/*
* Copyright (c) Contributors, http://opensimulator.org/
* See CONTRIBUTORS.TXT for a full list of copyright holders.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * 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.
* * Neither the name of the OpenSim Project nor the
* names of its contributors may be used to endorse or promote products
* derived from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE DEVELOPERS ``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 CONTRIBUTORS 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.
*/
using System;
using System.IO;
using System.Collections.Generic;
using Tools;
namespace OpenSim.Region.ScriptEngine.Shared.CodeTools
{
public class CSCodeGenerator : ICodeConverter
{
private SYMBOL m_astRoot = null;
private int m_braceCount; // for indentation
///
/// Pass the new CodeGenerator a string containing the LSL source.
///
/// String containing LSL source.
public CSCodeGenerator()
{
}
///
/// Pass the new CodeGenerator an abstract syntax tree.
///
/// The root node of the AST.
public CSCodeGenerator(SYMBOL astRoot)
{
m_braceCount = 0;
m_astRoot = astRoot;
}
///
/// Generate the code from the AST we have.
///
/// String containing the generated C# code.
public string Convert(string script)
{
Parser p = new LSLSyntax(new yyLSLSyntax(), new ErrorHandler(true));
// Obviously this needs to be in a try/except block.
LSL2CSCodeTransformer codeTransformer = new LSL2CSCodeTransformer(p.Parse(script));
m_astRoot = codeTransformer.Transform();
string retstr = String.Empty;
// standard preamble
//retstr = "using OpenSim.Region.ScriptEngine.Common;\n";
//retstr += "using System.Collections.Generic;\n\n";
//retstr += "namespace SecondLife\n";
//retstr += "{\n";
//retstr += " public class Script : OpenSim.Region.ScriptEngine.Common\n";
//retstr += " {\n";
// here's the payload
m_braceCount += 2;
retstr += "\n";
foreach (SYMBOL s in m_astRoot.kids)
retstr += GenerateNode(s);
// close braces!
//retstr += " }\n";
//retstr += "}\n";
m_braceCount -= 2;
return retstr;
}
///
/// Recursively called to generate each type of node. Will generate this
/// node, then all it's children.
///
/// The current node to generate code for.
/// String containing C# code for SYMBOL s.
private string GenerateNode(SYMBOL s)
{
string retstr = String.Empty;
// make sure to put type lower in the inheritance hierarchy first
// ie: since IdentArgument and ExpressionArgument inherit from
// Argument, put IdentArgument and ExpressionArgument before Argument
if (s is GlobalFunctionDefinition)
retstr += GenerateGlobalFunctionDefinition((GlobalFunctionDefinition) s);
else if (s is GlobalVariableDeclaration)
retstr += GenerateGlobalVariableDeclaration((GlobalVariableDeclaration) s);
else if (s is State)
retstr += GenerateState((State) s);
else if (s is CompoundStatement)
retstr += GenerateCompoundStatement((CompoundStatement) s);
else if (s is Declaration)
retstr += GenerateDeclaration((Declaration) s);
else if (s is Statement)
retstr += GenerateStatement((Statement) s);
else if (s is ReturnStatement)
retstr += GenerateReturnStatement((ReturnStatement) s);
else if (s is JumpLabel)
retstr += GenerateJumpLabel((JumpLabel) s);
else if (s is JumpStatement)
retstr += GenerateJumpStatement((JumpStatement) s);
else if (s is StateChange)
retstr += GenerateStateChange((StateChange) s);
else if (s is IfStatement)
retstr += GenerateIfStatement((IfStatement) s);
else if (s is WhileStatement)
retstr += GenerateWhileStatement((WhileStatement) s);
else if (s is DoWhileStatement)
retstr += GenerateDoWhileStatement((DoWhileStatement) s);
else if (s is ForLoop)
retstr += GenerateForLoop((ForLoop) s);
else if (s is ArgumentList)
retstr += GenerateArgumentList((ArgumentList) s);
else if (s is Assignment)
retstr += GenerateAssignment((Assignment) s);
else if (s is BinaryExpression)
retstr += GenerateBinaryExpression((BinaryExpression) s);
else if (s is ParenthesisExpression)
retstr += GenerateParenthesisExpression((ParenthesisExpression) s);
else if (s is UnaryExpression)
retstr += GenerateUnaryExpression((UnaryExpression) s);
else if (s is IncrementDecrementExpression)
retstr += GenerateIncrementDecrementExpression((IncrementDecrementExpression) s);
else if (s is TypecastExpression)
retstr += GenerateTypecastExpression((TypecastExpression) s);
else if (s is FunctionCall)
retstr += GenerateFunctionCall((FunctionCall) s);
else if (s is VectorConstant)
retstr += GenerateVectorConstant((VectorConstant) s);
else if (s is RotationConstant)
retstr += GenerateRotationConstant((RotationConstant) s);
else if (s is ListConstant)
retstr += GenerateListConstant((ListConstant) s);
else if (s is Constant)
retstr += GenerateConstant((Constant) s);
else if (s is IdentDotExpression)
retstr += ((IdentDotExpression) s).Name + "." + ((IdentDotExpression) s).Member;
else if (s is IdentExpression)
retstr += ((IdentExpression) s).Name;
else if (s is IDENT)
retstr += ((TOKEN) s).yytext;
else
{
foreach (SYMBOL kid in s.kids)
retstr += GenerateNode(kid);
}
return retstr;
}
///
/// Generates the code for a GlobalFunctionDefinition node.
///
/// The GlobalFunctionDefinition node.
/// String containing C# code for GlobalFunctionDefinition gf.
private string GenerateGlobalFunctionDefinition(GlobalFunctionDefinition gf)
{
string retstr = String.Empty;
// we need to separate the argument declaration list from other kids
List argumentDeclarationListKids = new List();
List remainingKids = new List();
foreach (SYMBOL kid in gf.kids)
if (kid is ArgumentDeclarationList)
argumentDeclarationListKids.Add(kid);
else
remainingKids.Add(kid);
retstr += WriteIndented(String.Format("{0} {1}(", gf.ReturnType, gf.Name));
// print the state arguments, if any
foreach (SYMBOL kid in argumentDeclarationListKids)
retstr += GenerateArgumentDeclarationList((ArgumentDeclarationList) kid);
retstr += ")\n";
foreach (SYMBOL kid in remainingKids)
retstr += GenerateNode(kid);
return retstr;
}
///
/// Generates the code for a GlobalVariableDeclaration node.
///
/// The GlobalVariableDeclaration node.
/// String containing C# code for GlobalVariableDeclaration gv.
private string GenerateGlobalVariableDeclaration(GlobalVariableDeclaration gv)
{
string retstr = String.Empty;
foreach (SYMBOL s in gv.kids)
{
retstr += Indent();
retstr += GenerateNode(s);
retstr += ";\n";
}
return retstr;
}
///
/// Generates the code for a State node.
///
/// The State node.
/// String containing C# code for State s.
private string GenerateState(State s)
{
string retstr = String.Empty;
foreach (SYMBOL kid in s.kids)
if (kid is StateEvent)
retstr += GenerateStateEvent((StateEvent) kid, s.Name);
else
retstr += String.Format("ERROR: State '{0}' contains a '{1}\n", s.Name, kid.GetType());
return retstr;
}
///
/// Generates the code for a StateEvent node.
///
/// The StateEvent node.
/// The name of the parent state.
/// String containing C# code for StateEvent se.
private string GenerateStateEvent(StateEvent se, string parentStateName)
{
string retstr = String.Empty;
// we need to separate the argument declaration list from other kids
List argumentDeclarationListKids = new List();
List remainingKids = new List();
foreach (SYMBOL kid in se.kids)
if (kid is ArgumentDeclarationList)
argumentDeclarationListKids.Add(kid);
else
remainingKids.Add(kid);
// "state" (function) declaration
retstr += WriteIndented(String.Format("public void {0}_event_{1}(", parentStateName, se.Name));
// print the state arguments, if any
foreach (SYMBOL kid in argumentDeclarationListKids)
retstr += GenerateArgumentDeclarationList((ArgumentDeclarationList) kid);
retstr += ")\n";
foreach (SYMBOL kid in remainingKids)
retstr += GenerateNode(kid);
return retstr;
}
///
/// Generates the code for an ArgumentDeclarationList node.
///
/// The ArgumentDeclarationList node.
/// String containing C# code for SYMBOL s.
private string GenerateArgumentDeclarationList(ArgumentDeclarationList adl)
{
string retstr = String.Empty;
int comma = adl.kids.Count - 1; // tells us whether to print a comma
foreach (Declaration d in adl.kids)
{
retstr += String.Format("{0} {1}", d.Datatype, d.Id);
if (0 < comma--)
retstr += ", ";
}
return retstr;
}
///
/// Generates the code for an ArgumentList node.
///
/// The ArgumentList node.
/// String containing C# code for SYMBOL s.
private string GenerateArgumentList(ArgumentList al)
{
string retstr = String.Empty;
int comma = al.kids.Count - 1; // tells us whether to print a comma
foreach (SYMBOL s in al.kids)
{
retstr += GenerateNode(s);
if (0 < comma--)
retstr += ", ";
}
return retstr;
}
///
/// Generates the code for a CompoundStatement node.
///
/// The CompoundStatement node.
/// String containing C# code for SYMBOL s.
private string GenerateCompoundStatement(CompoundStatement cs)
{
string retstr = String.Empty;
// opening brace
retstr += WriteIndentedLine("{");
m_braceCount++;
foreach (SYMBOL kid in cs.kids)
retstr += GenerateNode(kid);
// closing brace
m_braceCount--;
retstr += WriteIndentedLine("}");
return retstr;
}
///
/// Generates the code for a Declaration node.
///
/// The Declaration node.
/// String containing C# code for SYMBOL s.
private string GenerateDeclaration(Declaration d)
{
return String.Format("{0} {1}", d.Datatype, d.Id);
}
///
/// Generates the code for a Statement node.
///
/// The Statement node.
/// String containing C# code for SYMBOL s.
private string GenerateStatement(Statement s)
{
string retstr = String.Empty;
// Jump label prints its own colon, we don't need a semicolon.
bool printSemicolon = !(s.kids.Top is JumpLabel);
retstr += Indent();
foreach (SYMBOL kid in s.kids)
retstr += GenerateNode(kid);
if (printSemicolon)
retstr += ";\n";
return retstr;
}
///
/// Generates the code for an Assignment node.
///
/// The Assignment node.
/// String containing C# code for SYMBOL s.
private string GenerateAssignment(Assignment a)
{
string retstr = String.Empty;
retstr += GenerateNode((SYMBOL) a.kids.Pop());
retstr +=String.Format(" {0} ", a.AssignmentType);
foreach (SYMBOL kid in a.kids)
retstr += GenerateNode(kid);
return retstr;
}
///
/// Generates the code for a ReturnStatement node.
///
/// The ReturnStatement node.
/// String containing C# code for SYMBOL s.
private string GenerateReturnStatement(ReturnStatement rs)
{
string retstr = String.Empty;
retstr += "return ";
foreach (SYMBOL kid in rs.kids)
retstr += GenerateNode(kid);
return retstr;
}
///
/// Generates the code for a JumpLabel node.
///
/// The JumpLabel node.
/// String containing C# code for SYMBOL s.
private string GenerateJumpLabel(JumpLabel jl)
{
return String.Format("{0}:\n", jl.LabelName);
}
///
/// Generates the code for a JumpStatement node.
///
/// The JumpStatement node.
/// String containing C# code for SYMBOL s.
private string GenerateJumpStatement(JumpStatement js)
{
return String.Format("goto {0}", js.TargetName);
}
///
/// Generates the code for a IfStatement node.
///
/// The IfStatement node.
/// String containing C# code for SYMBOL s.
private string GenerateIfStatement(IfStatement ifs)
{
string retstr = String.Empty;
retstr += WriteIndented("if (");
retstr += GenerateNode((SYMBOL) ifs.kids.Pop());
retstr += ")\n";
// CompoundStatement handles indentation itself but we need to do it
// otherwise.
bool indentHere = ifs.kids.Top is Statement;
if (indentHere) m_braceCount++;
retstr += GenerateNode((SYMBOL) ifs.kids.Pop());
if (indentHere) m_braceCount--;
if (0 < ifs.kids.Count) // do it again for an else
{
retstr += WriteIndentedLine("else");
indentHere = ifs.kids.Top is Statement;
if (indentHere) m_braceCount++;
retstr += GenerateNode((SYMBOL) ifs.kids.Pop());
if (indentHere) m_braceCount--;
}
return retstr;
}
///
/// Generates the code for a StateChange node.
///
/// The StateChange node.
/// String containing C# code for SYMBOL s.
private string GenerateStateChange(StateChange sc)
{
return String.Format("state(\"{0}\")", sc.NewState);
}
///
/// Generates the code for a WhileStatement node.
///
/// The WhileStatement node.
/// String containing C# code for SYMBOL s.
private string GenerateWhileStatement(WhileStatement ws)
{
string retstr = String.Empty;
retstr += WriteIndented("while (");
retstr += GenerateNode((SYMBOL) ws.kids.Pop());
retstr += ")\n";
// CompoundStatement handles indentation itself but we need to do it
// otherwise.
bool indentHere = ws.kids.Top is Statement;
if (indentHere) m_braceCount++;
retstr += GenerateNode((SYMBOL) ws.kids.Pop());
if (indentHere) m_braceCount--;
return retstr;
}
///
/// Generates the code for a DoWhileStatement node.
///
/// The DoWhileStatement node.
/// String containing C# code for SYMBOL s.
private string GenerateDoWhileStatement(DoWhileStatement dws)
{
string retstr = String.Empty;
retstr += WriteIndentedLine("do");
// CompoundStatement handles indentation itself but we need to do it
// otherwise.
bool indentHere = dws.kids.Top is Statement;
if (indentHere) m_braceCount++;
retstr += GenerateNode((SYMBOL) dws.kids.Pop());
if (indentHere) m_braceCount--;
retstr += WriteIndented("while (");
retstr += GenerateNode((SYMBOL) dws.kids.Pop());
retstr += ");\n";
return retstr;
}
///
/// Generates the code for a ForLoop node.
///
/// The ForLoop node.
/// String containing C# code for SYMBOL s.
private string GenerateForLoop(ForLoop fl)
{
string retstr = String.Empty;
retstr += WriteIndented("for (");
// for ( x = 0 ; x < 10 ; x++ )
// ^^^^^^^
retstr += GenerateForLoopStatement((ForLoopStatement) fl.kids.Pop());
retstr += "; ";
// for ( x = 0 ; x < 10 ; x++ )
// ^^^^^^^^
retstr += GenerateNode((SYMBOL) fl.kids.Pop());
retstr += "; ";
// for ( x = 0 ; x < 10 ; x++ )
// ^^^^^
retstr += GenerateForLoopStatement((ForLoopStatement) fl.kids.Pop());
retstr += ")\n";
// CompoundStatement handles indentation itself but we need to do it
// otherwise.
bool indentHere = fl.kids.Top is Statement;
if (indentHere) m_braceCount++;
retstr += GenerateNode((SYMBOL) fl.kids.Pop());
if (indentHere) m_braceCount--;
return retstr;
}
///
/// Generates the code for a ForLoopStatement node.
///
/// The ForLoopStatement node.
/// String containing C# code for SYMBOL s.
private string GenerateForLoopStatement(ForLoopStatement fls)
{
string retstr = String.Empty;
int comma = fls.kids.Count - 1; // tells us whether to print a comma
foreach (SYMBOL s in fls.kids)
{
retstr += GenerateNode(s);
if (0 < comma--)
retstr += ", ";
}
return retstr;
}
///
/// Generates the code for a BinaryExpression node.
///
/// The BinaryExpression node.
/// String containing C# code for SYMBOL s.
private string GenerateBinaryExpression(BinaryExpression be)
{
string retstr = String.Empty;
retstr += GenerateNode((SYMBOL) be.kids.Pop());
retstr += String.Format(" {0} ", be.ExpressionSymbol);
foreach (SYMBOL kid in be.kids)
retstr += GenerateNode(kid);
return retstr;
}
///
/// Generates the code for a UnaryExpression node.
///
/// The UnaryExpression node.
/// String containing C# code for SYMBOL s.
private string GenerateUnaryExpression(UnaryExpression ue)
{
string retstr = String.Empty;
retstr += ue.UnarySymbol;
retstr += GenerateNode((SYMBOL) ue.kids.Pop());
return retstr;
}
///
/// Generates the code for a ParenthesisExpression node.
///
/// The ParenthesisExpression node.
/// String containing C# code for SYMBOL s.
private string GenerateParenthesisExpression(ParenthesisExpression pe)
{
string retstr = String.Empty;
retstr += "(";
foreach (SYMBOL kid in pe.kids)
retstr += GenerateNode(kid);
retstr += ")";
return retstr;
}
///
/// Generates the code for a IncrementDecrementExpression node.
///
/// The IncrementDecrementExpression node.
/// String containing C# code for SYMBOL s.
private string GenerateIncrementDecrementExpression(IncrementDecrementExpression ide)
{
string retstr = String.Empty;
if (0 < ide.kids.Count)
{
IdentDotExpression dot = (IdentDotExpression) ide.kids.Top;
retstr += String.Format("{0}", ide.PostOperation ? dot.Name + "." + dot.Member + ide.Operation : ide.Operation + dot.Name + "." + dot.Member);
}
else
retstr += String.Format("{0}", ide.PostOperation ? ide.Name + ide.Operation : ide.Operation + ide.Name);
return retstr;
}
///
/// Generates the code for a TypecastExpression node.
///
/// The TypecastExpression node.
/// String containing C# code for SYMBOL s.
private string GenerateTypecastExpression(TypecastExpression te)
{
string retstr = String.Empty;
// we wrap all typecasted statements in parentheses
retstr += String.Format("({0}) (", te.TypecastType);
retstr += GenerateNode((SYMBOL) te.kids.Pop());
retstr += ")";
return retstr;
}
///
/// Generates the code for a FunctionCall node.
///
/// The FunctionCall node.
/// String containing C# code for SYMBOL s.
private string GenerateFunctionCall(FunctionCall fc)
{
string retstr = String.Empty;
retstr += String.Format("{0}(", fc.Id);
foreach (SYMBOL kid in fc.kids)
retstr += GenerateNode(kid);
retstr += ")";
return retstr;
}
///
/// Generates the code for a Constant node.
///
/// The Constant node.
/// String containing C# code for SYMBOL s.
private string GenerateConstant(Constant c)
{
string retstr = String.Empty;
// Supprt LSL's weird acceptance of floats with no trailing digits
// after the period. Turn float x = 10.; into float x = 10.0;
if ("LSL_Types.LSLFloat" == c.Type)
{
int dotIndex = c.Value.IndexOf('.') + 1;
if (0 < dotIndex && (dotIndex == c.Value.Length || !Char.IsDigit(c.Value[dotIndex])))
c.Value = c.Value.Insert(dotIndex, "0");
}
// need to quote strings
if ("LSL_Types.LSLString" == c.Type)
retstr += "\"";
retstr += c.Value;
if ("LSL_Types.LSLString" == c.Type)
retstr += "\"";
return retstr;
}
///
/// Generates the code for a VectorConstant node.
///
/// The VectorConstant node.
/// String containing C# code for SYMBOL s.
private string GenerateVectorConstant(VectorConstant vc)
{
string retstr = String.Empty;
retstr += String.Format("new {0}(", vc.Type);
retstr += GenerateNode((SYMBOL) vc.kids.Pop());
retstr += ", ";
retstr += GenerateNode((SYMBOL) vc.kids.Pop());
retstr += ", ";
retstr += GenerateNode((SYMBOL) vc.kids.Pop());
retstr += ")";
return retstr;
}
///
/// Generates the code for a RotationConstant node.
///
/// The RotationConstant node.
/// String containing C# code for SYMBOL s.
private string GenerateRotationConstant(RotationConstant rc)
{
string retstr = String.Empty;
retstr += String.Format("new {0}(", rc.Type);
retstr += GenerateNode((SYMBOL) rc.kids.Pop());
retstr += ", ";
retstr += GenerateNode((SYMBOL) rc.kids.Pop());
retstr += ", ";
retstr += GenerateNode((SYMBOL) rc.kids.Pop());
retstr += ", ";
retstr += GenerateNode((SYMBOL) rc.kids.Pop());
retstr += ")";
return retstr;
}
///
/// Generates the code for a ListConstant node.
///
/// The ListConstant node.
/// String containing C# code for SYMBOL s.
private string GenerateListConstant(ListConstant lc)
{
string retstr = String.Empty;
retstr += String.Format("new {0}(", lc.Type);
foreach (SYMBOL kid in lc.kids)
retstr += GenerateNode(kid);
retstr += ")";
return retstr;
}
///
/// Prints text correctly indented, followed by a newline.
///
/// String of text to print.
/// String containing C# code for SYMBOL s.
private string WriteIndentedLine(string s)
{
return WriteIndented(s) + "\n";
}
///
/// Prints text correctly indented.
///
/// String of text to print.
/// String containing C# code for SYMBOL s.
private string WriteIndented(string s)
{
return Indent() + s;
}
///
/// Prints correct indentation.
///
/// String containing C# code for SYMBOL s.
private string Indent()
{
string retstr = String.Empty;
for (int i = 0; i < m_braceCount; i++)
retstr += " ";
return retstr;
}
}
}