/*********************************************************** Copyright (c) 1993, Oracle and/or its affiliates. Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice (including the next paragraph) shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. Copyright 1987, 1988 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 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. ******************************************************************/ /* Copyright 1987, 1988, 1998 The Open Group Permission to use, copy, modify, distribute, and sell this software and its documentation for any purpose is hereby granted without fee, provided that the above copyright notice appear in all copies and that both that copyright notice and this permission notice appear in supporting documentation. The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE OPEN GROUP BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. Except as contained in this notice, the name of The Open Group shall not be used in advertising or otherwise to promote the sale, use or other dealings in this Software without prior written authorization from The Open Group. */ #ifdef HAVE_CONFIG_H #include #endif #include "IntrinsicI.h" #include typedef struct _TMStringBufRec { _XtString start; _XtString current; Cardinal max; } TMStringBufRec, *TMStringBuf; #define STR_THRESHOLD 25 #define STR_INCAMOUNT 100 #define CHECK_STR_OVERFLOW(sb) \ if (sb->current - sb->start > (int)sb->max - STR_THRESHOLD) \ { \ _XtString old = sb->start; \ sb->start = XtRealloc(old, (Cardinal)(sb->max += STR_INCAMOUNT)); \ sb->current = sb->current - old + sb->start; \ } #define ExpandForChars(sb, nchars ) \ if ((unsigned)(sb->current - sb->start) > (sb->max - STR_THRESHOLD - (Cardinal) nchars)) { \ _XtString old = sb->start; \ sb->start = XtRealloc(old, \ (Cardinal)(sb->max = (Cardinal)(sb->max + STR_INCAMOUNT + (Cardinal) nchars))); \ sb->current = sb->current - old + sb->start; \ } #define ExpandToFit(sb, more) \ { \ size_t l = strlen(more); \ ExpandForChars(sb, l); \ } static void PrintModifiers(TMStringBuf sb, unsigned long mask, unsigned long mod) { Boolean notfirst = False; CHECK_STR_OVERFLOW(sb); if (mask == ~0UL && mod == 0) { *sb->current++ = '!'; *sb->current = '\0'; return; } #define PRINTMOD(modmask,modstring) \ if (mask & modmask) { \ if (! (mod & modmask)) { \ *sb->current++ = '~'; \ notfirst = True; \ } \ else if (notfirst) \ *sb->current++ = ' '; \ else notfirst = True; \ strcpy(sb->current, modstring); \ sb->current += strlen(sb->current); \ } PRINTMOD(ShiftMask, "Shift"); PRINTMOD(ControlMask, "Ctrl"); /* name is not CtrlMask... */ PRINTMOD(LockMask, "Lock"); PRINTMOD(Mod1Mask, "Mod1"); CHECK_STR_OVERFLOW(sb); PRINTMOD(Mod2Mask, "Mod2"); PRINTMOD(Mod3Mask, "Mod3"); PRINTMOD(Mod4Mask, "Mod4"); PRINTMOD(Mod5Mask, "Mod5"); CHECK_STR_OVERFLOW(sb); PRINTMOD(Button1Mask, "Button1"); PRINTMOD(Button2Mask, "Button2"); PRINTMOD(Button3Mask, "Button3"); CHECK_STR_OVERFLOW(sb); PRINTMOD(Button4Mask, "Button4"); PRINTMOD(Button5Mask, "Button5"); (void) notfirst; #undef PRINTMOD } static void PrintEventType(TMStringBuf sb, unsigned long event) { CHECK_STR_OVERFLOW(sb); switch (event) { #define PRINTEVENT(event, name) case event: (void) strcpy(sb->current, name); break; PRINTEVENT(KeyPress, "") PRINTEVENT(KeyRelease, "") PRINTEVENT(ButtonPress, "") PRINTEVENT(ButtonRelease, "") PRINTEVENT(MotionNotify, "") PRINTEVENT(EnterNotify, "") PRINTEVENT(LeaveNotify, "") PRINTEVENT(FocusIn, "") PRINTEVENT(FocusOut, "") PRINTEVENT(KeymapNotify, "") PRINTEVENT(Expose, "") PRINTEVENT(GraphicsExpose, "") PRINTEVENT(NoExpose, "") PRINTEVENT(VisibilityNotify, "") PRINTEVENT(CreateNotify, "") PRINTEVENT(DestroyNotify, "") PRINTEVENT(UnmapNotify, "") PRINTEVENT(MapNotify, "") PRINTEVENT(MapRequest, "") PRINTEVENT(ReparentNotify, "") PRINTEVENT(ConfigureNotify, "") PRINTEVENT(ConfigureRequest, "") PRINTEVENT(GravityNotify, "") PRINTEVENT(ResizeRequest, "") PRINTEVENT(CirculateNotify, "") PRINTEVENT(CirculateRequest, "") PRINTEVENT(PropertyNotify, "") PRINTEVENT(SelectionClear, "") PRINTEVENT(SelectionRequest, "") PRINTEVENT(SelectionNotify, "") PRINTEVENT(ColormapNotify, "") PRINTEVENT(ClientMessage, "") case _XtEventTimerEventType: (void) strcpy(sb->current, ""); break; default: (void) sprintf(sb->current, "<0x%x>", (int) event); #undef PRINTEVENT } sb->current += strlen(sb->current); } static void PrintCode(TMStringBuf sb, unsigned long mask, unsigned long code) { CHECK_STR_OVERFLOW(sb); if (mask != 0) { if (mask != ~0UL) (void) sprintf(sb->current, "0x%lx:0x%lx", mask, code); else (void) sprintf(sb->current, /*"0x%lx" */ "%u", (unsigned) code); sb->current += strlen(sb->current); } } static void PrintKeysym(TMStringBuf sb, KeySym keysym) { String keysymName; if (keysym == 0) return; CHECK_STR_OVERFLOW(sb); keysymName = XKeysymToString(keysym); if (keysymName == NULL) PrintCode(sb, ~0UL, (unsigned long) keysym); else { ExpandToFit(sb, keysymName); strcpy(sb->current, keysymName); sb->current += strlen(sb->current); } } static void PrintAtom(TMStringBuf sb, Display *dpy, Atom atom) { _XtString atomName; if (atom == 0) return; atomName = (dpy ? XGetAtomName(dpy, atom) : NULL); if (!atomName) PrintCode(sb, ~0UL, (unsigned long) atom); else { ExpandToFit(sb, atomName); strcpy(sb->current, atomName); sb->current += strlen(sb->current); XFree(atomName); } } static void PrintLateModifiers(TMStringBuf sb, LateBindingsPtr lateModifiers) { for (; lateModifiers->keysym; lateModifiers++) { CHECK_STR_OVERFLOW(sb); if (lateModifiers->knot) { *sb->current++ = '~'; } else { *sb->current++ = ' '; } strcpy(sb->current, XKeysymToString(lateModifiers->keysym)); sb->current += strlen(sb->current); if (lateModifiers->pair) { *(sb->current -= 2) = '\0'; /* strip "_L" */ lateModifiers++; /* skip _R keysym */ } } } static void PrintEvent(TMStringBuf sb, register TMTypeMatch typeMatch, register TMModifierMatch modMatch, Display *dpy) { if (modMatch->standard) *sb->current++ = ':'; PrintModifiers(sb, modMatch->modifierMask, modMatch->modifiers); if (modMatch->lateModifiers != NULL) PrintLateModifiers(sb, modMatch->lateModifiers); PrintEventType(sb, typeMatch->eventType); switch (typeMatch->eventType) { case KeyPress: case KeyRelease: PrintKeysym(sb, (KeySym) typeMatch->eventCode); break; case PropertyNotify: case SelectionClear: case SelectionRequest: case SelectionNotify: case ClientMessage: PrintAtom(sb, dpy, (Atom) typeMatch->eventCode); break; default: PrintCode(sb, typeMatch->eventCodeMask, typeMatch->eventCode); } } static void PrintParams(TMStringBuf sb, String *params, Cardinal num_params) { register Cardinal i; for (i = 0; i < num_params; i++) { ExpandToFit(sb, params[i]); if (i != 0) { *sb->current++ = ','; *sb->current++ = ' '; } *sb->current++ = '"'; strcpy(sb->current, params[i]); sb->current += strlen(sb->current); *sb->current++ = '"'; } *sb->current = '\0'; } static void PrintActions(TMStringBuf sb, register ActionPtr actions, XrmQuark *quarkTbl, Widget accelWidget) { while (actions != NULL) { String proc; *sb->current++ = ' '; if (accelWidget) { /* accelerator */ String name = XtName(accelWidget); int nameLen = (int) strlen(name); ExpandForChars(sb, nameLen); XtMemmove(sb->current, name, nameLen); sb->current += nameLen; *sb->current++ = '`'; } proc = XrmQuarkToString(quarkTbl[actions->idx]); ExpandToFit(sb, proc); strcpy(sb->current, proc); sb->current += strlen(proc); *sb->current++ = '('; PrintParams(sb, actions->params, actions->num_params); *sb->current++ = ')'; actions = actions->next; } *sb->current = '\0'; } static Boolean LookAheadForCycleOrMulticlick(register StatePtr state, StatePtr *state_return, /* state to print, usually startState */ int *countP, StatePtr *nextLevelP) { int repeatCount = 0; StatePtr startState = state; Boolean isCycle = startState->isCycleEnd; TMTypeMatch sTypeMatch; TMModifierMatch sModMatch; LOCK_PROCESS; sTypeMatch = TMGetTypeMatch(startState->typeIndex); sModMatch = TMGetModifierMatch(startState->modIndex); *state_return = startState; for (state = state->nextLevel; state != NULL; state = state->nextLevel) { TMTypeMatch typeMatch = TMGetTypeMatch(state->typeIndex); TMModifierMatch modMatch = TMGetModifierMatch(state->modIndex); /* try to pick up the correct state with actions, to be printed */ /* This is to accommodate (2+), for example */ if (state->isCycleStart) *state_return = state; if (state->isCycleEnd) { *countP = repeatCount; UNLOCK_PROCESS; return True; } if ((startState->typeIndex == state->typeIndex) && (startState->modIndex == state->modIndex)) { repeatCount++; *nextLevelP = state; } else if (typeMatch->eventType == _XtEventTimerEventType) continue; else { /* not same event as starting event and not timer */ unsigned int type = (unsigned) sTypeMatch->eventType; unsigned int t = (unsigned) typeMatch->eventType; if ((type == ButtonPress && t != ButtonRelease) || (type == ButtonRelease && t != ButtonPress) || (type == KeyPress && t != KeyRelease) || (type == KeyRelease && t != KeyPress) || typeMatch->eventCode != sTypeMatch->eventCode || modMatch->modifiers != sModMatch->modifiers || modMatch->modifierMask != sModMatch->modifierMask || modMatch->lateModifiers != sModMatch->lateModifiers || typeMatch->eventCodeMask != sTypeMatch->eventCodeMask || typeMatch->matchEvent != sTypeMatch->matchEvent || modMatch->standard != sModMatch->standard) /* not inverse of starting event, either */ break; } } *countP = repeatCount; UNLOCK_PROCESS; return isCycle; } static void PrintComplexState(TMStringBuf sb, Boolean includeRHS, StatePtr state, TMStateTree stateTree, Widget accelWidget, Display *dpy) { int clickCount = 0; Boolean cycle; StatePtr nextLevel = NULL; StatePtr triggerState = NULL; /* print the current state */ if (!state) return; LOCK_PROCESS; cycle = LookAheadForCycleOrMulticlick(state, &triggerState, &clickCount, &nextLevel); PrintEvent(sb, TMGetTypeMatch(triggerState->typeIndex), TMGetModifierMatch(triggerState->modIndex), dpy); if (cycle || clickCount) { if (clickCount) sprintf(sb->current, "(%d%s)", clickCount + 1, cycle ? "+" : ""); else (void) strncpy(sb->current, "(+)", 4); sb->current += strlen(sb->current); if (!state->actions && nextLevel) state = nextLevel; while (!state->actions && !state->isCycleEnd) state = state->nextLevel; /* should be trigger state */ } if (state->actions) { if (includeRHS) { CHECK_STR_OVERFLOW(sb); *sb->current++ = ':'; PrintActions(sb, state->actions, ((TMSimpleStateTree) stateTree)->quarkTbl, accelWidget); *sb->current++ = '\n'; } } else { if (state->nextLevel && !cycle && !clickCount) *sb->current++ = ','; else { /* no actions are attached to this production */ *sb->current++ = ':'; *sb->current++ = '\n'; } } *sb->current = '\0'; /* print succeeding states */ if (state->nextLevel && !cycle && !clickCount) PrintComplexState(sb, includeRHS, state->nextLevel, stateTree, accelWidget, dpy); UNLOCK_PROCESS; } typedef struct { TMShortCard tIndex; TMShortCard bIndex; } PrintRec, *Print; static int FindNextMatch(PrintRec *printData, TMShortCard numPrints, XtTranslations xlations, TMBranchHead branchHead, StatePtr nextLevel, TMShortCard startIndex) { TMShortCard i; StatePtr currState, candState; Boolean noMatch = True; for (i = startIndex; noMatch && i < numPrints; i++) { TMBranchHead prBranchHead; TMComplexStateTree stateTree; stateTree = (TMComplexStateTree) xlations->stateTreeTbl[printData[i].tIndex]; prBranchHead = &(stateTree->branchHeadTbl[printData[i].bIndex]); if ((prBranchHead->typeIndex == branchHead->typeIndex) && (prBranchHead->modIndex == branchHead->modIndex)) { if (prBranchHead->isSimple) { if (!nextLevel) return i; } else { currState = TMComplexBranchHead(stateTree, prBranchHead); currState = currState->nextLevel; candState = nextLevel; for (; ((currState && !currState->isCycleEnd) && (candState && !candState->isCycleEnd)); currState = currState->nextLevel, candState = candState->nextLevel) { if ((currState->typeIndex != candState->typeIndex) || (currState->modIndex != candState->modIndex)) break; } if (candState == currState) { return i; } } } } return TM_NO_MATCH; } static void ProcessLaterMatches(PrintRec *printData, XtTranslations xlations, TMShortCard tIndex, int bIndex, TMShortCard *numPrintsRtn) { TMComplexStateTree stateTree; int i, j; TMBranchHead branchHead, matchBranch = NULL; for (i = tIndex; i < (int) xlations->numStateTrees; i++) { stateTree = (TMComplexStateTree) xlations->stateTreeTbl[i]; if (i == tIndex) { matchBranch = &stateTree->branchHeadTbl[bIndex]; j = bIndex + 1; } else j = 0; for (branchHead = &stateTree->branchHeadTbl[j]; j < (int) stateTree->numBranchHeads; j++, branchHead++) { if ((branchHead->typeIndex == matchBranch->typeIndex) && (branchHead->modIndex == matchBranch->modIndex)) { StatePtr state; if (!branchHead->isSimple) state = TMComplexBranchHead(stateTree, branchHead); else state = NULL; if ((!branchHead->isSimple || branchHead->hasActions) && (FindNextMatch(printData, *numPrintsRtn, xlations, branchHead, (state ? state->nextLevel : NULL), 0) == TM_NO_MATCH)) { printData[*numPrintsRtn].tIndex = (TMShortCard) i; printData[*numPrintsRtn].bIndex = (TMShortCard) j; (*numPrintsRtn)++; } } } } } static void ProcessStateTree(PrintRec *printData, XtTranslations xlations, TMShortCard tIndex, TMShortCard *numPrintsRtn) { TMComplexStateTree stateTree; int i; TMBranchHead branchHead; stateTree = (TMComplexStateTree) xlations->stateTreeTbl[tIndex]; for (i = 0, branchHead = stateTree->branchHeadTbl; i < (int) stateTree->numBranchHeads; i++, branchHead++) { StatePtr state; if (!branchHead->isSimple) state = TMComplexBranchHead(stateTree, branchHead); else state = NULL; if (FindNextMatch(printData, *numPrintsRtn, xlations, branchHead, (state ? state->nextLevel : NULL), 0) == TM_NO_MATCH) { if (!branchHead->isSimple || branchHead->hasActions) { printData[*numPrintsRtn].tIndex = tIndex; printData[*numPrintsRtn].bIndex = (TMShortCard) i; (*numPrintsRtn)++; } LOCK_PROCESS; if (_XtGlobalTM.newMatchSemantics == False) ProcessLaterMatches(printData, xlations, tIndex, i, numPrintsRtn); UNLOCK_PROCESS; } } } static void PrintState(TMStringBuf sb, TMStateTree tree, TMBranchHead branchHead, Boolean includeRHS, Widget accelWidget, Display *dpy) { TMComplexStateTree stateTree = (TMComplexStateTree) tree; LOCK_PROCESS; if (branchHead->isSimple) { PrintEvent(sb, TMGetTypeMatch(branchHead->typeIndex), TMGetModifierMatch(branchHead->modIndex), dpy); if (includeRHS) { ActionRec actRec; CHECK_STR_OVERFLOW(sb); *sb->current++ = ':'; actRec.idx = TMBranchMore(branchHead); actRec.num_params = 0; actRec.params = NULL; actRec.next = NULL; PrintActions(sb, &actRec, stateTree->quarkTbl, accelWidget); *sb->current++ = '\n'; } else *sb->current++ = ','; #ifdef TRACE_TM if (!branchHead->hasActions) printf(" !! no actions !! "); #endif } else { /* it's a complex branchHead */ StatePtr state = TMComplexBranchHead(stateTree, branchHead); PrintComplexState(sb, includeRHS, state, tree, accelWidget, (Display *) NULL); } *sb->current = '\0'; UNLOCK_PROCESS; } _XtString _XtPrintXlations(Widget w, XtTranslations xlations, Widget accelWidget, _XtBoolean includeRHS) { register Cardinal i; #define STACKPRINTSIZE 250 PrintRec stackPrints[STACKPRINTSIZE]; PrintRec *prints; TMStringBufRec sbRec, *sb = &sbRec; TMShortCard numPrints, maxPrints; #ifdef TRACE_TM TMBindData bindData = (TMBindData) w->core.tm.proc_table; Boolean hasAccel = (accelWidget ? True : False); #endif /* TRACE_TM */ if (xlations == NULL) return NULL; sb->current = sb->start = __XtMalloc((Cardinal) 1000); sb->max = 1000; maxPrints = 0; for (i = 0; i < xlations->numStateTrees; i++) maxPrints = (TMShortCard) (maxPrints + ((TMSimpleStateTree) (xlations->stateTreeTbl[i]))-> numBranchHeads); prints = (PrintRec *) XtStackAlloc(maxPrints * sizeof(PrintRec), stackPrints); numPrints = 0; for (i = 0; i < xlations->numStateTrees; i++) ProcessStateTree(prints, xlations, (TMShortCard) i, &numPrints); for (i = 0; i < numPrints; i++) { TMSimpleStateTree stateTree = (TMSimpleStateTree) xlations->stateTreeTbl[prints[i].tIndex]; TMBranchHead branchHead = &stateTree->branchHeadTbl[prints[i].bIndex]; #ifdef TRACE_TM TMComplexBindProcs complexBindProcs; if (hasAccel == False) { accelWidget = NULL; if (bindData->simple.isComplex) { complexBindProcs = TMGetComplexBindEntry(bindData, 0); accelWidget = complexBindProcs[prints[i].tIndex].widget; } } #endif /* TRACE_TM */ PrintState(sb, (TMStateTree) stateTree, branchHead, (Boolean) includeRHS, accelWidget, XtDisplay(w)); } XtStackFree((XtPointer) prints, (XtPointer) stackPrints); return (sb->start); } #ifndef NO_MIT_HACKS void _XtDisplayTranslations(Widget widget, XEvent *event _X_UNUSED, String *params _X_UNUSED, Cardinal *num_params _X_UNUSED) { _XtString xString; xString = _XtPrintXlations(widget, widget->core.tm.translations, NULL, True); if (xString) { printf("%s\n", xString); XtFree(xString); } } void _XtDisplayAccelerators(Widget widget, XEvent *event _X_UNUSED, String *params _X_UNUSED, Cardinal *num_params _X_UNUSED) { _XtString xString; xString = _XtPrintXlations(widget, widget->core.accelerators, NULL, True); if (xString) { printf("%s\n", xString); XtFree(xString); } } void _XtDisplayInstalledAccelerators(Widget widget, XEvent *event, String *params _X_UNUSED, Cardinal *num_params _X_UNUSED) { Widget eventWidget = XtWindowToWidget(event->xany.display, event->xany.window); register Cardinal i; TMStringBufRec sbRec, *sb = &sbRec; XtTranslations xlations; #define STACKPRINTSIZE 250 PrintRec stackPrints[STACKPRINTSIZE]; PrintRec *prints; TMShortCard numPrints, maxPrints; TMBindData bindData; TMComplexBindProcs complexBindProcs; if ((eventWidget == NULL) || (eventWidget->core.tm.translations == NULL)) return; xlations = eventWidget->core.tm.translations; bindData = (TMBindData) eventWidget->core.tm.proc_table; if (bindData->simple.isComplex == False) return; sb->current = sb->start = __XtMalloc((Cardinal) 1000); sb->start[0] = '\0'; sb->max = 1000; maxPrints = 0; for (i = 0; i < xlations->numStateTrees; i++) maxPrints = (TMShortCard) (maxPrints + ((TMSimpleStateTree) xlations-> stateTreeTbl[i])->numBranchHeads); prints = (PrintRec *) XtStackAlloc(maxPrints * sizeof(PrintRec), stackPrints); numPrints = 0; complexBindProcs = TMGetComplexBindEntry(bindData, 0); for (i = 0; i < xlations->numStateTrees; i++, complexBindProcs++) { if (complexBindProcs->widget) { ProcessStateTree(prints, xlations, (TMShortCard) i, &numPrints); } } for (i = 0; i < numPrints; i++) { TMSimpleStateTree stateTree = (TMSimpleStateTree) xlations->stateTreeTbl[prints[i].tIndex]; TMBranchHead branchHead = &stateTree->branchHeadTbl[prints[i].bIndex]; complexBindProcs = TMGetComplexBindEntry(bindData, 0); PrintState(sb, (TMStateTree) stateTree, branchHead, True, complexBindProcs[prints[i].tIndex].widget, XtDisplay(widget)); } XtStackFree((XtPointer) prints, (XtPointer) stackPrints); printf("%s\n", sb->start); XtFree(sb->start); } #endif /*NO_MIT_HACKS */ String _XtPrintActions(register ActionRec *actions, XrmQuark *quarkTbl) { TMStringBufRec sbRec, *sb = &sbRec; sb->max = 1000; sb->current = sb->start = __XtMalloc((Cardinal) 1000); PrintActions(sb, actions, quarkTbl, (Widget) NULL); return sb->start; } String _XtPrintState(TMStateTree stateTree, TMBranchHead branchHead) { TMStringBufRec sbRec, *sb = &sbRec; sb->current = sb->start = __XtMalloc((Cardinal) 1000); sb->max = 1000; PrintState(sb, stateTree, branchHead, True, (Widget) NULL, (Display *) NULL); return sb->start; } String _XtPrintEventSeq(register EventSeqPtr eventSeq, Display *dpy) { TMStringBufRec sbRec, *sb = &sbRec; #define MAXSEQS 100 EventSeqPtr eventSeqs[MAXSEQS]; TMShortCard i, j; Boolean cycle = False; sb->current = sb->start = __XtMalloc((Cardinal) 1000); sb->max = 1000; for (i = 0; i < MAXSEQS && eventSeq != NULL && !cycle; eventSeq = eventSeq->next, i++) { eventSeqs[i] = eventSeq; for (j = 0; j < i && !cycle; j++) if (eventSeqs[j] == eventSeq) cycle = True; } LOCK_PROCESS; for (j = 0; j < i; j++) { TMTypeMatch typeMatch; TMModifierMatch modMatch; typeMatch = TMGetTypeMatch(_XtGetTypeIndex(&eventSeqs[j]->event)); modMatch = TMGetModifierMatch(_XtGetModifierIndex(&eventSeqs[j]->event)); PrintEvent(sb, typeMatch, modMatch, dpy); *sb->current++ = ','; } UNLOCK_PROCESS; return sb->start; }