package main import ( "regexp" "strings" ) type lookupResultClass struct { PackageName string } type lookupResultTypedef struct { PackageName string Typedef CppTypedef } type lookupResultEnum struct { PackageName string Enum CppEnum } var ( KnownClassnames map[string]lookupResultClass // Entries of the form QFoo::Bar if it is an inner class KnownTypedefs map[string]lookupResultTypedef KnownEnums map[string]lookupResultEnum ) func init() { KnownClassnames = make(map[string]lookupResultClass) KnownTypedefs = make(map[string]lookupResultTypedef) KnownEnums = make(map[string]lookupResultEnum) } type CppParameter struct { ParameterName string ParameterType string Const bool Pointer bool PointerCount int ByRef bool Optional bool QtCppOriginalType *CppParameter // If we rewrote QStringList->QList, this field contains the original QStringList. Otherwise, it's blank } func (p *CppParameter) ApplyTypedef(matchedUnderlyingType CppParameter) { if p.QtCppOriginalType == nil { tmp := *p // Copy p.QtCppOriginalType = &tmp // Overwrite once only, at the earliest base type } p.ParameterType = matchedUnderlyingType.ParameterType // If this was a pointer to a typedef'd type, or a typedef of a pointer type, we need to preserve that p.Const = p.Const || matchedUnderlyingType.Const p.Pointer = p.Pointer || matchedUnderlyingType.Pointer p.PointerCount += matchedUnderlyingType.PointerCount p.ByRef = p.ByRef || matchedUnderlyingType.ByRef p.Optional = p.Optional || matchedUnderlyingType.Optional } func (p *CppParameter) PointerTo() CppParameter { ret := *p // Copy ret.Pointer = true ret.PointerCount++ return ret } func (p *CppParameter) ConstCast(isConst bool) CppParameter { ret := *p // Copy ret.Const = isConst return ret } func (p *CppParameter) GetQtCppType() *CppParameter { if p.QtCppOriginalType != nil { return p.QtCppOriginalType } return p } func (p CppParameter) QFlagsOf() (CppParameter, bool) { if strings.HasPrefix(p.ParameterType, `QFlags<`) { ret := parseSingleTypeString(p.ParameterType[7 : len(p.ParameterType)-1]) ret.ParameterName = p.ParameterName + "_qf" return ret, true } if under := p.QtCppOriginalType; under != nil { if strings.HasPrefix(under.ParameterType, `QFlags<`) { ret := parseSingleTypeString(under.ParameterType[7 : len(under.ParameterType)-1]) ret.ParameterName = under.ParameterName + "_qf" return ret, true } } return CppParameter{}, false } func (p CppParameter) IsFlagType() bool { _, ok := p.QFlagsOf() return ok } func (p CppParameter) QtClassType() bool { // Maybe if it's an inner class if _, ok := KnownClassnames[p.ParameterType]; ok { return true } if p.ParameterType == "QString" || p.ParameterType == "QByteArray" { return true } return false } func (p CppParameter) IsKnownEnum() bool { _, ok := KnownEnums[p.ParameterType] return ok } func (p CppParameter) QListOf() (CppParameter, bool) { if strings.HasPrefix(p.ParameterType, "QList<") && strings.HasSuffix(p.ParameterType, `>`) { ret := parseSingleTypeString(p.ParameterType[6 : len(p.ParameterType)-1]) ret.ParameterName = p.ParameterName + "_lv" return ret, true } if strings.HasPrefix(p.ParameterType, "QVector<") && strings.HasSuffix(p.ParameterType, `>`) { ret := parseSingleTypeString(p.ParameterType[8 : len(p.ParameterType)-1]) ret.ParameterName = p.ParameterName + "_vv" return ret, true } return CppParameter{}, false } func (p CppParameter) QMapOf() bool { return strings.HasPrefix(p.ParameterType, `QMap<`) || strings.HasPrefix(p.ParameterType, `QHash<`) // TODO support this } func (p CppParameter) QPairOf() bool { return strings.HasPrefix(p.ParameterType, `QPair<`) // TODO support this } func (p CppParameter) QSetOf() (CppParameter, bool) { if strings.HasPrefix(p.ParameterType, `QSet<`) { ret := parseSingleTypeString(p.ParameterType[5 : len(p.ParameterType)-1]) ret.ParameterName = p.ParameterName + "_sv" return ret, true } return CppParameter{}, false } func (p CppParameter) IntType() bool { if p.IsKnownEnum() { return true } switch p.ParameterType { case "int", "unsigned int", "uint", "short", "unsigned short", "ushort", "qint16", "quint16", "uint16_t", "int16_t", "qint8", "quint8", "unsigned char", "signed char", "uchar", "long", "unsigned long", "ulong", "qint32", "quint32", "int32_t", "uint32_t", "longlong", "ulonglong", "qlonglong", "qulonglong", "qint64", "quint64", "int64_t", "uint64_t", "long long", "unsigned long long", "qintptr", "quintptr", "uintptr_t", "intptr_t", "qsizetype", "size_t", "QIntegerForSizeof::Unsigned", "QIntegerForSizeof::Signed", "QIntegerForSizeof::Signed", "qptrdiff", "ptrdiff_t", "double", "float", "qreal": return true case "char": // Only count char as an integer type with cast assertions if it's // not possibly a char* string in disguise // (However, unsigned chars are always like ints) return !p.Pointer default: return false } } type CppProperty struct { PropertyName string PropertyType string Visibility string } type CppMethod struct { MethodName string // C++ method name, unless OverrideMethodName is set, in which case a nice alternative name OverrideMethodName string // C++ method name, present only if we changed the target ReturnType CppParameter // Name not used Parameters []CppParameter IsStatic bool IsSignal bool IsConst bool HiddenParams []CppParameter // Populated if there is an overload with more parameters LinuxOnly bool } func (m CppMethod) CppCallTarget() string { if m.OverrideMethodName != "" { return m.OverrideMethodName } return m.MethodName } func (m *CppMethod) Rename(newName string) { if m.OverrideMethodName == "" { m.OverrideMethodName = m.MethodName } else { // If it was already set, we're already a level of overload resolution deep - preserve it } m.MethodName = newName } func IsArgcArgv(params []CppParameter, pos int) bool { // Check if the arguments starting at position=pos are the argc/argv pattern. // QApplication/QGuiApplication constructors are the only expected example of this. return (len(params) > pos+1 && params[pos].ParameterName == "argc" && params[pos].ParameterType == "int" && params[pos].ByRef && params[pos+1].ParameterName == "argv" && params[pos+1].ParameterType == "char") && params[pos+1].Pointer && params[pos+1].PointerCount == 2 } func IsReceiverMethod(params []CppParameter, pos int) bool { // Check if the arguments starting at position=pos are the receiver/member pattern. // QMenu->addAction is the main example of this return (len(params) > pos+1 && params[pos].ParameterName == "receiver" && params[pos].ParameterType == "QObject" && params[pos].Pointer && params[pos+1].ParameterName == "member" && params[pos+1].ParameterType == "char" && params[pos+1].Pointer) } func (nm CppMethod) IsReceiverMethod() bool { // Returns true if any of the parameters use the receiever-method pattern for i := 0; i < len(nm.Parameters); i++ { if IsReceiverMethod(nm.Parameters, i) { return true } } return false } func (nm CppMethod) SafeMethodName() string { tmp := nm.MethodName // Strip redundant Qt prefix, we know these are all Qt functions if strings.HasPrefix(tmp, "qt_") { tmp = tmp[3:] } // Operator-overload methods have names not representable in binding // languages. Replace more specific cases first replacer := strings.NewReplacer( `==`, `Equal`, `!=`, `NotEqual`, `>=`, `GreaterOrEqual`, `<=`, `LesserOrEqual`, `=`, `Assign`, `<<`, `ShiftLeft`, // Qt classes use it more for stream functions e.g. in QDataStream `>>`, `ShiftRight`, `>`, `Greater`, `<`, `Lesser`, `+`, `Plus`, `-`, `Minus`, `*`, `Multiply`, `/`, `Divide`, `%`, `Modulo`, `&&`, `LogicalAnd`, `||`, `LogicalOr`, `!`, `Not`, `&`, `BitwiseAnd`, `|`, `BitwiseOr`, `~`, `BitwiseXor`, `^`, `BitwiseNot`, `->`, `PointerDereference`, `[]`, `Subscript`, `()`, `Call`, ) tmp = replacer.Replace(tmp) // Also make the first letter uppercase so it becomes public in Go tmp = titleCase(tmp) // Also replace any underscore_case with CamelCase tmp = regexp.MustCompile(`_([a-z])`).ReplaceAllStringFunc(tmp, func(match string) string { return strings.ToUpper(match[1:]) }) return tmp } type CppEnumEntry struct { EntryName string EntryValue string } type CppEnum struct { EnumName string UnderlyingType CppParameter Entries []CppEnumEntry } func (e CppEnum) ShortEnumName() string { // Strip back one single :: pair from the generated variable name if nameParts := strings.Split(e.EnumName, `::`); len(nameParts) > 1 { nameParts = nameParts[0 : len(nameParts)-1] return strings.Join(nameParts, `::`) } // No change return e.EnumName } type CppClass struct { ClassName string Abstract bool Ctors []CppMethod // only use the parameters Inherits []string // other class names Methods []CppMethod Props []CppProperty CanDelete bool ChildTypedefs []CppTypedef ChildClassdefs []CppClass ChildEnums []CppEnum } type CppTypedef struct { Alias string UnderlyingType CppParameter } type CppParsedHeader struct { Filename string Typedefs []CppTypedef Enums []CppEnum Classes []CppClass } func (c CppParsedHeader) Empty() bool { return len(c.Typedefs) == 0 && len(c.Enums) == 0 && len(c.Classes) == 0 } func (c *CppParsedHeader) AddContentFrom(other *CppParsedHeader) { c.Classes = append(c.Classes, other.Classes...) c.Enums = append(c.Enums, other.Enums...) c.Typedefs = append(c.Typedefs, other.Typedefs...) }