// zeroConst returns a new "zero" constant of the specified type,
// which must not be an array or struct type: the zero values of
// aggregates are well-defined but cannot be represented by Const.
//
func zeroConst(t types.Type) *Const {
switch t := t.(type) {
case *types.Basic:
switch {
case t.Info()&types.IsBoolean != 0:
return NewConst(exact.MakeBool(false), t)
case t.Info()&types.IsNumeric != 0:
return NewConst(exact.MakeInt64(0), t)
case t.Info()&types.IsString != 0:
return NewConst(exact.MakeString(""), t)
case t.Kind() == types.UnsafePointer:
fallthrough
case t.Kind() == types.UntypedNil:
return nilConst(t)
default:
panic(fmt.Sprint("zeroConst for unexpected type:", t))
}
case *types.Pointer, *types.Slice, *types.Interface, *types.Chan, *types.Map, *types.Signature:
return nilConst(t)
case *types.Named:
return NewConst(zeroConst(t.Underlying()).Value, t)
case *types.Array, *types.Struct, *types.Tuple:
panic(fmt.Sprint("zeroConst applied to aggregate:", t))
}
panic(fmt.Sprint("zeroConst: unexpected ", t))
}
func (tm *llvmTypeMap) getBackendType(t types.Type) backendType {
switch t := t.(type) {
case *types.Named:
return tm.getBackendType(t.Underlying())
case *types.Basic:
switch t.Kind() {
case types.Bool, types.Uint8:
return &intBType{1, false}
case types.Int8:
return &intBType{1, true}
case types.Uint16:
return &intBType{2, false}
case types.Int16:
return &intBType{2, true}
case types.Uint32:
return &intBType{4, false}
case types.Int32:
return &intBType{4, true}
case types.Uint64:
return &intBType{8, false}
case types.Int64:
return &intBType{8, true}
case types.Uint, types.Uintptr:
return &intBType{tm.target.PointerSize(), false}
case types.Int:
return &intBType{tm.target.PointerSize(), true}
case types.Float32:
return &floatBType{false}
case types.Float64:
return &floatBType{true}
case types.UnsafePointer:
return &ptrBType{}
case types.Complex64:
f32 := &floatBType{false}
return &structBType{[]backendType{f32, f32}}
case types.Complex128:
f64 := &floatBType{true}
return &structBType{[]backendType{f64, f64}}
case types.String:
return &structBType{[]backendType{&ptrBType{}, &intBType{tm.target.PointerSize(), false}}}
}
case *types.Struct:
var fields []backendType
for i := 0; i != t.NumFields(); i++ {
f := t.Field(i)
fields = append(fields, tm.getBackendType(f.Type()))
}
return &structBType{fields}
case *types.Pointer, *types.Signature, *types.Map, *types.Chan:
return &ptrBType{}
case *types.Interface:
i8ptr := &ptrBType{}
return &structBType{[]backendType{i8ptr, i8ptr}}
case *types.Slice:
return tm.sliceBackendType()
case *types.Array:
return &arrayBType{uint64(t.Len()), tm.getBackendType(t.Elem())}
}
panic("unhandled type: " + t.String())
}
func reflectKind(t types.Type) reflect.Kind {
switch t := t.(type) {
case *types.Named:
return reflectKind(t.Underlying())
case *types.Basic:
switch t.Kind() {
case types.Bool:
return reflect.Bool
case types.Int:
return reflect.Int
case types.Int8:
return reflect.Int8
case types.Int16:
return reflect.Int16
case types.Int32:
return reflect.Int32
case types.Int64:
return reflect.Int64
case types.Uint:
return reflect.Uint
case types.Uint8:
return reflect.Uint8
case types.Uint16:
return reflect.Uint16
case types.Uint32:
return reflect.Uint32
case types.Uint64:
return reflect.Uint64
case types.Uintptr:
return reflect.Uintptr
case types.Float32:
return reflect.Float32
case types.Float64:
return reflect.Float64
case types.Complex64:
return reflect.Complex64
case types.Complex128:
return reflect.Complex128
case types.String:
return reflect.String
case types.UnsafePointer:
return reflect.UnsafePointer
}
case *types.Array:
return reflect.Array
case *types.Chan:
return reflect.Chan
case *types.Signature:
return reflect.Func
case *types.Interface:
return reflect.Interface
case *types.Map:
return reflect.Map
case *types.Pointer:
return reflect.Ptr
case *types.Slice:
return reflect.Slice
case *types.Struct:
return reflect.Struct
}
panic(fmt.Sprint("unexpected type: ", t))
}
// 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.Tuple:
if t.Len() == 1 {
return zero(t.At(0).Type())
}
s := make(tuple, t.Len())
for i := range s {
s[i] = zero(t.At(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))
}
// hashFor computes the hash of t.
func (h Hasher) hashFor(t types.Type) uint32 {
// See Identical for rationale.
switch t := t.(type) {
case *types.Basic:
return uint32(t.Kind())
case *types.Array:
return 9043 + 2*uint32(t.Len()) + 3*h.Hash(t.Elem())
case *types.Slice:
return 9049 + 2*h.Hash(t.Elem())
case *types.Struct:
var hash uint32 = 9059
for i, n := 0, t.NumFields(); i < n; i++ {
f := t.Field(i)
if f.Anonymous() {
hash += 8861
}
hash += hashString(t.Tag(i))
hash += hashString(f.Name()) // (ignore f.Pkg)
hash += h.Hash(f.Type())
}
return hash
case *types.Pointer:
return 9067 + 2*h.Hash(t.Elem())
case *types.Signature:
var hash uint32 = 9091
if t.Variadic() {
hash *= 8863
}
return hash + 3*h.hashTuple(t.Params()) + 5*h.hashTuple(t.Results())
case *types.Interface:
var hash uint32 = 9103
for i, n := 0, t.NumMethods(); i < n; i++ {
// See go/types.identicalMethods for rationale.
// Method order is not significant.
// Ignore m.Pkg().
m := t.Method(i)
hash += 3*hashString(m.Name()) + 5*h.Hash(m.Type())
}
return hash
case *types.Map:
return 9109 + 2*h.Hash(t.Key()) + 3*h.Hash(t.Elem())
case *types.Chan:
return 9127 + 2*uint32(t.Dir()) + 3*h.Hash(t.Elem())
case *types.Named:
// Not safe with a copying GC; objects may move.
return uint32(reflect.ValueOf(t.Obj()).Pointer())
case *types.Tuple:
return h.hashTuple(t)
}
panic(t)
}