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// 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.
/*
Package unsafe contains operations that step around the type safety of Go programs.
Packages that import unsafe may be non-portable and are not protected by the
Go 1 compatibility guidelines.
*/
package unsafe
// ArbitraryType is here for the purposes of documentation only and is not actually
// part of the unsafe package. It represents the type of an arbitrary Go expression.
type ArbitraryType int
// IntegerType is here for the purposes of documentation only and is not actually
// part of the unsafe package. It represents any arbitrary integer type.
type IntegerType int
// Pointer represents a pointer to an arbitrary type. There are four special operations
// available for type Pointer that are not available for other types:
// - A pointer value of any type can be converted to a Pointer.
// - A Pointer can be converted to a pointer value of any type.
// - A uintptr can be converted to a Pointer.
// - A Pointer can be converted to a uintptr.
//
// Pointer therefore allows a program to defeat the type system and read and write
// arbitrary memory. It should be used with extreme care.
//
// The following patterns involving Pointer are valid.
// Code not using these patterns is likely to be invalid today
// or to become invalid in the future.
// Even the valid patterns below come with important caveats.
//
// Running "go vet" can help find uses of Pointer that do not conform to these patterns,
// but silence from "go vet" is not a guarantee that the code is valid.
//
// (1) Conversion of a *T1 to Pointer to *T2.
//
// Provided that T2 is no larger than T1 and that the two share an equivalent
// memory layout, this conversion allows reinterpreting data of one type as
// data of another type. An example is the implementation of
// math.Float64bits:
//
// func Float64bits(f float64) uint64 {
// return *(*uint64)(unsafe.Pointer(&f))
// }
//
// (2) Conversion of a Pointer to a uintptr (but not back to Pointer).
//
// Converting a Pointer to a uintptr produces the memory address of the value
// pointed at, as an integer. The usual use for such a uintptr is to print it.
//
// Conversion of a uintptr back to Pointer is not valid in general.
//
// A uintptr is an integer, not a reference.
// Converting a Pointer to a uintptr creates an integer value
// with no pointer semantics.
// Even if a uintptr holds the address of some object,
// the garbage collector will not update that uintptr's value
// if the object moves, nor will that uintptr keep the object
// from being reclaimed.
//
// The remaining patterns enumerate the only valid conversions
// from uintptr to Pointer.
//
// (3) Conversion of a Pointer to a uintptr and back, with arithmetic.
//
// If p points into an allocated object, it can be advanced through the object
// by conversion to uintptr, addition of an offset, and conversion back to Pointer.
//
// p = unsafe.Pointer(uintptr(p) + offset)
//
// The most common use of this pattern is to access fields in a struct
// or elements of an array:
//
// // equivalent to f := unsafe.Pointer(&s.f)
// f := unsafe.Pointer(uintptr(unsafe.Pointer(&s)) + unsafe.Offsetof(s.f))
//
// // equivalent to e := unsafe.Pointer(&x[i])
// e := unsafe.Pointer(uintptr(unsafe.Pointer(&x[0])) + i*unsafe.Sizeof(x[0]))
//
// It is valid both to add and to subtract offsets from a pointer in this way.
// It is also valid to use &^ to round pointers, usually for alignment.
// In all cases, the result must continue to point into the original allocated object.
//
// Unlike in C, it is not valid to advance a pointer just beyond the end of
// its original allocation:
//
// // INVALID: end points outside allocated space.
// var s thing
// end = unsafe.Pointer(uintptr(unsafe.Pointer(&s)) + unsafe.Sizeof(s))
//
// // INVALID: end points outside allocated space.
// b := make([]byte, n)
// end = unsafe.Pointer(uintptr(unsafe.Pointer(&b[0])) + uintptr(n))
//
// Note that both conversions must appear in the same expression, with only
// the intervening arithmetic between them:
//
// // INVALID: uintptr cannot be stored in variable
// // before conversion back to Pointer.
// u := uintptr(p)
// p = unsafe.Pointer(u + offset)
//
// Note that the pointer must point into an allocated object, so it may not be nil.
//
// // INVALID: conversion of nil pointer
// u := unsafe.Pointer(nil)
// p := unsafe.Pointer(uintptr(u) + offset)
//
// (4) Conversion of a Pointer to a uintptr when calling syscall.Syscall.
//
// The Syscall functions in package syscall pass their uintptr arguments directly
// to the operating system, which then may, depending on the details of the call,
// reinterpret some of them as pointers.
// That is, the system call implementation is implicitly converting certain arguments
// back from uintptr to pointer.
//
// If a pointer argument must be converted to uintptr for use as an argument,
// that conversion must appear in the call expression itself:
//
// syscall.Syscall(SYS_READ, uintptr(fd), uintptr(unsafe.Pointer(p)), uintptr(n))
//
// The compiler handles a Pointer converted to a uintptr in the argument list of
// a call to a function implemented in assembly by arranging that the referenced
// allocated object, if any, is retained and not moved until the call completes,
// even though from the types alone it would appear that the object is no longer
// needed during the call.
//
// For the compiler to recognize this pattern,
// the conversion must appear in the argument list:
//
// // INVALID: uintptr cannot be stored in variable
// // before implicit conversion back to Pointer during system call.
// u := uintptr(unsafe.Pointer(p))
// syscall.Syscall(SYS_READ, uintptr(fd), u, uintptr(n))
//
// (5) Conversion of the result of reflect.Value.Pointer or reflect.Value.UnsafeAddr
// from uintptr to Pointer.
//
// Package reflect's Value methods named Pointer and UnsafeAddr return type uintptr
// instead of unsafe.Pointer to keep callers from changing the result to an arbitrary
// type without first importing "unsafe". However, this means that the result is
// fragile and must be converted to Pointer immediately after making the call,
// in the same expression:
//
// p := (*int)(unsafe.Pointer(reflect.ValueOf(new(int)).Pointer()))
//
// As in the cases above, it is invalid to store the result before the conversion:
//
// // INVALID: uintptr cannot be stored in variable
// // before conversion back to Pointer.
// u := reflect.ValueOf(new(int)).Pointer()
// p := (*int)(unsafe.Pointer(u))
//
// (6) Conversion of a reflect.SliceHeader or reflect.StringHeader Data field to or from Pointer.
//
// As in the previous case, the reflect data structures SliceHeader and StringHeader
// declare the field Data as a uintptr to keep callers from changing the result to
// an arbitrary type without first importing "unsafe". However, this means that
// SliceHeader and StringHeader are only valid when interpreting the content
// of an actual slice or string value.
//
// var s string
// hdr := (*reflect.StringHeader)(unsafe.Pointer(&s)) // case 1
// hdr.Data = uintptr(unsafe.Pointer(p)) // case 6 (this case)
// hdr.Len = n
//
// In this usage hdr.Data is really an alternate way to refer to the underlying
// pointer in the string header, not a uintptr variable itself.
//
// In general, reflect.SliceHeader and reflect.StringHeader should be used
// only as *reflect.SliceHeader and *reflect.StringHeader pointing at actual
// slices or strings, never as plain structs.
// A program should not declare or allocate variables of these struct types.
//
// // INVALID: a directly-declared header will not hold Data as a reference.
// var hdr reflect.StringHeader
// hdr.Data = uintptr(unsafe.Pointer(p))
// hdr.Len = n
// s := *(*string)(unsafe.Pointer(&hdr)) // p possibly already lost
type Pointer *ArbitraryType
// Sizeof takes an expression x of any type and returns the size in bytes
// of a hypothetical variable v as if v was declared via var v = x.
// The size does not include any memory possibly referenced by x.
// For instance, if x is a slice, Sizeof returns the size of the slice
// descriptor, not the size of the memory referenced by the slice.
// For a struct, the size includes any padding introduced by field alignment.
// The return value of Sizeof is a Go constant if the type of the argument x
// does not have variable size.
// (A type has variable size if it is a type parameter or if it is an array
// or struct type with elements of variable size).
func Sizeof(x ArbitraryType) uintptr
// Offsetof returns the offset within the struct of the field represented by x,
// which must be of the form structValue.field. In other words, it returns the
// number of bytes between the start of the struct and the start of the field.
// The return value of Offsetof is a Go constant if the type of the argument x
// does not have variable size.
// (See the description of [Sizeof] for a definition of variable sized types.)
func Offsetof(x ArbitraryType) uintptr
// Alignof takes an expression x of any type and returns the required alignment
// of a hypothetical variable v as if v was declared via var v = x.
// It is the largest value m such that the address of v is always zero mod m.
// It is the same as the value returned by reflect.TypeOf(x).Align().
// As a special case, if a variable s is of struct type and f is a field
// within that struct, then Alignof(s.f) will return the required alignment
// of a field of that type within a struct. This case is the same as the
// value returned by reflect.TypeOf(s.f).FieldAlign().
// The return value of Alignof is a Go constant if the type of the argument
// does not have variable size.
// (See the description of [Sizeof] for a definition of variable sized types.)
func Alignof(x ArbitraryType) uintptr
// The function Add adds len to ptr and returns the updated pointer
// Pointer(uintptr(ptr) + uintptr(len)).
// The len argument must be of integer type or an untyped constant.
// A constant len argument must be representable by a value of type int;
// if it is an untyped constant it is given type int.
// The rules for valid uses of Pointer still apply.
func Add(ptr Pointer, len IntegerType) Pointer
// The function Slice returns a slice whose underlying array starts at ptr
// and whose length and capacity are len.
// Slice(ptr, len) is equivalent to
//
// (*[len]ArbitraryType)(unsafe.Pointer(ptr))[:]
//
// except that, as a special case, if ptr is nil and len is zero,
// Slice returns nil.
//
// The len argument must be of integer type or an untyped constant.
// A constant len argument must be non-negative and representable by a value of type int;
// if it is an untyped constant it is given type int.
// At run time, if len is negative, or if ptr is nil and len is not zero,
// a run-time panic occurs.
func Slice(ptr *ArbitraryType, len IntegerType) []ArbitraryType
// SliceData returns a pointer to the underlying array of the argument
// slice.
// - If cap(slice) > 0, SliceData returns &slice[:1][0].
// - If slice == nil, SliceData returns nil.
// - Otherwise, SliceData returns a non-nil pointer to an
// unspecified memory address.
func SliceData(slice []ArbitraryType) *ArbitraryType
// String returns a string value whose underlying bytes
// start at ptr and whose length is len.
//
// The len argument must be of integer type or an untyped constant.
// A constant len argument must be non-negative and representable by a value of type int;
// if it is an untyped constant it is given type int.
// At run time, if len is negative, or if ptr is nil and len is not zero,
// a run-time panic occurs.
//
// Since Go strings are immutable, the bytes passed to String
// must not be modified afterwards.
func String(ptr *byte, len IntegerType) string
// StringData returns a pointer to the underlying bytes of str.
// For an empty string the return value is unspecified, and may be nil.
//
// Since Go strings are immutable, the bytes returned by StringData
// must not be modified.
func StringData(str string) *byte