/// <summary>
/// Extracts all fields from the user type.
/// </summary>
/// <param name="factory">The user type factory.</param>
/// <param name="generationFlags">The user type generation flags.</param>
protected override IEnumerable<UserTypeField> ExtractFields(UserTypeFactory factory, UserTypeGenerationFlags generationFlags)
{
ExportStaticFields = true;
var fields = Symbol.Fields.OrderBy(s => s.Name).ToArray();
bool useThisClass = generationFlags.HasFlag(UserTypeGenerationFlags.UseClassFieldsFromDiaSymbolProvider);
string previousName = "";
foreach (var field in fields)
{
if (string.IsNullOrEmpty(field.Type.Name))
continue;
if (IsFieldFiltered(field) || field.Name == previousName)
continue;
if (field.Name.Contains("@"))
{
// Skip names contaings '@'
continue;
}
// Skip fields that are actual values of enum values
if (field.Type.Tag == Dia2Lib.SymTagEnum.SymTagEnum && field.Type.GetEnumValues().Any(t => t.Item1 == field.Name))
continue;
var userField = ExtractField(field, factory, generationFlags, forceIsStatic: true);
if (field.Type.Tag == Dia2Lib.SymTagEnum.SymTagPointerType)
{
// Do not use const values for pointers.
// We do not allow user type implicit conversion from integers.
userField.ConstantValue = string.Empty;
}
userField.FieldName = NormalizeSymbolNamespace(userField.FieldName);
userField.PropertyName = NormalizeSymbolNamespace(userField.PropertyName);
yield return userField;
previousName = field.Name;
}
foreach (var field in GetAutoGeneratedFields(false, useThisClass))
yield return field;
}
/// <summary>
/// Adds the symbol to user type factory and generates the user type.
/// </summary>
/// <param name="symbol">The non-template symbol.</param>
/// <param name="type">The XML type description.</param>
/// <param name="nameSpace">The namespace.</param>
/// <param name="generationFlags">The user type generation flags.</param>
/// <returns>Generated user type for the specified symbol.</returns>
internal UserType AddSymbol(Symbol symbol, XmlType type, string nameSpace, UserTypeGenerationFlags generationFlags)
{
UserType userType;
if (symbol.Tag == SymTagEnum.SymTagEnum)
{
userType = new EnumUserType(symbol, nameSpace);
}
else if (symbol.Tag == SymTagEnum.SymTagExe)
{
userType = new GlobalsUserType(symbol, type, nameSpace);
}
else if (generationFlags.HasFlag(UserTypeGenerationFlags.GeneratePhysicalMappingOfUserTypes))
{
userType = new PhysicalUserType(symbol, type, nameSpace);
}
else
{
userType = new UserType(symbol, type, nameSpace);
}
symbol.UserType = userType;
return userType;
}
/// <summary>
/// Writes the code for this user type to the specified output.
/// </summary>
/// <param name="output">The output.</param>
/// <param name="error">The error text writer.</param>
/// <param name="factory">The user type factory.</param>
/// <param name="generationFlags">The user type generation flags.</param>
/// <param name="indentation">The current indentation.</param>
public override void WriteCode(IndentedWriter output, TextWriter error, UserTypeFactory factory, UserTypeGenerationFlags generationFlags, int indentation = 0)
{
// Check if we need to write namespace
string nameSpace = (DeclaredInType as NamespaceUserType)?.FullClassName ?? Namespace;
if ((DeclaredInType == null || (!generationFlags.HasFlag(UserTypeGenerationFlags.SingleFileExport) && DeclaredInType is NamespaceUserType)) && !string.IsNullOrEmpty(nameSpace))
{
output.WriteLine(indentation, "namespace {0}", nameSpace);
output.WriteLine(indentation++, "{{");
}
// Write beginning of the enumeration
if (generationFlags.HasFlag(UserTypeGenerationFlags.GenerateFieldTypeInfoComment))
output.WriteLine(indentation, "// {0} (original name: {1})", ClassName, Symbol.Name);
if (AreValuesFlags())
output.WriteLine(indentation, @"[System.Flags]");
if (Symbol.Size != 0)
output.WriteLine(indentation, @"public enum {0} : {1}", ClassName, GetEnumBasicType(Symbol));
else
output.WriteLine(indentation, @"public enum {0}", ClassName);
output.WriteLine(indentation++, @"{{");
// Write values
foreach (var enumValue in Symbol.GetEnumValues())
{
output.WriteLine(indentation, "{0} = {1},", enumValue.Item1, enumValue.Item2);
}
// Enumeration end
output.WriteLine(--indentation, @"}}");
if ((DeclaredInType == null || (!generationFlags.HasFlag(UserTypeGenerationFlags.SingleFileExport) && DeclaredInType is NamespaceUserType)) && !string.IsNullOrEmpty(nameSpace))
{
output.WriteLine(--indentation, "}}");
}
}
/// <summary>
/// Adds the symbols to user type factory and generates the user types.
/// </summary>
/// <param name="symbols">The template symbols grouped around the same template type.</param>
/// <param name="type">The XML type description.</param>
/// <param name="nameSpace">The namespace.</param>
/// <param name="generationFlags">The user type generation flags.</param>
/// <returns>Generated user types for the specified symbols.</returns>
internal IEnumerable<UserType> AddSymbols(IEnumerable<Symbol> symbols, XmlType type, string nameSpace, UserTypeGenerationFlags generationFlags)
{
if (!type.IsTemplate && symbols.Count() > 1)
throw new Exception("Type has more than one symbol for " + type.Name);
if (!type.IsTemplate)
{
yield return AddSymbol(symbols.First(), type, nameSpace, generationFlags);
}
else
{
// Bucketize template user types based on number of template arguments
var buckets = new Dictionary<int, List<TemplateUserType>>();
foreach (Symbol symbol in symbols)
{
UserType userType = null;
try
{
// We want to ignore "empty" generic classes (for now)
if (symbol.Name == null || symbol.Size == 0)
continue;
// Generate template user type
TemplateUserType templateType = new TemplateUserType(symbol, type, nameSpace, this);
#if false // TODO: Verify if we want to use simple user type instead of template user type
if (templateType.AllTemplateArguments.Count == 0)
{
// Template does not have arguments that can be used by generic
// Make it specialized type
userType = this.AddSymbol(symbol, null, moduleName, generationOptions);
}
else
#endif
{
List<TemplateUserType> templates;
symbol.UserType = templateType;
if (!buckets.TryGetValue(templateType.AllTemplateArguments.Count, out templates))
buckets.Add(templateType.AllTemplateArguments.Count, templates = new List<TemplateUserType>());
templates.Add(templateType);
}
}
catch (Exception ex)
{
// TODO: Verify if we need to add this as specialization
if (ex.Message != "Wrongly formed template argument")
throw;
}
if (userType != null)
yield return userType;
}
// Add newly generated types
foreach (List<TemplateUserType> templatesInBucket in buckets.Values)
{
// TODO: Verify that all templates in the list can be described by the same class (also do check for inner-types)
// Sort Templates by Class Name.
// This removes ambiguity caused by parallel type processing.
//
List<TemplateUserType> templates = templatesInBucket.OrderBy(t => t.Symbol.Name.Count(c => c == '*'))
.ThenBy(t => t.Symbol.Name.Count(c => c == '<'))
.ThenBy(t => t.Symbol.Name).ToList();
// Select best suited type for template
TemplateUserType template = templates.First();
foreach (var specializedTemplate in templates)
{
var arguments = specializedTemplate.AllTemplateArguments;
// Check if all arguments are different
if (arguments.Distinct().Count() == arguments.Count())
{
// Check if all arguments are simple user type
bool simpleUserType = true;
foreach (var argument in arguments)
{
var argumentSymbol = GlobalCache.GetSymbol(argument, specializedTemplate.Module);
if (argumentSymbol.Tag != SymTagEnum.SymTagUDT || argumentSymbol.Name.Contains("<"))
{
simpleUserType = false;
break;
}
}
if (simpleUserType)
{
template = specializedTemplate;
break;
}
// Check if none of the arguments is template user type
bool noneIsTemplate = true;
foreach (var argument in arguments)
{
var argumentSymbol = GlobalCache.GetSymbol(argument, specializedTemplate.Module);
if (argumentSymbol.Tag == SymTagEnum.SymTagUDT && argumentSymbol.Name.Contains("<"))
{
noneIsTemplate = false;
break;
}
}
if (noneIsTemplate)
{
template = specializedTemplate;
continue;
}
}
// This one is as good as any...
}
// Move all types under the selected type
foreach (var specializedTemplate in templates)
{
template.SpecializedTypes.Add(specializedTemplate);
specializedTemplate.TemplateType = template;
}
yield return template;
}
}
}
/// <summary>
/// Adds template symbols to user type factory and generates template user types.
/// </summary>
/// <param name="symbols">The template symbols grouped around the same template type.</param>
/// <param name="nameSpace">The namespace.</param>
/// <param name="generationFlags">The user type generation flags.</param>
/// <returns>Generated user types for the specified symbols.</returns>
internal IEnumerable <UserType> AddTemplateSymbols(IEnumerable <Symbol> symbols, string nameSpace, UserTypeGenerationFlags generationFlags)
{
// Bucketize template user types based on number of template arguments
var buckets = new Dictionary <int, List <SpecializedTemplateUserType> >();
foreach (Symbol symbol in symbols)
{
UserType userType = null;
// We want to ignore "empty" generic classes (for now)
if (symbol.Name == null || symbol.Size == 0)
{
continue;
}
// Generate template user type
SpecializedTemplateUserType templateType = new SpecializedTemplateUserType(symbol, null, nameSpace, this);
if (!templateType.WronglyFormed)
{
List <SpecializedTemplateUserType> templates;
symbol.UserType = templateType;
if (!buckets.TryGetValue(templateType.AllTemplateArguments.Count, out templates))
{
buckets.Add(templateType.AllTemplateArguments.Count, templates = new List <SpecializedTemplateUserType>());
}
templates.Add(templateType);
}
if (userType != null)
{
yield return(userType);
}
}
// Add newly generated types
foreach (List <SpecializedTemplateUserType> templatesInBucket in buckets.Values)
{
// TODO: Verify that all templates in the list can be described by the same class (also do check for inner-types)
// Sort Templates by Class Name.
// This removes ambiguity caused by parallel type processing.
//
List <SpecializedTemplateUserType> templates = templatesInBucket.OrderBy(t => t.Symbol.Name.Count(c => c == '*'))
.ThenBy(t => t.Symbol.Name.Count(c => c == '<'))
.ThenBy(t => t.Symbol.Name).ToList();
// Select best suited type for template
SpecializedTemplateUserType template = templates.First();
int bestScore = int.MaxValue;
foreach (var specializedTemplate in templates)
{
var arguments = specializedTemplate.AllTemplateArguments;
int score = 0;
for (int i = 0; i < arguments.Count; i++)
{
var argument = arguments[i];
// Check if this is repeated type
bool repeated = false;
for (int j = 0; j < i && !repeated; j++)
{
repeated = argument == arguments[j];
}
if (repeated)
{
score += 100;
}
// Check if argument is constant
if (argument.Tag == CodeTypeTag.TemplateArgumentConstant)
{
continue;
}
// Check if argument is simple user type
if ((argument.Tag == CodeTypeTag.Class || argument.Tag == CodeTypeTag.Structure || argument.Tag == CodeTypeTag.Union || argument.Tag == CodeTypeTag.Enum) && !argument.Name.Contains("<"))
{
score += 1;
continue;
}
// Check if argments is function
if (argument.Tag == CodeTypeTag.Function)
{
score += 2;
continue;
}
// Check if argument is template
if (argument.Name.Contains("<"))
{
score += 20;
continue;
}
// All others fall into the same category
score += 5;
}
// Check if this is the best one
if (score < bestScore)
{
bestScore = score;
template = specializedTemplate;
}
}
yield return(new TemplateUserType(template, templates, this));
}
}
/// <summary>
/// Generates user types using the specified XML configuration.
/// </summary>
/// <param name="xmlConfig">The XML configuration.</param>
/// <param name="logger">The logger text writer. If set to null, Console.Out will be used.</param>
/// <param name="errorLogger">The error logger text writer. If set to null, Console.Error will be used.</param>
public static void Generate(XmlConfig xmlConfig, TextWriter logger = null, TextWriter errorLogger = null)
{
var sw = System.Diagnostics.Stopwatch.StartNew();
XmlModule[] xmlModules = xmlConfig.Modules;
XmlType[] typeNames = xmlConfig.Types;
XmlIncludedFile[] includedFiles = xmlConfig.IncludedFiles;
XmlReferencedAssembly[] referencedAssemblies = xmlConfig.ReferencedAssemblies;
UserTypeGenerationFlags generationOptions = xmlConfig.GetGenerationFlags();
ConcurrentDictionary <string, string> generatedFiles = new ConcurrentDictionary <string, string>();
var syntaxTrees = new ConcurrentBag <SyntaxTree>();
string currentDirectory = Directory.GetCurrentDirectory();
string outputDirectory = currentDirectory + "\\output\\";
// Check logger and error logger
if (errorLogger == null)
{
errorLogger = Console.Error;
}
if (logger == null)
{
logger = Console.Out;
}
// Create output directory
Directory.CreateDirectory(outputDirectory);
// Verify that included files exist
if (!string.IsNullOrEmpty(xmlConfig.GeneratedAssemblyName))
{
foreach (var file in includedFiles)
{
if (!File.Exists(file.Path))
{
throw new FileNotFoundException("", file.Path);
}
}
}
// Loading modules
ConcurrentDictionary <Module, XmlModule> modules = new ConcurrentDictionary <Module, XmlModule>();
ConcurrentDictionary <XmlModule, Symbol[]> globalTypesPerModule = new ConcurrentDictionary <XmlModule, Symbol[]>();
logger.Write("Loading modules...");
Parallel.ForEach(xmlModules, (xmlModule) =>
{
Module module = Module.Open(xmlModule);
modules.TryAdd(module, xmlModule);
});
logger.WriteLine(" {0}", sw.Elapsed);
// Enumerating symbols
logger.Write("Enumerating symbols...");
Parallel.ForEach(modules, (mm) =>
{
XmlModule xmlModule = mm.Value;
Module module = mm.Key;
string moduleName = xmlModule.Name;
string nameSpace = xmlModule.Namespace;
List <Symbol> symbols = new List <Symbol>();
foreach (var type in typeNames)
{
Symbol[] foundSymbols = module.FindGlobalTypeWildcard(type.NameWildcard);
if (foundSymbols.Length == 0)
{
errorLogger.WriteLine("Symbol not found: {0}", type.Name);
}
else
{
symbols.AddRange(foundSymbols);
}
}
symbols.AddRange(module.GetAllTypes());
globalTypesPerModule.TryAdd(xmlModule, symbols.ToArray());
});
List <Symbol> allSymbols = new List <Symbol>();
Symbol[][] symbolsPerModule = globalTypesPerModule.Select(ss => ss.Value).ToArray();
int maxSymbols = symbolsPerModule.Max(ss => ss.Length);
for (int i = 0; i < maxSymbols; i++)
{
for (int j = 0; j < symbolsPerModule.Length; j++)
{
if (i < symbolsPerModule[j].Length)
{
allSymbols.Add(symbolsPerModule[j][i]);
}
}
}
logger.WriteLine(" {0}", sw.Elapsed);
#if false
// Initialize symbol fields and base classes
logger.Write("Initializing symbol values...");
Parallel.ForEach(Partitioner.Create(allSymbols), (symbol) =>
{
var fields = symbol.Fields;
var baseClasses = symbol.BaseClasses;
});
logger.WriteLine(" {0}", sw.Elapsed);
#endif
logger.Write("Deduplicating symbols...");
// Group duplicated symbols
Dictionary <string, List <Symbol> > symbolsByName = new Dictionary <string, List <Symbol> >();
Dictionary <Symbol, List <Symbol> > duplicatedSymbols = new Dictionary <Symbol, List <Symbol> >();
foreach (var symbol in allSymbols)
{
List <Symbol> symbols;
if (!symbolsByName.TryGetValue(symbol.Name, out symbols))
{
symbolsByName.Add(symbol.Name, symbols = new List <Symbol>());
}
bool found = false;
foreach (var s in symbols.ToArray())
{
if (s.Size != 0 && symbol.Size != 0 && s.Size != symbol.Size)
{
#if DEBUG
logger.WriteLine("{0}!{1} ({2}) {3}!{4} ({5})", s.Module.Name, s.Name, s.Size, symbol.Module.Name, symbol.Name, symbol.Size);
#endif
continue;
}
if (s.Size == 0 && symbol.Size != 0)
{
List <Symbol> duplicates;
if (!duplicatedSymbols.TryGetValue(s, out duplicates))
{
duplicatedSymbols.Add(s, duplicates = new List <Symbol>());
}
duplicatedSymbols.Remove(s);
duplicates.Add(s);
duplicatedSymbols.Add(symbol, duplicates);
symbols.Remove(s);
symbols.Add(symbol);
}
else
{
List <Symbol> duplicates;
if (!duplicatedSymbols.TryGetValue(s, out duplicates))
{
duplicatedSymbols.Add(s, duplicates = new List <Symbol>());
}
duplicates.Add(symbol);
}
found = true;
break;
}
if (!found)
{
symbols.Add(symbol);
}
}
// Unlink duplicated symbols if two or more are named the same
foreach (var symbols in symbolsByName.Values)
{
if (symbols.Count <= 1)
{
continue;
}
foreach (var s in symbols.ToArray())
{
List <Symbol> duplicates;
if (!duplicatedSymbols.TryGetValue(s, out duplicates))
{
continue;
}
symbols.AddRange(duplicates);
duplicatedSymbols.Remove(s);
}
}
// Extracting deduplicated symbols
Dictionary <string, Symbol[]> deduplicatedSymbols = new Dictionary <string, Symbol[]>();
Dictionary <Symbol, string> symbolNamespaces = new Dictionary <Symbol, string>();
foreach (var symbols in symbolsByName.Values)
{
if (symbols.Count != 1)
{
foreach (var s in symbols)
{
symbolNamespaces.Add(s, modules[s.Module].Namespace);
}
}
else
{
Symbol symbol = symbols.First();
List <Symbol> duplicates;
if (!duplicatedSymbols.TryGetValue(symbol, out duplicates))
{
duplicates = new List <Symbol>();
}
duplicates.Insert(0, symbol);
deduplicatedSymbols.Add(symbol.Name, duplicates.ToArray());
foreach (var s in duplicates)
{
symbolNamespaces.Add(s, xmlConfig.CommonTypesNamespace);
}
}
}
var globalTypes = symbolsByName.SelectMany(s => s.Value).ToArray();
logger.WriteLine(" {0}", sw.Elapsed);
logger.WriteLine(" Total symbols: {0}", globalTypesPerModule.Sum(gt => gt.Value.Length));
logger.WriteLine(" Unique symbol names: {0}", symbolsByName.Count);
logger.WriteLine(" Dedupedlicated symbols: {0}", globalTypes.Length);
// Initialize GlobalCache with deduplicatedSymbols
GlobalCache.Update(deduplicatedSymbols);
// Collecting types
logger.Write("Collecting types...");
var factory = new UserTypeFactory(xmlConfig.Transformations);
List <UserType> userTypes = new List <UserType>();
foreach (var module in modules.Keys)
{
userTypes.Add(factory.AddSymbol(module.GlobalScope, new XmlType()
{
Name = "ModuleGlobals"
}, modules[module].Namespace, generationOptions));
}
ConcurrentBag <Symbol> simpleSymbols = new ConcurrentBag <Symbol>();
Dictionary <Tuple <string, string>, List <Symbol> > templateSymbols = new Dictionary <Tuple <string, string>, List <Symbol> >();
Parallel.ForEach(Partitioner.Create(globalTypes), (symbol) =>
{
string symbolName = symbol.Name;
// TODO: Add configurable filter
//
if (symbolName.StartsWith("$") || symbolName.StartsWith("__vc_attributes") || symbolName.Contains("`anonymous-namespace'") || symbolName.Contains("`anonymous namespace'") || symbolName.Contains("::$") || symbolName.Contains("`"))
{
return;
}
// Do not handle template referenced arguments
if (symbolName.Contains("&"))
{
// TODO: Convert this to function pointer
return;
}
// TODO: For now remove all unnamed-type symbols
string scopedClassName = symbol.Namespaces.Last();
if (scopedClassName.StartsWith("<") || symbolName.Contains("::<"))
{
return;
}
// Check if symbol contains template type.
if (SymbolNameHelper.ContainsTemplateType(symbolName) && symbol.Tag == SymTagEnum.SymTagUDT)
{
List <string> namespaces = symbol.Namespaces;
string className = namespaces.Last();
var symbolId = Tuple.Create(symbolNamespaces[symbol], SymbolNameHelper.CreateLookupNameForSymbol(symbol));
lock (templateSymbols)
{
if (templateSymbols.ContainsKey(symbolId) == false)
{
templateSymbols[symbolId] = new List <Symbol>()
{
symbol
}
}
;
else
{
templateSymbols[symbolId].Add(symbol);
}
}
// TODO:
// Do not add physical types for template specialization (not now)
// do if types contains static fields
// nested in templates
}
else
{
simpleSymbols.Add(symbol);
}
});
logger.WriteLine(" {0}", sw.Elapsed);
// Populate Templates
logger.Write("Populating templates...");
foreach (List <Symbol> symbols in templateSymbols.Values)
{
Symbol symbol = symbols.First();
string symbolName = SymbolNameHelper.CreateLookupNameForSymbol(symbol);
XmlType type = new XmlType()
{
Name = symbolName
};
userTypes.AddRange(factory.AddSymbols(symbols, type, symbolNamespaces[symbol], generationOptions));
}
logger.WriteLine(" {0}", sw.Elapsed);
// Specialized class
logger.Write("Populating specialized classes...");
foreach (Symbol symbol in simpleSymbols)
{
userTypes.Add(factory.AddSymbol(symbol, null, symbolNamespaces[symbol], generationOptions));
}
logger.WriteLine(" {0}", sw.Elapsed);
// To solve template dependencies. Update specialization arguments once all the templates has been populated.
logger.Write("Updating template arguments...");
foreach (TemplateUserType templateUserType in userTypes.OfType <TemplateUserType>())
{
foreach (TemplateUserType specializedTemplateUserType in templateUserType.SpecializedTypes)
{
if (!specializedTemplateUserType.UpdateTemplateArguments(factory))
{
#if DEBUG
logger.WriteLine("Template user type cannot be updated: {0}", specializedTemplateUserType.Symbol.Name);
#endif
}
}
}
logger.WriteLine(" {0}", sw.Elapsed);
// Post processing user types (filling DeclaredInType)
logger.Write("Post processing user types...");
var namespaceTypes = factory.ProcessTypes(userTypes, symbolNamespaces).ToArray();
userTypes.AddRange(namespaceTypes);
logger.WriteLine(" {0}", sw.Elapsed);
// Code generation and saving it to disk
logger.Write("Saving code to disk...");
if (!generationOptions.HasFlag(UserTypeGenerationFlags.SingleFileExport))
{
// Generate Code
Parallel.ForEach(userTypes,
(symbolEntry) =>
{
Tuple <string, string> result = GenerateCode(symbolEntry, factory, outputDirectory, errorLogger, generationOptions, generatedFiles);
string text = result.Item1;
string filename = result.Item2;
if (xmlConfig.GenerateAssemblyWithRoslyn && !string.IsNullOrEmpty(xmlConfig.GeneratedAssemblyName) && !string.IsNullOrEmpty(text))
{
lock (syntaxTrees)
{
syntaxTrees.Add(CSharpSyntaxTree.ParseText(text, path: filename, encoding: System.Text.UTF8Encoding.Default));
}
}
});
}
else
{
string filename = string.Format(@"{0}\everything.exported.cs", outputDirectory);
HashSet <string> usings = new HashSet <string>();
foreach (var symbolEntry in userTypes)
{
foreach (var u in symbolEntry.Usings)
{
usings.Add(u);
}
}
generatedFiles.TryAdd(filename.ToLowerInvariant(), filename);
using (StringWriter stringOutput = new StringWriter())
using (TextWriter masterOutput = !xmlConfig.DontSaveGeneratedCodeFiles ? new StreamWriter(filename, false /* append */, System.Text.Encoding.UTF8, 16 * 1024 * 1024) : TextWriter.Null)
{
foreach (var u in usings.OrderBy(s => s))
{
masterOutput.WriteLine("using {0};", u);
if (xmlConfig.GenerateAssemblyWithRoslyn && !string.IsNullOrEmpty(xmlConfig.GeneratedAssemblyName))
{
stringOutput.WriteLine("using {0};", u);
}
}
masterOutput.WriteLine();
if (xmlConfig.GenerateAssemblyWithRoslyn)
{
stringOutput.WriteLine();
}
ObjectPool <StringWriter> stringWriterPool = new ObjectPool <StringWriter>(() => new StringWriter());
Parallel.ForEach(userTypes,
(symbolEntry) =>
{
var output = stringWriterPool.GetObject();
output.GetStringBuilder().Clear();
GenerateCodeInSingleFile(output, symbolEntry, factory, errorLogger, generationOptions);
string text = output.ToString();
if (!string.IsNullOrEmpty(text))
{
lock (masterOutput)
{
masterOutput.WriteLine(text);
if (xmlConfig.GenerateAssemblyWithRoslyn && !string.IsNullOrEmpty(xmlConfig.GeneratedAssemblyName))
{
stringOutput.WriteLine(text);
}
}
}
stringWriterPool.PutObject(output);
});
if (xmlConfig.GenerateAssemblyWithRoslyn && !string.IsNullOrEmpty(xmlConfig.GeneratedAssemblyName))
{
syntaxTrees.Add(CSharpSyntaxTree.ParseText(stringOutput.ToString(), path: filename, encoding: UTF8Encoding.Default));
}
}
}
logger.WriteLine(" {0}", sw.Elapsed);
// Compiling the code
string binFolder = Path.GetDirectoryName(Assembly.GetExecutingAssembly().Location);
if (xmlConfig.GenerateAssemblyWithRoslyn && !string.IsNullOrEmpty(xmlConfig.GeneratedAssemblyName))
{
List <MetadataReference> references = new List <MetadataReference>
{
MetadataReference.CreateFromFile(typeof(object).Assembly.Location),
MetadataReference.CreateFromFile(typeof(Enumerable).Assembly.Location)
};
references.AddRange(xmlConfig.ReferencedAssemblies.Select(r => MetadataReference.CreateFromFile(r.Path)));
foreach (var includedFile in includedFiles)
{
syntaxTrees.Add(CSharpSyntaxTree.ParseText(File.ReadAllText(includedFile.Path), path: includedFile.Path, encoding: System.Text.UTF8Encoding.Default));
}
CSharpCompilation compilation = CSharpCompilation.Create(
Path.GetFileNameWithoutExtension(xmlConfig.GeneratedAssemblyName),
syntaxTrees: syntaxTrees,
references: references,
options: new CSharpCompilationOptions(OutputKind.DynamicallyLinkedLibrary, platform: Platform.AnyCpu));
logger.WriteLine("Syntax trees: {0}", syntaxTrees.Count);
string dllFilename = Path.Combine(outputDirectory, xmlConfig.GeneratedAssemblyName);
string pdbFilename = Path.Combine(outputDirectory, Path.GetFileNameWithoutExtension(dllFilename) + ".pdb");
using (var dllStream = new FileStream(dllFilename, FileMode.Create))
using (var pdbStream = new FileStream(pdbFilename, FileMode.Create))
{
var result = compilation.Emit(dllStream, !xmlConfig.DisablePdbGeneration ? pdbStream : null);
if (!result.Success)
{
IEnumerable <Diagnostic> failures = result.Diagnostics.Where(diagnostic =>
diagnostic.IsWarningAsError ||
diagnostic.Severity == DiagnosticSeverity.Error);
errorLogger.WriteLine("Compile errors (top 1000):");
foreach (var diagnostic in failures.Take(1000))
{
errorLogger.WriteLine(diagnostic);
}
}
else
{
logger.WriteLine("DLL size: {0}", dllStream.Position);
logger.WriteLine("PDB size: {0}", pdbStream.Position);
}
}
logger.WriteLine("Compiling: {0}", sw.Elapsed);
}
// Check whether we should generate assembly
if (!xmlConfig.GenerateAssemblyWithRoslyn && !string.IsNullOrEmpty(xmlConfig.GeneratedAssemblyName))
{
var codeProvider = new CSharpCodeProvider();
var compilerParameters = new CompilerParameters()
{
IncludeDebugInformation = !xmlConfig.DisablePdbGeneration,
OutputAssembly = outputDirectory + xmlConfig.GeneratedAssemblyName,
};
compilerParameters.ReferencedAssemblies.AddRange(AppDomain.CurrentDomain.GetAssemblies().Where(a => !a.IsDynamic).Select(a => a.Location).ToArray());
//compilerParameters.ReferencedAssemblies.AddRange(referencedAssemblies);
const string MicrosoftCSharpDll = "Microsoft.CSharp.dll";
if (!compilerParameters.ReferencedAssemblies.Cast <string>().Where(a => a.Contains(MicrosoftCSharpDll)).Any())
{
compilerParameters.ReferencedAssemblies.Add(MicrosoftCSharpDll);
}
compilerParameters.ReferencedAssemblies.Add(Path.Combine(binFolder, "CsDebugScript.Engine.dll"));
compilerParameters.ReferencedAssemblies.Add(Path.Combine(binFolder, "CsDebugScript.CommonUserTypes.dll"));
var filesToCompile = generatedFiles.Values.Union(includedFiles.Select(f => f.Path)).ToArray();
var compileResult = codeProvider.CompileAssemblyFromFile(compilerParameters, filesToCompile);
if (compileResult.Errors.Count > 0)
{
errorLogger.WriteLine("Compile errors (top 1000):");
foreach (CompilerError err in compileResult.Errors.Cast <CompilerError>().Take(1000))
{
errorLogger.WriteLine(err);
}
}
logger.WriteLine("Compiling: {0}", sw.Elapsed);
}
// Generating props file
if (!string.IsNullOrEmpty(xmlConfig.GeneratedPropsFileName))
{
using (TextWriter output = new StreamWriter(outputDirectory + xmlConfig.GeneratedPropsFileName, false /* append */, System.Text.Encoding.UTF8, 16 * 1024 * 1024))
{
output.WriteLine(@"<?xml version=""1.0"" encoding=""utf-8""?>");
output.WriteLine(@"<Project xmlns=""http://schemas.microsoft.com/developer/msbuild/2003"">");
output.WriteLine(@" <ItemGroup>");
foreach (var file in generatedFiles.Values)
{
output.WriteLine(@" <Compile Include=""{0}"" />", file);
}
output.WriteLine(@" </ItemGroup>");
output.WriteLine(@"</Project>");
}
}
logger.WriteLine("Total time: {0}", sw.Elapsed);
}
/// <summary>
/// Writes the field code.
/// </summary>
/// <param name="output">The output.</param>
/// <param name="indentation">The indentation.</param>
/// <param name="options">The options.</param>
public override void WriteFieldCode(IndentedWriter output, int indentation, UserTypeGenerationFlags options)
{
output.WriteLine(indentation, "{0} {1}();", FieldType, FieldName);
}
/// <summary>
/// Generates the constructors.
/// </summary>
/// <param name="generationFlags">The user type generation flags.</param>
protected override IEnumerable<UserTypeConstructor> GenerateConstructors(UserTypeGenerationFlags generationFlags)
{
yield return new UserTypeConstructor()
{
ContainsFieldDefinitions = true,
Static = true,
};
}
/// <summary>
/// Adds the symbols to user type factory and generates the user types.
/// </summary>
/// <param name="symbols">The template symbols grouped around the same template type.</param>
/// <param name="type">The XML type description.</param>
/// <param name="nameSpace">The namespace.</param>
/// <param name="generationFlags">The user type generation flags.</param>
/// <returns>Generated user types for the specified symbols.</returns>
internal IEnumerable <UserType> AddSymbols(IEnumerable <Symbol> symbols, XmlType type, string nameSpace, UserTypeGenerationFlags generationFlags)
{
if (!type.IsTemplate && symbols.Count() > 1)
{
throw new Exception("Type has more than one symbol for " + type.Name);
}
if (!type.IsTemplate)
{
yield return(AddSymbol(symbols.First(), type, nameSpace, generationFlags));
}
else
{
// Bucketize template user types based on number of template arguments
var buckets = new Dictionary <int, List <TemplateUserType> >();
foreach (Symbol symbol in symbols)
{
UserType userType = null;
try
{
// We want to ignore "empty" generic classes (for now)
if (symbol.Name == null || symbol.Size == 0)
{
continue;
}
// Generate template user type
TemplateUserType templateType = new TemplateUserType(symbol, type, nameSpace, this);
#if false // TODO: Verify if we want to use simple user type instead of template user type
if (templateType.NumberOfTemplateArguments == 0)
{
// Template does not have arguments that can be used by generic
// Make it specialized type
userType = this.AddSymbol(symbol, null, moduleName, generationOptions);
}
else
#endif
{
List <TemplateUserType> templates;
symbol.UserType = templateType;
if (!buckets.TryGetValue(templateType.NumberOfTemplateArguments, out templates))
{
buckets.Add(templateType.NumberOfTemplateArguments, templates = new List <TemplateUserType>());
}
templates.Add(templateType);
}
}
catch (Exception ex)
{
// TODO: Verify if we need to add this as specialization
if (ex.Message != "Wrongly formed template argument")
{
throw;
}
}
if (userType != null)
{
yield return(userType);
}
}
// Add newly generated types
foreach (var templates in buckets.Values)
{
// TODO: Verify that all templates in the list can be described by the same class (also do check for inner-types)
// Sort Templates by Class Name.
// This removes ambiguity caused by parallel type processing.
//
templates.Sort((a, b) => string.Compare(a.Symbol.Name, b.Symbol.Name, StringComparison.InvariantCulture));
// Select best suited type for template
TemplateUserType template = templates.First();
foreach (var specializedTemplate in templates)
{
var arguments = specializedTemplate.TemplateArguments;
// Check if all arguments are different
if (arguments.Distinct().Count() == arguments.Count())
{
// Check if all arguments are simple user type
bool simpleUserType = true;
foreach (var argument in arguments)
{
var argumentSymbol = GlobalCache.GetSymbol(argument, specializedTemplate.Module);
if (argumentSymbol.Tag != SymTagEnum.SymTagUDT || argumentSymbol.Name.Contains("<"))
{
simpleUserType = false;
break;
}
}
if (simpleUserType)
{
template = specializedTemplate;
break;
}
// Check if none of the arguments is template user type
bool noneIsTemplate = true;
foreach (var argument in arguments)
{
var argumentSymbol = GlobalCache.GetSymbol(argument, specializedTemplate.Module);
if (argumentSymbol.Tag == SymTagEnum.SymTagUDT && argumentSymbol.Name.Contains("<"))
{
noneIsTemplate = false;
break;
}
}
if (noneIsTemplate)
{
template = specializedTemplate;
continue;
}
}
// This one is good as any...
}
// Move all types under the selected type
foreach (var specializedTemplate in templates)
{
template.SpecializedTypes.Add(specializedTemplate);
specializedTemplate.TemplateType = template;
}
yield return(template);
}
}
}
/// <summary>
/// Writes the code for this user type to the specified output.
/// </summary>
/// <param name="output">The output.</param>
/// <param name="error">The error text writer.</param>
/// <param name="factory">The user type factory.</param>
/// <param name="generationFlags">The user type generation flags.</param>
/// <param name="indentation">The current indentation.</param>
public override void WriteCode(IndentedWriter output, TextWriter error, UserTypeFactory factory, UserTypeGenerationFlags generationFlags, int indentation = 0)
{
// Declared In Type with namespace
if (DeclaredInType != null)
{
foreach (string innerClass in namespaces)
{
output.WriteLine(indentation, "public static partial class {0}", innerClass);
output.WriteLine(indentation++, @"{{");
}
}
else
{
output.WriteLine(indentation, "namespace {0}", Namespace);
output.WriteLine(indentation++, @"{{");
}
// Inner types
foreach (var innerType in InnerTypes)
{
output.WriteLine();
innerType.WriteCode(output, error, factory, generationFlags, indentation);
}
// Declared In Type with namespace
if (DeclaredInType != null)
{
foreach (string innerClass in namespaces)
{
output.WriteLine(--indentation, "}}");
}
}
else
{
output.WriteLine(--indentation, "}}");
}
}
/// <summary>
/// Writes the property code to the specified output.
/// </summary>
/// <param name="output">The output.</param>
/// <param name="indentation">The current indentation.</param>
/// <param name="generationFlags">The user type generation flags.</param>
/// <param name="firstField">if set to <c>true</c> this is the first field in the user type.</param>
public virtual void WritePropertyCode(IndentedWriter output, int indentation, UserTypeGenerationFlags generationFlags, ref bool firstField)
{
if (string.IsNullOrEmpty(ConstantValue))
{
if (generationFlags.HasFlag(UserTypeGenerationFlags.SingleLineProperty))
{
if (firstField)
{
output.WriteLine();
firstField = false;
}
if (!UseUserMember && !CacheResult && generationFlags.HasFlag(UserTypeGenerationFlags.GenerateFieldTypeInfoComment) && !string.IsNullOrEmpty(FieldTypeInfoComment))
{
output.WriteLine(indentation, FieldTypeInfoComment);
}
if (UseUserMember && CacheResult)
{
output.WriteLine(indentation, "public {0}{1} {2} {{ get {{ return {3}.Value; }} }}", Static ? "static " : "", FieldType, PropertyName, FieldName);
}
else if (CacheResult)
{
output.WriteLine(indentation, "public {0}{1} {2} {{ get {{ return {3}; }} }}", Static ? "static " : "", FieldType, PropertyName, FieldName);
}
else
{
output.WriteLine(indentation, "public {0}{1} {2} {{ get {{ return {3}; }} }}", Static ? "static " : "", FieldType, PropertyName, ConstructorText);
}
}
else
{
output.WriteLine();
if (!UseUserMember && !CacheResult && generationFlags.HasFlag(UserTypeGenerationFlags.GenerateFieldTypeInfoComment) && !string.IsNullOrEmpty(FieldTypeInfoComment))
{
output.WriteLine(indentation, FieldTypeInfoComment);
}
output.WriteLine(indentation, "public {0}{1} {2}", Static ? "static " : "", FieldType, PropertyName);
output.WriteLine(indentation++, "{{");
output.WriteLine(indentation, "get");
output.WriteLine(indentation++, "{{");
if (UseUserMember && CacheResult)
{
output.WriteLine(indentation, "return {0}.Value;", FieldName);
}
else if (CacheResult)
{
output.WriteLine(indentation, "return {0};", FieldName);
}
else
{
output.WriteLine(indentation, "return {0};", ConstructorText);
}
output.WriteLine(--indentation, "}}");
output.WriteLine(--indentation, "}}");
}
}
}
/// <summary>
/// Writes the code for this user type to the specified output.
/// </summary>
/// <param name="output">The output.</param>
/// <param name="error">The error text writer.</param>
/// <param name="factory">The user type factory.</param>
/// <param name="generationFlags">The user type generation flags.</param>
/// <param name="indentation">The current indentation.</param>
public override void WriteCode(IndentedWriter output, TextWriter error, UserTypeFactory factory, UserTypeGenerationFlags generationFlags, int indentation = 0)
{
string[] namespaces = this.namespaces;
if (generationFlags.HasFlag(UserTypeGenerationFlags.GenerateNamespaceAsStaticClass))
{
namespaces = NamespaceSymbol.Split(".".ToCharArray());
}
// Declared In Type with namespace
if (DeclaredInType != null || generationFlags.HasFlag(UserTypeGenerationFlags.GenerateNamespaceAsStaticClass))
{
foreach (string innerClass in namespaces)
{
output.WriteLine(indentation, "public static partial class {0}", innerClass);
output.WriteLine(indentation++, @"{{");
}
}
else
{
output.WriteLine(indentation, "namespace {0}", Namespace);
output.WriteLine(indentation++, @"{{");
}
// Inner types
foreach (var innerType in InnerTypes)
{
output.WriteLine();
innerType.WriteCode(output, error, factory, generationFlags, indentation);
}
// Declared In Type with namespace
if (DeclaredInType != null || generationFlags.HasFlag(UserTypeGenerationFlags.GenerateNamespaceAsStaticClass))
{
foreach (string innerClass in namespaces)
{
output.WriteLine(--indentation, "}}");
}
}
else
{
output.WriteLine(--indentation, "}}");
}
}
/// <summary>
/// Generates user type field based on the specified symbol field and all other fields that are prepared for this function.
/// Do not use this function directly, unless you are calling it from overridden function.
/// </summary>
/// <param name="field">The symbol field.</param>
/// <param name="fieldType">The field tree type.</param>
/// <param name="factory">The user type factory.</param>
/// <param name="simpleFieldValue">The code foe "simple field value" used when creating transformation.</param>
/// <param name="gettingField">The code for getting field variable.</param>
/// <param name="isStatic">if set to <c>true</c> generated field should be static.</param>
/// <param name="generationFlags">The user type generation flags.</param>
/// <param name="extractingBaseClass">if set to <c>true</c> user type field is being generated for getting base class.</param>
protected override UserTypeField ExtractFieldInternal(SymbolField field, TypeTree fieldType, UserTypeFactory factory, string simpleFieldValue, string gettingField, bool isStatic, UserTypeGenerationFlags generationFlags, bool extractingBaseClass)
{
// Physical code generation make sense only for non-static fields
if (!isStatic)
{
bool lazyCacheUserTypeFields = generationFlags.HasFlag(UserTypeGenerationFlags.LazyCacheUserTypeFields);
bool cacheUserTypeFields = generationFlags.HasFlag(UserTypeGenerationFlags.CacheUserTypeFields);
bool cacheStaticUserTypeFields = generationFlags.HasFlag(UserTypeGenerationFlags.CacheStaticUserTypeFields);
string constructorText = "";
string fieldName = field.Name;
string fieldTypeString = fieldType.GetTypeString();
BasicTypeTree baseType = fieldType as BasicTypeTree;
ArrayTypeTree codeArrayType = fieldType as ArrayTypeTree;
UserTypeTree userType = fieldType as UserTypeTree;
TransformationTypeTree transformationType = fieldType as TransformationTypeTree;
bool isEmbedded = field.Type.Tag != CodeTypeTag.Pointer;
// Specialization for basic types
if (baseType != null)
{
if (baseType.BasicType == "string")
{
int charSize = field.Type.ElementType.Size;
constructorText = string.Format("ReadString(GetCodeType().Module.Process, ReadPointer(memoryBuffer, memoryBufferOffset + {0}, {1}), {2})", field.Offset, field.Type.Size, charSize);
}
else if (baseType.BasicType != "NakedPointer")
{
if (field.LocationType == LocationType.BitField)
{
constructorText = string.Format("Read{0}(memoryBuffer, memoryBufferOffset + {1}, {2}, {3})", baseType.GetTypeString().UppercaseFirst(), field.Offset, field.Size, field.BitPosition);
}
else
{
constructorText = string.Format("Read{0}(memoryBuffer, memoryBufferOffset + {1})", baseType.GetTypeString().UppercaseFirst(), field.Offset);
}
}
}
// Specialization for arrays
else if (codeArrayType != null)
{
if (codeArrayType.ElementType is BasicTypeTree)
{
baseType = (BasicTypeTree)codeArrayType.ElementType;
if (baseType != null && baseType.BasicType != "string" && baseType.BasicType != "NakedPointer")
{
int arraySize = field.Type.Size;
int elementSize = field.Type.ElementType.Size;
if (baseType.BasicType == "char")
{
constructorText = string.Format("Read{0}Array(memoryBuffer, memoryBufferOffset + {1}, {2}, {3})", baseType.GetTypeString().UppercaseFirst(), field.Offset, arraySize / elementSize, elementSize);
}
else
{
constructorText = string.Format("Read{0}Array(memoryBuffer, memoryBufferOffset + {1}, {2})", baseType.GetTypeString().UppercaseFirst(), field.Offset, arraySize / elementSize);
}
fieldTypeString = baseType.GetTypeString() + "[]";
}
}
}
// Specialization for user types
else if (userType != null && !extractingBaseClass)
{
if (!(userType.UserType is EnumUserType))
{
string thisClassCodeType;
if (IsTypeUsingStaticCodeType(this))
{
thisClassCodeType = ClassCodeType;
}
else
{
thisClassCodeType = "thisClass.Value.GetCodeType()";
usedThisClass = true;
}
// Check if type is embedded
if (!isEmbedded)
{
// If user type is not embedded, we do have pointer inside of our memory buffer that we can read directly
if (IsTypeUsingStaticCodeType(this))
{
constructorText = string.Format("ReadPointer<{0}>({4}, \"{1}\", memoryBuffer, memoryBufferOffset + {2}, {3})", fieldTypeString, fieldName, field.Offset, field.Type.Size, ClassCodeType);
}
else
{
constructorText = string.Format("ReadPointer<{0}>(thisClass, \"{1}\", memoryBuffer, memoryBufferOffset + {2}, {3})", fieldTypeString, fieldName, field.Offset, field.Type.Size);
usedThisClass = true;
}
// Do downcasting if field has vtable
if (userType.UserType.Symbol.HasVTable() && userType.UserType.DerivedClasses.Count > 0)
{
constructorText += ".DowncastObject()";
}
}
else
{
// If user type is embedded, we can reuse memory buffer that we already have in this class
string fieldAddress = string.Format("memoryBufferAddress + (ulong)(memoryBufferOffset + {0})", field.Offset);
string fieldCodeType = string.Format("{0}.GetClassFieldType(\"{1}\")", thisClassCodeType, fieldName);
if (IsTypeUsingStaticCodeType(userType.UserType))
{
fieldCodeType = string.Format("{0}.{1}", userType.UserType.FullClassName, ClassCodeType);
}
else if (IsTypeUsingStaticCodeType(this))
{
fieldCodeType = AddFieldCodeType(fieldName);
}
constructorText = string.Format("new {0}(memoryBuffer, memoryBufferOffset + {1}, memoryBufferAddress, {2}, {3}, \"{4}\")", fieldTypeString, field.Offset, fieldCodeType, fieldAddress, fieldName);
}
}
else
{
// TODO: This is enum. Read how much enum base type is big and just cast to enum type...
}
}
// Specialization for transformations
else if (transformationType != null)
{
if (!isEmbedded)
{
string thisClassCodeType;
if (IsTypeUsingStaticCodeType(this))
{
thisClassCodeType = ClassCodeType;
}
else
{
thisClassCodeType = "thisClass.Value.GetCodeType()";
usedThisClass = true;
}
string fieldAddress = string.Format("memoryBufferAddress + (ulong)(memoryBufferOffset + {0})", field.Offset);
string fieldVariable = string.Format("Variable.CreateNoCast({0}.GetClassFieldType(\"{1}\"), {2}, \"{1}\")", thisClassCodeType, fieldName, fieldAddress);
if (transformationType.Transformation.Transformation.HasPhysicalConstructor)
{
fieldVariable = string.Format("{0}, memoryBuffer, memoryBufferOffset + {1}, memoryBufferAddress", fieldVariable, field.Offset);
}
simpleFieldValue = fieldVariable;
constructorText = string.Format("new {0}({1})", fieldTypeString, fieldVariable);
}
}
// If we found suitable physical representation, generate the field
if (!string.IsNullOrEmpty(constructorText))
{
return new UserTypeField()
{
ConstructorText = constructorText,
FieldName = "_" + fieldName,
FieldType = fieldTypeString,
FieldTypeInfoComment = string.Format("// {0} {1};", field.Type.Name, fieldName),
PropertyName = UserTypeField.GetPropertyName(field, this),
Static = isStatic,
UseUserMember = lazyCacheUserTypeFields,
CacheResult = cacheUserTypeFields || (isStatic && cacheStaticUserTypeFields),
SimpleFieldValue = simpleFieldValue,
}
}
;
}
return(base.ExtractFieldInternal(field, fieldType, factory, simpleFieldValue, gettingField, isStatic, generationFlags, extractingBaseClass));
}
/// <summary>
/// Generates the code for user type in single file.
/// </summary>
/// <param name="output">The output text writer.</param>
/// <param name="userType">The user type.</param>
/// <param name="factory">The user type factory.</param>
/// <param name="errorOutput">The error output.</param>
/// <param name="generationFlags">The user type generation flags.</param>
/// <returns><c>true</c> if code was generated for the type; otherwise <c>false</c></returns>
private static bool GenerateCodeInSingleFile(TextWriter output, UserType userType, UserTypeFactory factory, TextWriter errorOutput, UserTypeGenerationFlags generationFlags)
{
Symbol symbol = userType.Symbol;
if (symbol != null && symbol.Tag == SymTagEnum.SymTagBaseType)
{
// ignore Base (Primitive) types.
return(false);
}
if (userType.DeclaredInType != null)
{
return(false);
}
userType.WriteCode(new IndentedWriter(output, generationFlags.HasFlag(UserTypeGenerationFlags.CompressedOutput)), errorOutput, factory, generationFlags);
return(true);
}
/// <summary>
/// Generates the code for user type and creates a file for it.
/// </summary>
/// <param name="userType">The user type.</param>
/// <param name="factory">The user type factory.</param>
/// <param name="outputDirectory">The output directory where code file will be stored.</param>
/// <param name="errorOutput">The error output.</param>
/// <param name="generationFlags">The user type generation flags.</param>
/// <param name="generatedFiles">The list of already generated files.</param>
/// <returns>Tuple of generated code and filename</returns>
private static Tuple <string, string> GenerateCode(UserType userType, UserTypeFactory factory, string outputDirectory, TextWriter errorOutput, UserTypeGenerationFlags generationFlags, ConcurrentDictionary <string, string> generatedFiles)
{
Symbol symbol = userType.Symbol;
if (symbol != null && symbol.Tag == SymTagEnum.SymTagBaseType)
{
// ignore Base (Primitive) types.
return(Tuple.Create("", ""));
}
bool allParentsAreNamespaces = true;
for (UserType parentType = userType.DeclaredInType; parentType != null && allParentsAreNamespaces; parentType = parentType.DeclaredInType)
{
allParentsAreNamespaces = parentType is NamespaceUserType;
}
if (userType is NamespaceUserType || !allParentsAreNamespaces)
{
return(Tuple.Create("", ""));
}
string classOutputDirectory = outputDirectory;
string nameSpace = (userType.DeclaredInType as NamespaceUserType)?.FullClassName ?? userType.Namespace;
if (!string.IsNullOrEmpty(nameSpace))
{
classOutputDirectory = Path.Combine(classOutputDirectory, nameSpace.Replace(".", "\\").Replace(":", "."));
}
Directory.CreateDirectory(classOutputDirectory);
bool isEnum = userType is EnumUserType;
string filename = string.Format(@"{0}\{1}{2}.exported.cs", classOutputDirectory, userType.ConstructorName, isEnum ? "_enum" : "");
int index = 1;
while (true)
{
if (generatedFiles.TryAdd(filename.ToLowerInvariant(), filename))
{
break;
}
filename = string.Format(@"{0}\{1}{2}_{3}.exported.cs", classOutputDirectory, userType.ConstructorName, isEnum ? "_enum" : "", index++);
}
using (TextWriter output = new StreamWriter(filename))
using (StringWriter stringOutput = new StringWriter())
{
userType.WriteCode(new IndentedWriter(stringOutput, generationFlags.HasFlag(UserTypeGenerationFlags.CompressedOutput)), errorOutput, factory, generationFlags);
string text = stringOutput.ToString();
output.WriteLine(text);
return(Tuple.Create(text, filename));
}
}
/// <summary>
/// Generates the constructors.
/// </summary>
/// <param name="generationFlags">The user type generation flags.</param>
protected override IEnumerable<UserTypeConstructor> GenerateConstructors(UserTypeGenerationFlags generationFlags)
{
yield return new UserTypeConstructor()
{
ContainsFieldDefinitions = true,
Static = true,
};
yield return new UserTypeConstructor()
{
Arguments = "Variable variable",
BaseClassInitialization = string.Format("this(variable.GetBaseClass(baseClassString), Debugger.ReadMemory(variable.GetCodeType().Module.Process, variable.GetBaseClass(baseClassString).GetPointerAddress(), {0}), 0, variable.GetBaseClass(baseClassString).GetPointerAddress())", Symbol.Size),
ContainsFieldDefinitions = false,
Static = false,
};
yield return new UserTypeConstructor()
{
Arguments = "Variable variable, CsDebugScript.Engine.Utility.MemoryBuffer buffer, int offset, ulong bufferAddress",
BaseClassInitialization = string.Format("base(variable, buffer, offset{0}, bufferAddress)", baseClassOffset > 0 ? " + " + baseClassOffset : ""),
ContainsFieldDefinitions = true,
Static = false,
};
yield return new UserTypeConstructor()
{
Arguments = "CsDebugScript.Engine.Utility.MemoryBuffer buffer, int offset, ulong bufferAddress, CodeType codeType, ulong address, string name = Variable.ComputedName, string path = Variable.UnknownPath",
BaseClassInitialization = string.Format("base(buffer, offset{0}, bufferAddress, codeType, address, name, path)", baseClassOffset > 0 ? " + " + baseClassOffset : ""),
ContainsFieldDefinitions = true,
Static = false,
};
}
/// <summary>
/// Generates user type field based on the specified symbol field and all other fields that are prepared for this function.
/// Do not use this function directly, unless you are calling it from overridden function.
/// </summary>
/// <param name="field">The symbol field.</param>
/// <param name="fieldType">The field tree type.</param>
/// <param name="factory">The user type factory.</param>
/// <param name="simpleFieldValue">The code foe "simple field value" used when creating transformation.</param>
/// <param name="gettingField">The code for getting field variable.</param>
/// <param name="isStatic">if set to <c>true</c> generated field should be static.</param>
/// <param name="generationFlags">The user type generation flags.</param>
/// <param name="extractingBaseClass">if set to <c>true</c> user type field is being generated for getting base class.</param>
protected override UserTypeField ExtractFieldInternal(SymbolField field, TypeTree fieldType, UserTypeFactory factory, string simpleFieldValue, string gettingField, bool isStatic, UserTypeGenerationFlags generationFlags, bool extractingBaseClass)
{
// Physical code generation make sense only for non-static fields
if (!isStatic)
{
bool lazyCacheUserTypeFields = generationFlags.HasFlag(UserTypeGenerationFlags.LazyCacheUserTypeFields);
bool cacheUserTypeFields = generationFlags.HasFlag(UserTypeGenerationFlags.CacheUserTypeFields);
bool cacheStaticUserTypeFields = generationFlags.HasFlag(UserTypeGenerationFlags.CacheStaticUserTypeFields);
string constructorText = "";
string fieldName = field.Name;
string fieldTypeString = fieldType.GetTypeString();
BasicTypeTree baseType = fieldType as BasicTypeTree;
ArrayTypeTree codeArrayType = fieldType as ArrayTypeTree;
UserTypeTree userType = fieldType as UserTypeTree;
TransformationTypeTree transformationType = fieldType as TransformationTypeTree;
bool isEmbedded = field.Type.Tag != SymTagEnum.SymTagPointerType;
// Specialization for basic types
if (baseType != null)
{
if (baseType.BasicType == "string")
{
int charSize = field.Type.ElementType.Size;
constructorText = string.Format("ReadString(GetCodeType().Module.Process, ReadPointer(memoryBuffer, memoryBufferOffset + {0}, {1}), {2})", field.Offset, field.Type.Size, charSize);
}
else if (baseType.BasicType != "NakedPointer")
{
if (field.LocationType == LocationType.BitField)
constructorText = string.Format("Read{0}(memoryBuffer, memoryBufferOffset + {1}, {2}, {3})", baseType.GetTypeString().UppercaseFirst(), field.Offset, field.Size, field.BitPosition);
else
constructorText = string.Format("Read{0}(memoryBuffer, memoryBufferOffset + {1})", baseType.GetTypeString().UppercaseFirst(), field.Offset);
}
}
// Specialization for arrays
else if (codeArrayType != null)
{
if (codeArrayType.ElementType is BasicTypeTree)
{
baseType = (BasicTypeTree)codeArrayType.ElementType;
if (baseType != null && baseType.BasicType != "string" && baseType.BasicType != "NakedPointer")
{
int arraySize = field.Type.Size;
int elementSize = field.Type.ElementType.Size;
if (baseType.BasicType == "char")
constructorText = string.Format("Read{0}Array(memoryBuffer, memoryBufferOffset + {1}, {2}, {3})", baseType.GetTypeString().UppercaseFirst(), field.Offset, arraySize / elementSize, elementSize);
else
constructorText = string.Format("Read{0}Array(memoryBuffer, memoryBufferOffset + {1}, {2})", baseType.GetTypeString().UppercaseFirst(), field.Offset, arraySize / elementSize);
fieldTypeString = baseType.GetTypeString() + "[]";
}
}
}
// Specialization for user types
else if (userType != null && !extractingBaseClass)
{
if (!(userType.UserType is EnumUserType))
{
string thisClassCodeType;
if (IsTypeUsingStaticCodeType(this))
thisClassCodeType = ClassCodeType;
else
{
thisClassCodeType = "thisClass.Value.GetCodeType()";
usedThisClass = true;
}
// Check if type is embedded
if (!isEmbedded)
{
// If user type is not embedded, we do have pointer inside of our memory buffer that we can read directly
if (IsTypeUsingStaticCodeType(this))
constructorText = string.Format("ReadPointer<{0}>({4}, \"{1}\", memoryBuffer, memoryBufferOffset + {2}, {3})", fieldTypeString, fieldName, field.Offset, field.Type.Size, ClassCodeType);
else
{
constructorText = string.Format("ReadPointer<{0}>(thisClass, \"{1}\", memoryBuffer, memoryBufferOffset + {2}, {3})", fieldTypeString, fieldName, field.Offset, field.Type.Size);
usedThisClass = true;
}
// Do downcasting if field has vtable
if (userType.UserType.Symbol.HasVTable() && userType.UserType.DerivedClasses.Count > 0)
constructorText += ".DowncastObject()";
}
else
{
// If user type is embedded, we can reuse memory buffer that we already have in this class
string fieldAddress = string.Format("memoryBufferAddress + (ulong)(memoryBufferOffset + {0})", field.Offset);
string fieldCodeType = string.Format("{0}.GetClassFieldType(\"{1}\")", thisClassCodeType, fieldName);
if (IsTypeUsingStaticCodeType(userType.UserType))
{
fieldCodeType = string.Format("{0}.{1}", userType.UserType.FullClassName, ClassCodeType);
}
else if (IsTypeUsingStaticCodeType(this))
{
fieldCodeType = AddFieldCodeType(fieldName);
}
constructorText = string.Format("new {0}(memoryBuffer, memoryBufferOffset + {1}, memoryBufferAddress, {2}, {3}, \"{4}\")", fieldTypeString, field.Offset, fieldCodeType, fieldAddress, fieldName);
}
}
else
{
// TODO: This is enum. Read how much enum base type is big and just cast to enum type...
}
}
// Specialization for transformations
else if (transformationType != null)
{
if (!isEmbedded)
{
string thisClassCodeType;
if (IsTypeUsingStaticCodeType(this))
thisClassCodeType = ClassCodeType;
else
{
thisClassCodeType = "thisClass.Value.GetCodeType()";
usedThisClass = true;
}
string fieldAddress = string.Format("memoryBufferAddress + (ulong)(memoryBufferOffset + {0})", field.Offset);
string fieldVariable = string.Format("Variable.CreateNoCast({0}.GetClassFieldType(\"{1}\"), {2}, \"{1}\")", thisClassCodeType, fieldName, fieldAddress);
if (transformationType.Transformation.Transformation.HasPhysicalConstructor)
{
fieldVariable = string.Format("{0}, memoryBuffer, memoryBufferOffset + {1}, memoryBufferAddress", fieldVariable, field.Offset);
}
simpleFieldValue = fieldVariable;
constructorText = string.Format("new {0}({1})", fieldTypeString, fieldVariable);
}
}
// If we found suitable physical representation, generate the field
if (!string.IsNullOrEmpty(constructorText))
return new UserTypeField()
{
ConstructorText = constructorText,
FieldName = "_" + fieldName,
FieldType = fieldTypeString,
FieldTypeInfoComment = string.Format("// {0} {1};", field.Type.Name, fieldName),
PropertyName = UserTypeField.GetPropertyName(fieldName, this),
Static = isStatic,
UseUserMember = lazyCacheUserTypeFields,
CacheResult = cacheUserTypeFields || (isStatic && cacheStaticUserTypeFields),
SimpleFieldValue = simpleFieldValue,
};
}
return base.ExtractFieldInternal(field, fieldType, factory, simpleFieldValue, gettingField, isStatic, generationFlags, extractingBaseClass);
}
/// <summary>
/// Writes the code for this user type to the specified output.
/// </summary>
/// <param name="output">The output.</param>
/// <param name="error">The error text writer.</param>
/// <param name="factory">The user type factory.</param>
/// <param name="generationFlags">The user type generation flags.</param>
/// <param name="indentation">The current indentation.</param>
public override void WriteCode(IndentedWriter output, TextWriter error, UserTypeFactory factory, UserTypeGenerationFlags generationFlags, int indentation = 0)
{
// Check if we need to write namespace
string nameSpace = (DeclaredInType as NamespaceUserType)?.FullClassName ?? Namespace;
string enumBasicType = GetEnumBasicType(Symbol);
if ((DeclaredInType == null || (!generationFlags.HasFlag(UserTypeGenerationFlags.SingleFileExport) && DeclaredInType is NamespaceUserType)) && !string.IsNullOrEmpty(nameSpace))
{
output.WriteLine(indentation, "namespace {0}", nameSpace);
output.WriteLine(indentation++, "{{");
}
// Write beginning of the enumeration
if (generationFlags.HasFlag(UserTypeGenerationFlags.GenerateFieldTypeInfoComment))
{
output.WriteLine(indentation, "// {0} (original name: {1})", ClassName, Symbol.Name);
}
if (AreValuesFlags())
{
output.WriteLine(indentation, @"[System.Flags]");
}
if (Symbol.Size != 0)
{
output.WriteLine(indentation, @"public enum {0} : {1}", ClassName, enumBasicType);
}
else
{
output.WriteLine(indentation, @"public enum {0}", ClassName);
}
output.WriteLine(indentation++, @"{{");
// Write values
foreach (var enumValue in Symbol.EnumValues)
{
string value = enumValue.Item2;
if (!FitsBasicType(enumBasicType, ref value))
{
output.WriteLine(indentation, "{0} = ({1}){2},", enumValue.Item1, enumBasicType, value);
}
else
{
output.WriteLine(indentation, "{0} = {1},", enumValue.Item1, value);
}
}
// Enumeration end
output.WriteLine(--indentation, @"}}");
if ((DeclaredInType == null || (!generationFlags.HasFlag(UserTypeGenerationFlags.SingleFileExport) && DeclaredInType is NamespaceUserType)) && !string.IsNullOrEmpty(nameSpace))
{
output.WriteLine(--indentation, "}}");
}
}
/// <summary>
/// Gets the user type generation flags.
/// </summary>
internal UserTypeGenerationFlags GetGenerationFlags()
{
UserTypeGenerationFlags generationFlags = UserTypeGenerationFlags.None;
if (CompressedOutput)
{
generationFlags |= UserTypeGenerationFlags.CompressedOutput;
DontGenerateFieldTypeInfoComment = true;
MultiLineProperties = false;
}
if (!DontGenerateFieldTypeInfoComment)
{
generationFlags |= UserTypeGenerationFlags.GenerateFieldTypeInfoComment;
}
if (!MultiLineProperties)
{
generationFlags |= UserTypeGenerationFlags.SingleLineProperty;
}
if (UseDirectClassAccess)
{
generationFlags |= UserTypeGenerationFlags.UseDirectClassAccess;
}
if (ForceUserTypesToNewInsteadOfCasting)
{
generationFlags |= UserTypeGenerationFlags.ForceUserTypesToNewInsteadOfCasting;
}
if (CacheUserTypeFields)
{
generationFlags |= UserTypeGenerationFlags.CacheUserTypeFields;
}
if (CacheStaticUserTypeFields)
{
generationFlags |= UserTypeGenerationFlags.CacheStaticUserTypeFields;
}
if (LazyCacheUserTypeFields)
{
generationFlags |= UserTypeGenerationFlags.LazyCacheUserTypeFields;
}
if (GeneratePhysicalMappingOfUserTypes)
{
generationFlags |= UserTypeGenerationFlags.GeneratePhysicalMappingOfUserTypes;
}
if (!MultiFileExport)
{
generationFlags |= UserTypeGenerationFlags.SingleFileExport;
}
if (UseHungarianNotation)
{
generationFlags |= UserTypeGenerationFlags.UseHungarianNotation;
}
if (GenerateNamespaceAsStaticClass)
{
generationFlags |= UserTypeGenerationFlags.GenerateNamespaceAsStaticClass;
}
if (DontSaveGeneratedCodeFiles && GenerateAssemblyWithRoslyn)
{
generationFlags |= UserTypeGenerationFlags.DontSaveGeneratedCodeFiles;
}
if (InitializeSymbolCaches)
{
generationFlags |= UserTypeGenerationFlags.InitializeSymbolCaches;
}
return(generationFlags);
}
/// <summary>
/// Extracts all fields from the user type.
/// </summary>
/// <param name="factory">The user type factory.</param>
/// <param name="generationFlags">The user type generation flags.</param>
protected override IEnumerable <UserTypeField> ExtractFields(UserTypeFactory factory, UserTypeGenerationFlags generationFlags)
{
ExportStaticFields = true;
var fields = Symbol.Fields.OrderBy(s => s.Name).ToArray();
bool useThisClass = generationFlags.HasFlag(UserTypeGenerationFlags.UseClassFieldsFromDiaSymbolProvider);
string previousName = "";
foreach (var field in fields)
{
if (string.IsNullOrEmpty(field.Type.Name))
{
continue;
}
if (IsFieldFiltered(field) || field.Name == previousName)
{
continue;
}
if (field.Name.Contains("@"))
{
// Skip names contaings '@'
continue;
}
// Skip fields that are actual values of enum values
if (field.Type.Tag == Dia2Lib.SymTagEnum.SymTagEnum && field.Type.GetEnumValues().Any(t => t.Item1 == field.Name))
{
continue;
}
var userField = ExtractField(field, factory, generationFlags, forceIsStatic: true);
if (field.Type.Tag == Dia2Lib.SymTagEnum.SymTagPointerType)
{
// Do not use const values for pointers.
// We do not allow user type implicit conversion from integers.
userField.ConstantValue = string.Empty;
}
userField.FieldName = NormalizeSymbolNamespace(userField.FieldName);
userField.PropertyName = NormalizeSymbolNamespace(userField.PropertyName);
yield return(userField);
previousName = field.Name;
}
foreach (var field in GetAutoGeneratedFields(false, useThisClass))
{
yield return(field);
}
}
/// <summary>
/// Writes the property code.
/// </summary>
/// <param name="output">The output.</param>
/// <param name="indentation">The indentation.</param>
/// <param name="options">The options.</param>
/// <param name="firstField">if set to <c>true</c> [first field].</param>
public override void WritePropertyCode(IndentedWriter output, int indentation, UserTypeGenerationFlags options, ref bool firstField)
{
// Do nothing
}
/// <summary>
/// Initializes a new instance of the <see cref="DotNetCodeWriter"/> class.
/// </summary>
/// <param name="generationFlags">The code generation options</param>
/// <param name="nameLimit">Maximum number of characters that generated name can have.</param>
/// <param name="fixKeywordsInUserNaming">Should we fix keywords by adding @ when fixing user naming?</param>
public DotNetCodeWriter(UserTypeGenerationFlags generationFlags, int nameLimit, bool fixKeywordsInUserNaming)
{
GenerationFlags = generationFlags;
NameLimit = nameLimit;
FixKeywordsInUserNaming = fixKeywordsInUserNaming;
}
/// <summary>
/// Writes the code for this user type to the specified output.
/// </summary>
/// <param name="output">The output.</param>
/// <param name="error">The error text writer.</param>
/// <param name="factory">The user type factory.</param>
/// <param name="generationFlags">The user type generation flags.</param>
/// <param name="indentation">The current indentation.</param>
public override void WriteCode(IndentedWriter output, TextWriter error, UserTypeFactory factory, UserTypeGenerationFlags generationFlags, int indentation = 0)
{
// Declared In Type with namespace
if (DeclaredInType != null)
{
foreach (string innerClass in namespaces)
{
output.WriteLine(indentation, "public static partial class {0}", innerClass);
output.WriteLine(indentation++, @"{{");
}
}
else
{
output.WriteLine(indentation, "namespace {0}", Namespace);
output.WriteLine(indentation++, @"{{");
}
// Inner types
foreach (var innerType in InnerTypes)
{
output.WriteLine();
innerType.WriteCode(output, error, factory, generationFlags, indentation);
}
// Declared In Type with namespace
if (DeclaredInType != null)
foreach (string innerClass in namespaces)
output.WriteLine(--indentation, "}}");
else
output.WriteLine(--indentation, "}}");
}
/// <summary>
/// Extracts all fields from the user type.
/// </summary>
/// <param name="factory">The user type factory.</param>
/// <param name="generationFlags">The user type generation flags.</param>
protected override IEnumerable <UserTypeField> ExtractFields(UserTypeFactory factory, UserTypeGenerationFlags generationFlags)
{
ExportStaticFields = true;
var fields = Symbol.Fields.OrderBy(s => s.Name).ToArray();
bool useThisClass = generationFlags.HasFlag(UserTypeGenerationFlags.UseDirectClassAccess);
HashSet <string> usedNames = new HashSet <string>();
foreach (var field in fields)
{
if (string.IsNullOrEmpty(field.Type.Name))
{
continue;
}
if (IsFieldFiltered(field))
{
continue;
}
field.PropertyName = NormalizeSymbolNamespace(UserTypeField.GetPropertyName(field, this));
while (usedNames.Contains(field.PropertyName))
{
field.PropertyName += "_";
}
if (field.Name.Contains("@") || field.PropertyName.Length > 511)
{
// Skip names containing '@'
continue;
}
// Skip fields that are actual values of enum values
if (field.Type.Tag == CodeTypeTag.Enum && field.Type.EnumValues.Any(t => t.Item1 == field.Name))
{
continue;
}
var userField = ExtractField(field, factory, generationFlags, forceIsStatic: true);
if (field.Type.Tag == CodeTypeTag.Pointer)
{
// Do not use const values for pointers.
// We do not allow user type implicit conversion from integers.
userField.ConstantValue = string.Empty;
}
userField.FieldName = NormalizeSymbolNamespace(userField.FieldName);
userField.PropertyName = NormalizeSymbolNamespace(userField.PropertyName);
yield return(userField);
usedNames.Add(field.PropertyName);
}
foreach (var field in GetAutoGeneratedFields(false, useThisClass))
{
yield return(field);
}
}
