head 1.1;A access ; symbols ; locks ; strict; comment @ * @; 1.1 date 85.03.31.18.10.45; author bbanerje; state Exp; branches ; next ; desc @@ 1.1 log @Initial revision @ text @/* Cursor motion subroutines for GNU Emacs. Copyright (C) 1984 Richard M. Stallman based primarily on public domain code written by Chris Torek This file is part of GNU Emacs. GNU Emacs is distributed in the hope that it will be useful, but without any warranty. No author or distributor accepts responsibility to anyone for the consequences of using it or for whether it serves any particular purpose or works at all, unless he says so in writing. Everyone is granted permission to copy, modify and redistribute GNU Emacs, but only under the conditions described in the document "GNU Emacs copying permission notice". An exact copy of the document is supposed to have been given to you along with GNU Emacs so that you can know how you may redistribute it all. It should be in a file named COPYING. Among other things, the copyright notice and this notice must be preserved on all copies. */ #include #include #include "cm.h" #define BIG 9999 /* 9999 good on VAXen. For 16 bit machines use about 2000.... */ char *malloc (), *mytgoto (), *getenv (); static int cost; /* sums up costs */ /* * In order to accomodate binary cursor motion on certain terminals, the NUL * character '\0' is put into the string by "character stuffing" using 4 as * the magic escape code. (0 breaks the termcap routines since that is their * end-of-string marker.) The cmevalcost and cmput routines decode these. */ static cmevalcost (c) char c; { static int esc; if (esc) { esc = 0; return; } if (c == 4) esc++; cost++; } static cmput (c) char c; { static int esc; if (esc) { esc = 0; if (c == 9) c = 0; putchar (c); return; } if (c == 4) { esc++; } else putchar (c); } /* * But here we don't bother with such silliness. */ /* ARGSUSED */ static evalcost (c) char c; { cost++; } static put (c) char c; { putchar (c); } /* NEXT TWO ARE DONE WITH MACROS */ #if 0 /* * Assume the cursor is at row row, column col. Normally used only after * clearing the screen, when the cursor is at (0, 0), but what the heck, * let's let the guy put it anywhere. */ static at (row, col) { curY = row; curX = col; } /* * Add n columns to the current cursor position. */ static addcol (n) { curX += n; /* * If cursor hit edge of screen, what happened? * N.B.: DO NOT!! write past edge of screen. If you do, you * deserve what you get. Furthermore, on terminals with * autowrap (but not magicwrap), don't write in the last column * of the last line. */ if (curX == Wcm.cm_cols) { /* * Well, if magicwrap, still there, past the edge of the * screen (!). If autowrap, on the col 0 of the next line. * Otherwise on last column. */ if (Wcm.cm_magicwrap) ; /* "limbo" */ else if (Wcm.cm_autowrap) { curX = 0; curY++; /* Beware end of screen! */ } else curX--; } } #endif /* * (Re)Initialize the cost factors, given the output speed of the terminal * in the variable ospeed. (Note: this holds B300, B9600, etc -- ie stuff * out of .) */ static costinit () { char *p; #define COST(x,e) (x ? (cost = 0, tputs (x, 1, e), cost) : BIG) Wcm.cc_up = COST (Wcm.cm_up, evalcost); Wcm.cc_down = COST (Wcm.cm_down, evalcost); Wcm.cc_left = COST (Wcm.cm_left, evalcost); Wcm.cc_right = COST (Wcm.cm_right, evalcost); Wcm.cc_home = COST (Wcm.cm_home, evalcost); Wcm.cc_cr = COST (Wcm.cm_cr, evalcost); Wcm.cc_ll = COST (Wcm.cm_ll, evalcost); Wcm.cc_tab = Wcm.cm_tabwidth ? COST (Wcm.cm_tab, evalcost) : BIG; /* * These last three are actually minimum costs. When (if) they are * candidates for the least-cost motion, the real cost is computed. * (Note that "0" is the assumed to generate the minimum cost. * While this is not necessarily true, I have yet to see a terminal * for which is not; all the terminals that have variable-cost * cursor motion seem to take straight numeric values. --ACT) */ p = mytgoto (Wcm.cm_abs, 0, 0); Wcm.cc_abs = COST (p, cmevalcost); p = mytgoto (Wcm.cm_habs, 0, 0); Wcm.cc_habs = COST (p, cmevalcost); p = mytgoto (Wcm.cm_vabs, 0, 0); Wcm.cc_vabs = COST (p, cmevalcost); #undef COST } /* * Calculate the cost to move from (srcy, srcx) to (dsty, dstx) using * up and down, and left and right, motions, and tabs. If doit is set * actually perform the motion. */ static calccost (srcy, srcx, dsty, dstx, doit) { register int deltay, deltax, c, totalcost; int ntabs, n2tabs, tabx, tab2x, tabcost; register char *p; totalcost = 0; if ((deltay = dsty - srcy) == 0) goto x; if (deltay < 0) p = Wcm.cm_up, c = Wcm.cc_up, deltay = -deltay; else p = Wcm.cm_down, c = Wcm.cc_down; if (c == BIG) { /* caint get thar from here */ if (doit) printf ("OOPS"); return c; } totalcost = c * deltay; if (doit) while (--deltay >= 0) tputs (p, 1, put); x: if ((deltax = dstx - srcx) == 0) goto done; if (deltax < 0) { p = Wcm.cm_left, c = Wcm.cc_left, deltax = -deltax; goto dodelta; /* skip all the tab junk */ } /* Tabs (the toughie) */ if (Wcm.cc_tab >= BIG || !Wcm.cm_usetabs) goto olddelta; /* forget it! */ /* * ntabs is # tabs towards but not past dstx; n2tabs is one more * (ie past dstx), but this is only valid if that is not past the * right edge of the screen. We can check that at the same time * as we figure out where we would be if we use the tabs (which * we will put into tabx (for ntabs) and tab2x (for n2tabs)). */ ntabs = deltax / Wcm.cm_tabwidth; n2tabs = ntabs + 1; tabx = (srcx / Wcm.cm_tabwidth + ntabs) * Wcm.cm_tabwidth; tab2x = tabx + Wcm.cm_tabwidth; if (tab2x >= Wcm.cm_cols) /* too far (past edge) */ n2tabs = 0; /* * Now set tabcost to the cost for using ntabs, and c to the cost * for using n2tabs, then pick the minimum. */ /* cost for ntabs + cost for right motion */ tabcost = ntabs ? ntabs * Wcm.cc_tab + (dstx - tabx) * Wcm.cc_right : BIG; /* cost for n2tabs + cost for left motion */ c = n2tabs ? n2tabs * Wcm.cc_tab + (tab2x - dstx) * Wcm.cc_left : BIG; if (c < tabcost) /* then cheaper to overshoot & back up */ ntabs = n2tabs, tabcost = c, tabx = tab2x; if (tabcost >= BIG) /* caint use tabs */ goto newdelta; /* * See if tabcost is less than just moving right */ if (tabcost < (deltax * Wcm.cc_right)) { totalcost += tabcost; /* use the tabs */ if (doit) while (--ntabs >= 0) tputs (Wcm.cm_tab, 1, put); srcx = tabx; } /* * Now might as well just recompute the delta. */ newdelta: if ((deltax = dstx - srcx) == 0) goto done; olddelta: if (deltax > 0) p = Wcm.cm_right, c = Wcm.cc_right; else p = Wcm.cm_left, c = Wcm.cc_left, deltax = -deltax; dodelta: if (c == BIG) { /* caint get thar from here */ if (doit) printf ("OOPS"); return c; } totalcost += c * deltax; if (doit) while (--deltax >= 0) tputs (p, 1, put); done: return totalcost; } losecursor () { curY = -1; } #define USEREL 0 #define USEHOME 1 #define USELL 2 #define USECR 3 static xgoto (row, col) { int homecost, crcost, llcost, relcost, directcost; int use; char *p, *dcm; /* First the degenerate case */ if (row == curY && col == curX)/* already there */ return; if (curY >= 0 && curX >= 0) { /* * Pick least-cost motions */ relcost = calccost (curY, curX, row, col, 0); use = USEREL; if ((homecost = Wcm.cc_home) < BIG) homecost += calccost (0, 0, row, col, 0); if (homecost < relcost) relcost = homecost, use = USEHOME; if ((llcost = Wcm.cc_ll) < BIG) llcost += calccost (Wcm.cm_rows - 1, 0, row, col, 0); if (llcost < relcost) relcost = llcost, use = USELL; if ((crcost = Wcm.cc_cr) < BIG) { if (Wcm.cm_autolf) if (curY + 1 >= Wcm.cm_rows) crcost = BIG; else crcost += calccost (curY + 1, 0, row, col, 0); else crcost += calccost (curY, 0, row, col, 0); } if (crcost < relcost) relcost = crcost, use = USECR; directcost = Wcm.cc_abs, dcm = Wcm.cm_abs; if (row == curY && Wcm.cc_habs < BIG) directcost = Wcm.cc_habs, dcm = Wcm.cm_habs; else if (col == curX && Wcm.cc_vabs < BIG) directcost = Wcm.cc_vabs, dcm = Wcm.cm_vabs; } else { directcost = 0, relcost = 100000; } /* * In the following comparison, the = in <= is because when the costs * are the same, it looks nicer (I think) to move directly there. */ if (directcost <= relcost) { /* compute REAL direct cost */ cost = 0; p = dcm == Wcm.cm_habs ? mytgoto (dcm, row, col) : mytgoto (dcm, col, row); tputs (p, 1, cmevalcost); if (cost <= relcost) { /* really is cheaper */ tputs (p, 1, cmput); curY = row, curX = col; return; } } switch (use) { case USEHOME: tputs (Wcm.cm_home, 1, put); curY = 0, curX = 0; break; case USELL: tputs (Wcm.cm_ll, 1, put); curY = Wcm.cm_rows - 1, curX = 0; break; case USECR: tputs (Wcm.cm_cr, 1, put); if (Wcm.cm_autolf) curY++; curX = 0; break; } (void) calccost (curY, curX, row, col, 1); curY = row, curX = col; } /* Clear out all terminal info. Used before copying into it the info on the actual terminal. */ Wcm_clear () { bzero (&Wcm, sizeof Wcm); } /* * Initialized stuff * Return 0 if can do CM. */ Wcm_init () { Wcm.cx_put = put; Wcm.cx_costinit = costinit; Wcm.cx_goto = xgoto; /* Check that we know the size of the screen.... */ if (Wcm.cm_rows <= 0 || Wcm.cm_cols <= 0) return - 1; if (Wcm.cm_abs && !Wcm.cm_ds) return 0; /* Require up and left, and, if no absolute, down and right */ if (!Wcm.cm_up || !Wcm.cm_left) return - 1; if (!Wcm.cm_abs && (!Wcm.cm_down || !Wcm.cm_right)) return - 1; return 0; } /* * This is a lot like the standard tgoto routine except that it knows: * %m - for NIH 7000 terminals. (We had someone using one.) * Magic cm stuff for faking a NUL (and ^D...) */ static char * mytgoto (CM, col, line) char *CM; int col, line; { static char cmbuf[100], add[100]; register char *cp, *op; register int c; int val, toggle; if ((cp = CM) == 0) return 0; op = cmbuf; val = line; toggle = 0; *add = 0; *op = 0; while (c = *cp++) { if (c != '%') { *op++ = c; continue; } switch (c = *cp++) { case 0: cp--; break; case 'm': col ^= 0177; line ^= 0177; goto setval; case 'n': col ^= 0140; line ^= 0140; goto setval; case 'd': if (val < 10) goto onedigit; if (val < 100) goto twodigit; case '3': *op++ = (val / 100) + '0'; val %= 100; case '2': twodigit: *op++ = (val / 10) + '0'; onedigit: *op++ = (val % 10) + '0'; swap: toggle = 1 - toggle; setval: val = toggle ? col : line; continue; case '>': if (val > *cp++) val += *cp++; else cp++; continue; case '+': val += *cp++; case '.': use: if (Wcm.cm_ds) { while (val == 0 || index (Wcm.cm_ds, val)) { strcat (add, toggle ? Wcm.cm_left : Wcm.cm_up); ++val; } } if (val == 0) { *op++ = 4; *op++ = 9; /* 4 and 9 are "magic" */ } else if (val == 4) { *op++ = 4; *op++ = 4; /* another magic combo */ } else *op++ = val; goto swap; case 'r': toggle = 1; goto setval; case 'i': ++col, ++line, ++val; continue; case '%': *op++ = c; continue; case 'B': val = ((val / 10) << 4) + val % 10; continue; case 'D': val = val - 2 * (val % 16); continue; default: val += c; goto use; } } cp = add; while (*cp) *op++ = *cp++; *op = 0; return cmbuf; } @