// Code generated by "go test -run=Generate -write=all"; DO NOT EDIT.
// Source: ../../cmd/compile/internal/types2/sizes.go
// 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.
// This file implements Sizes.
package types
// Sizes defines the sizing functions for package unsafe.
type Sizes interface {
// Alignof returns the alignment of a variable of type T.
// Alignof must implement the alignment guarantees required by the spec.
// The result must be >= 1.
Alignof(T Type) int64
// Offsetsof returns the offsets of the given struct fields, in bytes.
// Offsetsof must implement the offset guarantees required by the spec.
// A negative entry in the result indicates that the struct is too large.
Offsetsof(fields []*Var) []int64
// Sizeof returns the size of a variable of type T.
// Sizeof must implement the size guarantees required by the spec.
// A negative result indicates that T is too large.
Sizeof(T Type) int64
}
// StdSizes is a convenience type for creating commonly used Sizes.
// It makes the following simplifying assumptions:
//
// - The size of explicitly sized basic types (int16, etc.) is the
// specified size.
// - The size of strings and interfaces is 2*WordSize.
// - The size of slices is 3*WordSize.
// - The size of an array of n elements corresponds to the size of
// a struct of n consecutive fields of the array's element type.
// - The size of a struct is the offset of the last field plus that
// field's size. As with all element types, if the struct is used
// in an array its size must first be aligned to a multiple of the
// struct's alignment.
// - All other types have size WordSize.
// - Arrays and structs are aligned per spec definition; all other
// types are naturally aligned with a maximum alignment MaxAlign.
//
// *StdSizes implements Sizes.
type StdSizes struct {
WordSize int64 // word size in bytes - must be >= 4 (32bits)
MaxAlign int64 // maximum alignment in bytes - must be >= 1
}
func (s *StdSizes) Alignof(T Type) (result int64) {
defer func() {
assert(result >= 1)
}()
// For arrays and structs, alignment is defined in terms
// of alignment of the elements and fields, respectively.
switch t := under(T).(type) {
case *Array:
// spec: "For a variable x of array type: unsafe.Alignof(x)
// is the same as unsafe.Alignof(x[0]), but at least 1."
return s.Alignof(t.elem)
case *Struct:
if len(t.fields) == 0 && _IsSyncAtomicAlign64(T) {
// Special case: sync/atomic.align64 is an
// empty struct we recognize as a signal that
// the struct it contains must be
// 64-bit-aligned.
//
// This logic is equivalent to the logic in
// cmd/compile/internal/types/size.go:calcStructOffset
return 8
}
// spec: "For a variable x of struct type: unsafe.Alignof(x)
// is the largest of the values unsafe.Alignof(x.f) for each
// field f of x, but at least 1."
max := int64(1)
for _, f := range t.fields {
if a := s.Alignof(f.typ); a > max {
max = a
}
}
return max
case *Slice, *Interface:
// Multiword data structures are effectively structs
// in which each element has size WordSize.
// Type parameters lead to variable sizes/alignments;
// StdSizes.Alignof won't be called for them.
assert(!isTypeParam(T))
return s.WordSize
case *Basic:
// Strings are like slices and interfaces.
if t.Info()&IsString != 0 {
return s.WordSize
}
case *TypeParam, *Union:
panic("unreachable")
}
a := s.Sizeof(T) // may be 0 or negative
// spec: "For a variable x of any type: unsafe.Alignof(x) is at least 1."
if a < 1 {
return 1
}
// complex{64,128} are aligned like [2]float{32,64}.
if isComplex(T) {
a /= 2
}
if a > s.MaxAlign {
return s.MaxAlign
}
return a
}
func _IsSyncAtomicAlign64(T Type) bool {
named := asNamed(T)
if named == nil {
return false
}
obj := named.Obj()
return obj.Name() == "align64" &&
obj.Pkg() != nil &&
(obj.Pkg().Path() == "sync/atomic" ||
obj.Pkg().Path() == "internal/runtime/atomic")
}
func (s *StdSizes) Offsetsof(fields []*Var) []int64 {
offsets := make([]int64, len(fields))
var offs int64
for i, f := range fields {
if offs < 0 {
// all remaining offsets are too large
offsets[i] = -1
continue
}
// offs >= 0
a := s.Alignof(f.typ)
offs = align(offs, a) // possibly < 0 if align overflows
offsets[i] = offs
if d := s.Sizeof(f.typ); d >= 0 && offs >= 0 {
offs += d // ok to overflow to < 0
} else {
offs = -1 // f.typ or offs is too large
}
}
return offsets
}
var basicSizes = [...]byte{
Bool: 1,
Int8: 1,
Int16: 2,
Int32: 4,
Int64: 8,
Uint8: 1,
Uint16: 2,
Uint32: 4,
Uint64: 8,
Float32: 4,
Float64: 8,
Complex64: 8,
Complex128: 16,
}
func (s *StdSizes) Sizeof(T Type) int64 {
switch t := under(T).(type) {
case *Basic:
assert(isTyped(T))
k := t.kind
if int(k) < len(basicSizes) {
if s := basicSizes[k]; s > 0 {
return int64(s)
}
}
if k == String {
return s.WordSize * 2
}
case *Array:
n := t.len
if n <= 0 {
return 0
}
// n > 0
esize := s.Sizeof(t.elem)
if esize < 0 {
return -1 // element too large
}
if esize == 0 {
return 0 // 0-size element
}
// esize > 0
a := s.Alignof(t.elem)
ea := align(esize, a) // possibly < 0 if align overflows
if ea < 0 {
return -1
}
// ea >= 1
n1 := n - 1 // n1 >= 0
// Final size is ea*n1 + esize; and size must be <= maxInt64.
const maxInt64 = 1<<63 - 1
if n1 > 0 && ea > maxInt64/n1 {
return -1 // ea*n1 overflows
}
return ea*n1 + esize // may still overflow to < 0 which is ok
case *Slice:
return s.WordSize * 3
case *Struct:
n := t.NumFields()
if n == 0 {
return 0
}
offsets := s.Offsetsof(t.fields)
offs := offsets[n-1]
size := s.Sizeof(t.fields[n-1].typ)
if offs < 0 || size < 0 {
return -1 // type too large
}
return offs + size // may overflow to < 0 which is ok
case *Interface:
// Type parameters lead to variable sizes/alignments;
// StdSizes.Sizeof won't be called for them.
assert(!isTypeParam(T))
return s.WordSize * 2
case *TypeParam, *Union:
panic("unreachable")
}
return s.WordSize // catch-all
}
// common architecture word sizes and alignments
var gcArchSizes = map[string]*gcSizes{
"386": {4, 4},
"amd64": {8, 8},
"amd64p32": {4, 8},
"arm": {4, 4},
"arm64": {8, 8},
"loong64": {8, 8},
"mips": {4, 4},
"mipsle": {4, 4},
"mips64": {8, 8},
"mips64le": {8, 8},
"ppc64": {8, 8},
"ppc64le": {8, 8},
"riscv64": {8, 8},
"s390x": {8, 8},
"sparc64": {8, 8},
"wasm": {8, 8},
// When adding more architectures here,
// update the doc string of SizesFor below.
}
// SizesFor returns the Sizes used by a compiler for an architecture.
// The result is nil if a compiler/architecture pair is not known.
//
// Supported architectures for compiler "gc":
// "386", "amd64", "amd64p32", "arm", "arm64", "loong64", "mips", "mipsle",
// "mips64", "mips64le", "ppc64", "ppc64le", "riscv64", "s390x", "sparc64", "wasm".
func SizesFor(compiler, arch string) Sizes {
switch compiler {
case "gc":
if s := gcSizesFor(compiler, arch); s != nil {
return Sizes(s)
}
case "gccgo":
if s, ok := gccgoArchSizes[arch]; ok {
return Sizes(s)
}
}
return nil
}
// stdSizes is used if Config.Sizes == nil.
var stdSizes = SizesFor("gc", "amd64")
func (conf *Config) alignof(T Type) int64 {
f := stdSizes.Alignof
if conf.Sizes != nil {
f = conf.Sizes.Alignof
}
if a := f(T); a >= 1 {
return a
}
panic("implementation of alignof returned an alignment < 1")
}
func (conf *Config) offsetsof(T *Struct) []int64 {
var offsets []int64
if T.NumFields() > 0 {
// compute offsets on demand
f := stdSizes.Offsetsof
if conf.Sizes != nil {
f = conf.Sizes.Offsetsof
}
offsets = f(T.fields)
// sanity checks
if len(offsets) != T.NumFields() {
panic("implementation of offsetsof returned the wrong number of offsets")
}
}
return offsets
}
// offsetof returns the offset of the field specified via
// the index sequence relative to T. All embedded fields
// must be structs (rather than pointers to structs).
// If the offset is too large (because T is too large),
// the result is negative.
func (conf *Config) offsetof(T Type, index []int) int64 {
var offs int64
for _, i := range index {
s := under(T).(*Struct)
d := conf.offsetsof(s)[i]
if d < 0 {
return -1
}
offs += d
if offs < 0 {
return -1
}
T = s.fields[i].typ
}
return offs
}
// sizeof returns the size of T.
// If T is too large, the result is negative.
func (conf *Config) sizeof(T Type) int64 {
f := stdSizes.Sizeof
if conf.Sizes != nil {
f = conf.Sizes.Sizeof
}
return f(T)
}
// align returns the smallest y >= x such that y % a == 0.
// a must be within 1 and 8 and it must be a power of 2.
// The result may be negative due to overflow.
func align(x, a int64) int64 {
assert(x >= 0 && 1 <= a && a <= 8 && a&(a-1) == 0)
return (x + a - 1) &^ (a - 1)
}