// Copyright 2009 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. // Runtime type representation. package runtime import "unsafe" // tflag is documented in reflect/type.go. // // tflag values must be kept in sync with copies in: // cmd/compile/internal/gc/reflect.go // cmd/link/internal/ld/decodesym.go // reflect/type.go type tflag uint8 const ( tflagUncommon tflag = 1 << 0 tflagExtraStar tflag = 1 << 1 tflagNamed tflag = 1 << 2 ) // Needs to be in sync with ../cmd/link/internal/ld/decodesym.go:/^func.commonsize, // ../cmd/compile/internal/gc/reflect.go:/^func.dcommontype and // ../reflect/type.go:/^type.rtype. type _type struct { size uintptr ptrdata uintptr // size of memory prefix holding all pointers hash uint32 tflag tflag align uint8 fieldalign uint8 kind uint8 alg *typeAlg // gcdata stores the GC type data for the garbage collector. // If the KindGCProg bit is set in kind, gcdata is a GC program. // Otherwise it is a ptrmask bitmap. See mbitmap.go for details. gcdata *byte str nameOff ptrToThis typeOff } func (t *_type) string() string { s := t.nameOff(t.str).name() if t.tflag&tflagExtraStar != 0 { return s[1:] } return s } func (t *_type) uncommon() *uncommontype { if t.tflag&tflagUncommon == 0 { return nil } switch t.kind & kindMask { case kindStruct: type u struct { structtype u uncommontype } return &(*u)(unsafe.Pointer(t)).u case kindPtr: type u struct { ptrtype u uncommontype } return &(*u)(unsafe.Pointer(t)).u case kindFunc: type u struct { functype u uncommontype } return &(*u)(unsafe.Pointer(t)).u case kindSlice: type u struct { slicetype u uncommontype } return &(*u)(unsafe.Pointer(t)).u case kindArray: type u struct { arraytype u uncommontype } return &(*u)(unsafe.Pointer(t)).u case kindChan: type u struct { chantype u uncommontype } return &(*u)(unsafe.Pointer(t)).u case kindMap: type u struct { maptype u uncommontype } return &(*u)(unsafe.Pointer(t)).u case kindInterface: type u struct { interfacetype u uncommontype } return &(*u)(unsafe.Pointer(t)).u default: type u struct { _type u uncommontype } return &(*u)(unsafe.Pointer(t)).u } } func hasPrefix(s, prefix string) bool { return len(s) >= len(prefix) && s[:len(prefix)] == prefix } func (t *_type) name() string { if t.tflag&tflagNamed == 0 { return "" } s := t.string() i := len(s) - 1 for i >= 0 { if s[i] == '.' { break } i-- } return s[i+1:] } // reflectOffs holds type offsets defined at run time by the reflect package. // // When a type is defined at run time, its *rtype data lives on the heap. // There are a wide range of possible addresses the heap may use, that // may not be representable as a 32-bit offset. Moreover the GC may // one day start moving heap memory, in which case there is no stable // offset that can be defined. // // To provide stable offsets, we add pin *rtype objects in a global map // and treat the offset as an identifier. We use negative offsets that // do not overlap with any compile-time module offsets. // // Entries are created by reflect.addReflectOff. var reflectOffs struct { lock mutex next int32 m map[int32]unsafe.Pointer minv map[unsafe.Pointer]int32 } func reflectOffsLock() { lock(&reflectOffs.lock) if raceenabled { raceacquire(unsafe.Pointer(&reflectOffs.lock)) } } func reflectOffsUnlock() { if raceenabled { racerelease(unsafe.Pointer(&reflectOffs.lock)) } unlock(&reflectOffs.lock) } func resolveNameOff(ptrInModule unsafe.Pointer, off nameOff) name { if off == 0 { return name{} } base := uintptr(ptrInModule) for md := &firstmoduledata; md != nil; md = md.next { if base >= md.types && base < md.etypes { res := md.types + uintptr(off) if res > md.etypes { println("runtime: nameOff", hex(off), "out of range", hex(md.types), "-", hex(md.etypes)) throw("runtime: name offset out of range") } return name{(*byte)(unsafe.Pointer(res))} } } // No module found. see if it is a run time name. reflectOffsLock() res, found := reflectOffs.m[int32(off)] reflectOffsUnlock() if !found { println("runtime: nameOff", hex(off), "base", hex(base), "not in ranges:") for next := &firstmoduledata; next != nil; next = next.next { println("\ttypes", hex(next.types), "etypes", hex(next.etypes)) } throw("runtime: name offset base pointer out of range") } return name{(*byte)(res)} } func (t *_type) nameOff(off nameOff) name { return resolveNameOff(unsafe.Pointer(t), off) } func resolveTypeOff(ptrInModule unsafe.Pointer, off typeOff) *_type { if off == 0 { return nil } base := uintptr(ptrInModule) var md *moduledata for next := &firstmoduledata; next != nil; next = next.next { if base >= next.types && base < next.etypes { md = next break } } if md == nil { reflectOffsLock() res := reflectOffs.m[int32(off)] reflectOffsUnlock() if res == nil { println("runtime: typeOff", hex(off), "base", hex(base), "not in ranges:") for next := &firstmoduledata; next != nil; next = next.next { println("\ttypes", hex(next.types), "etypes", hex(next.etypes)) } throw("runtime: type offset base pointer out of range") } return (*_type)(res) } if t := md.typemap[off]; t != nil { return t } res := md.types + uintptr(off) if res > md.etypes { println("runtime: typeOff", hex(off), "out of range", hex(md.types), "-", hex(md.etypes)) throw("runtime: type offset out of range") } return (*_type)(unsafe.Pointer(res)) } func (t *_type) typeOff(off typeOff) *_type { return resolveTypeOff(unsafe.Pointer(t), off) } func (t *_type) textOff(off textOff) unsafe.Pointer { base := uintptr(unsafe.Pointer(t)) var md *moduledata for next := &firstmoduledata; next != nil; next = next.next { if base >= next.types && base < next.etypes { md = next break } } if md == nil { reflectOffsLock() res := reflectOffs.m[int32(off)] reflectOffsUnlock() if res == nil { println("runtime: textOff", hex(off), "base", hex(base), "not in ranges:") for next := &firstmoduledata; next != nil; next = next.next { println("\ttypes", hex(next.types), "etypes", hex(next.etypes)) } throw("runtime: text offset base pointer out of range") } return res } res := uintptr(0) // The text, or instruction stream is generated as one large buffer. The off (offset) for a method is // its offset within this buffer. If the total text size gets too large, there can be issues on platforms like ppc64 if // the target of calls are too far for the call instruction. To resolve the large text issue, the text is split // into multiple text sections to allow the linker to generate long calls when necessary. When this happens, the vaddr // for each text section is set to its offset within the text. Each method's offset is compared against the section // vaddrs and sizes to determine the containing section. Then the section relative offset is added to the section's // relocated baseaddr to compute the method addess. if len(md.textsectmap) > 1 { for i := range md.textsectmap { sectaddr := md.textsectmap[i].vaddr sectlen := md.textsectmap[i].length if uintptr(off) >= sectaddr && uintptr(off) <= sectaddr+sectlen { res = md.textsectmap[i].baseaddr + uintptr(off) - uintptr(md.textsectmap[i].vaddr) break } } } else { // single text section res = md.text + uintptr(off) } if res > md.etext { println("runtime: textOff", hex(off), "out of range", hex(md.text), "-", hex(md.etext)) throw("runtime: text offset out of range") } return unsafe.Pointer(res) } func (t *functype) in() []*_type { // See funcType in reflect/type.go for details on data layout. uadd := uintptr(unsafe.Sizeof(functype{})) if t.typ.tflag&tflagUncommon != 0 { uadd += unsafe.Sizeof(uncommontype{}) } return (*[1 << 20]*_type)(add(unsafe.Pointer(t), uadd))[:t.inCount] } func (t *functype) out() []*_type { // See funcType in reflect/type.go for details on data layout. uadd := uintptr(unsafe.Sizeof(functype{})) if t.typ.tflag&tflagUncommon != 0 { uadd += unsafe.Sizeof(uncommontype{}) } outCount := t.outCount & (1<<15 - 1) return (*[1 << 20]*_type)(add(unsafe.Pointer(t), uadd))[t.inCount : t.inCount+outCount] } func (t *functype) dotdotdot() bool { return t.outCount&(1<<15) != 0 } type nameOff int32 type typeOff int32 type textOff int32 type method struct { name nameOff mtyp typeOff ifn textOff tfn textOff } type uncommontype struct { pkgpath nameOff mcount uint16 // number of methods _ uint16 // unused moff uint32 // offset from this uncommontype to [mcount]method _ uint32 // unused } type imethod struct { name nameOff ityp typeOff } type interfacetype struct { typ _type pkgpath name mhdr []imethod } type maptype struct { typ _type key *_type elem *_type bucket *_type // internal type representing a hash bucket hmap *_type // internal type representing a hmap keysize uint8 // size of key slot indirectkey bool // store ptr to key instead of key itself valuesize uint8 // size of value slot indirectvalue bool // store ptr to value instead of value itself bucketsize uint16 // size of bucket reflexivekey bool // true if k==k for all keys needkeyupdate bool // true if we need to update key on an overwrite } type arraytype struct { typ _type elem *_type slice *_type len uintptr } type chantype struct { typ _type elem *_type dir uintptr } type slicetype struct { typ _type elem *_type } type functype struct { typ _type inCount uint16 outCount uint16 } type ptrtype struct { typ _type elem *_type } type structfield struct { name name typ *_type offsetAnon uintptr } func (f *structfield) offset() uintptr { return f.offsetAnon >> 1 } type structtype struct { typ _type pkgPath name fields []structfield } // name is an encoded type name with optional extra data. // See reflect/type.go for details. type name struct { bytes *byte } func (n name) data(off int) *byte { return (*byte)(add(unsafe.Pointer(n.bytes), uintptr(off))) } func (n name) isExported() bool { return (*n.bytes)&(1<<0) != 0 } func (n name) nameLen() int { return int(uint16(*n.data(1))<<8 | uint16(*n.data(2))) } func (n name) tagLen() int { if *n.data(0)&(1<<1) == 0 { return 0 } off := 3 + n.nameLen() return int(uint16(*n.data(off))<<8 | uint16(*n.data(off + 1))) } func (n name) name() (s string) { if n.bytes == nil { return "" } nl := n.nameLen() if nl == 0 { return "" } hdr := (*stringStruct)(unsafe.Pointer(&s)) hdr.str = unsafe.Pointer(n.data(3)) hdr.len = nl return s } func (n name) tag() (s string) { tl := n.tagLen() if tl == 0 { return "" } nl := n.nameLen() hdr := (*stringStruct)(unsafe.Pointer(&s)) hdr.str = unsafe.Pointer(n.data(3 + nl + 2)) hdr.len = tl return s } func (n name) pkgPath() string { if n.bytes == nil || *n.data(0)&(1<<2) == 0 { return "" } off := 3 + n.nameLen() if tl := n.tagLen(); tl > 0 { off += 2 + tl } var nameOff nameOff copy((*[4]byte)(unsafe.Pointer(&nameOff))[:], (*[4]byte)(unsafe.Pointer(n.data(off)))[:]) pkgPathName := resolveNameOff(unsafe.Pointer(n.bytes), nameOff) return pkgPathName.name() } // typelinksinit scans the types from extra modules and builds the // moduledata typemap used to de-duplicate type pointers. func typelinksinit() { if firstmoduledata.next == nil { return } typehash := make(map[uint32][]*_type, len(firstmoduledata.typelinks)) modules := activeModules() prev := modules[0] for _, md := range modules[1:] { // Collect types from the previous module into typehash. collect: for _, tl := range prev.typelinks { var t *_type if prev.typemap == nil { t = (*_type)(unsafe.Pointer(prev.types + uintptr(tl))) } else { t = prev.typemap[typeOff(tl)] } // Add to typehash if not seen before. tlist := typehash[t.hash] for _, tcur := range tlist { if tcur == t { continue collect } } typehash[t.hash] = append(tlist, t) } if md.typemap == nil { // If any of this module's typelinks match a type from a // prior module, prefer that prior type by adding the offset // to this module's typemap. tm := make(map[typeOff]*_type, len(md.typelinks)) pinnedTypemaps = append(pinnedTypemaps, tm) md.typemap = tm for _, tl := range md.typelinks { t := (*_type)(unsafe.Pointer(md.types + uintptr(tl))) for _, candidate := range typehash[t.hash] { seen := map[_typePair]struct{}{} if typesEqual(t, candidate, seen) { t = candidate break } } md.typemap[typeOff(tl)] = t } } prev = md } } type _typePair struct { t1 *_type t2 *_type } // typesEqual reports whether two types are equal. // // Everywhere in the runtime and reflect packages, it is assumed that // there is exactly one *_type per Go type, so that pointer equality // can be used to test if types are equal. There is one place that // breaks this assumption: buildmode=shared. In this case a type can // appear as two different pieces of memory. This is hidden from the // runtime and reflect package by the per-module typemap built in // typelinksinit. It uses typesEqual to map types from later modules // back into earlier ones. // // Only typelinksinit needs this function. func typesEqual(t, v *_type, seen map[_typePair]struct{}) bool { tp := _typePair{t, v} if _, ok := seen[tp]; ok { return true } // mark these types as seen, and thus equivalent which prevents an infinite loop if // the two types are identical, but recursively defined and loaded from // different modules seen[tp] = struct{}{} if t == v { return true } kind := t.kind & kindMask if kind != v.kind&kindMask { return false } if t.string() != v.string() { return false } ut := t.uncommon() uv := v.uncommon() if ut != nil || uv != nil { if ut == nil || uv == nil { return false } pkgpatht := t.nameOff(ut.pkgpath).name() pkgpathv := v.nameOff(uv.pkgpath).name() if pkgpatht != pkgpathv { return false } } if kindBool <= kind && kind <= kindComplex128 { return true } switch kind { case kindString, kindUnsafePointer: return true case kindArray: at := (*arraytype)(unsafe.Pointer(t)) av := (*arraytype)(unsafe.Pointer(v)) return typesEqual(at.elem, av.elem, seen) && at.len == av.len case kindChan: ct := (*chantype)(unsafe.Pointer(t)) cv := (*chantype)(unsafe.Pointer(v)) return ct.dir == cv.dir && typesEqual(ct.elem, cv.elem, seen) case kindFunc: ft := (*functype)(unsafe.Pointer(t)) fv := (*functype)(unsafe.Pointer(v)) if ft.outCount != fv.outCount || ft.inCount != fv.inCount { return false } tin, vin := ft.in(), fv.in() for i := 0; i < len(tin); i++ { if !typesEqual(tin[i], vin[i], seen) { return false } } tout, vout := ft.out(), fv.out() for i := 0; i < len(tout); i++ { if !typesEqual(tout[i], vout[i], seen) { return false } } return true case kindInterface: it := (*interfacetype)(unsafe.Pointer(t)) iv := (*interfacetype)(unsafe.Pointer(v)) if it.pkgpath.name() != iv.pkgpath.name() { return false } if len(it.mhdr) != len(iv.mhdr) { return false } for i := range it.mhdr { tm := &it.mhdr[i] vm := &iv.mhdr[i] // Note the mhdr array can be relocated from // another module. See #17724. tname := resolveNameOff(unsafe.Pointer(tm), tm.name) vname := resolveNameOff(unsafe.Pointer(vm), vm.name) if tname.name() != vname.name() { return false } if tname.pkgPath() != vname.pkgPath() { return false } tityp := resolveTypeOff(unsafe.Pointer(tm), tm.ityp) vityp := resolveTypeOff(unsafe.Pointer(vm), vm.ityp) if !typesEqual(tityp, vityp, seen) { return false } } return true case kindMap: mt := (*maptype)(unsafe.Pointer(t)) mv := (*maptype)(unsafe.Pointer(v)) return typesEqual(mt.key, mv.key, seen) && typesEqual(mt.elem, mv.elem, seen) case kindPtr: pt := (*ptrtype)(unsafe.Pointer(t)) pv := (*ptrtype)(unsafe.Pointer(v)) return typesEqual(pt.elem, pv.elem, seen) case kindSlice: st := (*slicetype)(unsafe.Pointer(t)) sv := (*slicetype)(unsafe.Pointer(v)) return typesEqual(st.elem, sv.elem, seen) case kindStruct: st := (*structtype)(unsafe.Pointer(t)) sv := (*structtype)(unsafe.Pointer(v)) if len(st.fields) != len(sv.fields) { return false } for i := range st.fields { tf := &st.fields[i] vf := &sv.fields[i] if tf.name.name() != vf.name.name() { return false } if tf.name.pkgPath() != vf.name.pkgPath() { return false } if !typesEqual(tf.typ, vf.typ, seen) { return false } if tf.name.tag() != vf.name.tag() { return false } if tf.offsetAnon != vf.offsetAnon { return false } } return true default: println("runtime: impossible type kind", kind) throw("runtime: impossible type kind") return false } }