// Copyright 2013 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package interp import ( "bytes" "fmt" "go/token" "strings" "sync" "syscall" "unsafe" "code.google.com/p/go.tools/go/exact" "code.google.com/p/go.tools/go/types" "code.google.com/p/go.tools/ssa" ) // If the target program panics, the interpreter panics with this type. type targetPanic struct { v value } func (p targetPanic) String() string { return toString(p.v) } // If the target program calls exit, the interpreter panics with this type. type exitPanic int // constValue returns the value of the constant with the // dynamic type tag appropriate for c.Type(). func constValue(c *ssa.Const) value { if c.IsNil() { return zero(c.Type()) // typed nil } // By destination type: switch t := c.Type().Underlying().(type) { case *types.Basic: // TODO(adonovan): eliminate untyped constants from SSA form. switch t.Kind() { case types.Bool, types.UntypedBool: return exact.BoolVal(c.Value) case types.Int, types.UntypedInt: // Assume sizeof(int) is same on host and target. return int(c.Int64()) case types.Int8: return int8(c.Int64()) case types.Int16: return int16(c.Int64()) case types.Int32, types.UntypedRune: return int32(c.Int64()) case types.Int64: return c.Int64() case types.Uint: // Assume sizeof(uint) is same on host and target. return uint(c.Uint64()) case types.Uint8: return uint8(c.Uint64()) case types.Uint16: return uint16(c.Uint64()) case types.Uint32: return uint32(c.Uint64()) case types.Uint64: return c.Uint64() case types.Uintptr: // Assume sizeof(uintptr) is same on host and target. return uintptr(c.Uint64()) case types.Float32: return float32(c.Float64()) case types.Float64, types.UntypedFloat: return c.Float64() case types.Complex64: return complex64(c.Complex128()) case types.Complex128, types.UntypedComplex: return c.Complex128() case types.String, types.UntypedString: if c.Value.Kind() == exact.String { return exact.StringVal(c.Value) } return string(rune(c.Int64())) case types.UnsafePointer: panic("unsafe.Pointer constant") // not possible case types.UntypedNil: // nil was handled above. } case *types.Slice: switch et := t.Elem().Underlying().(type) { case *types.Basic: switch et.Kind() { case types.Byte: // string -> []byte var v []value for _, b := range []byte(exact.StringVal(c.Value)) { v = append(v, b) } return v case types.Rune: // string -> []rune var v []value for _, r := range []rune(exact.StringVal(c.Value)) { v = append(v, r) } return v } } } panic(fmt.Sprintf("constValue: Value.(type)=%T Type()=%s", c.Value, c.Type())) } // asInt converts x, which must be an integer, to an int suitable for // use as a slice or array index or operand to make(). func asInt(x value) int { switch x := x.(type) { case int: return x case int8: return int(x) case int16: return int(x) case int32: return int(x) case int64: return int(x) case uint: return int(x) case uint8: return int(x) case uint16: return int(x) case uint32: return int(x) case uint64: return int(x) case uintptr: return int(x) } panic(fmt.Sprintf("cannot convert %T to int", x)) } // asUint64 converts x, which must be an unsigned integer, to a uint64 // suitable for use as a bitwise shift count. func asUint64(x value) uint64 { switch x := x.(type) { case uint: return uint64(x) case uint8: return uint64(x) case uint16: return uint64(x) case uint32: return uint64(x) case uint64: return x case uintptr: return uint64(x) } panic(fmt.Sprintf("cannot convert %T to uint64", x)) } // zero returns a new "zero" value of the specified type. func zero(t types.Type) value { switch t := t.(type) { case *types.Basic: if t.Kind() == types.UntypedNil { panic("untyped nil has no zero value") } if t.Info()&types.IsUntyped != 0 { // TODO(adonovan): make it an invariant that // this is unreachable. Currently some // constants have 'untyped' types when they // should be defaulted by the typechecker. t = ssa.DefaultType(t).(*types.Basic) } switch t.Kind() { case types.Bool: return false case types.Int: return int(0) case types.Int8: return int8(0) case types.Int16: return int16(0) case types.Int32: return int32(0) case types.Int64: return int64(0) case types.Uint: return uint(0) case types.Uint8: return uint8(0) case types.Uint16: return uint16(0) case types.Uint32: return uint32(0) case types.Uint64: return uint64(0) case types.Uintptr: return uintptr(0) case types.Float32: return float32(0) case types.Float64: return float64(0) case types.Complex64: return complex64(0) case types.Complex128: return complex128(0) case types.String: return "" case types.UnsafePointer: return unsafe.Pointer(nil) default: panic(fmt.Sprint("zero for unexpected type:", t)) } case *types.Pointer: return (*value)(nil) case *types.Array: a := make(array, t.Len()) for i := range a { a[i] = zero(t.Elem()) } return a case *types.Named: return zero(t.Underlying()) case *types.Interface: return iface{} // nil type, methodset and value case *types.Slice: return []value(nil) case *types.Struct: s := make(structure, t.NumFields()) for i := range s { s[i] = zero(t.Field(i).Type()) } return s case *types.Chan: return chan value(nil) case *types.Map: if usesBuiltinMap(t.Key()) { return map[value]value(nil) } return (*hashmap)(nil) case *types.Signature: return (*ssa.Function)(nil) } panic(fmt.Sprint("zero: unexpected ", t)) } // slice returns x[lo:hi]. Either or both of lo and hi may be nil. func slice(x, lo, hi value) value { l := 0 if lo != nil { l = asInt(lo) } switch x := x.(type) { case string: if hi != nil { return x[l:asInt(hi)] } return x[l:] case []value: if hi != nil { return x[l:asInt(hi)] } return x[l:] case *value: // *array a := (*x).(array) if hi != nil { return []value(a)[l:asInt(hi)] } return []value(a)[l:] } panic(fmt.Sprintf("slice: unexpected X type: %T", x)) } // lookup returns x[idx] where x is a map or string. func lookup(instr *ssa.Lookup, x, idx value) value { switch x := x.(type) { // map or string case map[value]value, *hashmap: var v value var ok bool switch x := x.(type) { case map[value]value: v, ok = x[idx] case *hashmap: v = x.lookup(idx.(hashable)) ok = v != nil } if ok { v = copyVal(v) } else { v = zero(instr.X.Type().Underlying().(*types.Map).Elem()) } if instr.CommaOk { v = tuple{v, ok} } return v case string: return x[asInt(idx)] } panic(fmt.Sprintf("unexpected x type in Lookup: %T", x)) } // binop implements all arithmetic and logical binary operators for // numeric datatypes and strings. Both operands must have identical // dynamic type. // func binop(op token.Token, t types.Type, x, y value) value { switch op { case token.ADD: switch x.(type) { case int: return x.(int) + y.(int) case int8: return x.(int8) + y.(int8) case int16: return x.(int16) + y.(int16) case int32: return x.(int32) + y.(int32) case int64: return x.(int64) + y.(int64) case uint: return x.(uint) + y.(uint) case uint8: return x.(uint8) + y.(uint8) case uint16: return x.(uint16) + y.(uint16) case uint32: return x.(uint32) + y.(uint32) case uint64: return x.(uint64) + y.(uint64) case uintptr: return x.(uintptr) + y.(uintptr) case float32: return x.(float32) + y.(float32) case float64: return x.(float64) + y.(float64) case complex64: return x.(complex64) + y.(complex64) case complex128: return x.(complex128) + y.(complex128) case string: return x.(string) + y.(string) } case token.SUB: switch x.(type) { case int: return x.(int) - y.(int) case int8: return x.(int8) - y.(int8) case int16: return x.(int16) - y.(int16) case int32: return x.(int32) - y.(int32) case int64: return x.(int64) - y.(int64) case uint: return x.(uint) - y.(uint) case uint8: return x.(uint8) - y.(uint8) case uint16: return x.(uint16) - y.(uint16) case uint32: return x.(uint32) - y.(uint32) case uint64: return x.(uint64) - y.(uint64) case uintptr: return x.(uintptr) - y.(uintptr) case float32: return x.(float32) - y.(float32) case float64: return x.(float64) - y.(float64) case complex64: return x.(complex64) - y.(complex64) case complex128: return x.(complex128) - y.(complex128) } case token.MUL: switch x.(type) { case int: return x.(int) * y.(int) case int8: return x.(int8) * y.(int8) case int16: return x.(int16) * y.(int16) case int32: return x.(int32) * y.(int32) case int64: return x.(int64) * y.(int64) case uint: return x.(uint) * y.(uint) case uint8: return x.(uint8) * y.(uint8) case uint16: return x.(uint16) * y.(uint16) case uint32: return x.(uint32) * y.(uint32) case uint64: return x.(uint64) * y.(uint64) case uintptr: return x.(uintptr) * y.(uintptr) case float32: return x.(float32) * y.(float32) case float64: return x.(float64) * y.(float64) case complex64: return x.(complex64) * y.(complex64) case complex128: return x.(complex128) * y.(complex128) } case token.QUO: switch x.(type) { case int: return x.(int) / y.(int) case int8: return x.(int8) / y.(int8) case int16: return x.(int16) / y.(int16) case int32: return x.(int32) / y.(int32) case int64: return x.(int64) / y.(int64) case uint: return x.(uint) / y.(uint) case uint8: return x.(uint8) / y.(uint8) case uint16: return x.(uint16) / y.(uint16) case uint32: return x.(uint32) / y.(uint32) case uint64: return x.(uint64) / y.(uint64) case uintptr: return x.(uintptr) / y.(uintptr) case float32: return x.(float32) / y.(float32) case float64: return x.(float64) / y.(float64) case complex64: return x.(complex64) / y.(complex64) case complex128: return x.(complex128) / y.(complex128) } case token.REM: switch x.(type) { case int: return x.(int) % y.(int) case int8: return x.(int8) % y.(int8) case int16: return x.(int16) % y.(int16) case int32: return x.(int32) % y.(int32) case int64: return x.(int64) % y.(int64) case uint: return x.(uint) % y.(uint) case uint8: return x.(uint8) % y.(uint8) case uint16: return x.(uint16) % y.(uint16) case uint32: return x.(uint32) % y.(uint32) case uint64: return x.(uint64) % y.(uint64) case uintptr: return x.(uintptr) % y.(uintptr) } case token.AND: switch x.(type) { case int: return x.(int) & y.(int) case int8: return x.(int8) & y.(int8) case int16: return x.(int16) & y.(int16) case int32: return x.(int32) & y.(int32) case int64: return x.(int64) & y.(int64) case uint: return x.(uint) & y.(uint) case uint8: return x.(uint8) & y.(uint8) case uint16: return x.(uint16) & y.(uint16) case uint32: return x.(uint32) & y.(uint32) case uint64: return x.(uint64) & y.(uint64) case uintptr: return x.(uintptr) & y.(uintptr) } case token.OR: switch x.(type) { case int: return x.(int) | y.(int) case int8: return x.(int8) | y.(int8) case int16: return x.(int16) | y.(int16) case int32: return x.(int32) | y.(int32) case int64: return x.(int64) | y.(int64) case uint: return x.(uint) | y.(uint) case uint8: return x.(uint8) | y.(uint8) case uint16: return x.(uint16) | y.(uint16) case uint32: return x.(uint32) | y.(uint32) case uint64: return x.(uint64) | y.(uint64) case uintptr: return x.(uintptr) | y.(uintptr) } case token.XOR: switch x.(type) { case int: return x.(int) ^ y.(int) case int8: return x.(int8) ^ y.(int8) case int16: return x.(int16) ^ y.(int16) case int32: return x.(int32) ^ y.(int32) case int64: return x.(int64) ^ y.(int64) case uint: return x.(uint) ^ y.(uint) case uint8: return x.(uint8) ^ y.(uint8) case uint16: return x.(uint16) ^ y.(uint16) case uint32: return x.(uint32) ^ y.(uint32) case uint64: return x.(uint64) ^ y.(uint64) case uintptr: return x.(uintptr) ^ y.(uintptr) } case token.AND_NOT: switch x.(type) { case int: return x.(int) &^ y.(int) case int8: return x.(int8) &^ y.(int8) case int16: return x.(int16) &^ y.(int16) case int32: return x.(int32) &^ y.(int32) case int64: return x.(int64) &^ y.(int64) case uint: return x.(uint) &^ y.(uint) case uint8: return x.(uint8) &^ y.(uint8) case uint16: return x.(uint16) &^ y.(uint16) case uint32: return x.(uint32) &^ y.(uint32) case uint64: return x.(uint64) &^ y.(uint64) case uintptr: return x.(uintptr) &^ y.(uintptr) } case token.SHL: y := asUint64(y) switch x.(type) { case int: return x.(int) << y case int8: return x.(int8) << y case int16: return x.(int16) << y case int32: return x.(int32) << y case int64: return x.(int64) << y case uint: return x.(uint) << y case uint8: return x.(uint8) << y case uint16: return x.(uint16) << y case uint32: return x.(uint32) << y case uint64: return x.(uint64) << y case uintptr: return x.(uintptr) << y } case token.SHR: y := asUint64(y) switch x.(type) { case int: return x.(int) >> y case int8: return x.(int8) >> y case int16: return x.(int16) >> y case int32: return x.(int32) >> y case int64: return x.(int64) >> y case uint: return x.(uint) >> y case uint8: return x.(uint8) >> y case uint16: return x.(uint16) >> y case uint32: return x.(uint32) >> y case uint64: return x.(uint64) >> y case uintptr: return x.(uintptr) >> y } case token.LSS: switch x.(type) { case int: return x.(int) < y.(int) case int8: return x.(int8) < y.(int8) case int16: return x.(int16) < y.(int16) case int32: return x.(int32) < y.(int32) case int64: return x.(int64) < y.(int64) case uint: return x.(uint) < y.(uint) case uint8: return x.(uint8) < y.(uint8) case uint16: return x.(uint16) < y.(uint16) case uint32: return x.(uint32) < y.(uint32) case uint64: return x.(uint64) < y.(uint64) case uintptr: return x.(uintptr) < y.(uintptr) case float32: return x.(float32) < y.(float32) case float64: return x.(float64) < y.(float64) case string: return x.(string) < y.(string) } case token.LEQ: switch x.(type) { case int: return x.(int) <= y.(int) case int8: return x.(int8) <= y.(int8) case int16: return x.(int16) <= y.(int16) case int32: return x.(int32) <= y.(int32) case int64: return x.(int64) <= y.(int64) case uint: return x.(uint) <= y.(uint) case uint8: return x.(uint8) <= y.(uint8) case uint16: return x.(uint16) <= y.(uint16) case uint32: return x.(uint32) <= y.(uint32) case uint64: return x.(uint64) <= y.(uint64) case uintptr: return x.(uintptr) <= y.(uintptr) case float32: return x.(float32) <= y.(float32) case float64: return x.(float64) <= y.(float64) case string: return x.(string) <= y.(string) } case token.EQL: return eqnil(t, x, y) case token.NEQ: return !eqnil(t, x, y) case token.GTR: switch x.(type) { case int: return x.(int) > y.(int) case int8: return x.(int8) > y.(int8) case int16: return x.(int16) > y.(int16) case int32: return x.(int32) > y.(int32) case int64: return x.(int64) > y.(int64) case uint: return x.(uint) > y.(uint) case uint8: return x.(uint8) > y.(uint8) case uint16: return x.(uint16) > y.(uint16) case uint32: return x.(uint32) > y.(uint32) case uint64: return x.(uint64) > y.(uint64) case uintptr: return x.(uintptr) > y.(uintptr) case float32: return x.(float32) > y.(float32) case float64: return x.(float64) > y.(float64) case string: return x.(string) > y.(string) } case token.GEQ: switch x.(type) { case int: return x.(int) >= y.(int) case int8: return x.(int8) >= y.(int8) case int16: return x.(int16) >= y.(int16) case int32: return x.(int32) >= y.(int32) case int64: return x.(int64) >= y.(int64) case uint: return x.(uint) >= y.(uint) case uint8: return x.(uint8) >= y.(uint8) case uint16: return x.(uint16) >= y.(uint16) case uint32: return x.(uint32) >= y.(uint32) case uint64: return x.(uint64) >= y.(uint64) case uintptr: return x.(uintptr) >= y.(uintptr) case float32: return x.(float32) >= y.(float32) case float64: return x.(float64) >= y.(float64) case string: return x.(string) >= y.(string) } } panic(fmt.Sprintf("invalid binary op: %T %s %T", x, op, y)) } // eqnil returns the comparison x == y using the equivalence relation // appropriate for type t. // If t is a reference type, at most one of x or y may be a nil value // of that type. // func eqnil(t types.Type, x, y value) bool { switch t.Underlying().(type) { case *types.Map, *types.Signature, *types.Slice: // Since these types don't support comparison, // one of the operands must be a literal nil. switch x := x.(type) { case *hashmap: return (x != nil) == (y.(*hashmap) != nil) case map[value]value: return (x != nil) == (y.(map[value]value) != nil) case *ssa.Function: switch y := y.(type) { case *ssa.Function: return (x != nil) == (y != nil) case *closure: return true } case *closure: return (x != nil) == (y.(*ssa.Function) != nil) case []value: return (x != nil) == (y.([]value) != nil) } panic(fmt.Sprintf("eqnil(%s): illegal dynamic type: %T", t, x)) } return equals(t, x, y) } func unop(instr *ssa.UnOp, x value) value { switch instr.Op { case token.ARROW: // receive v, ok := <-x.(chan value) if !ok { v = zero(instr.X.Type().Underlying().(*types.Chan).Elem()) } if instr.CommaOk { v = tuple{v, ok} } return v case token.SUB: switch x := x.(type) { case int: return -x case int8: return -x case int16: return -x case int32: return -x case int64: return -x case uint: return -x case uint8: return -x case uint16: return -x case uint32: return -x case uint64: return -x case uintptr: return -x case float32: return -x case float64: return -x case complex64: return -x case complex128: return -x } case token.MUL: return copyVal(*x.(*value)) // load case token.NOT: return !x.(bool) case token.XOR: switch x := x.(type) { case int: return ^x case int8: return ^x case int16: return ^x case int32: return ^x case int64: return ^x case uint: return ^x case uint8: return ^x case uint16: return ^x case uint32: return ^x case uint64: return ^x case uintptr: return ^x } } panic(fmt.Sprintf("invalid unary op %s %T", instr.Op, x)) } // typeAssert checks whether dynamic type of itf is instr.AssertedType. // It returns the extracted value on success, and panics on failure, // unless instr.CommaOk, in which case it always returns a "value,ok" tuple. // func typeAssert(i *interpreter, instr *ssa.TypeAssert, itf iface) value { var v value err := "" if itf.t == nil { err = fmt.Sprintf("interface conversion: interface is nil, not %s", instr.AssertedType) } else if idst, ok := instr.AssertedType.Underlying().(*types.Interface); ok { v = itf err = checkInterface(i, idst, itf) } else if types.IsIdentical(itf.t, instr.AssertedType) { v = copyVal(itf.v) // extract value } else { err = fmt.Sprintf("interface conversion: interface is %s, not %s", itf.t, instr.AssertedType) } if err != "" { if !instr.CommaOk { panic(err) } return tuple{zero(instr.AssertedType), false} } if instr.CommaOk { return tuple{v, true} } return v } // If CapturedOutput is non-nil, all writes by the interpreted program // to file descriptors 1 and 2 will also be written to CapturedOutput. // // (The $GOROOT/test system requires that the test be considered a // failure if "BUG" appears in the combined stdout/stderr output, even // if it exits zero. This is a global variable shared by all // interpreters in the same process.) // var CapturedOutput *bytes.Buffer var capturedOutputMu sync.Mutex // write writes bytes b to the target program's file descriptor fd. // The print/println built-ins and the write() system call funnel // through here so they can be captured by the test driver. func write(fd int, b []byte) (int, error) { if CapturedOutput != nil && (fd == 1 || fd == 2) { capturedOutputMu.Lock() CapturedOutput.Write(b) // ignore errors capturedOutputMu.Unlock() } return syscall.Write(fd, b) } // callBuiltin interprets a call to builtin fn with arguments args, // returning its result. func callBuiltin(caller *frame, callpos token.Pos, fn *ssa.Builtin, args []value) value { switch fn.Name() { case "append": if len(args) == 1 { return args[0] } if s, ok := args[1].(string); ok { // append([]byte, ...string) []byte arg0 := args[0].([]value) for i := 0; i < len(s); i++ { arg0 = append(arg0, s[i]) } return arg0 } // append([]T, ...[]T) []T return append(args[0].([]value), args[1].([]value)...) case "copy": // copy([]T, []T) int if _, ok := args[1].(string); ok { panic("copy([]byte, string) not yet implemented") } return copy(args[0].([]value), args[1].([]value)) case "close": // close(chan T) close(args[0].(chan value)) return nil case "delete": // delete(map[K]value, K) switch m := args[0].(type) { case map[value]value: delete(m, args[1]) case *hashmap: m.delete(args[1].(hashable)) default: panic(fmt.Sprintf("illegal map type: %T", m)) } return nil case "print", "println": // print(any, ...) ln := fn.Name() == "println" var buf bytes.Buffer for i, arg := range args { if i > 0 && ln { buf.WriteRune(' ') } buf.WriteString(toString(arg)) } if ln { buf.WriteRune('\n') } write(1, buf.Bytes()) return nil case "len": switch x := args[0].(type) { case string: return len(x) case array: return len(x) case *value: return len((*x).(array)) case []value: return len(x) case map[value]value: return len(x) case *hashmap: return x.len() case chan value: return len(x) default: panic(fmt.Sprintf("len: illegal operand: %T", x)) } case "cap": switch x := args[0].(type) { case array: return cap(x) case *value: return cap((*x).(array)) case []value: return cap(x) case chan value: return cap(x) default: panic(fmt.Sprintf("cap: illegal operand: %T", x)) } case "real": switch c := args[0].(type) { case complex64: return real(c) case complex128: return real(c) default: panic(fmt.Sprintf("real: illegal operand: %T", c)) } case "imag": switch c := args[0].(type) { case complex64: return imag(c) case complex128: return imag(c) default: panic(fmt.Sprintf("imag: illegal operand: %T", c)) } case "complex": switch f := args[0].(type) { case float32: return complex(f, args[1].(float32)) case float64: return complex(f, args[1].(float64)) default: panic(fmt.Sprintf("complex: illegal operand: %T", f)) } case "panic": // ssa.Panic handles most cases; this is only for "go // panic" or "defer panic". panic(targetPanic{args[0]}) case "recover": return doRecover(caller) } panic("unknown built-in: " + fn.Name()) } func rangeIter(x value, t types.Type) iter { switch x := x.(type) { case map[value]value: // TODO(adonovan): fix: leaks goroutines and channels // on each incomplete map iteration. We need to open // up an iteration interface using the // reflect.(Value).MapKeys machinery. it := make(mapIter) go func() { for k, v := range x { it <- [2]value{k, v} } close(it) }() return it case *hashmap: // TODO(adonovan): fix: leaks goroutines and channels // on each incomplete map iteration. We need to open // up an iteration interface using the // reflect.(Value).MapKeys machinery. it := make(mapIter) go func() { for _, e := range x.table { for e != nil { it <- [2]value{e.key, e.value} e = e.next } } close(it) }() return it case string: return &stringIter{Reader: strings.NewReader(x)} } panic(fmt.Sprintf("cannot range over %T", x)) } // widen widens a basic typed value x to the widest type of its // category, one of: // bool, int64, uint64, float64, complex128, string. // This is inefficient but reduces the size of the cross-product of // cases we have to consider. // func widen(x value) value { switch y := x.(type) { case bool, int64, uint64, float64, complex128, string, unsafe.Pointer: return x case int: return int64(y) case int8: return int64(y) case int16: return int64(y) case int32: return int64(y) case uint: return uint64(y) case uint8: return uint64(y) case uint16: return uint64(y) case uint32: return uint64(y) case uintptr: return uint64(y) case float32: return float64(y) case complex64: return complex128(y) } panic(fmt.Sprintf("cannot widen %T", x)) } // conv converts the value x of type t_src to type t_dst and returns // the result. // Possible cases are described with the ssa.Convert operator. // func conv(t_dst, t_src types.Type, x value) value { ut_src := t_src.Underlying() ut_dst := t_dst.Underlying() // Destination type is not an "untyped" type. if b, ok := ut_dst.(*types.Basic); ok && b.Info()&types.IsUntyped != 0 { panic("oops: conversion to 'untyped' type: " + b.String()) } // Nor is it an interface type. if _, ok := ut_dst.(*types.Interface); ok { if _, ok := ut_src.(*types.Interface); ok { panic("oops: Convert should be ChangeInterface") } else { panic("oops: Convert should be MakeInterface") } } // Remaining conversions: // + untyped string/number/bool constant to a specific // representation. // + conversions between non-complex numeric types. // + conversions between complex numeric types. // + integer/[]byte/[]rune -> string. // + string -> []byte/[]rune. // // All are treated the same: first we extract the value to the // widest representation (int64, uint64, float64, complex128, // or string), then we convert it to the desired type. switch ut_src := ut_src.(type) { case *types.Pointer: switch ut_dst := ut_dst.(type) { case *types.Basic: // *value to unsafe.Pointer? if ut_dst.Kind() == types.UnsafePointer { return unsafe.Pointer(x.(*value)) } } case *types.Slice: // []byte or []rune -> string // TODO(adonovan): fix: type B byte; conv([]B -> string). switch ut_src.Elem().(*types.Basic).Kind() { case types.Byte: x := x.([]value) b := make([]byte, 0, len(x)) for i := range x { b = append(b, x[i].(byte)) } return string(b) case types.Rune: x := x.([]value) r := make([]rune, 0, len(x)) for i := range x { r = append(r, x[i].(rune)) } return string(r) } case *types.Basic: x = widen(x) // integer -> string? // TODO(adonovan): fix: test integer -> named alias of string. if ut_src.Info()&types.IsInteger != 0 { if ut_dst, ok := ut_dst.(*types.Basic); ok && ut_dst.Kind() == types.String { return string(asInt(x)) } } // string -> []rune, []byte or string? if s, ok := x.(string); ok { switch ut_dst := ut_dst.(type) { case *types.Slice: var res []value // TODO(adonovan): fix: test named alias of rune, byte. switch ut_dst.Elem().(*types.Basic).Kind() { case types.Rune: for _, r := range []rune(s) { res = append(res, r) } return res case types.Byte: for _, b := range []byte(s) { res = append(res, b) } return res } case *types.Basic: if ut_dst.Kind() == types.String { return x.(string) } } break // fail: no other conversions for string } // unsafe.Pointer -> *value if ut_src.Kind() == types.UnsafePointer { // TODO(adonovan): this is wrong and cannot // really be fixed with the current design. // // return (*value)(x.(unsafe.Pointer)) // creates a new pointer of a different // type but the underlying interface value // knows its "true" type and so cannot be // meaningfully used through the new pointer. // // To make this work, the interpreter needs to // simulate the memory layout of a real // compiled implementation. // // To at least preserve type-safety, we'll // just return the zero value of the // destination type. return zero(t_dst) } // Conversions between complex numeric types? if ut_src.Info()&types.IsComplex != 0 { switch ut_dst.(*types.Basic).Kind() { case types.Complex64: return complex64(x.(complex128)) case types.Complex128: return x.(complex128) } break // fail: no other conversions for complex } // Conversions between non-complex numeric types? if ut_src.Info()&types.IsNumeric != 0 { kind := ut_dst.(*types.Basic).Kind() switch x := x.(type) { case int64: // signed integer -> numeric? switch kind { case types.Int: return int(x) case types.Int8: return int8(x) case types.Int16: return int16(x) case types.Int32: return int32(x) case types.Int64: return int64(x) case types.Uint: return uint(x) case types.Uint8: return uint8(x) case types.Uint16: return uint16(x) case types.Uint32: return uint32(x) case types.Uint64: return uint64(x) case types.Uintptr: return uintptr(x) case types.Float32: return float32(x) case types.Float64: return float64(x) } case uint64: // unsigned integer -> numeric? switch kind { case types.Int: return int(x) case types.Int8: return int8(x) case types.Int16: return int16(x) case types.Int32: return int32(x) case types.Int64: return int64(x) case types.Uint: return uint(x) case types.Uint8: return uint8(x) case types.Uint16: return uint16(x) case types.Uint32: return uint32(x) case types.Uint64: return uint64(x) case types.Uintptr: return uintptr(x) case types.Float32: return float32(x) case types.Float64: return float64(x) } case float64: // floating point -> numeric? switch kind { case types.Int: return int(x) case types.Int8: return int8(x) case types.Int16: return int16(x) case types.Int32: return int32(x) case types.Int64: return int64(x) case types.Uint: return uint(x) case types.Uint8: return uint8(x) case types.Uint16: return uint16(x) case types.Uint32: return uint32(x) case types.Uint64: return uint64(x) case types.Uintptr: return uintptr(x) case types.Float32: return float32(x) case types.Float64: return float64(x) } } } } panic(fmt.Sprintf("unsupported conversion: %s -> %s, dynamic type %T", t_src, t_dst, x)) } // checkInterface checks that the method set of x implements the // interface itype. // On success it returns "", on failure, an error message. // func checkInterface(i *interpreter, itype *types.Interface, x iface) string { if meth, _ := types.MissingMethod(x.t, itype, true); meth != nil { return fmt.Sprintf("interface conversion: %v is not %v: missing method %s", x.t, itype, meth.Name()) } return "" // ok }