// Copyright 2023 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 rttype allows the compiler to share type information with // the runtime. The shared type information is stored in // internal/abi. This package translates those types from the host // machine on which the compiler runs to the target machine on which // the compiled program will run. In particular, this package handles // layout differences between e.g. a 64 bit compiler and 32 bit // target. package rttype import ( "cmd/compile/internal/base" "cmd/compile/internal/objw" "cmd/compile/internal/types" "cmd/internal/obj" "internal/abi" "reflect" ) // The type structures shared with the runtime. var Type *types.Type var ArrayType *types.Type var ChanType *types.Type var FuncType *types.Type var InterfaceType *types.Type var MapType *types.Type var PtrType *types.Type var SliceType *types.Type var StructType *types.Type // Types that are parts of the types above. var IMethod *types.Type var Method *types.Type var StructField *types.Type var UncommonType *types.Type // Type switches and asserts var InterfaceSwitch *types.Type var TypeAssert *types.Type func Init() { // Note: this has to be called explicitly instead of being // an init function so it runs after the types package has // been properly initialized. Type = fromReflect(reflect.TypeOf(abi.Type{})) ArrayType = fromReflect(reflect.TypeOf(abi.ArrayType{})) ChanType = fromReflect(reflect.TypeOf(abi.ChanType{})) FuncType = fromReflect(reflect.TypeOf(abi.FuncType{})) InterfaceType = fromReflect(reflect.TypeOf(abi.InterfaceType{})) MapType = fromReflect(reflect.TypeOf(abi.MapType{})) PtrType = fromReflect(reflect.TypeOf(abi.PtrType{})) SliceType = fromReflect(reflect.TypeOf(abi.SliceType{})) StructType = fromReflect(reflect.TypeOf(abi.StructType{})) IMethod = fromReflect(reflect.TypeOf(abi.Imethod{})) Method = fromReflect(reflect.TypeOf(abi.Method{})) StructField = fromReflect(reflect.TypeOf(abi.StructField{})) UncommonType = fromReflect(reflect.TypeOf(abi.UncommonType{})) InterfaceSwitch = fromReflect(reflect.TypeOf(abi.InterfaceSwitch{})) TypeAssert = fromReflect(reflect.TypeOf(abi.TypeAssert{})) // Make sure abi functions are correct. These functions are used // by the linker which doesn't have the ability to do type layout, // so we check the functions it uses here. ptrSize := types.PtrSize if got, want := int64(abi.CommonSize(ptrSize)), Type.Size(); got != want { base.Fatalf("abi.CommonSize() == %d, want %d", got, want) } if got, want := int64(abi.StructFieldSize(ptrSize)), StructField.Size(); got != want { base.Fatalf("abi.StructFieldSize() == %d, want %d", got, want) } if got, want := int64(abi.UncommonSize()), UncommonType.Size(); got != want { base.Fatalf("abi.UncommonSize() == %d, want %d", got, want) } if got, want := int64(abi.TFlagOff(ptrSize)), Type.OffsetOf("TFlag"); got != want { base.Fatalf("abi.TFlagOff() == %d, want %d", got, want) } } // fromReflect translates from a host type to the equivalent target type. func fromReflect(rt reflect.Type) *types.Type { t := reflectToType(rt) types.CalcSize(t) return t } // reflectToType converts from a reflect.Type (which is a compiler // host type) to a *types.Type, which is a target type. The result // must be CalcSize'd before using. func reflectToType(rt reflect.Type) *types.Type { switch rt.Kind() { case reflect.Bool: return types.Types[types.TBOOL] case reflect.Int: return types.Types[types.TINT] case reflect.Int32: return types.Types[types.TINT32] case reflect.Uint8: return types.Types[types.TUINT8] case reflect.Uint16: return types.Types[types.TUINT16] case reflect.Uint32: return types.Types[types.TUINT32] case reflect.Uintptr: return types.Types[types.TUINTPTR] case reflect.Ptr, reflect.Func, reflect.UnsafePointer: // TODO: there's no mechanism to distinguish different pointer types, // so we treat them all as unsafe.Pointer. return types.Types[types.TUNSAFEPTR] case reflect.Slice: return types.NewSlice(reflectToType(rt.Elem())) case reflect.Array: return types.NewArray(reflectToType(rt.Elem()), int64(rt.Len())) case reflect.Struct: fields := make([]*types.Field, rt.NumField()) for i := 0; i < rt.NumField(); i++ { f := rt.Field(i) ft := reflectToType(f.Type) fields[i] = &types.Field{Sym: &types.Sym{Name: f.Name}, Type: ft} } return types.NewStruct(fields) default: base.Fatalf("unhandled kind %s", rt.Kind()) return nil } } // A Cursor represents a typed location inside a static variable where we // are going to write. type Cursor struct { lsym *obj.LSym offset int64 typ *types.Type } // NewCursor returns a cursor starting at lsym+off and having type t. func NewCursor(lsym *obj.LSym, off int64, t *types.Type) Cursor { return Cursor{lsym: lsym, offset: off, typ: t} } // WritePtr writes a pointer "target" to the component at the location specified by c. func (c Cursor) WritePtr(target *obj.LSym) { if c.typ.Kind() != types.TUNSAFEPTR { base.Fatalf("can't write ptr, it has kind %s", c.typ.Kind()) } if target == nil { objw.Uintptr(c.lsym, int(c.offset), 0) } else { objw.SymPtr(c.lsym, int(c.offset), target, 0) } } func (c Cursor) WriteUintptr(val uint64) { if c.typ.Kind() != types.TUINTPTR { base.Fatalf("can't write uintptr, it has kind %s", c.typ.Kind()) } objw.Uintptr(c.lsym, int(c.offset), val) } func (c Cursor) WriteUint32(val uint32) { if c.typ.Kind() != types.TUINT32 { base.Fatalf("can't write uint32, it has kind %s", c.typ.Kind()) } objw.Uint32(c.lsym, int(c.offset), val) } func (c Cursor) WriteUint16(val uint16) { if c.typ.Kind() != types.TUINT16 { base.Fatalf("can't write uint16, it has kind %s", c.typ.Kind()) } objw.Uint16(c.lsym, int(c.offset), val) } func (c Cursor) WriteUint8(val uint8) { if c.typ.Kind() != types.TUINT8 { base.Fatalf("can't write uint8, it has kind %s", c.typ.Kind()) } objw.Uint8(c.lsym, int(c.offset), val) } func (c Cursor) WriteInt(val int64) { if c.typ.Kind() != types.TINT { base.Fatalf("can't write int, it has kind %s", c.typ.Kind()) } objw.Uintptr(c.lsym, int(c.offset), uint64(val)) } func (c Cursor) WriteInt32(val int32) { if c.typ.Kind() != types.TINT32 { base.Fatalf("can't write int32, it has kind %s", c.typ.Kind()) } objw.Uint32(c.lsym, int(c.offset), uint32(val)) } func (c Cursor) WriteBool(val bool) { if c.typ.Kind() != types.TBOOL { base.Fatalf("can't write bool, it has kind %s", c.typ.Kind()) } objw.Bool(c.lsym, int(c.offset), val) } // WriteSymPtrOff writes a "pointer" to the given symbol. The symbol // is encoded as a uint32 offset from the start of the section. func (c Cursor) WriteSymPtrOff(target *obj.LSym, weak bool) { if c.typ.Kind() != types.TINT32 && c.typ.Kind() != types.TUINT32 { base.Fatalf("can't write SymPtr, it has kind %s", c.typ.Kind()) } if target == nil { objw.Uint32(c.lsym, int(c.offset), 0) } else if weak { objw.SymPtrWeakOff(c.lsym, int(c.offset), target) } else { objw.SymPtrOff(c.lsym, int(c.offset), target) } } // WriteSlice writes a slice header to c. The pointer is target+off, the len and cap fields are given. func (c Cursor) WriteSlice(target *obj.LSym, off, len, cap int64) { if c.typ.Kind() != types.TSLICE { base.Fatalf("can't write slice, it has kind %s", c.typ.Kind()) } objw.SymPtr(c.lsym, int(c.offset), target, int(off)) objw.Uintptr(c.lsym, int(c.offset)+types.PtrSize, uint64(len)) objw.Uintptr(c.lsym, int(c.offset)+2*types.PtrSize, uint64(cap)) // TODO: ability to switch len&cap. Maybe not needed here, as every caller // passes the same thing for both? if len != cap { base.Fatalf("len != cap (%d != %d)", len, cap) } } // Reloc adds a relocation from the current cursor position. // Reloc fills in Off and Siz fields. Caller should fill in the rest (Type, others). func (c Cursor) Reloc() *obj.Reloc { r := obj.Addrel(c.lsym) r.Off = int32(c.offset) r.Siz = uint8(c.typ.Size()) return r } // Field selects the field with the given name from the struct pointed to by c. func (c Cursor) Field(name string) Cursor { if c.typ.Kind() != types.TSTRUCT { base.Fatalf("can't call Field on non-struct %v", c.typ) } for _, f := range c.typ.Fields() { if f.Sym.Name == name { return Cursor{lsym: c.lsym, offset: c.offset + f.Offset, typ: f.Type} } } base.Fatalf("couldn't find field %s in %v", name, c.typ) return Cursor{} } type ArrayCursor struct { c Cursor // cursor pointing at first element n int // number of elements } // NewArrayCursor returns a cursor starting at lsym+off and having n copies of type t. func NewArrayCursor(lsym *obj.LSym, off int64, t *types.Type, n int) ArrayCursor { return ArrayCursor{ c: NewCursor(lsym, off, t), n: n, } } // Elem selects element i of the array pointed to by c. func (a ArrayCursor) Elem(i int) Cursor { if i < 0 || i >= a.n { base.Fatalf("element index %d out of range [0:%d]", i, a.n) } return Cursor{lsym: a.c.lsym, offset: a.c.offset + int64(i)*a.c.typ.Size(), typ: a.c.typ} } // ModifyArray converts a cursor pointing at a type [k]T to a cursor pointing // at a type [n]T. // Also returns the size delta, aka (n-k)*sizeof(T). func (c Cursor) ModifyArray(n int) (ArrayCursor, int64) { if c.typ.Kind() != types.TARRAY { base.Fatalf("can't call ModifyArray on non-array %v", c.typ) } k := c.typ.NumElem() return ArrayCursor{c: Cursor{lsym: c.lsym, offset: c.offset, typ: c.typ.Elem()}, n: n}, (int64(n) - k) * c.typ.Elem().Size() }