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Length: 10143 (0x279f) Types: TextFile Names: »input.c«
└─⟦5f3412b64⟧ Bits:30000745 8mm tape, Rational 1000, ENVIRONMENT 12_6_5 TOOLS └─ ⟦91c658230⟧ »DATA« └─⟦5d656759a⟧ └─⟦50f09e4e4⟧ └─ ⟦this⟧ »./input.c« └─⟦5f3412b64⟧ Bits:30000745 8mm tape, Rational 1000, ENVIRONMENT 12_6_5 TOOLS └─ ⟦91c658230⟧ »DATA« └─⟦5d656759a⟧ └─⟦610eb0a19⟧ └─ ⟦this⟧ »./input.c« └─⟦5f3412b64⟧ Bits:30000745 8mm tape, Rational 1000, ENVIRONMENT 12_6_5 TOOLS └─ ⟦91c658230⟧ »DATA« └─⟦5d656759a⟧ └─⟦d97085656⟧ └─ ⟦this⟧ »./input.c«
/* * $XConsortium: input.c,v 1.5 88/09/06 17:08:05 jim Exp $ */ #ifndef lint static char *rcsid_input_c = "$XConsortium: input.c,v 1.5 88/09/06 17:08:05 jim Exp $"; #endif /* lint */ #include <X11/copyright.h> /* * Copyright 1987 by Digital Equipment Corporation, Maynard, Massachusetts. * * All Rights Reserved * * Permission to use, copy, modify, and distribute this software and its * documentation for any purpose and without fee is hereby granted, * provided that the above copyright notice appear in all copies and that * both that copyright notice and this permission notice appear in * supporting documentation, and that the name of Digital Equipment * Corporation not be used in advertising or publicity pertaining to * distribution of the software without specific, written prior permission. * * * DIGITAL DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING * ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO EVENT SHALL * DIGITAL BE LIABLE FOR ANY SPECIAL, INDIRECT OR CONSEQUENTIAL DAMAGES OR * ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, * WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, * ARISING OUT OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS * SOFTWARE. */ /* input.c */ #ifndef lint static char rcs_id[] = "$XConsortium: input.c,v 1.5 88/09/06 17:08:05 jim Exp $"; #endif /* lint */ #include <X11/Xlib.h> #include <X11/keysym.h> #include <X11/DECkeysym.h> #define XK_LATIN1 #include <X11/keysymdef.h> #include <X11/Intrinsic.h> #include <X11/Xutil.h> #include <setjmp.h> #include <stdio.h> #include "ptyx.h" #include "data.h" #include "ratmenu.h" #include "rcg.h" extern Boolean KeyCodeTable_ShiftLock; /* Lock == ShiftLock (!= CapsLock)*/ extern Boolean KeyCodeTable_Inited; /* Are tables good? */ extern KeySym KeyCodeTable_Shifted[]; /* Shifted KeySym for a given key */ extern KeySym KeyCodeTable_Unshifted[]; /* Unshifted KeySym for given key */ static XComposeStatus compose_status = {NULL, 0}; static char *kypd_num = " XXXXXXXX\tXXX\rXXXxxxxXXXXXXXXXXXXXXXXXXXXX*+,-.\\0123456789XXX="; static char *kypd_apl = " ABCDEFGHIJKLMNOPQRSTUVWXYZ??????abcdefghijklmnopqrstuvwxyzXXX"; static char *cur = "DACB"; static int funcvalue(), sunfuncvalue(); extern Boolean sunFunctionKeys; void AdjustAfterInput (screen) register TScreen *screen; { if(screen->scrollkey && screen->topline != 0) WindowScroll(screen, 0); if(screen->marginbell) { int col = screen->max_col - screen->nmarginbell; if(screen->bellarmed >= 0) { if(screen->bellarmed == screen->cur_row) { if(screen->cur_col >= col) { if(screen->cur_col == col) Bell(); screen->bellarmed = -1; } } else screen->bellarmed = screen->cur_col < col ? screen->cur_row : -1; } else if(screen->cur_col < col) screen->bellarmed = screen->cur_row; } } Input (keyboard, screen, event, eightbit) register TKeyboard *keyboard; register TScreen *screen; register XKeyPressedEvent *event; Bool eightbit; { #define STRBUFSIZE 100 register int col, key = FALSE; int pty = screen->respond; if (term->misc.rational) { /* Rational Keyboard Mode. * Transmit up to 4 characters for each key stroke. * Take the KeySym and split it into two 8 bit pieces; the upper 8 * and the lowere 8. * Between these two pieces we insert 3 bits; one each for Shift, * Control, and Meta. Take the resulting 19 bits and break it up * into groups of 6 bits. Non-zero groups get sent. See ratmenu.h * for the actual code. * We ignore modifiers Mod2..Mod5 completely. So far we don't have * any customers that have more than Control/Meta/Shift as modifiers. * If we ever get one that has more modifiers then there are the 2 * available bits at the top of the first character. After than we * could try xor'ing those bits with the high order bits of the KeySym * value. The rationale is that the high order bits differentiate the * various character sets; one keyboard is unlikely to be able to * transmit more than one disseparate sets at one moment. (You also * have to be an octopus to use 5 Meta keys plus Control and Shift at * the same time.) GEB 06/16/88 */ register KeySym keycode; char buf[4]; char *bp = &buf[0]; key = event->keycode; /* key pressed */ col = event->state; /* modifier state */ /*--If Shift is down; if Lock is set and we have ShiftLock; * if Lock is set and we are an English letter; then go for the * shifted KeySym. If he isn't there then take his unshifted KeySym * and retain the ShiftMask flag. The tables will have both forms * (A/a,B/b,...) for letter keys with one caption on them. */ keycode = KeyCodeTable_Shifted[key]; if (col & ShiftMask || (col & LockMask && (KeyCodeTable_ShiftLock || (keycode >= XK_A && keycode <= XK_Z)))) { if (keycode == NoSymbol) { if ((key = KeyCodeTable_Unshifted[key]) == NoSymbol) { return; /* Modifier or an Unreal key */ }; col |= ShiftMask; } else { key = keycode; col &= ~ShiftMask; } } else { if ((key = KeyCodeTable_Unshifted[key]) == NoSymbol) { return; } } /*--Watch out for DEC's vendor-specific keysyms. We remove the * funny high order bit(s) and also remove bit 15 (0x8000) in order * to keep their vendor-specific keysyms from conflicting with * our Rational Mouse fake-keys which have codes 0xFF00..0xFF08. */ if (key & 0x10000000) { key &= 0x7FFF; } /*--Figure the characters and put them out. */ col = (col & ControlMask ? RControlMask : 0) | (col & Mod1Mask ? RMod1Mask : 0) | (col & ShiftMask ? RShiftMask : 0); DoRMaskChar( bp, col, key ); v_write( pty, buf, (int)(bp-buf) ); key = TRUE; } else { char strbuf[STRBUFSIZE]; register char *string; int nbytes; KeySym keycode; ANSI reply; /*--Normal VT100 keystrokes. */ nbytes = XLookupString ((XKeyEvent *)event, strbuf, STRBUFSIZE, &keycode, &compose_status); string = &strbuf[0]; reply.a_pintro = 0; reply.a_final = 0; reply.a_nparam = 0; reply.a_inters = 0; if (IsPFKey(keycode)) { reply.a_type = SS3; unparseseq(&reply, pty); unparseputc((char)(keycode-XK_KP_F1+'P'), pty); key = TRUE; } else if (IsKeypadKey(keycode)) { if (keyboard->flags & KYPD_APL) { reply.a_type = SS3; unparseseq(&reply, pty); unparseputc(kypd_apl[keycode-XK_KP_Space], pty); } else unparseputc(kypd_num[keycode-XK_KP_Space], pty); key = TRUE; } else if (IsCursorKey(keycode) && keycode != XK_Prior && keycode != XK_Next) { if (keyboard->flags & CURSOR_APL) { reply.a_type = SS3; unparseseq(&reply, pty); unparseputc(cur[keycode-XK_Left], pty); } else { reply.a_type = CSI; reply.a_final = cur[keycode-XK_Left]; unparseseq(&reply, pty); } key = TRUE; } else if (IsFunctionKey(keycode) || IsMiscFunctionKey(keycode) || keycode == XK_Prior || keycode == XK_Next || keycode == DXK_Remove) { reply.a_type = CSI; reply.a_nparam = 1; if (sunFunctionKeys) { reply.a_param[0] = sunfuncvalue (keycode); reply.a_final = 'z'; } else { reply.a_param[0] = funcvalue (keycode); reply.a_final = '~'; } if (reply.a_param[0] > 0) unparseseq(&reply, pty); key = TRUE; } else if (nbytes > 0) { if ((nbytes == 1) && eightbit) { if (screen->eight_bits) *string |= 0x80; /* turn on eighth bit */ else unparseputc (033, pty); /* escape */ } while (nbytes-- > 0) unparseputc(*string++, pty); key = TRUE; } } if(key) AdjustAfterInput(screen); return; } StringInput (screen, string) register TScreen *screen; register char *string; { int pty = screen->respond; int nbytes; nbytes = strlen(string); while (nbytes-- > 0) unparseputc(*string++, pty); AdjustAfterInput(screen); } static int funcvalue (keycode) int keycode; { switch (keycode) { case XK_F1: return(11); case XK_F2: return(12); case XK_F3: return(13); case XK_F4: return(14); case XK_F5: return(15); case XK_F6: return(17); case XK_F7: return(18); case XK_F8: return(19); case XK_F9: return(20); case XK_F10: return(21); case XK_F11: return(23); case XK_F12: return(24); case XK_F13: return(25); case XK_F14: return(26); case XK_F15: return(28); case XK_Help: return(28); case XK_F16: return(29); case XK_Menu: return(29); case XK_F17: return(31); case XK_F18: return(32); case XK_F19: return(33); case XK_F20: return(34); case XK_Find : return(1); case XK_Insert: return(2); case XK_Delete: return(3); case DXK_Remove: return(3); case XK_Select: return(4); case XK_Prior: return(5); case XK_Next: return(6); default: return(-1); } } static int sunfuncvalue (keycode) int keycode; { switch (keycode) { case XK_F1: return(224); case XK_F2: return(225); case XK_F3: return(226); case XK_F4: return(227); case XK_F5: return(228); case XK_F6: return(229); case XK_F7: return(230); case XK_F8: return(231); case XK_F9: return(232); case XK_F10: return(233); case XK_F11: return(192); case XK_F12: return(193); case XK_F13: return(194); case XK_F14: return(195); case XK_F15: return(196); case XK_Help: return(196); case XK_F16: return(197); case XK_Menu: return(197); case XK_F17: return(198); case XK_F18: return(199); case XK_F19: return(200); case XK_F20: return(201); case XK_R1: return(208); case XK_R2: return(209); case XK_R3: return(210); case XK_R4: return(211); case XK_R5: return(212); case XK_R6: return(213); case XK_R7: return(214); case XK_R8: return(215); case XK_R9: return(216); case XK_R10: return(217); case XK_R11: return(218); case XK_R12: return(219); case XK_R13: return(220); case XK_R14: return(221); case XK_R15: return(222); case XK_Find : return(1); case XK_Insert: return(2); case XK_Delete: return(3); case DXK_Remove: return(3); case XK_Select: return(4); case XK_Prior: return(5); case XK_Next: return(6); default: return(-1); } }