/* ** thingdef_states.cpp ** ** Actor definitions - the state parser ** **--------------------------------------------------------------------------- ** Copyright 2002-2007 Christoph Oelckers ** Copyright 2004-2007 Randy Heit ** All rights reserved. ** ** Redistribution and use in source and binary forms, with or without ** modification, are permitted provided that the following conditions ** are met: ** ** 1. Redistributions of source code must retain the above copyright ** notice, this list of conditions and the following disclaimer. ** 2. Redistributions in binary form must reproduce the above copyright ** notice, this list of conditions and the following disclaimer in the ** documentation and/or other materials provided with the distribution. ** 3. The name of the author may not be used to endorse or promote products ** derived from this software without specific prior written permission. ** 4. When not used as part of ZDoom or a ZDoom derivative, this code will be ** covered by the terms of the GNU General Public License as published by ** the Free Software Foundation; either version 2 of the License, or (at ** your option) any later version. ** ** THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR ** IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES ** OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. ** IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, ** INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT ** NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, ** DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY ** THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT ** (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF ** THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. **--------------------------------------------------------------------------- ** */ #include "actor.h" #include "info.h" #include "sc_man.h" #include "tarray.h" #include "templates.h" #include "cmdlib.h" #include "p_lnspec.h" #include "a_action.h" #include "p_local.h" #include "v_palette.h" #include "doomerrors.h" #include "thingdef.h" #include "a_sharedglobal.h" #include "s_sound.h" #include "i_system.h" #include "colormatcher.h" #include "thingdef_exp.h" #include "version.h" #include "templates.h" TDeletingArray StateTempCalls; //========================================================================== //*** // DoActionSpecials // handles action specials as code pointers // //========================================================================== FxVMFunctionCall *DoActionSpecials(FScanner &sc, FState & state, Baggage &bag) { int i; int min_args, max_args; FString specname = sc.String; int special = P_FindLineSpecial(sc.String, &min_args, &max_args); if (special > 0 && min_args >= 0) { FArgumentList *args = new FArgumentList; args->Push(new FxParameter(new FxConstant(special, sc))); i = 0; // Make this consistent with all other parameter parsing if (sc.CheckToken('(')) { while (i < 5) { args->Push(new FxParameter(new FxIntCast(ParseExpression(sc, bag.Info)))); i++; if (!sc.CheckToken (',')) break; } sc.MustGetToken (')'); } if (i < min_args) { sc.ScriptError ("Too few arguments to %s", specname.GetChars()); } if (i > max_args) { sc.ScriptError ("Too many arguments to %s", specname.GetChars()); } return new FxVMFunctionCall(FindGlobalActionFunction("A_CallSpecial"), args, sc); } return NULL; } //========================================================================== //*** // Reads a state label that may contain '.'s. // processes a state block // //========================================================================== static FString ParseStateString(FScanner &sc) { FString statestring; sc.MustGetString(); statestring = sc.String; if (sc.CheckString("::")) { sc.MustGetString (); statestring << "::" << sc.String; } while (sc.CheckString (".")) { sc.MustGetString (); statestring << "." << sc.String; } return statestring; } //========================================================================== //*** // ParseStates // parses a state block // //========================================================================== void ParseStates(FScanner &sc, PClassActor * actor, AActor * defaults, Baggage &bag) { FString statestring; FState state; char lastsprite[5] = ""; FStateTempCall *tcall = NULL; FArgumentList *args = NULL; sc.MustGetStringName ("{"); sc.SetEscape(false); // disable escape sequences in the state parser while (!sc.CheckString ("}") && !sc.End) { memset(&state,0,sizeof(state)); statestring = ParseStateString(sc); if (!statestring.CompareNoCase("GOTO")) { do_goto: statestring = ParseStateString(sc); if (sc.CheckString ("+")) { sc.MustGetNumber (); statestring += '+'; statestring += sc.String; } if (!bag.statedef.SetGotoLabel(statestring)) { sc.ScriptError("GOTO before first state"); } } else if (!statestring.CompareNoCase("STOP")) { do_stop: if (!bag.statedef.SetStop()) { sc.ScriptError("STOP before first state"); continue; } } else if (!statestring.CompareNoCase("WAIT") || !statestring.CompareNoCase("FAIL")) { if (!bag.statedef.SetWait()) { sc.ScriptError("%s before first state", sc.String); continue; } } else if (!statestring.CompareNoCase("LOOP")) { if (!bag.statedef.SetLoop()) { sc.ScriptError("LOOP before first state"); continue; } } else { sc.MustGetString(); if (sc.Compare (":")) { do { bag.statedef.AddStateLabel(statestring); statestring = ParseStateString(sc); if (!statestring.CompareNoCase("GOTO")) { goto do_goto; } else if (!statestring.CompareNoCase("STOP")) { goto do_stop; } sc.MustGetString (); } while (sc.Compare (":")); // continue; } sc.UnGet (); if (statestring.Len() != 4) { sc.ScriptError ("Sprite names must be exactly 4 characters\n"); } state.sprite = GetSpriteIndex(statestring); state.Misc1 = state.Misc2 = 0; sc.MustGetString(); statestring = sc.String; if (tcall == NULL) { tcall = new FStateTempCall; } if (sc.CheckString("RANDOM")) { int min, max; sc.MustGetStringName("("); sc.MustGetNumber(); min = clamp(sc.Number, -1, SHRT_MAX); sc.MustGetStringName(","); sc.MustGetNumber(); max = clamp(sc.Number, -1, SHRT_MAX); sc.MustGetStringName(")"); if (min > max) { swapvalues(min, max); } state.Tics = min; state.TicRange = max - min; } else { sc.MustGetNumber(); state.Tics = clamp(sc.Number, -1, SHRT_MAX); state.TicRange = 0; } while (sc.GetString() && (!sc.Crossed || sc.Compare("{"))) { if (sc.Compare("BRIGHT")) { state.Fullbright = true; continue; } if (sc.Compare("FAST")) { state.Fast = true; continue; } if (sc.Compare("SLOW")) { state.Slow = true; continue; } if (sc.Compare("NODELAY")) { if (bag.statedef.GetStateLabelIndex(NAME_Spawn) == bag.statedef.GetStateCount()) { state.NoDelay = true; } else { sc.ScriptMessage("NODELAY may only be used immediately after Spawn:"); } continue; } if (sc.Compare("OFFSET")) { // specify a weapon offset sc.MustGetStringName("("); sc.MustGetNumber(); state.Misc1 = sc.Number; sc.MustGetStringName (","); sc.MustGetNumber(); state.Misc2 = sc.Number; sc.MustGetStringName(")"); continue; } if (sc.Compare("LIGHT")) { sc.MustGetStringName("("); do { sc.MustGetString(); #ifdef DYNLIGHT AddStateLight(&state, sc.String); #endif } while (sc.CheckString(",")); sc.MustGetStringName(")"); continue; } if (sc.Compare("CANRAISE")) { state.CanRaise = true; continue; } bool hasfinalret; tcall->Code = ParseActions(sc, state, statestring, bag, tcall->Proto, hasfinalret); if (!hasfinalret) { AddImplicitReturn(static_cast(tcall->Code), tcall->Proto, sc); } goto endofstate; } sc.UnGet(); endofstate: int count = bag.statedef.AddStates(&state, statestring); if (count < 0) { sc.ScriptError ("Invalid frame character string '%s'", statestring.GetChars()); count = -count; } if (tcall->Code != NULL) { tcall->ActorClass = actor; tcall->FirstState = bag.statedef.GetStateCount() - count; tcall->NumStates = count; StateTempCalls.Push(tcall); tcall = NULL; } } } if (tcall != NULL) { delete tcall; } if (args != NULL) { delete args; } sc.SetEscape(true); // re-enable escape sequences } //========================================================================== // // AddImplicitReturn // // Adds an implied return; statement to the end of a code sequence. // //========================================================================== void AddImplicitReturn(FxSequence *code, const PPrototype *proto, FScanner &sc) { if (code == NULL) { return; } if (proto == NULL || proto->ReturnTypes.Size() == 0) { // Returns nothing. Good. We can safely add an implied return. code->Add(new FxReturnStatement(NULL, sc)); } else { // Something was returned earlier in the sequence. Make it an error // instead of adding an implicit one. sc.ScriptError("Action list must end with a return statement"); } } //========================================================================== // // ReturnCheck // // If proto1 is NULL, returns proto2. If proto2 is NULL, returns proto1. // If neither is null, checks if both prototypes define the same return // types. If not, an error is flagged. // //========================================================================== static PPrototype *ReturnCheck(PPrototype *proto1, PPrototype *proto2, FScanner &sc) { if (proto1 == NULL) { return proto2; } if (proto2 == NULL) { return proto1; } // A prototype that defines fewer return types can be compatible with // one that defines more if the shorter one matches the initial types // for the longer one. if (proto2->ReturnTypes.Size() < proto1->ReturnTypes.Size()) { // Make proto1 the shorter one to avoid code duplication below. swapvalues(proto1, proto2); } // If one prototype returns nothing, they both must. if (proto1->ReturnTypes.Size() == 0) { if (proto2->ReturnTypes.Size() == 0) { return proto1; } proto1 = NULL; } else { for (unsigned i = 0; i < proto1->ReturnTypes.Size(); ++i) { if (proto1->ReturnTypes[i] != proto2->ReturnTypes[i]) { // Incompatible proto1 = NULL; break; } } } if (proto1 == NULL) { sc.ScriptError("Return types are incompatible"); } return proto1; } //========================================================================== // // ParseActions // // If this action block contains any return statements, the prototype for // one of them will be returned. This is used for deducing the return type // of anonymous functions. All called functions passed to return must have // matching return types. // //========================================================================== FxExpression *ParseActions(FScanner &sc, FState state, FString statestring, Baggage &bag, PPrototype *&retproto, bool &endswithret) { // If it's not a '{', then it should be a single action. // Otherwise, it's a sequence of actions. if (!sc.Compare("{")) { FxVMFunctionCall *call = ParseAction(sc, state, statestring, bag); retproto = call->GetVMFunction()->Proto; endswithret = true; return new FxReturnStatement(call, sc); } const FScriptPosition pos(sc); FxSequence *seq = NULL; PPrototype *proto = NULL; bool lastwasret = false; sc.MustGetString(); while (!sc.Compare("}")) { FxExpression *add; lastwasret = false; if (sc.Compare("if")) { // Hangle an if statement FxExpression *cond; FxExpression *true_part, *false_part = NULL; PPrototype *true_proto, *false_proto = NULL; bool true_ret, false_ret = false; sc.MustGetStringName("("); cond = ParseExpression(sc, bag.Info); sc.MustGetStringName(")"); sc.MustGetStringName("{"); // braces are mandatory true_part = ParseActions(sc, state, statestring, bag, true_proto, true_ret); sc.MustGetString(); if (sc.Compare("else")) { sc.MustGetStringName("{"); // braces are still mandatory false_part = ParseActions(sc, state, statestring, bag, false_proto, false_ret); sc.MustGetString(); } add = new FxIfStatement(cond, true_part, false_part, sc); proto = ReturnCheck(proto, true_proto, sc); proto = ReturnCheck(proto, false_proto, sc); // If one side does not end with a return, we don't consider the if statement // to end with a return. if (true_ret && (false_proto == NULL || false_ret)) { lastwasret = true; } } else if (sc.Compare("return")) { // Handle a return statement lastwasret = true; FxVMFunctionCall *retexp = NULL; PPrototype *retproto; sc.MustGetString(); if (!sc.Compare(";")) { retexp = ParseAction(sc, state, statestring, bag); sc.MustGetStringName(";"); retproto = retexp->GetVMFunction()->Proto; } else { // Returning nothing; we still need a prototype for that. TArray notypes(0); retproto = NewPrototype(notypes, notypes); } proto = ReturnCheck(proto, retproto, sc); sc.MustGetString(); add = new FxReturnStatement(retexp, sc); } else { // Handle a regular action function call add = ParseAction(sc, state, statestring, bag); sc.MustGetStringName(";"); sc.MustGetString(); } // Only return a sequence if it has actual content. if (add != NULL) { if (seq == NULL) { seq = new FxSequence(pos); } seq->Add(add); } } endswithret = lastwasret; retproto = proto; return seq; } //========================================================================== // // ParseAction // //========================================================================== FxVMFunctionCall *ParseAction(FScanner &sc, FState state, FString statestring, Baggage &bag) { FxVMFunctionCall *call; // Make the action name lowercase strlwr (sc.String); call = DoActionSpecials(sc, state, bag); if (call != NULL) { return call; } PFunction *afd = dyn_cast(bag.Info->Symbols.FindSymbol(FName(sc.String, true), true)); if (afd != NULL) { FArgumentList *args = new FArgumentList; ParseFunctionParameters(sc, bag.Info, *args, afd, statestring, &bag.statedef); call = new FxVMFunctionCall(afd, args->Size() > 0 ? args : NULL, sc); if (args->Size() == 0) { delete args; } return call; } sc.ScriptError("Invalid state parameter %s\n", sc.String); return NULL; } //========================================================================== // // ParseFunctionParameters // // Parses the parameters for a VM function. Called by both ParseStates // (which will set statestring and statedef) and by ParseExpression0 (which // will not set them). The first token returned by the scanner when entering // this function should be '('. // //========================================================================== void ParseFunctionParameters(FScanner &sc, PClassActor *cls, TArray &out_params, PFunction *afd, FString statestring, FStateDefinitions *statedef) { const TArray ¶ms = afd->Variants[0].Implementation->Proto->ArgumentTypes; const TArray ¶mflags = afd->Variants[0].ArgFlags; int numparams = (int)params.Size(); int pnum = 0; bool zeroparm; if (afd->Flags & VARF_Method) { numparams--; pnum++; } if (afd->Flags & VARF_Action) { numparams -= 2; pnum += 2; } assert(numparams >= 0); zeroparm = numparams == 0; if (numparams > 0 && !(paramflags[pnum] & VARF_Optional)) { sc.MustGetStringName("("); } else { if (!sc.CheckString("(")) { return; } } while (numparams > 0) { FxExpression *x; if (statedef != NULL && params[pnum] == TypeState && sc.CheckNumber()) { // Special case: State label as an offset if (sc.Number > 0 && statestring.Len() > 1) { sc.ScriptError("You cannot use state jumps commands with a jump offset on multistate definitions\n"); } int v = sc.Number; if (v < 0) { sc.ScriptError("Negative jump offsets are not allowed"); } if (v > 0) { x = new FxStateByIndex(statedef->GetStateCount() + v, sc); } else { x = new FxConstant((FState*)NULL, sc); } } else { // Use the generic parameter parser for everything else x = ParseParameter(sc, cls, params[pnum], false); } out_params.Push(new FxParameter(x)); pnum++; numparams--; if (numparams > 0) { if (params[pnum] == NULL) { // varargs function if (sc.CheckString(")")) { return; } pnum--; numparams++; } else if ((paramflags[pnum] & VARF_Optional) && sc.CheckString(")")) { return; } sc.MustGetStringName (","); } } if (zeroparm) { if (!sc.CheckString(")")) { sc.ScriptError("You cannot pass parameters to '%s'\n", afd->SymbolName.GetChars()); } } else { sc.MustGetStringName(")"); } }