/************************************************************ Copyright (c) 1994 by Silicon Graphics Computer Systems, Inc. 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 Silicon Graphics not be used in advertising or publicity pertaining to distribution of the software without specific prior written permission. Silicon Graphics makes no representation about the suitability of this software for any purpose. It is provided "as is" without any express or implied warranty. SILICON GRAPHICS DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. IN NO EVENT SHALL SILICON GRAPHICS 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. ********************************************************/ #include #include "xkbcomp.h" #include "tokens.h" #include "expr.h" #include "vmod.h" #include "misc.h" #include "indicators.h" #include "action.h" #include "compat.h" typedef struct _SymInterpInfo { CommonInfo defs; XkbSymInterpretRec interp; } SymInterpInfo; #define _SI_VirtualMod (1<<0) #define _SI_Action (1<<1) #define _SI_AutoRepeat (1<<2) #define _SI_LockingKey (1<<3) #define _SI_LevelOneOnly (1<<4) typedef struct _GroupCompatInfo { unsigned char fileID; unsigned char merge; Bool defined; unsigned char real_mods; unsigned short vmods; } GroupCompatInfo; typedef struct _CompatInfo { char *name; unsigned fileID; int errorCount; int nInterps; SymInterpInfo *interps; SymInterpInfo dflt; LEDInfo ledDflt; GroupCompatInfo groupCompat[XkbNumKbdGroups]; LEDInfo *leds; VModInfo vmods; ActionInfo *act; XkbDescPtr xkb; } CompatInfo; /***====================================================================***/ #define ReportSINotArray(si,f,i) \ ReportNotArray("symbol interpretation",(f),siText((si),(i))) #define ReportSIBadType(si,f,w,i) \ ReportBadType("symbol interpretation",(f),siText((si),(i)),(w)) /***====================================================================***/ static char * siText(SymInterpInfo * si, CompatInfo * info) { static char buf[128]; if (si == &info->dflt) { snprintf(buf, sizeof(buf), "default"); } else { snprintf(buf, sizeof(buf), "%s+%s(%s)", XkbKeysymText(si->interp.sym, XkbMessage), XkbSIMatchText(si->interp.match, XkbMessage), XkbModMaskText(si->interp.mods, XkbMessage)); } return buf; } static void InitCompatInfo(CompatInfo * info, XkbDescPtr xkb) { info->xkb = xkb; info->name = NULL; info->fileID = 0; info->errorCount = 0; info->nInterps = 0; info->interps = NULL; info->act = NULL; info->dflt.defs.fileID = info->fileID; info->dflt.defs.defined = 0; info->dflt.defs.merge = MergeOverride; info->dflt.interp.flags = 0; info->dflt.interp.virtual_mod = XkbNoModifier; info->dflt.interp.act.type = XkbSA_NoAction; for (int i = 0; i < XkbAnyActionDataSize; i++) { info->dflt.interp.act.data[i] = 0; } ClearIndicatorMapInfo(xkb->dpy, &info->ledDflt); info->ledDflt.defs.fileID = info->fileID; info->ledDflt.defs.defined = 0; info->ledDflt.defs.merge = MergeOverride; bzero(&info->groupCompat[0], XkbNumKbdGroups * sizeof(GroupCompatInfo)); info->leds = NULL; InitVModInfo(&info->vmods, xkb); return; } static void ClearCompatInfo(CompatInfo * info, XkbDescPtr xkb) { free(info->name); info->name = NULL; info->dflt.defs.defined = 0; info->dflt.defs.merge = MergeAugment; info->dflt.interp.flags = 0; info->dflt.interp.virtual_mod = XkbNoModifier; info->dflt.interp.act.type = XkbSA_NoAction; for (int i = 0; i < XkbAnyActionDataSize; i++) { info->dflt.interp.act.data[i] = 0; } ClearIndicatorMapInfo(xkb->dpy, &info->ledDflt); info->nInterps = 0; info->interps = (SymInterpInfo *) ClearCommonInfo(&info->interps->defs); bzero(&info->groupCompat[0], XkbNumKbdGroups * sizeof(GroupCompatInfo)); info->leds = (LEDInfo *) ClearCommonInfo(&info->leds->defs); /* 3/30/94 (ef) -- XXX! Should free action info here */ ClearVModInfo(&info->vmods, xkb); return; } static SymInterpInfo * NextInterp(CompatInfo * info) { SymInterpInfo *si; si = calloc(1, sizeof(SymInterpInfo)); if (si) { info->interps = (SymInterpInfo *) AddCommonInfo(&info->interps->defs, (CommonInfo *) si); info->nInterps++; } return si; } static SymInterpInfo * FindMatchingInterp(CompatInfo * info, SymInterpInfo * new) { SymInterpInfo *old; for (old = info->interps; old != NULL; old = (SymInterpInfo *) old->defs.next) { if ((old->interp.sym == new->interp.sym) && (old->interp.mods == new->interp.mods) && (old->interp.match == new->interp.match)) { return old; } } return NULL; } static Bool AddInterp(CompatInfo * info, SymInterpInfo * new) { SymInterpInfo *old; old = FindMatchingInterp(info, new); if (old != NULL) { unsigned collide = 0; if (new->defs.merge == MergeReplace) { SymInterpInfo *next = (SymInterpInfo *) old->defs.next; if (((old->defs.fileID == new->defs.fileID) && (warningLevel > 0)) || (warningLevel > 9)) { WARN("Multiple definitions for \"%s\"\n", siText(new, info)); ACTION("Earlier interpretation ignored\n"); } *old = *new; old->defs.next = &next->defs; return True; } if (UseNewField(_SI_VirtualMod, &old->defs, &new->defs, &collide)) { old->interp.virtual_mod = new->interp.virtual_mod; old->defs.defined |= _SI_VirtualMod; } if (UseNewField(_SI_Action, &old->defs, &new->defs, &collide)) { old->interp.act = new->interp.act; old->defs.defined |= _SI_Action; } if (UseNewField(_SI_AutoRepeat, &old->defs, &new->defs, &collide)) { old->interp.flags &= ~XkbSI_AutoRepeat; old->interp.flags |= (new->interp.flags & XkbSI_AutoRepeat); old->defs.defined |= _SI_AutoRepeat; } if (UseNewField(_SI_LockingKey, &old->defs, &new->defs, &collide)) { old->interp.flags &= ~XkbSI_LockingKey; old->interp.flags |= (new->interp.flags & XkbSI_LockingKey); old->defs.defined |= _SI_LockingKey; } if (UseNewField(_SI_LevelOneOnly, &old->defs, &new->defs, &collide)) { old->interp.match &= ~XkbSI_LevelOneOnly; old->interp.match |= (new->interp.match & XkbSI_LevelOneOnly); old->defs.defined |= _SI_LevelOneOnly; } if (collide && (warningLevel > 0)) { WARN("Multiple interpretations of \"%s\"\n", siText(new, info)); ACTION("Using %s definition for duplicate fields\n", (new->defs.merge != MergeAugment ? "last" : "first")); } return True; } old = new; if ((new = NextInterp(info)) == NULL) return False; *new = *old; new->defs.next = NULL; return True; } static Bool AddGroupCompat(CompatInfo * info, unsigned group, GroupCompatInfo * newGC) { GroupCompatInfo *gc; unsigned merge; merge = newGC->merge; gc = &info->groupCompat[group]; if (((gc->real_mods == newGC->real_mods) && (gc->vmods == newGC->vmods))) { return True; } if (((gc->defined && gc->fileID == newGC->fileID) && (warningLevel > 0)) || (warningLevel > 9)) { WARN("Compat map for group %d redefined\n", group + 1); ACTION("Using %s definition\n", (merge == MergeAugment ? "old" : "new")); } if(newGC->defined && (merge != MergeAugment || !gc->defined)) *gc = *newGC; return True; } /***====================================================================***/ static Bool ResolveStateAndPredicate(ExprDef * expr, unsigned *pred_rtrn, unsigned *mods_rtrn, CompatInfo * info) { ExprResult result; if (expr == NULL) { *pred_rtrn = XkbSI_AnyOfOrNone; *mods_rtrn = ~0; return True; } *pred_rtrn = XkbSI_Exactly; if (expr->op == ExprActionDecl) { char *pred_txt = XkbAtomText(NULL, expr->value.action.name, XkbMessage); if (uStrCaseCmp(pred_txt, "noneof") == 0) *pred_rtrn = XkbSI_NoneOf; else if (uStrCaseCmp(pred_txt, "anyofornone") == 0) *pred_rtrn = XkbSI_AnyOfOrNone; else if (uStrCaseCmp(pred_txt, "anyof") == 0) *pred_rtrn = XkbSI_AnyOf; else if (uStrCaseCmp(pred_txt, "allof") == 0) *pred_rtrn = XkbSI_AllOf; else if (uStrCaseCmp(pred_txt, "exactly") == 0) *pred_rtrn = XkbSI_Exactly; else { ERROR("Illegal modifier predicate \"%s\"\n", pred_txt); ACTION("Ignored\n"); return False; } expr = expr->value.action.args; } else if (expr->op == ExprIdent) { char *pred_txt = XkbAtomText(NULL, expr->value.str, XkbMessage); if ((pred_txt) && (uStrCaseCmp(pred_txt, "any") == 0)) { *pred_rtrn = XkbSI_AnyOf; *mods_rtrn = 0xff; return True; } } if (ExprResolveModMask(expr, &result, NULL, NULL)) { *mods_rtrn = result.uval; return True; } return False; } /***====================================================================***/ static void MergeIncludedCompatMaps(CompatInfo * into, CompatInfo * from, unsigned merge) { LEDInfo *next; GroupCompatInfo *gcm; int i; if (from->errorCount > 0) { into->errorCount += from->errorCount; return; } if (into->name == NULL) { into->name = from->name; from->name = NULL; } for (SymInterpInfo *si = from->interps; si; si = (SymInterpInfo *) si->defs.next) { if (merge != MergeDefault) si->defs.merge = merge; if (!AddInterp(into, si)) into->errorCount++; } for (i = 0, gcm = &from->groupCompat[0]; i < XkbNumKbdGroups; i++, gcm++) { if (merge != MergeDefault) gcm->merge = merge; if (!AddGroupCompat(into, i, gcm)) into->errorCount++; } for (LEDInfo *led = from->leds; led != NULL; led = next) { LEDInfo *rtrn; next = (LEDInfo *) led->defs.next; if (merge != MergeDefault) led->defs.merge = merge; rtrn = AddIndicatorMap(into->leds, led); if (rtrn != NULL) into->leds = rtrn; else into->errorCount++; } return; } typedef void (*FileHandler) (XkbFile * /* rtrn */ , XkbDescPtr /* xkb */ , unsigned /* merge */ , CompatInfo * /* info */ ); static Bool HandleIncludeCompatMap(IncludeStmt * stmt, XkbDescPtr xkb, CompatInfo * info, FileHandler hndlr) { unsigned newMerge; XkbFile *rtrn; CompatInfo included; Bool haveSelf; haveSelf = False; if ((stmt->file == NULL) && (stmt->map == NULL)) { haveSelf = True; included = *info; bzero(info, sizeof(CompatInfo)); } else if (ProcessIncludeFile(stmt, XkmCompatMapIndex, &rtrn, &newMerge)) { InitCompatInfo(&included, xkb); included.fileID = rtrn->id; included.dflt = info->dflt; included.dflt.defs.fileID = rtrn->id; included.dflt.defs.merge = newMerge; included.ledDflt.defs.fileID = rtrn->id; included.ledDflt.defs.merge = newMerge; included.act = info->act; (*hndlr) (rtrn, xkb, MergeOverride, &included); if (stmt->stmt != NULL) { free(included.name); included.name = stmt->stmt; stmt->stmt = NULL; } } else { info->errorCount += 10; return False; } if ((stmt->next != NULL) && (included.errorCount < 1)) { IncludeStmt *next; unsigned op; CompatInfo next_incl; for (next = stmt->next; next != NULL; next = next->next) { if ((next->file == NULL) && (next->map == NULL)) { haveSelf = True; MergeIncludedCompatMaps(&included, info, next->merge); ClearCompatInfo(info, xkb); } else if (ProcessIncludeFile(next, XkmCompatMapIndex, &rtrn, &op)) { InitCompatInfo(&next_incl, xkb); next_incl.fileID = rtrn->id; next_incl.dflt = info->dflt; next_incl.dflt.defs.fileID = rtrn->id; next_incl.dflt.defs.merge = op; next_incl.ledDflt.defs.fileID = rtrn->id; next_incl.ledDflt.defs.merge = op; next_incl.act = info->act; (*hndlr) (rtrn, xkb, MergeOverride, &next_incl); MergeIncludedCompatMaps(&included, &next_incl, op); ClearCompatInfo(&next_incl, xkb); } else { info->errorCount += 10; return False; } } } if (haveSelf) *info = included; else { MergeIncludedCompatMaps(info, &included, newMerge); ClearCompatInfo(&included, xkb); } return (info->errorCount == 0); } static LookupEntry useModMapValues[] = { {"levelone", 1}, {"level1", 1}, {"anylevel", 0}, {"any", 0}, {NULL, 0} }; static int SetInterpField(SymInterpInfo * si, XkbDescPtr xkb, const char *field, ExprDef * arrayNdx, ExprDef * value, CompatInfo * info) { int ok = 1; ExprResult tmp; if (uStrCaseCmp(field, "action") == 0) { if (arrayNdx != NULL) return ReportSINotArray(si, field, info); ok = HandleActionDef(value, xkb, &si->interp.act, si->defs.merge, info->act); if (ok) si->defs.defined |= _SI_Action; } else if ((uStrCaseCmp(field, "virtualmodifier") == 0) || (uStrCaseCmp(field, "virtualmod") == 0)) { if (arrayNdx != NULL) return ReportSINotArray(si, field, info); ok = ResolveVirtualModifier(value, &tmp, &info->vmods); if (ok) { si->interp.virtual_mod = tmp.uval; si->defs.defined |= _SI_VirtualMod; } else return ReportSIBadType(si, field, "virtual modifier", info); } else if (uStrCaseCmp(field, "repeat") == 0) { if (arrayNdx != NULL) return ReportSINotArray(si, field, info); ok = ExprResolveBoolean(value, &tmp, NULL, NULL); if (ok) { if (tmp.uval) si->interp.flags |= XkbSI_AutoRepeat; else si->interp.flags &= ~XkbSI_AutoRepeat; si->defs.defined |= _SI_AutoRepeat; } else return ReportSIBadType(si, field, "boolean", info); } else if (uStrCaseCmp(field, "locking") == 0) { if (arrayNdx != NULL) return ReportSINotArray(si, field, info); ok = ExprResolveBoolean(value, &tmp, NULL, NULL); if (ok) { if (tmp.uval) si->interp.flags |= XkbSI_LockingKey; else si->interp.flags &= ~XkbSI_LockingKey; si->defs.defined |= _SI_LockingKey; } else return ReportSIBadType(si, field, "boolean", info); } else if ((uStrCaseCmp(field, "usemodmap") == 0) || (uStrCaseCmp(field, "usemodmapmods") == 0)) { if (arrayNdx != NULL) return ReportSINotArray(si, field, info); ok = ExprResolveEnum(value, &tmp, useModMapValues); if (ok) { if (tmp.uval) si->interp.match |= XkbSI_LevelOneOnly; else si->interp.match &= ~XkbSI_LevelOneOnly; si->defs.defined |= _SI_LevelOneOnly; } else return ReportSIBadType(si, field, "level specification", info); } else { ok = ReportBadField("symbol interpretation", field, siText(si, info)); } return ok; } LookupEntry groupNames[] = { {"group1", 0x01} , {"group2", 0x02} , {"group3", 0x04} , {"group4", 0x08} , {"group5", 0x10} , {"group6", 0x20} , {"group7", 0x40} , {"group8", 0x80} , {"none", 0x00} , {"all", 0xff} , {NULL, 0} }; static int HandleInterpVar(VarDef * stmt, XkbDescPtr xkb, CompatInfo * info) { ExprResult elem, field; ExprDef *ndx; if (ExprResolveLhs(stmt->name, &elem, &field, &ndx) == 0) return 0; /* internal error, already reported */ if (elem.str && (uStrCaseCmp(elem.str, "interpret") == 0)) return SetInterpField(&info->dflt, xkb, field.str, ndx, stmt->value, info); if (elem.str && (uStrCaseCmp(elem.str, "indicator") == 0)) { return SetIndicatorMapField(&info->ledDflt, xkb, field.str, ndx, stmt->value); } return SetActionField(xkb, elem.str, field.str, ndx, stmt->value, &info->act); } static int HandleInterpBody(VarDef * def, XkbDescPtr xkb, SymInterpInfo * si, CompatInfo * info) { int ok = 1; ExprResult tmp, field; ExprDef *arrayNdx; for (; def != NULL; def = (VarDef *) def->common.next) { if ((def->name) && (def->name->type == ExprFieldRef)) { ok = HandleInterpVar(def, xkb, info); continue; } ok = ExprResolveLhs(def->name, &tmp, &field, &arrayNdx); if (ok) ok = SetInterpField(si, xkb, field.str, arrayNdx, def->value, info); } return ok; } static int HandleInterpDef(InterpDef * def, XkbDescPtr xkb, unsigned merge, CompatInfo * info) { unsigned pred, mods; SymInterpInfo si; if (!ResolveStateAndPredicate(def->match, &pred, &mods, info)) { ERROR("Couldn't determine matching modifiers\n"); ACTION("Symbol interpretation ignored\n"); return True; } if (def->ignore) { ERROR("Couldn't lookup keysym\n"); ACTION("Symbol interpretation ignored\n"); return True; } if (def->merge != MergeDefault) merge = def->merge; si = info->dflt; si.defs.merge = merge; si.interp.sym = def->sym; si.interp.match = pred & XkbSI_OpMask; si.interp.mods = mods; if (!HandleInterpBody(def->def, xkb, &si, info)) { info->errorCount++; return False; } if (!AddInterp(info, &si)) { info->errorCount++; return False; } return True; } static int HandleGroupCompatDef(GroupCompatDef * def, XkbDescPtr xkb, unsigned merge, CompatInfo * info) { ExprResult val; GroupCompatInfo tmp; if (def->merge != MergeDefault) merge = def->merge; if (!XkbIsLegalGroup(def->group - 1)) { ERROR("Keyboard group must be in the range 1..%d\n", XkbNumKbdGroups + 1); ACTION("Compatibility map for illegal group %d ignored\n", def->group); return False; } tmp.fileID = info->fileID; tmp.merge = merge; if (!ExprResolveModMask(def->def, &val, LookupVModMask, (XPointer) xkb)) { ERROR("Expected a modifier mask in group compatibility definition\n"); ACTION("Ignoring illegal compatibility map for group %d\n", def->group); return False; } tmp.real_mods = val.uval & 0xff; tmp.vmods = (val.uval >> 8) & 0xffff; tmp.defined = True; return AddGroupCompat(info, def->group - 1, &tmp); } static void HandleCompatMapFile(XkbFile * file, XkbDescPtr xkb, unsigned merge, CompatInfo * info) { ParseCommon *stmt; if (merge == MergeDefault) merge = MergeAugment; info->name = uStringDup(file->name); stmt = file->defs; while (stmt) { switch (stmt->stmtType) { case StmtInclude: if (!HandleIncludeCompatMap((IncludeStmt *) stmt, xkb, info, HandleCompatMapFile)) info->errorCount++; break; case StmtInterpDef: if (!HandleInterpDef((InterpDef *) stmt, xkb, merge, info)) info->errorCount++; break; case StmtGroupCompatDef: if (!HandleGroupCompatDef ((GroupCompatDef *) stmt, xkb, merge, info)) info->errorCount++; break; case StmtIndicatorMapDef: { LEDInfo *rtrn; rtrn = HandleIndicatorMapDef((IndicatorMapDef *) stmt, xkb, &info->ledDflt, info->leds, merge); if (rtrn != NULL) info->leds = rtrn; else info->errorCount++; } break; case StmtVarDef: if (!HandleInterpVar((VarDef *) stmt, xkb, info)) info->errorCount++; break; case StmtVModDef: if (!HandleVModDef((VModDef *) stmt, merge, &info->vmods)) info->errorCount++; break; case StmtKeycodeDef: ERROR("Interpretation files may not include other types\n"); ACTION("Ignoring definition of key name\n"); info->errorCount++; break; default: WSGO("Unexpected statement type %d in HandleCompatMapFile\n", stmt->stmtType); break; } stmt = stmt->next; if (info->errorCount > 10) { #ifdef NOISY ERROR("Too many errors\n"); #endif ACTION("Abandoning compatibility map \"%s\"\n", file->topName); break; } } return; } static void CopyInterps(CompatInfo * info, XkbCompatMapPtr compat, Bool needSymbol, unsigned pred) { for (SymInterpInfo *si = info->interps; si; si = (SymInterpInfo *) si->defs.next) { if (((si->interp.match & XkbSI_OpMask) != pred) || (needSymbol && (si->interp.sym == NoSymbol)) || ((!needSymbol) && (si->interp.sym != NoSymbol))) continue; if (compat->num_si >= compat->size_si) { WSGO("No room to merge symbol interpretations\n"); ACTION("Symbol interpretations lost\n"); return; } compat->sym_interpret[compat->num_si++] = si->interp; } return; } Bool CompileCompatMap(XkbFile * file, XkbFileInfo * result, unsigned merge, LEDInfo ** unboundLEDs) { CompatInfo info; XkbDescPtr xkb; xkb = result->xkb; InitCompatInfo(&info, xkb); info.dflt.defs.merge = merge; info.ledDflt.defs.merge = merge; HandleCompatMapFile(file, xkb, merge, &info); if (info.errorCount == 0) { int size, i; GroupCompatInfo *gcm; if (XkbAllocCompatMap(xkb, XkbAllCompatMask, info.nInterps) != Success) { WSGO("Couldn't allocate compatibility map\n"); ACTION("Exiting\n"); return False; } if (info.name != NULL) { if (XkbAllocNames(xkb, XkbCompatNameMask, 0, 0) == Success) xkb->names->compat = XkbInternAtom(xkb->dpy, info.name, False); else { WSGO("Couldn't allocate space for compat name\n"); ACTION("Name \"%s\" (from %s) NOT assigned\n", scanFile, info.name); } } size = info.nInterps * sizeof(XkbSymInterpretRec); if (size > 0) { CopyInterps(&info, xkb->compat, True, XkbSI_Exactly); CopyInterps(&info, xkb->compat, True, XkbSI_AllOf | XkbSI_NoneOf); CopyInterps(&info, xkb->compat, True, XkbSI_AnyOf); CopyInterps(&info, xkb->compat, True, XkbSI_AnyOfOrNone); CopyInterps(&info, xkb->compat, False, XkbSI_Exactly); CopyInterps(&info, xkb->compat, False, XkbSI_AllOf | XkbSI_NoneOf); CopyInterps(&info, xkb->compat, False, XkbSI_AnyOf); CopyInterps(&info, xkb->compat, False, XkbSI_AnyOfOrNone); } for (i = 0, gcm = &info.groupCompat[0]; i < XkbNumKbdGroups; i++, gcm++) { if ((gcm->fileID != 0) || (gcm->real_mods != 0) || (gcm->vmods != 0)) { xkb->compat->groups[i].mask = gcm->real_mods; xkb->compat->groups[i].real_mods = gcm->real_mods; xkb->compat->groups[i].vmods = gcm->vmods; } } if (info.leds != NULL) { if (!CopyIndicatorMapDefs(result, info.leds, unboundLEDs)) info.errorCount++; info.leds = NULL; } ClearCompatInfo(&info, xkb); return True; } free(info.interps); return False; }