/* $OpenBSD: random.c,v 1.24 2007/02/08 21:40:38 kjell Exp $ */ /* This file is in the public domain. */ /* * Assorted commands. * This file contains the command processors for a large assortment of * unrelated commands. The only thing they have in common is that they * are all command processors. */ #include "def.h" #include /* * Display a bunch of useful information about the current location of dot. * The character under the cursor (in octal), the current line, row, and * column, and approximate position of the cursor in the file (as a * percentage) is displayed. The column position assumes an infinite * position display; it does not truncate just because the screen does. * This is normally bound to "C-X =". */ /* ARGSUSED */ int showcpos(int f, int n) { struct line *clp; long nchar, cchar; int nline, row; int cline, cbyte; /* Current line/char/byte */ int ratio; /* collect the data */ clp = bfirstlp(curbp); cchar = 0; cline = 0; cbyte = 0; nchar = 0; nline = 0; for (;;) { /* count this line */ ++nline; if (clp == curwp->w_dotp) { /* mark line */ cline = nline; cchar = nchar + curwp->w_doto; if (curwp->w_doto == llength(clp)) cbyte = '\n'; else cbyte = lgetc(clp, curwp->w_doto); } /* now count the chars */ nchar += llength(clp); clp = lforw(clp); if (clp == curbp->b_headp) break; /* count the newline */ nchar++; } /* determine row */ row = curwp->w_toprow + 1; clp = curwp->w_linep; while (clp != curbp->b_headp && clp != curwp->w_dotp) { ++row; clp = lforw(clp); } /* NOSTRICT */ ratio = nchar ? (100L * cchar) / nchar : 100; ewprintf("Char: %c (0%o) point=%ld(%d%%) line=%d row=%d col=%d", cbyte, cbyte, cchar, ratio, cline, row, getcolpos()); return (TRUE); } int getcolpos(void) { int col, i, c; char tmp[5]; /* determine column */ col = 0; for (i = 0; i < curwp->w_doto; ++i) { c = lgetc(curwp->w_dotp, i); if (c == '\t' #ifdef NOTAB && !(curbp->b_flag & BFNOTAB) #endif /* NOTAB */ ) { col |= 0x07; col++; } else if (ISCTRL(c) != FALSE) col += 2; else if (isprint(c)) { col++; } else { col += snprintf(tmp, sizeof(tmp), "\\%o", c); } } return (col); } /* * Twiddle the two characters on either side of dot. If dot is at the end * of the line twiddle the two characters before it. Return with an error * if dot is at the beginning of line; it seems to be a bit pointless to * make this work. This fixes up a very common typo with a single stroke. * Normally bound to "C-T". This always works within a line, so "WFEDIT" * is good enough. */ /* ARGSUSED */ int twiddle(int f, int n) { struct line *dotp; int doto, cr; int fudge = FALSE; dotp = curwp->w_dotp; doto = curwp->w_doto; undo_add_boundary(); undo_boundary_enable(FALSE); if (doto == llength(dotp)) { if (--doto <= 0) return (FALSE); (void)backchar(FFRAND, 1); fudge = TRUE; } else { if (doto == 0) return (FALSE); } cr = lgetc(dotp, doto - 1); (void)backdel(FFRAND, 1); (void)forwchar(FFRAND, 1); linsert(1, cr); if (fudge != TRUE) (void)backchar(FFRAND, 1); undo_boundary_enable(TRUE); undo_add_boundary(); lchange(WFEDIT); return (TRUE); } /* * Open up some blank space. The basic plan is to insert a bunch of * newlines, and then back up over them. Everything is done by the * subcommand processors. They even handle the looping. Normally this * is bound to "C-O". */ /* ARGSUSED */ int openline(int f, int n) { int i, s; if (n < 0) return (FALSE); if (n == 0) return (TRUE); /* insert newlines */ i = n; do { s = lnewline(); } while (s == TRUE && --i); /* then go back up overtop of them all */ if (s == TRUE) s = backchar(f | FFRAND, n); return (s); } /* * Insert a newline. */ /* ARGSUSED */ int newline(int f, int n) { int s; if (n < 0) return (FALSE); while (n--) { if ((s = lnewline()) != TRUE) return (s); } return (TRUE); } /* * Delete blank lines around dot. What this command does depends if dot is * sitting on a blank line. If dot is sitting on a blank line, this command * deletes all the blank lines above and below the current line. If it is * sitting on a non blank line then it deletes all of the blank lines after * the line. Normally this command is bound to "C-X C-O". Any argument is * ignored. */ /* ARGSUSED */ int deblank(int f, int n) { struct line *lp1, *lp2; RSIZE nld; lp1 = curwp->w_dotp; while (llength(lp1) == 0 && (lp2 = lback(lp1)) != curbp->b_headp) lp1 = lp2; lp2 = lp1; nld = (RSIZE)0; while ((lp2 = lforw(lp2)) != curbp->b_headp && llength(lp2) == 0) ++nld; if (nld == 0) return (TRUE); curwp->w_dotp = lforw(lp1); curwp->w_doto = 0; return (ldelete((RSIZE)nld, KNONE)); } /* * Delete any whitespace around dot, then insert a space. */ int justone(int f, int n) { (void)delwhite(f, n); return (linsert(1, ' ')); } /* * Delete any whitespace around dot. */ /* ARGSUSED */ int delwhite(int f, int n) { int col, c, s; col = curwp->w_doto; while (col < llength(curwp->w_dotp) && ((c = lgetc(curwp->w_dotp, col)) == ' ' || c == '\t')) ++col; do { if (curwp->w_doto == 0) { s = FALSE; break; } if ((s = backchar(FFRAND, 1)) != TRUE) break; } while ((c = lgetc(curwp->w_dotp, curwp->w_doto)) == ' ' || c == '\t'); if (s == TRUE) (void)forwchar(FFRAND, 1); (void)ldelete((RSIZE)(col - curwp->w_doto), KNONE); return (TRUE); } /* * Insert a newline, then enough tabs and spaces to duplicate the indentation * of the previous line. Assumes tabs are every eight characters. Quite * simple. Figure out the indentation of the current line. Insert a newline * by calling the standard routine. Insert the indentation by inserting the * right number of tabs and spaces. Return TRUE if all ok. Return FALSE if * one of the subcommands failed. Normally bound to "C-M". */ /* ARGSUSED */ int indent(int f, int n) { int c, i, nicol; if (n < 0) return (FALSE); while (n--) { nicol = 0; for (i = 0; i < llength(curwp->w_dotp); ++i) { c = lgetc(curwp->w_dotp, i); if (c != ' ' && c != '\t') break; if (c == '\t') nicol |= 0x07; ++nicol; } if (lnewline() == FALSE || (( #ifdef NOTAB curbp->b_flag & BFNOTAB) ? linsert(nicol, ' ') == FALSE : ( #endif /* NOTAB */ ((i = nicol / 8) != 0 && linsert(i, '\t') == FALSE) || ((i = nicol % 8) != 0 && linsert(i, ' ') == FALSE)))) return (FALSE); } return (TRUE); } /* * Delete forward. This is real easy, because the basic delete routine does * all of the work. Watches for negative arguments, and does the right thing. * If any argument is present, it kills rather than deletes, to prevent loss * of text if typed with a big argument. Normally bound to "C-D". */ /* ARGSUSED */ int forwdel(int f, int n) { if (n < 0) return (backdel(f | FFRAND, -n)); /* really a kill */ if (f & FFARG) { if ((lastflag & CFKILL) == 0) kdelete(); thisflag |= CFKILL; } return (ldelete((RSIZE) n, (f & FFARG) ? KFORW : KNONE)); } /* * Delete backwards. This is quite easy too, because it's all done with * other functions. Just move the cursor back, and delete forwards. Like * delete forward, this actually does a kill if presented with an argument. */ /* ARGSUSED */ int backdel(int f, int n) { int s; if (n < 0) return (forwdel(f | FFRAND, -n)); /* really a kill */ if (f & FFARG) { if ((lastflag & CFKILL) == 0) kdelete(); thisflag |= CFKILL; } if ((s = backchar(f | FFRAND, n)) == TRUE) s = ldelete((RSIZE)n, (f & FFARG) ? KFORW : KNONE); return (s); } #ifdef NOTAB /* ARGSUSED */ int space_to_tabstop(int f, int n) { if (n < 0) return (FALSE); if (n == 0) return (TRUE); return (linsert((n << 3) - (curwp->w_doto & 7), ' ')); } #endif /* NOTAB */