static CodeBlock[] SplitBlocks (CodeInfo code)
{
var blocks = new List<CodeBlock>();
var instr = code.Instructions;
var jumpTo = FindJumpOffsets(code);
for (int i = 0; i < jumpTo.Length; i++)
{
var instrs = new List<IntPtr>();
var br = jumpTo[i];
var ind = Utils.IndexOfPtr(instr, br);
AnyInstruction* nextAddr = null;
for (var j = ind; j != -1 && j < instr.Length; j++)
{
var ins = instr[j];
if (i != jumpTo.Length - 1 && ins == jumpTo[i + 1]) // sorted
{
nextAddr = ins;
break;
}
instrs.Add((IntPtr)ins);
}
if (instrs.Count == 0)
continue;
if (i == jumpTo.Length - 1 && br > instr[instr.Length - 1]) // implicit 'ret' after last instruction
blocks.Add(new CodeBlock
{
Instructions = Utils.MPtrListToPtrArr(instrs),
BranchTo = null,
Type = BranchType.Unconditional
});
else
{
var lastI = (AnyInstruction*)(instrs[instrs.Count - 1]);
blocks.Add(new CodeBlock
{
Instructions = Utils.MPtrListToPtrArr(instrs),
BranchTo = lastI->Kind() == InstructionKind.Goto ? (AnyInstruction*)((long)lastI + lastI->Goto.Offset * 4L) : nextAddr /* can be null */,
Type = lastI->Kind() == InstructionKind.Goto ? lastI->Goto.Type() : BranchType.Unconditional
});
}
}
return blocks.ToArray();
}
static AnyInstruction*[] FindJumpOffsets(CodeInfo code)
{
var blocks = new List<CodeBlock>();
var instr = code.Instructions;
var ret = new List<IntPtr>();
ret.Add((IntPtr)instr[0]);
for (int i = 0; i < instr.Length; i++)
{
var ins = instr[i];
if (ins->Kind() == InstructionKind.Goto)
{
IntPtr p;
// instructions after a 'goto'
if (i < instr.Length - 1)
{
p = (IntPtr)instr[i + 1];
if (!ret.Contains(p))
ret.Add(p);
}
// goto targets
p = (IntPtr)((long)ins + ins->Goto.Offset * 4L);
if (!ret.Contains(p))
ret.Add(p);
}
}
ret.Sort(Utils.ComparePtrs);
var ret_ = new AnyInstruction*[ret.Count];
for (int i = 0; i < ret_.Length; i++)
ret_[i] = (AnyInstruction*)ret[i];
return ret_;
}
public static string DecompileCode(GMFileContent content, RefData rdata, CodeInfo code)
{
if (code.Instructions.Length == 0)
return String.Empty;
var sb = new StringBuilder();
var stack = new Stack<Expression>();
var dupts = new List <Expression>();
var firstI = (long)code.Instructions[0];
var graph = BuildCFGraph(content, code);
//TODO: CFG kind recognition stuff (if, if/else, for, while, etc)
var i = 0;
foreach (var g in graph)
{
var stmts = ParseStatements(content, rdata, code, g.Instructions, stack);
sb .Append(SR.HEX_PRE)
.Append(((long)g.Instructions[0] - firstI).ToString(SR.HEX_FM6))
.AppendLine(SR.COLON);
foreach (var s in stmts)
sb.Append(SR.INDENT4).AppendLine(s.ToString());
i++;
}
sb.Append(SR.INDENT4).AppendLine(FinalRet.ToString());
return sb.ToString();
}
public static Statement[] ParseStatements(GMFileContent content, RefData rdata, CodeInfo code, AnyInstruction*[] instr = null, Stack<Expression> stack = null, List<Expression> dupTars = null)
{
//! here be dragons
stack = stack ?? new Stack<Expression>();
dupTars = dupTars ?? new List <Expression>();
instr = instr ?? code.Instructions;
if (instr.Length == 0)
return EmptyStmtArray;
var stmts = new List<Statement>();
var firstI = code.Instructions[0];
//TODO: use locals
Func<Expression> Pop = () => stack.Count == 0 ? PopExpr : stack.Pop ();
//Func<Expression> Peek = () => stack.Count == 0 ? PopExpr : stack.Peek();
Func<int, IEnumerable<Expression>> PopMany = i =>
{
var ret = new List<Expression>();
for (int j = 0; j < i; j++)
ret.Add(Pop());
return ret;
};
#region Action FlushStack = () => { };
Action FlushStack = () =>
{
var readd = new Stack<Expression>();
//? not sure if this is a good idea (random 'push'es in the wild) (see TODO)
stmts.AddRange(stack.PopAll().Where(e =>
{
if (dupTars.Contains(e))
{
readd.Push(e);
return false;
}
return !(e is PopExpression); // 'push pop' is obviously stupid to emit
}).Reverse().Select(e =>
e is UnaryOperatorExpression &&
((UnaryOperatorExpression)e).Operator == UnaryOperator.Duplicate
? (Statement)new DupStatement() : new PushStatement { Expr = e }));
stack.PushRange(readd);
};
#endregion
Action<Statement> AddStmt = s =>
{
FlushStack();
stmts.Add(s);
};
Func<VariableType, Expression[]> TryGetIndices = vt =>
{
Expression index = null;
var dimentions = 0;
if (vt == VariableType.Array)
{
index = Pop();
var arrInd = Pop();
if ((arrInd is LiteralExpression) && ((LiteralExpression)arrInd).Value is short)
{
var s = (short)((LiteralExpression)arrInd).Value;
switch (s)
{
case -1:
dimentions = 2;
break;
case -5:
dimentions = 1;
break;
}
}
if (dimentions == 0)
{
stack.Push(arrInd);
stack.Push(index);
index = null;
}
}
if (index == null)
return null;
// analyse index for specified dimention
switch (dimentions)
{
case 2:
if (index is BinaryOperatorExpression && ((BinaryOperatorExpression)index).Operator == BinaryOperator.Addition)
{
var boe = (BinaryOperatorExpression)index;
var a = boe.Arg1;
var b = boe.Arg2;
if (a is BinaryOperatorExpression && ((BinaryOperatorExpression)a).Operator == BinaryOperator.Multiplication)
{
var a_ = (BinaryOperatorExpression)a;
var c = a_.Arg2;
if (c is LiteralExpression && ((LiteralExpression)c).ReturnType == DataType.Int32
&& (int /* should be */)((LiteralExpression)c).Value == 32000)
return new[] { a_.Arg1, b };
}
}
break;
}
return new[] { index };
};
for (int i = 0; i < instr.Length; i++)
{
var ins = instr[i];
#region stuff
var pst = (SingleTypeInstruction*)ins;
var pdt = (DoubleTypeInstruction*)ins;
var pcl = (CallInstruction *)ins;
var pps = (PushInstruction *)ins;
var pse = (SetInstruction *)ins;
var pbr = (GotoInstruction *)ins;
var pbk = (BreakInstruction *)ins;
var st = ins->SingleType;
var dt = ins->DoubleType;
var cl = ins->Call ;
var ps = ins->Push ;
var se = ins->Set ;
var t1 = ins->Kind() == InstructionKind.SingleType ? st.Type
: (ins->Kind() == InstructionKind.DoubleType ? dt.Types.Type1 : 0);
var t2 = ins->Kind() == InstructionKind.DoubleType ? dt.Types.Type2
: (ins->Kind() == InstructionKind.SingleType ? st.Type : 0);
#endregion
switch (ins->Code())
{
#region dup, pop
case OpCode.Dup:
var normal = true;
if (i < instr.Length - 1 && instr[i + 1]->OpCode == OpCode.Push)
{
var n = &instr[i + 1]->Push;
var t = ((Reference*)&n->ValueRest)->Type;
if (t == VariableType.Array && stack.Count > 1)
{
normal = false;
stack.Push(stack.Skip(1).First()); // second item
stack.Push(stack.Skip(1).First()); // first item (original stack top)
}
}
if (!normal)
break;
if (!dupTars.Contains(stack.Peek()))
dupTars.Add(stack.Peek());
if (stack.Peek().WalkExprTree(e => e is CallExpression).Any(_ => _))
{
stack.Push(new UnaryOperatorExpression
{
Input = stack.Peek(),
Operator = UnaryOperator.Duplicate,
OriginalType = stack.Peek().ReturnType,
ReturnType = st.Type
});
//AddStmt(new DupStatement());
}
else
stack.Push(stack.Peek());
break;
case OpCode.Pop:
if (stack.Count > 0 && stack.Peek() is CallExpression)
AddStmt(new CallStatement
{
Call = stack.Pop() as CallExpression
});
else
AddStmt(new PopStatement());
break;
#endregion
#region env
//TODO: use actual '(with obj ...)' syntax
//! it might mess with the CFG structure
case OpCode.PushEnv:
AddStmt(new PushEnvStatement
{
Target = (AnyInstruction*)((byte*)ins + pbr->Offset * 4L),
TargetOffset = (byte*)ins + pbr->Offset * 4L - (byte*)firstI,
Parent = stack.Pop()
});
break;
case OpCode.PopEnv :
AddStmt(new PopEnvStatement
{
Target = (AnyInstruction*)((byte*)ins + pbr->Offset * 4L),
TargetOffset = (byte*)ins + pbr->Offset * 4L - (byte*)firstI
});
break;
#endregion
#region branch
case OpCode.Brt:
case OpCode.Brf:
case OpCode.Br:
AddStmt(new BranchStatement
{
Type = pbr->Type(),
Conditional = pbr->Type() == BranchType.Unconditional ? null : Pop(),
Target = (AnyInstruction*)((byte*)ins + pbr->Offset * 4L),
TargetOffset = (byte*)ins + pbr->Offset * 4L - (byte*)firstI
});
break;
#endregion
#region break, ret, exit
case OpCode.Break:
stack.Push(new AssertExpression
{
ControlValue = pbk->Signal,
ReturnType = pbk->Type,
Expr = Pop()
});
break;
case OpCode.Ret:
AddStmt(new ReturnStatement
{
ReturnType = pst->Type,
RetValue = Pop()
});
break;
case OpCode.Exit:
AddStmt(new ExitStatement());
break;
#endregion
#region set
case OpCode.Set:
var ind = TryGetIndices(se.DestVar.Type); // call before Value's pop
AddStmt(new SetStatement
{
OriginalType = se.Types.Type1,
ReturnType = se.Types.Type2,
Type = se.DestVar.Type,
OwnerType = se.Instance,
OwnerName = se.Instance > InstanceType.StackTopOrGlobal ? SectionReader.GetObjectInfo(content, (uint)se.Instance).Name : null,
Target = rdata.Variables[rdata.VarAccessors[(IntPtr)ins]],
Value = Pop(),
ArrayIndices = ind ?? TryGetIndices(se.DestVar.Type)
});
break;
#endregion
default:
switch (ins->ExprType())
{
#region variable
case ExpressionType.Variable:
var vt = ((Reference*)&pps->ValueRest)->Type;
if (vt == VariableType.StackTop && (InstanceType)ps.Value == InstanceType.StackTopOrGlobal)
{
stack.Push(new MemberExpression
{
Owner = Pop(),
ReturnType = ps.Type,
Type = vt,
OwnerType = (InstanceType)ps.Value,
OwnerName = se.Instance > InstanceType.StackTopOrGlobal ? SectionReader.GetObjectInfo(content, (uint)se.Instance).Name : null,
Variable = rdata.Variables[rdata.VarAccessors[(IntPtr)ins]],
ArrayIndices = TryGetIndices(vt)
});
}
else
stack.Push(new VariableExpression
{
ReturnType = ps.Type,
Type = vt,
OwnerType = (InstanceType)ps.Value,
Variable = rdata.Variables[rdata.VarAccessors[(IntPtr)ins]],
ArrayIndices = TryGetIndices(vt)
});
break;
#endregion
#region literal
case ExpressionType.Literal:
object v = null;
var rest = &pps->ValueRest;
#region get value
switch (ps.Type)
{
case DataType.Int16:
v = ps.Value;
break;
case DataType.Boolean:
v = ((DwordBool*)rest)->IsTrue();
break;
case DataType.Double:
v = *(double*)rest;
break;
case DataType.Single:
v = *(float*)rest;
break;
case DataType.Int32:
v = *(int*)rest;
break;
case DataType.Int64:
v = *(long*)rest;
break;
case DataType.String:
v = SectionReader.GetStringInfo(content, ps.ValueRest);
break;
}
#endregion
stack.Push(new LiteralExpression
{
ReturnType = ps.Type,
Value = v
});
break;
#endregion
#region call
case ExpressionType.Call:
stack.Push(new CallExpression
{
ReturnType = cl.ReturnType,
Type = cl.Function.Type,
Function = rdata.Functions[rdata.FuncAccessors[(IntPtr)ins]],
Arguments = PopMany(cl.Arguments).Reverse().ToArray()
});
break;
#endregion
#region binaryop
case ExpressionType.BinaryOp:
var a1 = Pop();
var a2 = Pop();
stack.Push(new BinaryOperatorExpression
{
OriginalType = t1,
ReturnType = t2,
Arg1 = a2,
Arg2 = a1,
Operator = ins->BinaryOp()
});
break;
#endregion
#region unaryop
case ExpressionType.UnaryOp:
stack.Push(new UnaryOperatorExpression
{
OriginalType = t1,
ReturnType = t2,
Input = Pop(),
Operator = ins->UnaryOp()
});
break;
#endregion
}
break;
}
}
FlushStack();
return stmts.ToArray();
}
public static GraphVertex[] BuildCFGraph(GMFileContent content, CodeInfo code)
{
if (code.Instructions.Length == 0)
return EmptyGVArray;
return CreateVertices(content, code);
}
static GraphVertex[] CreateVertices(GMFileContent content, CodeInfo code)
{
var blocks = SplitBlocks(code);
var instr = code.Instructions;
var firstI = (long)instr[0];
// only one block -> just return it as a single vertex
if (blocks.Length == 1)
return new[]
{
new GraphVertex
{
Branches = EmptyGBArray,
Instructions = blocks[0].Instructions
}
};
var vertices = new GraphVertex[blocks.Length];
// create list of vertices
for (int i = 0; i < blocks.Length; i++)
{
var blk = blocks[i];
var hasNext = i < blocks.Length - 1 && blk.Type != BranchType.Unconditional /* no need to check if uncond */;
vertices[i] = new GraphVertex
{
Instructions = blk.Instructions,
Branches = new GraphBranch[hasNext ? 2 : 1]
};
vertices[i].Branches[0] = new GraphBranch
{
BranchTo = blk.BranchTo,
Type = blk.Type
};
if (hasNext)
vertices[i].Branches[1] = new GraphBranch
{
BranchTo = blocks[i + 1].Instructions[0],
Type = blk.Type.Invert()
};
}
// connect vertex branches to target vertices
for (int i = 0; i < vertices.Length; i++)
{
var v = vertices[i];
for (int j = 0; j < v.Branches.Length; j++)
v.Branches[j].ToVertex =
vertices.FirstOrDefault(ve => ve.Instructions[0] == v.Branches[j].BranchTo)
?? (i == vertices.Length - 1 ? null : vertices[i + 1]);
}
return vertices;
}
public static string DisplayInstructions(GMFileContent content, RefData rdata, CodeInfo code, AnyInstruction*[] instructions = null)
{
var instrs = instructions ?? code.Instructions;
if (instrs.Length == 0)
return String.Empty;
var sb = new StringBuilder();
var firstI = code.Instructions[0];
for (int i = 0; i < instrs.Length; i++)
{
var iptr = instrs[i];
var relInstr = (long)iptr - (long)firstI;
sb .Append(HEX_PRE).Append(relInstr.ToString(HEX_FM6))
.Append(' ').Append(iptr->Code().ToPrettyString()).Append(' ');
switch (iptr->Kind())
{
case InstructionKind.SingleType:
var st = iptr->SingleType;
sb.Append(st.Type.ToPrettyString());
break;
case InstructionKind.DoubleType:
var dt = iptr->DoubleType;
sb.Append(dt.Types);
break;
case InstructionKind.Goto:
var g = iptr->Goto;
sb.Append(HEX_PRE).Append((relInstr + g.Offset * 4L).ToString(HEX_FM6));
break;
#region set
case InstructionKind.Set:
var s = iptr->Set;
sb.Append(s.Types).Append(' ');
if (s.Instance <= InstanceType.StackTopOrGlobal)
sb.Append(s.Instance.ToPrettyString());
else
{
var o = SectionReader.GetObjectInfo(content, (uint)s.Instance);
sb.Append('[').Append(o.Name).Append(']');
}
sb.Append(':');
sb.Append(rdata.Variables[rdata.VarAccessors[(IntPtr)iptr]].Name);
sb.Append(s.DestVar.Type.ToPrettyString());
break;
#endregion
#region push
case InstructionKind.Push:
var pp = (PushInstruction*)iptr;
var p = iptr->Push;
sb.Append(p.Type.ToPrettyString()).Append(' ');
var r = p.ValueRest;
switch (p.Type)
{
case DataType.Int16:
sb.Append(p.Value.ToString(CultureInfo.InvariantCulture));
break;
case DataType.Variable:
var rv = *(Reference*)&r;
var inst = (InstanceType)p.Value;
if (inst <= InstanceType.StackTopOrGlobal)
sb.Append(inst.ToPrettyString());
else
{
var o = SectionReader.GetObjectInfo(content, (uint)inst);
sb.Append('[').Append(o.Name).Append(']');
}
sb.Append(':');
sb.Append(rdata.Variables[rdata.VarAccessors[(IntPtr)iptr]].Name);
sb.Append(rv.Type.ToPrettyString());
break;
case DataType.Boolean:
sb.Append(((DwordBool*)&r)->ToPrettyString());
break;
case DataType.Double:
sb.Append(((double*)&r)->ToString(CultureInfo.InvariantCulture));
break;
case DataType.Single:
sb.Append(((float*)&r)->ToString(CultureInfo.InvariantCulture));
break;
case DataType.Int32:
sb.Append(unchecked((int)r).ToString(CultureInfo.InvariantCulture));
break;
case DataType.Int64:
sb.Append(((long*)&pp->ValueRest)->ToString(CultureInfo.InvariantCulture));
break;
case DataType.String:
sb.Append(SectionReader.GetStringInfo(content, p.ValueRest).Escape());
break;
}
break;
#endregion
#region call
case InstructionKind.Call:
var c = iptr->Call;
sb.Append(c.ReturnType.ToPrettyString()).Append(':')
.Append(c.Arguments).Append(' ');
sb.Append(rdata.Functions[rdata.FuncAccessors[(IntPtr)iptr]].Name);
sb.Append(c.Function.Type.ToPrettyString());
break;
#endregion
case InstructionKind.Break:
var b = iptr->Break;
sb.Append(b.Type.ToPrettyString()).Append(' ').Append(b.Signal);
break;
}
sb.AppendLine();
}
return sb.ToString();
}
