characters until the end of the line. If the current
 * character is a '\n', then delete that char.
 */
void DLN()
{
  if (*cur_text == '\n')
        DCC();
  else
        delete(cur_line, cur_text, cur_line, cur_text + length_of(cur_text) -1);
}

/*
 * DNW() deletes the next word (as described in MN())
 */
void DNW()
{
  if (*cur_text == '\n')
        DCC();
  else
        move_next_word(DELETE);
}

/*
 * DPW() deletes the next word (as described in MP())
 */
void DPW()
{
  if (cur_text == cur_line->text)
        DPC();
  else
        move_previous_word(DELETE);
}

/*
 * Insert character `character' at current location.
 */
void S(character)
register char character;
{
  static char buffer[2];

  buffer[0] = character;
/* Insert the character */
  if (insert(cur_line, cur_text, buffer) == ERRORS)
        return;

/* Fix screen */
  if (character == '\n') {
        set_cursor(0, y);
        if (y == screenmax) {           /* Can't use display */
                line_print(cur_line);
                (void) forward_scroll();
        }
        else {
                reset(top_line, y);     /* Reset pointers */
                display(0, y, cur_line, last_y - y);
        }
        move_to(0, (y == screenmax) ? y : y + 1);
  }
  else if (x + 1 == XBREAK)/* If line must be shifted, just call move_to*/
        move_to(x + 1, y);
  else {                         /* else display rest of line */
        put_line(cur_line, x, FALSE);
        move_to(x + 1, y);
  }
}

/*
 * CTL inserts a control-char at the current location. A message that this
 * function is called is displayed at the status line.
 */
void CTL()
{
  register char ctrl;

  status_line("Enter control character.", NULL);
  if ((ctrl = getchar()) >= '\01' && ctrl <= '\037') {
        S(ctrl);                /* Insert the char */
        clear_status();
  }
  else
        error ("Unknown control character", NULL);
}

/*
 * LIB insert a line at the current position and moves back to the end of
 * the previous line.
 */
void LIB()
{
  S('\n');                      /* Insert the line */
  UP();                         /* Move one line up */
  move_to(LINE_END, y);         /* Move to end of this line */
}

/*
 * Line_insert() inserts a new line with text pointed to by `string'.
 * It returns the address of the new line.
 */
LINE *line_insert(line, string, len)
register LINE *line;
char *string;
int len;
{
  register LINE *new_line;

/* Allocate space for LINE structure and text */
  new_line = install_line(string, len);

/* Install the line into the double linked list */
  new_line->prev = line;
  new_line->next = line->next;
  line->next = new_line;
  new_line->next->prev = new_line;

/* Increment nlines */
  nlines++;

  return new_line;
}

/*
 * Insert() insert the string `string' at the given line and location.
 */
int insert(line, location, string)
register LINE *line;
char *location, *string;
{
  register char *bufp = text_buffer;    /* Buffer for building line */
  register char *textp = line->text;

  if (length_of(textp) + length_of(string) >= MAX_CHARS) {
        error("Line too long", NULL);
        return ERRORS;
  }

  modified = TRUE;                      /* File has been modified */

/* Copy part of line until `location' has been reached */
  while (textp != location)
        *bufp++ = *textp++;
  
/* Insert string at this location */
  while (*string != '\0')
        *bufp++ = *string++;
  *bufp = '\0';
  
  if (*(string - 1) == '\n')            /* Insert a new line */
        (void) line_insert(line, location, length_of(location));
  else                                  /* Append last part of line */
        copy_string(bufp, location);

/* Install the new text in this line */
  free_space(line->text);
  line->text = alloc(length_of(text_buffer) + 1);
  copy_string(line->text, text_buffer);

  return FINE;
}

/*
 * Line_delete() deletes the argument line out of the line list. The pointer to
 * the next line is returned.
 */
LINE *line_delete(line)
register LINE *line;
{
  register LINE *next_line = line->next;

/* Delete the line */
  line->prev->next = line->next;
  line->next->prev = line->prev;

/* Free allocated space */
  free_space(line->text);
  free_space((char*)line);

/* Decrement nlines */
  nlines--;

  return next_line;
}

/*
 * Delete() deletes all the characters (including newlines) between the
 * startposition and endposition and fixes the screen accordingly. It
 * returns the number of lines deleted.
 */
void delete(start_line, start_textp, end_line, end_textp)
register LINE *start_line;
LINE *end_line;
char *start_textp, *end_textp;
{
  register char *textp = start_line->text;
  register char *bufp = text_buffer;    /* Storage for new line->text */
  LINE *line, *stop;
  int line_cnt = 0;                     /* Nr of lines deleted */
  int count = 0;
  int shift = 0;                                /* Used in shift calculation */
  int nx = x;

  modified = TRUE;                      /* File has been modified */

/* Set up new line. Copy first part of start line until start_position. */
  while (textp < start_textp) {
        *bufp++ = *textp++;
        count++;
  }

/* Check if line doesn't exceed MAX_CHARS */
  if (count + length_of(end_textp) >= MAX_CHARS) {
        error("Line too long", NULL);
        return;
  }

/* Copy last part of end_line if end_line is not tail */
  copy_string(bufp, (end_textp != NULL) ? end_textp : "\n");

/* Delete all lines between start and end_position (including end_line) */
  line = start_line->next;
  stop = end_line->next;
  while (line != stop && line != tail) {
        line = line_delete(line);
        line_cnt++;
  }

/* Check if last line of file should be deleted */
  if (end_textp == NULL && length_of(start_line->text) == 1 && nlines > 1) {
        start_line = start_line->prev;
        (void) line_delete(start_line->next);
        line_cnt++;
  }
  else {        /* Install new text */
        free_space(start_line->text);
        start_line->text = alloc(length_of(text_buffer) + 1);
        copy_string(start_line->text, text_buffer);
  }

/* Fix screen. First check if line is shifted. Perhaps we should shift it back*/
  if (get_shift(start_line->shift_count)) {
        shift = (XBREAK - count_chars(start_line)) / SHIFT_SIZE;
        if (shift > 0) {                /* Shift line `shift' back */
                if (shift >= get_shift(start_line->shift_count))
                        start_line->shift_count = 0;
                else
                        start_line->shift_count -= shift;
                nx += shift * SHIFT_SIZE;/* Reset x value */
        }
  }

  if (line_cnt == 0) {              /* Check if only one line changed */
        if (shift > 0) {            /* Reprint whole line */
                set_cursor(0, y);
                line_print(start_line);
        }
        else {                      /* Just display last part of line */
                set_cursor(x, y);
                put_line(start_line, x, TRUE);
        }
        move_to(nx, y);    /* Reset cur_text */
        return;
  }

  shift = last_y;          /* Save value */
  reset(top_line, y);
  display(0, y, start_line, shift - y);
  move_to((line_cnt == 1) ? nx : 0, y);
}

/*  ========================================================================  *
 *                              Yank Commands                                 * 
 *  ========================================================================  */

LINE *mark_line;                        /* For marking position. */
char *mark_text;
int lines_saved;                        /* Nr of lines in buffer */

/*
 * PT() inserts the buffer at the current location.
 */
void PT()
{
  register int fd;              /* File descriptor for buffer */

  if ((fd = scratch_file(READ)) == ERRORS)
        error("Buffer is empty.", NULL);
  else {
        file_insert(fd, FALSE);/* Insert the buffer */
        (void) close(fd);
  }
}

/*
 * IF() prompt for a filename and inserts the file at the current location 
 * in the file.
 */
void IF()
{
  register int fd;              /* File descriptor of file */
  char name[LINE_LEN];          /* Buffer for file name */

/* Get the file name */
  if (get_file("Get and insert file:", name) != FINE)
        return;
  
  if ((fd = open(name, 0)) < 0)
        error("Cannot open ", name);
  else {
        file_insert(fd, TRUE);  /* Insert the file */
        (void) close(fd);
  }
}

/*
 * File_insert() inserts a an opened file (as given by filedescriptor fd)
 * at the current location.
 */
void file_insert(fd, old_pos)
int fd;
FLAG old_pos;
{
  char line_buffer[MAX_CHARS];          /* Buffer for next line */
  register LINE *line = cur_line;
  register int line_count = nlines;     /* Nr of lines inserted */
  LINE *page = cur_line;
  int ret = ERRORS;
  
/* Get the first piece of text (might be ended with a '\n') from fd */
  if (get_line(fd, line_buffer) == ERRORS)
        return;                         /* Empty file */

/* Insert this text at the current location. */
  if (insert(line, cur_text, line_buffer) == ERRORS)
        return;

/* Repeat getting lines (and inserting lines) until EOF is reached */
  while ((ret = get_line(fd, line_buffer)) != ERRORS && ret != NO_LINE)
        line = line_insert(line, line_buffer, ret);
  
  if (ret == NO_LINE) {         /* Last line read not ended by a '\n' */
        line = line->next;
        (void) insert(line, line->text, line_buffer);
  }

/* Calculate nr of lines added */
  line_count = nlines - line_count;

/* Fix the screen */
  if (line_count == 0) {                /* Only one line changed */
        set_cursor(0, y);
        line_print(line);
        move_to((old_pos == TRUE) ? x : x + length_of(line_buffer), y);
  }
  else {                                /* Several lines changed */
        reset(top_line, y);     /* Reset pointers */
        while (page != line && page != bot_line->next)
                page = page->next;
        if (page != bot_line->next || old_pos == TRUE)
                display(0, y, cur_line, screenmax - y);
        if (old_pos == TRUE)
                move_to(x, y);
        else if (ret == NO_LINE)
                move_to(length_of(line_buffer), find_y(line));
        else 
                move_to(0, find_y(line->next));
  }

/* If nr of added line >= REPORT, print the count */
  if (line_count >= REPORT)
        status_line(num_out((long) line_count), " lines added.");
}

/*
 * WB() writes the buffer (yank_file) into another file, which
 * is prompted for.
 */
void WB()
{
  register int new_fd;          /* Filedescriptor to copy file */
  int yank_fd;                  /* Filedescriptor to buffer */
  register int cnt;             /* Count check for read/write */
  int ret = 0;                  /* Error check for write */
  char file[LINE_LEN];          /* Output file */
  
/* Checkout the buffer */
  if ((yank_fd = scratch_file(READ)) == ERRORS) {
        error("Buffer is empty.", NULL);
        return;
  }

/* Get file name */
  if (get_file("Write buffer to file:", file) != FINE)
        return;
  
/* Creat the new file */
  if ((new_fd = creat(file, 0644)) < 0) {
        error("Cannot create ", file);
        return;
  }

  status_line("Writing ", file);
  
/* Copy buffer into file */
  while ((cnt = read(yank_fd, text_buffer, sizeof(text_buffer))) > 0)
        if (write(new_fd, text_buffer, cnt) != cnt) {
                bad_write(new_fd);
                ret = ERRORS;
                break;
        }

/* Clean up open files and status_line */
  (void) close(new_fd);
  (void) close(yank_fd);

  if (ret != ERRORS)                    /* Bad write */
        file_status("Wrote", chars_saved, file, lines_saved, TRUE, FALSE);
}

/*
 * MA sets mark_line (mark_text) to the current line (text pointer). 
 */
void MA()
{
  mark_line = cur_line;
  mark_text = cur_text;
  status_line("Mark set", NULL);
}

/*
 * YA() puts the text between the marked position and the current
 * in the buffer.
 */
void YA()
{
  set_up(NO_DELETE);
}

/*
 * DT() is essentially the same as YA(), but in DT() the text is deleted.
 */
void DT()
{
  set_up(DELETE);
}

/*
 * Set_up is an interface to the actual yank. It calls checkmark () to check
 * if the marked position is still valid. If it is, yank is called with the
 * arguments in the right order.
 */
void set_up(remove)
FLAG remove;                            /* DELETE if text should be deleted */
{
  switch (checkmark()) {
        case NOT_VALID :
                error("Mark not set.", NULL);
                return;
        case SMALLER :
                yank(mark_line, mark_text, cur_line, cur_text, remove);
                break;
        case BIGGER :
                yank(cur_line, cur_text, mark_line, mark_text, remove);
                break;
        case SAME :             /* Ignore stupid behaviour */
                yank_status = EMPTY;
                chars_saved = 0L;
                status_line("0 characters saved in buffer.", NULL);
                break;
  }
}

/*
 * Check_mark() checks if mark_line and mark_text are still valid pointers. If
 * they are it returns SMALLER if the marked position is before the current,
 * BIGGER if it isn't or SAME if somebody didn't get the point.
 * NOT_VALID is returned when mark_line and/or mark_text are no longer valid.
 * Legal() checks if mark_text is valid on the mark_line.
 */
FLAG checkmark()
{
  register LINE *line;
  FLAG cur_seen = FALSE;

/* Special case: check is mark_line and cur_line are the same. */
  if (mark_line == cur_line) {
        if (mark_text == cur_text)      /* Even same place */
                return SAME;
        if (legal() == ERRORS)          /* mark_text out of range */
                return NOT_VALID;
        return (mark_text < cur_text) ? SMALLER : BIGGER;
  }

/* Start looking for mark_line in the line structure */
  for (line = header->next; line != tail; line = line->next) {
        if (line == cur_line)
                cur_seen = TRUE;
        else if (line == mark_line)
                break;
  }

/* If we found mark_line (line != tail) check for legality of mark_text */
  if (line == tail || legal() == ERRORS)
        return NOT_VALID;

/* cur_seen is TRUE if cur_line is before mark_line */
  return (cur_seen == TRUE) ? BIGGER : SMALLER;
}

/*
 * Legal() checks if mark_text is still a valid pointer.
 */
int legal()
{
  register char *textp = mark_line->text;

/* Locate mark_text on mark_line */
  while (textp != mark_text && *textp++ != '\0')
        ;
  return (*textp == '\0') ? ERRORS : FINE;
}

/*
 * Yank puts all the text between start_position and end_position into
 * the buffer.
 * The caller must check that the arguments to yank() are valid. (E.g. in
 * the right order)
 */
void yank(start_line, start_textp, end_line, end_textp, remove)
LINE *start_line, *end_line;
char *start_textp, *end_textp;
FLAG remove;                            /* DELETE if text should be deleted */
{
  register LINE *line = start_line;
  register char *textp = start_textp;
  int fd;

/* Creat file to hold buffer */
  if ((fd = scratch_file(WRITE)) == ERRORS)
        return;
  
  chars_saved = 0L;
  lines_saved = 0;
  status_line("Saving text.", NULL);

/* Keep writing chars until the end_location is reached. */
  while (textp != end_textp) {
        if (write_char(fd, *textp) == ERRORS) {
                (void) close(fd);
                return;
        }
        if (*textp++ == '\n') { /* Move to the next line */
                line = line->next;
                textp = line->text;
                lines_saved++;
        }
        chars_saved++;
  }

/* Flush the I/O buffer and close file */
  if (flush_buffer(fd) == ERRORS) {
        (void) close(fd);
        return;
  }
  (void) close(fd);
  yank_status = VALID;

/*
 * Check if the text should be deleted as well. If it should, the following
 * hack is used to save a lot of code. First move back to the start_position.
 * (This might be the location we're on now!) and them delete the text.
 * It might be a bit confusing the first time somebody uses it.
 * Delete() will fix the screen.
 */
  if (remove == DELETE) {
        move_to(find_x(start_line, start_textp), find_y(start_line));
        delete(start_line, start_textp, end_line, end_textp);
  }

  status_line(num_out(chars_saved), " characters saved in buffer.");
}

/*
 * Scratch_file() creates a uniq file in /usr/tmp. If the file couldn't
 * be created other combinations of files are tried until a maximum
 * of MAXTRAILS times. After MAXTRAILS times, an error message is given
 * and ERRORS is returned.
 */

#define MAXTRAILS       26

int scratch_file(mode)
FLAG mode;                              /* Can be READ or WRITE permission */
{
  static int trials = 0;                /* Keep track of trails */
  register char *y_ptr, *n_ptr;
  int fd;                               /* Filedescriptor to buffer */

/* If yank_status == NOT_VALID, scratch_file is called for the first time */
  if (yank_status == NOT_VALID && mode == WRITE) { /* Create new file */
        /* Generate file name. */
        y_ptr = &yank_file[11];
        n_ptr = num_out((long) getpid());
        while ((*y_ptr = *n_ptr++) != '\0')
                y_ptr++;
        *y_ptr++ = 'a' + trials;
        *y_ptr = '\0';
        /* Check file existence */
        if (access(yank_file, 0) == 0 || (fd = creat(yank_file, 0644)) < 0) {
                if (trials++ >= MAXTRAILS) {
                        error("Unable to creat scratchfile.", NULL);
                        return ERRORS;
                }
                else
                        return scratch_file(mode);/* Have another go */
        }
  }
  else if ((mode == READ && (fd = open(yank_file, 0)) < 0) ||
                        (mode == WRITE && (fd = creat(yank_file, 0644)) < 0)) {
        yank_status = NOT_VALID;
        return ERRORS;
  }

  clear_buffer();
  return fd;
}

/*  ========================================================================  *
 *                              Search Routines                               * 
 *  ========================================================================  */

/*
 * A regular expression consists of a sequence of:
 *      1. A normal character matching that character.
 *      2. A . matching any character.
 *      3. A ^ matching the begin of a line.
 *      4. A $ (as last character of the pattern) mathing the end of a line.
 *      5. A \<character> matching <character>.
 *      6. A number of characters enclosed in [] pairs matching any of these
 *         characters. A list of characters can be indicated by a '-'. So
 *         [a-z] matches any letter of the alphabet. If the first character
 *         after the '[' is a '^' then the set is negated (matching none of
 *         the characters). 
 *         A ']', '^' or '-' can be escaped by putting a '\' in front of it.
 *      7. If one of the expressions as described in 1-6 is followed by a
 *         '*' than that expressions matches a sequence of 0 or more of
 *         that expression.
 */

char typed_expression[LINE_LEN];        /* Holds previous expr. */

/*
 * SF searches forward for an expression.
 */
void SF()
{
  search("Search forward:", FORWARD);
}

/*
 * SF searches backwards for an expression.
 */
void SR()
{
  search("Search reverse:", REVERSE);
}

/*
 * Get_expression() prompts for an expression. If just a return is typed, the
 * old expression is used. If the expression changed, compile() is called and
 * the returning REGEX structure is returned. It returns NULL upon error.
 * The save flag indicates whether the expression should be appended at the
 * message pointer.
 */
REGEX *get_expression(message)
char *message;
{
  static REGEX program;                 /* Program of expression */
  char exp_buf[LINE_LEN];                       /* Buffer for new expr. */

  if (get_string(message, exp_buf, FALSE) == ERRORS)
        return NULL;
  
  if (exp_buf[0] == '\0' && typed_expression[0] == '\0') {
        error("No previous expression.", NULL);
        return NULL;
  }

  if (exp_buf[0] != '\0') {             /* A new expr. is typed */
        copy_string(typed_expression, exp_buf);/* Save expr. */
        compile(exp_buf, &program);     /* Compile new expression */
  }

  if (program.status == REG_ERROR) {    /* Error during compiling */
        error(program.result.err_mess, NULL);
        return NULL;
  }
  return &program;
}

/*
 * GR() a replaces all matches from the current position until the end
 * of the file.
 */
void GR()
{
  change("Global replace:", VALID);
}

/*
 * LR() replaces all matches on the current line.
 */
void LR()
{
  change("Line replace:", NOT_VALID);
}

/*
 * Change() prompts for an expression and a substitution pattern and changes
 * all matches of the expression into the substitution. change() start looking
 * for expressions at the current line and continues until the end of the file
 * if the FLAG file is VALID.
 */
void change(message, file)
char *message;                          /* Message to prompt for expression */
FLAG file;
{
  char mess_buf[LINE_LEN];      /* Buffer to hold message */
  char replacement[LINE_LEN];   /* Buffer to hold subst. pattern */
  REGEX *program;                       /* Program resulting from compilation */
  register LINE *line = cur_line;
  register char *textp;
  long lines = 0L;              /* Nr of lines on which subs occurred */
  long subs = 0L;                       /* Nr of subs made */
  int page = y;                 /* Index to check if line is on screen*/

/* Save message and get expression */
  copy_string(mess_buf, message);
  if ((program = get_expression(mess_buf)) == NULL)
        return;
  
/* Get substitution pattern */
  build_string(mess_buf, "%s %s by:", mess_buf, typed_expression);
  if (get_string(mess_buf, replacement, FALSE) == ERRORS)
        return;
  
  set_cursor(0, ymax);
  flush();
/* Substitute until end of file */
  do {
        if (line_check(program, line->text, FORWARD)) {
                lines++;
                /* Repeat sub. on this line as long as we find a match*/
                do {
                        subs++; /* Increment subs */
                        if ((textp = substitute(line, program,replacement))
                                                                     == NULL)
                                return; /* Line too long */
                } while ((program->status & BEGIN_LINE) != BEGIN_LINE &&
                         (program->status & END_LINE) != END_LINE &&
                                          line_check(program, textp, FORWARD));
                /* Check to see if we can print the result */
                if (page <= screenmax) {
                        set_cursor(0, page);
                        line_print(line);
                }
        }
        if (page <= screenmax)
                page++;
        line = line->next;
  } while (line != tail && file == VALID && quit == FALSE);

  copy_string(mess_buf, (quit == TRUE) ? "(Aborted) " : "");
/* Fix the status line */
  if (subs == 0L && quit == FALSE)
        error("Pattern not found.", NULL);
  else if (lines >= REPORT || quit == TRUE) {
        build_string(mess_buf, "%s %D substitutions on %D lines.", mess_buf,
                                                                   subs, lines);
        status_line(mess_buf, NULL);
  }
  else if (file == NOT_VALID && subs >= REPORT)
        status_line(num_out(subs), " substitutions.");
  else
        clear_status();
  move_to (x, y);
}

/*
 * Substitute() replaces the match on this line by the substitute pattern
 * as indicated by the program. Every '&' in the replacement is replaced by 
 * the original match. A \ in the replacement escapes the next character.
 */
char *substitute(line, program, replacement)
LINE *line;
REGEX *program;
char *replacement;              /* Contains replacement pattern */
{
  register char *textp = text_buffer;
  register char *subp = replacement;
  char *linep = line->text;
  char *amp;

  modified = TRUE;

/* Copy part of line until the beginning of the match */
  while (linep != program->start_ptr)
        *textp++ = *linep++;
  
/*
 * Replace the match by the substitution pattern. Each occurrence of '&' is
 * replaced by the original match. A \ escapes the next character.
 */
  while (*subp != '\0' && textp < &text_buffer[MAX_CHARS]) {
        if (*subp == '&') {             /* Replace the original match */
                amp = program->start_ptr;
                while (amp < program->end_ptr && textp<&text_buffer[MAX_CHARS])
                        *textp++ = *amp++;
                subp++;
        }
        else {
                if (*subp == '\\' && *(subp + 1) != '\0')
                        subp++;
                *textp++ = *subp++;
        }
  }

/* Check for line length not exceeding MAX_CHARS */
  if (length_of(text_buffer) + length_of(program->end_ptr) >= MAX_CHARS) {
        error("Substitution result: line too big", NULL);
        return NULL;
  }

/* Append last part of line to the new build line */
  copy_string(textp, program->end_ptr);

/* Free old line and install new one */
  free_space(line->text);
  line->text = alloc(length_of(text_buffer) + 1);
  copy_string(line->text, text_buffer);

  return(line->text + (textp - text_buffer));
}

/*
 * Search() calls get_expression to fetch the expression. If this went well,
 * the function match() is called which returns the line with the next match.
 * If this line is the NULL, it means that a match could not be found.
 * Find_x() and find_y() display the right page on the screen, and return
 * the right coordinates for x and y. These coordinates are passed to move_to()
 */
void search(message, method)
char *message;
FLAG method;
{
  register REGEX *program;
  register LINE *match_line;

/* Get the expression */
  if ((program = get_expression(message)) == NULL)
        return;

  set_cursor(0, ymax);
  flush();
/* Find the match */
  if ((match_line = match(program, cur_text, method)) == NULL) {
        if (quit == TRUE)
                status_line("Aborted", NULL);
        else
                status_line("Pattern not found.", NULL);
        return;
  }

  move(0, program->start_ptr, find_y(match_line));
  clear_status();
}

/*
 * find_y() checks if the matched line is on the current page.  If it is, it
 * returns the new y coordinate, else it displays the correct page with the
 * matched line in the middle and returns the new y value;
 */
int find_y(match_line)
LINE *match_line;
{
  register LINE *line;
  register int count = 0;

/* Check if match_line is on the same page as currently displayed. */
  for (line = top_line; line != match_line && line != bot_line->next;
                                                      line = line->next)
        count++;
  if (line != bot_line->next)
        return count;

/* Display new page, with match_line in center. */
  if ((line = proceed(match_line, -(screenmax >> 1))) == header) {
  /* Can't display in the middle. Make first line of file top_line */
        count = 0;
        for (line = header->next; line != match_line; line = line->next)
                count++;
        line = header->next;
  }
  else  /* New page is displayed. Set cursor to middle of page */
        count = screenmax >> 1;

/* Reset pointers and redraw the screen */
  reset(line, 0);
  RD();

  return count;
}

/* Opcodes for characters */
#define NORMAL          0x0200
#define DOT             0x0400
#define EOLN            0x0800
#define STAR            0x1000
#define BRACKET         0x2000
#define NEGATE          0x0100
#define DONE            0x4000

/* Mask for opcodes and characters */
#define LOW_BYTE        0x00FF
#define HIGH_BYTE       0xFF00

/* Previous is the contents of the previous address (ptr) points to */
#define previous(ptr)           (*((ptr) - 1))

/* Buffer to store outcome of compilation */
int exp_buffer[BLOCK_SIZE];

/* Errors often used */
char *too_long = "Regular expression too long";

/*
 * Reg_error() is called by compile() is something went wrong. It set the
 * status of the structure to error, and assigns the error field of the union.
 */
#define reg_error(str)  program->status = REG_ERROR, \
                                        program->result.err_mess = (str)
/*
 * Finished() is called when everything went right during compilation. It
 * allocates space for the expression, and copies the expression buffer into
 * this field.
 */
void finished(program, last_exp)
register REGEX *program;
int *last_exp;
{
  register int length = (last_exp - exp_buffer) * sizeof(int);

/* Allocate space */
  program->result.expression = (int *) alloc(length);
/* Copy expression. (expression consists of ints!) */
  bcopy(exp_buffer, program->result.expression, length);
}

/*
 * Compile compiles the pattern into a more comprehensible form and returns a 
 * REGEX structure. If something went wrong, the status field of the structure
 * is set to REG_ERROR and an error message is set into the err_mess field of
 * the union. If all went well the expression is saved and the expression
 * pointer is set to the saved (and compiled) expression.
 */
void compile(pattern, program)
register char *pattern;                 /* Pointer to pattern */
REGEX *program;
{
  register int *expression = exp_buffer;
  int *prev_char;                       /* Pointer to previous compiled atom */
  int *acct_field;              /* Pointer to last BRACKET start */
  FLAG negate;                  /* Negate flag for BRACKET */
  char low_char;                        /* Index for chars in BRACKET */
  char c;

/* Check for begin of line */
  if (*pattern == '^') {
        program->status = BEGIN_LINE;
        pattern++;
  }
  else {
        program->status = 0;
/* If the first character is a '*' we have to assign it here. */
        if (*pattern == '*') {
                *expression++ = '*' + NORMAL;
                pattern++;
        }
  }

  for (; ;) {
        switch (c = *pattern++) {
        case '.' :
                *expression++ = DOT;
                break;
        case '$' :
                /*
                 * Only means EOLN if it is the last char of the pattern
                 */
                if (*pattern == '\0') {
                        *expression++ = EOLN | DONE;
                        program->status |= END_LINE;
                        finished(program, expression);
                        return;
                }
                else
                        *expression++ = NORMAL + '$';
                break;
        case '\0' :
                *expression++ = DONE;
                finished(program, expression);
                return;
        case '\\' :
                /* If last char, it must! mean a normal '\' */
                if (*pattern == '\0')
                        *expression++ = NORMAL + '\\';
                else
                        *expression++ = NORMAL + *pattern++;
                break;
        case '*' :
                /*
                 * If the previous expression was a [] find out the
                 * begin of the list, and adjust the opcode.
                 */
                prev_char = expression - 1;
                if (*prev_char & BRACKET)
                        *(expression - (*acct_field & LOW_BYTE))|= STAR;
                else
                        *prev_char |= STAR;
                break;
        case '[' :
                /*
                 * First field in expression gives information about
                 * the list.
                 * The opcode consists of BRACKET and if necessary
                 * NEGATE to indicate that the list should be negated
                 * and/or STAR to indicate a number of sequence of this 
                 * list.
                 * The lower byte contains the length of the list.
                 */
                acct_field = expression++;
                if (*pattern == '^') {  /* List must be negated */
                        pattern++;
                        negate = TRUE;
                }
                else
                        negate = FALSE;
                while (*pattern != ']') {
                        if (*pattern == '\0') {
                                reg_error("Missing ]");
                                return;
                        }
                        if (*pattern == '\\')
                                pattern++;
                        *expression++ = *pattern++;
                        if (*pattern == '-') {
                                                /* Make list of chars */
                                low_char = previous(pattern);
                                pattern++;      /* Skip '-' */
                                if (low_char++ > *pattern) {
                                        reg_error("Bad range in [a-z]");
                                        return;
                                }
                                /* Build list */
                                while (low_char <= *pattern)
                                        *expression++ = low_char++;
                                pattern++;
                        }
                        if (expression >= &exp_buffer[BLOCK_SIZE]) {
                                reg_error(too_long);
                                return;
                        }
                }
                pattern++;                      /* Skip ']' */
                /* Assign length of list in acct field */
                if ((*acct_field = (expression - acct_field)) == 1) {
                        reg_error("Empty []");
                        return;
                }
                /* Assign negate and bracket field */
                *acct_field |= BRACKET;
                if (negate == TRUE)
                        *acct_field |= NEGATE;
                /*
                 * Add BRACKET to opcode of last char in field because
                 * a '*' may be following the list.
                 */
                previous(expression) |= BRACKET;
                break;
        default :
                *expression++ = c + NORMAL;
        }
        if (expression == &exp_buffer[BLOCK_SIZE]) {
                reg_error(too_long);
                return;
        }
  }
  /* NOTREACHED */
}

/*
 * Match gets as argument the program, pointer to place in current line to 
 * start from and the method to search for (either FORWARD or REVERSE).
 * Match() will look through the whole file until a match is found.
 * NULL is returned if no match could be found.
 */
LINE *match(program, string, method)
REGEX *program;
char *string;
register FLAG method;
{
  register LINE *line = cur_line;
  char old_char;                                /* For saving chars */

/* Corrupted program */
  if (program->status == REG_ERROR)
        return NULL;

/* Check part of text first */
  if (!(program->status & BEGIN_LINE)) {
        if (method == FORWARD) {
                if (line_check(program, string + 1, method) == MATCH)
                        return cur_line;        /* Match found */
        }
        else if (!(program->status & END_LINE)) {
                old_char = *string;     /* Save char and */
                *string = '\n';         /* Assign '\n' for line_check */
                if (line_check(program, line->text, method) == MATCH) {
                        *string = old_char; /* Restore char */
                        return cur_line;    /* Found match */
                }
                *string = old_char;     /* No match, but restore char */
        }
  }

/* No match in last (or first) part of line. Check out rest of file */
  do {
        line = (method == FORWARD) ? line->next : line->prev;
        if (line->text == NULL) /* Header/tail */
                continue;
        if (line_check(program, line->text, method) == MATCH)
                return line;
  } while (line != cur_line && quit == FALSE);

/* No match found. */
  return NULL;
}

/*
 * Line_check() checks the line (or rather string) for a match. Method
 * indicates FORWARD or REVERSE search. It scans through the whole string
 * until a match is found, or the end of the string is reached.
 */
int line_check(program, string, method)
register REGEX *program;
char *string;
FLAG method;
{
  register char *textp = string;

/* Assign start_ptr field. We might find a match right away! */
  program->start_ptr = textp;

/* If the match must be anchored, just check the string. */
  if (program->status & BEGIN_LINE)
        return check_string(program, string, NULL);
  
  if (method == REVERSE) {
        /* First move to the end of the string */
        for (textp = string; *textp != '\n'; textp++)
                ;
        /* Start checking string until the begin of the string is met */
        while (textp >= string) {
                program->start_ptr = textp;
                if (check_string(program, textp--, NULL))
                        return MATCH;
        }
  }
  else {
        /* Move through the string until the end of is found */
        while (quit == FALSE && *textp != '\0') {
                program->start_ptr = textp;
                if (check_string(program, textp, NULL))
                        return MATCH;
                if (*textp == '\n')
                        break;
                textp++;
        }
  }

  return NO_MATCH;
}

/*
 * Check() checks of a match can be found in the given string. Whenever a STAR
 * is found during matching, then the begin position of the string is marked
 * and the maximum number of matches is performed. Then the function star()
 * is called which starts to finish the match from this position of the string
 * (and expression). Check() return MATCH for a match, NO_MATCH is the string 
 * couldn't be matched or REG_ERROR for an illegal opcode in expression.
 */
int check_string(program, string, expression)
REGEX *program;
register char *string;
int *expression;
{
  register int opcode;          /* Holds opcode of next expr. atom */
  char c;                               /* Char that must be matched */
  char *mark;                   /* For marking position */
  int star_fl;                  /* A star has been born */

  if (expression == NULL)
        expression = program->result.expression;

/* Loop until end of string or end of expression */
  while (quit == FALSE && !(*expression & DONE) &&
                                           *string != '\0' && *string != '\n') {
        c = *expression & LOW_BYTE;       /* Extract match char */
        opcode = *expression & HIGH_BYTE; /* Extract opcode */
        if (star_fl = (opcode & STAR)) {  /* Check star occurrence */
                opcode &= ~STAR;          /* Strip opcode */
                mark = string;            /* Mark current position */
        }
        expression++;           /* Increment expr. */
        switch (opcode) {
        case NORMAL :
                if (star_fl)
                        while (*string++ == c)  /* Skip all matches */
                                ;
                else if (*string++ != c)
                        return NO_MATCH;
                break;
        case DOT :
                string++;
                if (star_fl)                    /* Skip to eoln */
                        while (*string != '\0' && *string++ != '\n')
                                ;
                break;
        case NEGATE | BRACKET:
        case BRACKET :
                if (star_fl)
                        while (in_list(expression, *string++, c, opcode)
                                                                       == MATCH)
                                ;
                else if (in_list(expression, *string++, c, opcode) == NO_MATCH)
                        return NO_MATCH;
                expression += c - 1;    /* Add length of list */
                break;
        default :
                panic("Corrupted program in check_string()");
        }
        if (star_fl) 
                return star(program, mark, string, expression);
  }
  if (*expression & DONE) {
        program->end_ptr = string;      /* Match ends here */
        /*
         * We might have found a match. The last thing to do is check
         * whether a '$' was given at the end of the expression, or
         * the match was found on a null string. (E.g. [a-z]* always
         * matches) unless a ^ or $ was included in the pattern.
         */
        if ((*expression & EOLN) && *string != '\n' && *string != '\0')
                return NO_MATCH;
        if (string == program->start_ptr && !(program->status & BEGIN_LINE)
                                         && !(*expression & EOLN))
                return NO_MATCH;
        return MATCH;
  }
  return NO_MATCH;
}

/*
 * Star() calls check_string() to find out the longest match possible.
 * It searches backwards until the (in check_string()) marked position
 * is reached, or a match is found.
 */
int star(program, end_position, string, expression)
REGEX *program;
register char *end_position;
register char *string;
int *expression;
{
  do {
        string--;
        if (check_string(program, string, expression))
                return MATCH;
  } while (string != end_position);

  return NO_MATCH;
}

/*
 * In_list() checks if the given character is in the list of []. If it is
 * it returns MATCH. if it isn't it returns NO_MATCH. These returns values
 * are reversed when the NEGATE field in the opcode is present.
 */
int in_list(list, c, list_length, opcode)
register int *list;
char c;
register int list_length;
int opcode;
{
  if (c == '\0' || c == '\n')   /* End of string, never matches */
        return NO_MATCH;
  while (list_length-- > 1) {   /* > 1, don't check acct_field */
        if ((*list & LOW_BYTE) == c)
                return (opcode & NEGATE) ? NO_MATCH : MATCH;
        list++;
  }
  return (opcode & NEGATE) ? MATCH : NO_MATCH;
}

/*
 * Dummy_line() adds an empty line at the end of the file. This is sometimes
 * useful in combination with the EF and DN command in combination with the
 * Yank command set.
 */
void dummy_line()
{
        (void) line_insert(tail->prev, "\n", 1);
        tail->prev->shift_count = DUMMY;
        if (last_y != screenmax) {
                last_y++;
                bot_line = bot_line->next;
        }
}