qzdoom/src/scripting/zscript/ast.cpp
Leonard2 94410accf4 Renamed "VectorInitializer" to "VectorValue"
This was really confusing for me as this is an actual vector "value" rather than an "initializer"
2016-10-30 07:34:14 +01:00

910 lines
20 KiB
C++

/*
** ast.cpp
**
**---------------------------------------------------------------------------
** Copyright -2016 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.
**
** 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 "dobject.h"
#include "sc_man.h"
#include "memarena.h"
#include "zcc_parser.h"
#include "zcc-parse.h"
class FLispString;
extern void (* const TreeNodePrinter[NUM_AST_NODE_TYPES])(FLispString &, ZCC_TreeNode *);
static const char *BuiltInTypeNames[] =
{
"sint8", "uint8",
"sint16", "uint16",
"sint32", "uint32",
"intauto",
"bool",
"float32", "float64", "floatauto",
"string",
"vector2",
"vector3",
"name",
"color",
"state",
"sound",
"usertype",
};
class FLispString
{
public:
operator FString &() { return Str; }
FLispString()
{
NestDepth = Column = 0;
WrapWidth = 200;
NeedSpace = false;
ConsecOpens = 0;
}
void Open(const char *label)
{
size_t labellen = label != NULL ? strlen(label) : 0;
CheckWrap(labellen + 1 + NeedSpace);
if (NeedSpace)
{
Str << ' ';
ConsecOpens = 0;
}
Str << '(';
ConsecOpens++;
if (label != NULL)
{
Str.AppendCStrPart(label, labellen);
}
Column += labellen + 1 + NeedSpace;
NestDepth++;
NeedSpace = (label != NULL);
}
void Close()
{
assert(NestDepth != 0);
Str << ')';
Column++;
NestDepth--;
NeedSpace = true;
}
void Break()
{
// Don't break if not needed.
if (Column != NestDepth)
{
if (NeedSpace)
{
ConsecOpens = 0;
}
else
{ // Move hanging ( characters to the new line
Str.Truncate(long(Str.Len() - ConsecOpens));
NestDepth -= ConsecOpens;
}
Str << '\n';
Column = NestDepth;
NeedSpace = false;
if (NestDepth > 0)
{
Str.AppendFormat("%*s", (int)NestDepth, "");
}
if (ConsecOpens > 0)
{
for (size_t i = 0; i < ConsecOpens; ++i)
{
Str << '(';
}
NestDepth += ConsecOpens;
}
}
}
bool CheckWrap(size_t len)
{
if (len + Column > WrapWidth)
{
Break();
return true;
}
return false;
}
void Add(const char *str, size_t len)
{
CheckWrap(len + NeedSpace);
if (NeedSpace)
{
Str << ' ';
}
Str.AppendCStrPart(str, len);
Column += len + NeedSpace;
NeedSpace = true;
}
void Add(const char *str)
{
Add(str, strlen(str));
}
void Add(FString &str)
{
Add(str.GetChars(), str.Len());
}
void AddName(FName name)
{
size_t namelen = strlen(name.GetChars());
CheckWrap(namelen + 2 + NeedSpace);
if (NeedSpace)
{
NeedSpace = false;
Str << ' ';
}
Str << '\'' << name.GetChars() << '\'';
Column += namelen + 2 + NeedSpace;
NeedSpace = true;
}
void AddChar(char c)
{
Add(&c, 1);
}
void AddInt(int i, bool un=false)
{
char buf[16];
size_t len;
if (!un)
{
len = mysnprintf(buf, countof(buf), "%d", i);
}
else
{
len = mysnprintf(buf, countof(buf), "%uu", i);
}
Add(buf, len);
}
void AddHex(unsigned x)
{
char buf[10];
size_t len = mysnprintf(buf, countof(buf), "%08x", x);
Add(buf, len);
}
void AddFloat(double f, bool single)
{
char buf[32];
size_t len = mysnprintf(buf, countof(buf), "%.4f", f);
if (single)
{
buf[len++] = 'f';
buf[len] = '\0';
}
Add(buf, len);
}
private:
FString Str;
size_t NestDepth;
size_t Column;
size_t WrapWidth;
size_t ConsecOpens;
bool NeedSpace;
};
static void PrintNode(FLispString &out, ZCC_TreeNode *node)
{
assert(TreeNodePrinter[NUM_AST_NODE_TYPES-1] != NULL);
if (node->NodeType >= 0 && node->NodeType < NUM_AST_NODE_TYPES)
{
TreeNodePrinter[node->NodeType](out, node);
}
else
{
out.Open("unknown-node-type");
out.AddInt(node->NodeType);
out.Close();
}
}
static void PrintNodes(FLispString &out, ZCC_TreeNode *node, bool newlist=true, bool addbreaks=false)
{
ZCC_TreeNode *p;
if (node == NULL)
{
out.Add("nil", 3);
}
else
{
if (newlist)
{
out.Open(NULL);
}
p = node;
do
{
if (addbreaks)
{
out.Break();
}
PrintNode(out, p);
p = p->SiblingNext;
} while (p != node);
if (newlist)
{
out.Close();
}
}
}
static void PrintBuiltInType(FLispString &out, EZCCBuiltinType type)
{
assert(ZCC_NUM_BUILT_IN_TYPES == countof(BuiltInTypeNames));
if (unsigned(type) >= unsigned(ZCC_NUM_BUILT_IN_TYPES))
{
char buf[30];
size_t len = mysnprintf(buf, countof(buf), "bad-type-%u", type);
out.Add(buf, len);
}
else
{
out.Add(BuiltInTypeNames[type]);
}
}
static void PrintIdentifier(FLispString &out, ZCC_TreeNode *node)
{
ZCC_Identifier *inode = (ZCC_Identifier *)node;
out.Open("identifier");
out.AddName(inode->Id);
out.Close();
}
static void PrintStringConst(FLispString &out, FString str)
{
FString outstr;
outstr << '"';
for (size_t i = 0; i < str.Len(); ++i)
{
if (str[i] == '"')
{
outstr << "\"";
}
else if (str[i] == '\\')
{
outstr << "\\\\";
}
else if (str[i] >= 32)
{
outstr << str[i];
}
else
{
outstr.AppendFormat("\\x%02X", str[i]);
}
}
outstr << '"';
out.Add(outstr);
}
static void PrintClass(FLispString &out, ZCC_TreeNode *node)
{
ZCC_Class *cnode = (ZCC_Class *)node;
out.Break();
out.Open("class");
out.AddName(cnode->NodeName);
PrintNodes(out, cnode->ParentName);
PrintNodes(out, cnode->Replaces);
out.AddHex(cnode->Flags);
PrintNodes(out, cnode->Body, false, true);
out.Close();
}
static void PrintStruct(FLispString &out, ZCC_TreeNode *node)
{
ZCC_Struct *snode = (ZCC_Struct *)node;
out.Break();
out.Open("struct");
out.AddName(snode->NodeName);
PrintNodes(out, snode->Body, false, true);
out.Close();
}
static void PrintEnum(FLispString &out, ZCC_TreeNode *node)
{
ZCC_Enum *enode = (ZCC_Enum *)node;
out.Break();
out.Open("enum");
out.AddName(enode->NodeName);
PrintBuiltInType(out, enode->EnumType);
out.Add(enode->Elements == NULL ? "nil" : "...", 3);
out.Close();
}
static void PrintEnumTerminator(FLispString &out, ZCC_TreeNode *node)
{
out.Open("enum-term");
out.Close();
}
static void PrintStates(FLispString &out, ZCC_TreeNode *node)
{
ZCC_States *snode = (ZCC_States *)node;
out.Break();
out.Open("states");
PrintNodes(out, snode->Body, false, true);
out.Close();
}
static void PrintStatePart(FLispString &out, ZCC_TreeNode *node)
{
out.Open("state-part");
out.Close();
}
static void PrintStateLabel(FLispString &out, ZCC_TreeNode *node)
{
ZCC_StateLabel *snode = (ZCC_StateLabel *)node;
out.Open("state-label");
out.AddName(snode->Label);
out.Close();
}
static void PrintStateStop(FLispString &out, ZCC_TreeNode *node)
{
out.Open("state-stop");
out.Close();
}
static void PrintStateWait(FLispString &out, ZCC_TreeNode *node)
{
out.Open("state-wait");
out.Close();
}
static void PrintStateFail(FLispString &out, ZCC_TreeNode *node)
{
out.Open("state-fail");
out.Close();
}
static void PrintStateLoop(FLispString &out, ZCC_TreeNode *node)
{
out.Open("state-loop");
out.Close();
}
static void PrintStateGoto(FLispString &out, ZCC_TreeNode *node)
{
ZCC_StateGoto *snode = (ZCC_StateGoto *)node;
out.Open("state-goto");
PrintNodes(out, snode->Qualifier);
PrintNodes(out, snode->Label);
PrintNodes(out, snode->Offset);
out.Close();
}
static void PrintStateLine(FLispString &out, ZCC_TreeNode *node)
{
ZCC_StateLine *snode = (ZCC_StateLine *)node;
out.Open("state-line");
out.Add(*(snode->Sprite));
PrintNodes(out, snode->Duration);
if (snode->bNoDelay) out.Add("nodelay", 7);
if (snode->bBright) out.Add("bright", 6);
if (snode->bFast) out.Add("fast", 4);
if (snode->bSlow) out.Add("slow", 4);
if (snode->bCanRaise) out.Add("canraise", 8);
out.Add(*(snode->Frames));
PrintNodes(out, snode->Offset);
PrintNodes(out, snode->Action, false);
out.Close();
}
static void PrintVarName(FLispString &out, ZCC_TreeNode *node)
{
ZCC_VarName *vnode = (ZCC_VarName *)node;
out.Open("var-name");
PrintNodes(out, vnode->ArraySize);
out.AddName(vnode->Name);
out.Close();
}
static void PrintVarInit(FLispString &out, ZCC_TreeNode *node)
{
ZCC_VarInit *vnode = (ZCC_VarInit *)node;
out.Open("var-init");
PrintNodes(out, vnode->ArraySize);
PrintNodes(out, vnode->Init);
if (vnode->InitIsArray) out.Add("array", 5);
out.AddName(vnode->Name);
out.Close();
}
static void PrintType(FLispString &out, ZCC_TreeNode *node)
{
ZCC_Type *tnode = (ZCC_Type *)node;
out.Open("bad-type");
PrintNodes(out, tnode->ArraySize);
out.Close();
}
static void PrintBasicType(FLispString &out, ZCC_TreeNode *node)
{
ZCC_BasicType *tnode = (ZCC_BasicType *)node;
out.Open("basic-type");
PrintNodes(out, tnode->ArraySize);
PrintBuiltInType(out, tnode->Type);
if (tnode->Type == ZCC_UserType)
{
PrintNodes(out, tnode->UserType, false);
}
out.Close();
}
static void PrintMapType(FLispString &out, ZCC_TreeNode *node)
{
ZCC_MapType *tnode = (ZCC_MapType *)node;
out.Open("map-type");
PrintNodes(out, tnode->ArraySize);
PrintNodes(out, tnode->KeyType);
PrintNodes(out, tnode->ValueType);
out.Close();
}
static void PrintDynArrayType(FLispString &out, ZCC_TreeNode *node)
{
ZCC_DynArrayType *tnode = (ZCC_DynArrayType *)node;
out.Open("dyn-array-type");
PrintNodes(out, tnode->ArraySize);
PrintNodes(out, tnode->ElementType);
out.Close();
}
static void PrintClassType(FLispString &out, ZCC_TreeNode *node)
{
ZCC_ClassType *tnode = (ZCC_ClassType *)node;
out.Open("class-type");
PrintNodes(out, tnode->ArraySize);
PrintNodes(out, tnode->Restriction);
out.Close();
}
static void OpenExprType(FLispString &out, EZCCExprType type)
{
char buf[32];
if (unsigned(type) < PEX_COUNT_OF)
{
mysnprintf(buf, countof(buf), "expr-%s", ZCC_OpInfo[type].OpName);
}
else
{
mysnprintf(buf, countof(buf), "bad-pex-%u", type);
}
out.Open(buf);
}
static void PrintExpression(FLispString &out, ZCC_TreeNode *node)
{
ZCC_Expression *enode = (ZCC_Expression *)node;
OpenExprType(out, enode->Operation);
out.Close();
}
static void PrintExprID(FLispString &out, ZCC_TreeNode *node)
{
ZCC_ExprID *enode = (ZCC_ExprID *)node;
assert(enode->Operation == PEX_ID);
out.Open("expr-id");
out.AddName(enode->Identifier);
out.Close();
}
static void PrintExprTypeRef(FLispString &out, ZCC_TreeNode *node)
{
ZCC_ExprTypeRef *enode = (ZCC_ExprTypeRef *)node;
assert(enode->Operation == PEX_TypeRef);
out.Open("expr-type-ref");
if (enode->RefType == TypeSInt8) { out.Add("sint8"); }
else if (enode->RefType == TypeUInt8) { out.Add("uint8"); }
else if (enode->RefType == TypeSInt16) { out.Add("sint16"); }
else if (enode->RefType == TypeSInt32) { out.Add("sint32"); }
else if (enode->RefType == TypeFloat32) { out.Add("float32"); }
else if (enode->RefType == TypeFloat64) { out.Add("float64"); }
else if (enode->RefType == TypeString) { out.Add("string"); }
else if (enode->RefType == TypeName) { out.Add("name"); }
else if (enode->RefType == TypeColor) { out.Add("color"); }
else if (enode->RefType == TypeSound) { out.Add("sound"); }
else { out.Add("other"); }
out.Close();
}
static void PrintExprConstant(FLispString &out, ZCC_TreeNode *node)
{
ZCC_ExprConstant *enode = (ZCC_ExprConstant *)node;
assert(enode->Operation == PEX_ConstValue);
out.Open("expr-const");
if (enode->Type == TypeString)
{
PrintStringConst(out, *enode->StringVal);
}
else if (enode->Type == TypeFloat64)
{
out.AddFloat(enode->DoubleVal, false);
}
else if (enode->Type == TypeFloat32)
{
out.AddFloat(enode->DoubleVal, true);
}
else if (enode->Type == TypeName)
{
out.AddName(ENamedName(enode->IntVal));
}
else if (enode->Type->IsKindOf(RUNTIME_CLASS(PInt)))
{
out.AddInt(enode->IntVal, static_cast<PInt *>(enode->Type)->Unsigned);
}
out.Close();
}
static void PrintExprFuncCall(FLispString &out, ZCC_TreeNode *node)
{
ZCC_ExprFuncCall *enode = (ZCC_ExprFuncCall *)node;
assert(enode->Operation == PEX_FuncCall);
out.Open("expr-func-call");
PrintNodes(out, enode->Function);
PrintNodes(out, enode->Parameters, false);
out.Close();
}
static void PrintExprMemberAccess(FLispString &out, ZCC_TreeNode *node)
{
ZCC_ExprMemberAccess *enode = (ZCC_ExprMemberAccess *)node;
assert(enode->Operation == PEX_MemberAccess);
out.Open("expr-member-access");
PrintNodes(out, enode->Left);
out.AddName(enode->Right);
out.Close();
}
static void PrintExprUnary(FLispString &out, ZCC_TreeNode *node)
{
ZCC_ExprUnary *enode = (ZCC_ExprUnary *)node;
OpenExprType(out, enode->Operation);
PrintNodes(out, enode->Operand, false);
out.Close();
}
static void PrintExprBinary(FLispString &out, ZCC_TreeNode *node)
{
ZCC_ExprBinary *enode = (ZCC_ExprBinary *)node;
OpenExprType(out, enode->Operation);
PrintNodes(out, enode->Left);
PrintNodes(out, enode->Right);
out.Close();
}
static void PrintExprTrinary(FLispString &out, ZCC_TreeNode *node)
{
ZCC_ExprTrinary *enode = (ZCC_ExprTrinary *)node;
OpenExprType(out, enode->Operation);
PrintNodes(out, enode->Test);
PrintNodes(out, enode->Left);
PrintNodes(out, enode->Right);
out.Close();
}
static void PrintVectorInitializer(FLispString &out, ZCC_TreeNode *node)
{
ZCC_VectorValue *enode = (ZCC_VectorValue *)node;
OpenExprType(out, enode->Operation);
PrintNodes(out, enode->X);
PrintNodes(out, enode->Y);
PrintNodes(out, enode->Z);
out.Close();
}
static void PrintFuncParam(FLispString &out, ZCC_TreeNode *node)
{
ZCC_FuncParm *pnode = (ZCC_FuncParm *)node;
out.Break();
out.Open("func-parm");
out.AddName(pnode->Label);
PrintNodes(out, pnode->Value, false);
out.Close();
}
static void PrintStatement(FLispString &out, ZCC_TreeNode *node)
{
out.Open("statement");
out.Close();
}
static void PrintCompoundStmt(FLispString &out, ZCC_TreeNode *node)
{
ZCC_CompoundStmt *snode = (ZCC_CompoundStmt *)node;
out.Break();
out.Open("compound-stmt");
PrintNodes(out, snode->Content, false, true);
out.Close();
}
static void PrintDefault(FLispString &out, ZCC_TreeNode *node)
{
ZCC_Default *snode = (ZCC_Default *)node;
out.Break();
out.Open("default");
PrintNodes(out, snode->Content, false, true);
out.Close();
}
static void PrintContinueStmt(FLispString &out, ZCC_TreeNode *node)
{
out.Break();
out.Open("continue-stmt");
out.Close();
}
static void PrintBreakStmt(FLispString &out, ZCC_TreeNode *node)
{
out.Break();
out.Open("break-stmt");
out.Close();
}
static void PrintReturnStmt(FLispString &out, ZCC_TreeNode *node)
{
ZCC_ReturnStmt *snode = (ZCC_ReturnStmt *)node;
out.Break();
out.Open("return-stmt");
PrintNodes(out, snode->Values, false);
out.Close();
}
static void PrintExpressionStmt(FLispString &out, ZCC_TreeNode *node)
{
ZCC_ExpressionStmt *snode = (ZCC_ExpressionStmt *)node;
out.Break();
out.Open("expression-stmt");
PrintNodes(out, snode->Expression, false);
out.Close();
}
static void PrintIterationStmt(FLispString &out, ZCC_TreeNode *node)
{
ZCC_IterationStmt *snode = (ZCC_IterationStmt *)node;
out.Break();
out.Open("iteration-stmt");
out.Add((snode->CheckAt == ZCC_IterationStmt::Start) ? "start" : "end");
out.Break();
PrintNodes(out, snode->LoopCondition);
out.Break();
PrintNodes(out, snode->LoopBumper);
out.Break();
PrintNodes(out, snode->LoopStatement);
out.Close();
}
static void PrintIfStmt(FLispString &out, ZCC_TreeNode *node)
{
ZCC_IfStmt *snode = (ZCC_IfStmt *)node;
out.Break();
out.Open("if-stmt");
PrintNodes(out, snode->Condition);
out.Break();
PrintNodes(out, snode->TruePath);
out.Break();
PrintNodes(out, snode->FalsePath);
out.Close();
}
static void PrintSwitchStmt(FLispString &out, ZCC_TreeNode *node)
{
ZCC_SwitchStmt *snode = (ZCC_SwitchStmt *)node;
out.Break();
out.Open("switch-stmt");
PrintNodes(out, snode->Condition);
out.Break();
PrintNodes(out, snode->Content, false);
out.Close();
}
static void PrintCaseStmt(FLispString &out, ZCC_TreeNode *node)
{
ZCC_CaseStmt *snode = (ZCC_CaseStmt *)node;
out.Break();
out.Open("case-stmt");
PrintNodes(out, snode->Condition, false);
out.Close();
}
static void BadAssignOp(FLispString &out, int op)
{
char buf[32];
size_t len = mysnprintf(buf, countof(buf), "assign-op-%d", op);
out.Add(buf, len);
}
static void PrintAssignStmt(FLispString &out, ZCC_TreeNode *node)
{
ZCC_AssignStmt *snode = (ZCC_AssignStmt *)node;
out.Open("assign-stmt");
PrintNodes(out, snode->Dests);
PrintNodes(out, snode->Sources);
out.Close();
}
static void PrintLocalVarStmt(FLispString &out, ZCC_TreeNode *node)
{
ZCC_LocalVarStmt *snode = (ZCC_LocalVarStmt *)node;
out.Open("local-var-stmt");
PrintNodes(out, snode->Type);
PrintNodes(out, snode->Vars);
out.Close();
}
static void PrintFuncParamDecl(FLispString &out, ZCC_TreeNode *node)
{
ZCC_FuncParamDecl *dnode = (ZCC_FuncParamDecl *)node;
out.Break();
out.Open("func-param-decl");
PrintNodes(out, dnode->Type);
out.AddName(dnode->Name);
out.AddHex(dnode->Flags);
PrintNodes(out, dnode->Default);
out.Close();
}
static void PrintConstantDef(FLispString &out, ZCC_TreeNode *node)
{
ZCC_ConstantDef *dnode = (ZCC_ConstantDef *)node;
out.Break();
out.Open("constant-def");
out.AddName(dnode->NodeName);
PrintNodes(out, dnode->Value, false);
out.Close();
}
static void PrintDeclarator(FLispString &out, ZCC_TreeNode *node)
{
ZCC_Declarator *dnode = (ZCC_Declarator *)node;
out.Break();
out.Open("declarator");
out.AddHex(dnode->Flags);
PrintNodes(out, dnode->Type);
out.Close();
}
static void PrintVarDeclarator(FLispString &out, ZCC_TreeNode *node)
{
ZCC_VarDeclarator *dnode = (ZCC_VarDeclarator *)node;
out.Break();
out.Open("var-declarator");
out.AddHex(dnode->Flags);
PrintNodes(out, dnode->Type);
PrintNodes(out, dnode->Names);
out.Close();
}
static void PrintFuncDeclarator(FLispString &out, ZCC_TreeNode *node)
{
ZCC_FuncDeclarator *dnode = (ZCC_FuncDeclarator *)node;
out.Break();
out.Open("func-declarator");
out.AddHex(dnode->Flags);
PrintNodes(out, dnode->Type);
out.AddName(dnode->Name);
PrintNodes(out, dnode->Params);
PrintNodes(out, dnode->Body, false);
out.Close();
}
static void PrintFlagStmt(FLispString &out, ZCC_TreeNode *node)
{
auto dnode = (ZCC_FlagStmt *)node;
out.Break();
out.Open("flag-stmt");
PrintNodes(out, dnode->name, false);
out.AddInt(dnode->set);
out.Close();
}
static void PrintPropertyStmt(FLispString &out, ZCC_TreeNode *node)
{
auto dnode = (ZCC_PropertyStmt *)node;
out.Break();
out.Open("property-stmt");
PrintNodes(out, dnode->Prop, false);
PrintNodes(out, dnode->Values, false);
out.Close();
}
void (* const TreeNodePrinter[NUM_AST_NODE_TYPES])(FLispString &, ZCC_TreeNode *) =
{
PrintIdentifier,
PrintClass,
PrintStruct,
PrintEnum,
PrintEnumTerminator,
PrintStates,
PrintStatePart,
PrintStateLabel,
PrintStateStop,
PrintStateWait,
PrintStateFail,
PrintStateLoop,
PrintStateGoto,
PrintStateLine,
PrintVarName,
PrintVarInit,
PrintType,
PrintBasicType,
PrintMapType,
PrintDynArrayType,
PrintClassType,
PrintExpression,
PrintExprID,
PrintExprTypeRef,
PrintExprConstant,
PrintExprFuncCall,
PrintExprMemberAccess,
PrintExprUnary,
PrintExprBinary,
PrintExprTrinary,
PrintFuncParam,
PrintStatement,
PrintCompoundStmt,
PrintContinueStmt,
PrintBreakStmt,
PrintReturnStmt,
PrintExpressionStmt,
PrintIterationStmt,
PrintIfStmt,
PrintSwitchStmt,
PrintCaseStmt,
PrintAssignStmt,
PrintLocalVarStmt,
PrintFuncParamDecl,
PrintConstantDef,
PrintDeclarator,
PrintVarDeclarator,
PrintFuncDeclarator,
PrintDefault,
PrintFlagStmt,
PrintPropertyStmt,
PrintVectorInitializer,
};
FString ZCC_PrintAST(ZCC_TreeNode *root)
{
FLispString out;
PrintNodes(out, root);
return out;
}