package analyzer import "fmt" import "git.tebibyte.media/arf/arf/parser" import "git.tebibyte.media/arf/arf/infoerr" // TypeKind represents what kind of type a type is. type TypeKind int const ( // TypeKindBasic means it's a single value. TypeKindBasic TypeKind = iota // TypeKindPointer means it's a pointer TypeKindPointer // TypeKindVariableArray means it's an array of variable length. TypeKindVariableArray ) // Type represents a description of a type. It must eventually point to a // TypeSection. type Type struct { locatable // one of these must be nil. actual *TypeSection points *Type mutable bool kind TypeKind primitiveCache *TypeSection singularCache *bool // if this is greater than 1, it means that this is a fixed-length array // of whatever the type is. even if the type is a variable length array. // because literally why not. length uint64 } // ToString returns all data stored within the type, in string form. func (what Type) ToString (indent int) (output string) { output += doIndent(indent, "type ", what.length) if what.mutable { output += " mutable" } switch what.kind { case TypeKindBasic: output += " basic" case TypeKindPointer: output += " pointer" case TypeKindVariableArray: output += " variableArray" } if what.points != nil { output += " {\n" output += what.points.ToString(indent + 1) output += doIndent(indent, "}") } if what.actual != nil { output += " " + what.actual.Name() } output += "\n" return } // underlyingPrimitive returns the primitive that this type eventually inherits // from. If the type ends up pointing to something, this returns nil. func (what Type) underlyingPrimitive () (underlying *TypeSection) { // if we have already done this operation, return the cahced result. if what.primitiveCache != nil { underlying = what.primitiveCache return } if what.kind != TypeKindBasic { // if we point to something, return nil because there is no void // pointer bullshit in this language return } actual := what.actual switch actual { case &PrimitiveF32, &PrimitiveF64, &PrimitiveFunc, &PrimitiveFace, &PrimitiveObj, &PrimitiveU64, &PrimitiveU32, &PrimitiveU16, &PrimitiveU8, &PrimitiveI64, &PrimitiveI32, &PrimitiveI16, &PrimitiveI8, &PrimitiveUInt, &PrimitiveInt: underlying = actual return case nil: panic("invalid state: Type.actual is nil") default: // if none of the primitives matched, recurse. underlying = actual.what.underlyingPrimitive() return } } // isSingular returns whether or not the type is a singular value. this goes // all the way up the inheritence chain, only stopping when it hits a non-basic // type because this is about data storage of a value. func (what Type) isSingular () (singular bool) { // if we have already done this operation, return the cahced result. if what.singularCache != nil { singular = *what.singularCache return } if what.length > 0 { singular = true return } // decide whether or not to recurse if what.kind != TypeKindBasic { return } actual := what.actual if actual == nil { return } else { singular = actual.what.isSingular() } return } // reduce ascends up the inheritence chain and gets the first type it finds that // isn't basic. If the type has a clear path of inheritence to a simple // primitive, there will be no non-basic types in the chain and this method will // return false for reducible. If the type this method is called on is not // basic, it itself is returned. func (what Type) reduce () (reduced Type, reducible bool) { reducible = true // returns itself if it is not basic (cannot be reduced further) if what.kind != TypeKindBasic { reduced = what return } // if we can't recurse, return false for reducible if what.actual == nil { reducible = false return } // otherwise, recurse reduced, reducible = what.actual.what.reduce() return } // analyzeType analyzes a type specifier. func (analyzer analysisOperation) analyzeType ( inputType parser.Type, ) ( outputType Type, err error, ) { outputType.mutable = inputType.Mutable() outputType.length = inputType.Length() outputType.location = inputType.Location() if outputType.length < 1 { err = inputType.NewError ( "cannot specify a length of zero", infoerr.ErrorKindError) return } // analyze type this type points to, if it exists if inputType.Kind() != parser.TypeKindBasic { var points Type points, err = analyzer.analyzeType(inputType.Points()) outputType.points = &points } else { var bitten parser.Identifier var actual Section actual, bitten, err = analyzer.fetchSectionFromIdentifier(inputType.Name()) if err != nil { return } if actual == nil { err = inputType.NewError ( "this type does not exist", infoerr.ErrorKindError) return } var worked bool outputType.actual, worked = actual.(*TypeSection) if !worked { err = inputType.NewError ( "this must refer to a type or an interface", infoerr.ErrorKindError) return } if bitten.Length() > 0 { err = bitten.NewError( "cannot use member selection in this context", infoerr.ErrorKindError) return } } // TODO return } // Describe provides a human readable description of the type. The value of this // should not be computationally analyzed. func (what Type) Describe () (description string) { if what.kind == TypeKindBasic { actual := what.actual switch actual { case &PrimitiveF32: description += "F32" case &PrimitiveF64: description += "F64" case &PrimitiveFunc: description += "Func" case &PrimitiveFace: description += "Face" case &PrimitiveObj: description += "Obj" case &PrimitiveU64: description += "U64" case &PrimitiveU32: description += "U32" case &PrimitiveU16: description += "U16" case &PrimitiveU8: description += "U8" case &PrimitiveI64: description += "I64" case &PrimitiveI32: description += "I32" case &PrimitiveI16: description += "I16" case &PrimitiveI8: description += "I8" case &PrimitiveUInt: description += "UInt" case &PrimitiveInt: description += "Int" case &BuiltInString: description += "String" case nil: panic("invalid state: Type.actual is nil") default: description += actual.ModuleName() + "." + actual.Name() return } } else { description += "{" description += what.points.Describe() description += "}" } if what.length > 0 { description += fmt.Sprint(":", what.length) } return }