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hash.go
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hash.go
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//go:build !cmd_go_bootstrap
package openssl
// #include "goopenssl.h"
import "C"
import (
"crypto"
"errors"
"hash"
"runtime"
"strconv"
"sync"
"unsafe"
)
// NOTE: Implementation ported from https://go-review.googlesource.com/c/go/+/404295.
// The cgo calls in this file are arranged to avoid marking the parameters as escaping.
// To do that, we call noescape (including via addr).
// We must also make sure that the data pointer arguments have the form unsafe.Pointer(&...)
// so that cgo does not annotate them with cgoCheckPointer calls. If it did that, it might look
// beyond the byte slice and find Go pointers in unprocessed parts of a larger allocation.
// To do both of these simultaneously, the idiom is unsafe.Pointer(&*addr(p)),
// where addr returns the base pointer of p, substituting a non-nil pointer for nil,
// and applying a noescape along the way.
// This is all to preserve compatibility with the allocation behavior of the non-openssl implementations.
func hashOneShot(ch crypto.Hash, p []byte, sum []byte) bool {
return C.go_openssl_EVP_Digest(unsafe.Pointer(&*addr(p)), C.size_t(len(p)), (*C.uchar)(unsafe.Pointer(&*addr(sum))), nil, cryptoHashToMD(ch), nil) != 0
}
func MD4(p []byte) (sum [16]byte) {
if !hashOneShot(crypto.MD4, p, sum[:]) {
panic("openssl: MD4 failed")
}
return
}
func MD5(p []byte) (sum [16]byte) {
if !hashOneShot(crypto.MD5, p, sum[:]) {
panic("openssl: MD5 failed")
}
return
}
func SHA1(p []byte) (sum [20]byte) {
if !hashOneShot(crypto.SHA1, p, sum[:]) {
panic("openssl: SHA1 failed")
}
return
}
func SHA224(p []byte) (sum [28]byte) {
if !hashOneShot(crypto.SHA224, p, sum[:]) {
panic("openssl: SHA224 failed")
}
return
}
func SHA256(p []byte) (sum [32]byte) {
if !hashOneShot(crypto.SHA256, p, sum[:]) {
panic("openssl: SHA256 failed")
}
return
}
func SHA384(p []byte) (sum [48]byte) {
if !hashOneShot(crypto.SHA384, p, sum[:]) {
panic("openssl: SHA384 failed")
}
return
}
func SHA512(p []byte) (sum [64]byte) {
if !hashOneShot(crypto.SHA512, p, sum[:]) {
panic("openssl: SHA512 failed")
}
return
}
// SupportsHash returns true if a hash.Hash implementation is supported for h.
func SupportsHash(h crypto.Hash) bool {
return cryptoHashToMD(h) != nil
}
func SHA3_224(p []byte) (sum [28]byte) {
if !hashOneShot(crypto.SHA3_224, p, sum[:]) {
panic("openssl: SHA3_224 failed")
}
return
}
func SHA3_256(p []byte) (sum [32]byte) {
if !hashOneShot(crypto.SHA3_256, p, sum[:]) {
panic("openssl: SHA3_256 failed")
}
return
}
func SHA3_384(p []byte) (sum [48]byte) {
if !hashOneShot(crypto.SHA3_384, p, sum[:]) {
panic("openssl: SHA3_384 failed")
}
return
}
func SHA3_512(p []byte) (sum [64]byte) {
if !hashOneShot(crypto.SHA3_512, p, sum[:]) {
panic("openssl: SHA3_512 failed")
}
return
}
var isMarshallableCache sync.Map
// isHashMarshallable returns true if the memory layout of cb
// is known by this library and can therefore be marshalled.
func isHashMarshallable(ch crypto.Hash) bool {
if vMajor == 1 {
return true
}
if v, ok := isMarshallableCache.Load(ch); ok {
return v.(bool)
}
md := cryptoHashToMD(ch)
if md == nil {
return false
}
prov := C.go_openssl_EVP_MD_get0_provider(md)
if prov == nil {
return false
}
cname := C.go_openssl_OSSL_PROVIDER_get0_name(prov)
if cname == nil {
return false
}
name := C.GoString(cname)
// We only know the memory layout of the built-in providers.
// See evpHash.hashState for more details.
marshallable := name == "default" || name == "fips"
isMarshallableCache.Store(ch, marshallable)
return marshallable
}
// evpHash implements generic hash methods.
type evpHash struct {
ctx C.GO_EVP_MD_CTX_PTR
// ctx2 is used in evpHash.sum to avoid changing
// the state of ctx. Having it here allows reusing the
// same allocated object multiple times.
ctx2 C.GO_EVP_MD_CTX_PTR
size int
blockSize int
marshallable bool
}
func newEvpHash(ch crypto.Hash) *evpHash {
md := cryptoHashToMD(ch)
if md == nil {
panic("openssl: unsupported hash function: " + strconv.Itoa(int(ch)))
}
ctx := C.go_openssl_EVP_MD_CTX_new()
if C.go_openssl_EVP_DigestInit_ex(ctx, md, nil) != 1 {
C.go_openssl_EVP_MD_CTX_free(ctx)
panic(newOpenSSLError("EVP_DigestInit_ex"))
}
ctx2 := C.go_openssl_EVP_MD_CTX_new()
blockSize := int(C.go_openssl_EVP_MD_get_block_size(md))
h := &evpHash{
ctx: ctx,
ctx2: ctx2,
size: ch.Size(),
blockSize: blockSize,
marshallable: isHashMarshallable(ch),
}
runtime.SetFinalizer(h, (*evpHash).finalize)
return h
}
func (h *evpHash) finalize() {
C.go_openssl_EVP_MD_CTX_free(h.ctx)
C.go_openssl_EVP_MD_CTX_free(h.ctx2)
}
func (h *evpHash) Reset() {
// There is no need to reset h.ctx2 because it is always reset after
// use in evpHash.sum.
if C.go_openssl_EVP_DigestInit_ex(h.ctx, nil, nil) != 1 {
panic(newOpenSSLError("EVP_DigestInit_ex"))
}
runtime.KeepAlive(h)
}
func (h *evpHash) Write(p []byte) (int, error) {
if len(p) > 0 && C.go_openssl_EVP_DigestUpdate(h.ctx, unsafe.Pointer(&*addr(p)), C.size_t(len(p))) != 1 {
panic(newOpenSSLError("EVP_DigestUpdate"))
}
runtime.KeepAlive(h)
return len(p), nil
}
func (h *evpHash) WriteString(s string) (int, error) {
if len(s) > 0 && C.go_openssl_EVP_DigestUpdate(h.ctx, unsafe.Pointer(unsafe.StringData(s)), C.size_t(len(s))) == 0 {
panic("openssl: EVP_DigestUpdate failed")
}
runtime.KeepAlive(h)
return len(s), nil
}
func (h *evpHash) WriteByte(c byte) error {
if C.go_openssl_EVP_DigestUpdate(h.ctx, unsafe.Pointer(&c), 1) == 0 {
panic("openssl: EVP_DigestUpdate failed")
}
runtime.KeepAlive(h)
return nil
}
func (h *evpHash) Size() int {
return h.size
}
func (h *evpHash) BlockSize() int {
return h.blockSize
}
func (h *evpHash) sum(out []byte) {
if C.go_hash_sum(h.ctx, h.ctx2, base(out)) != 1 {
panic(newOpenSSLError("go_hash_sum"))
}
runtime.KeepAlive(h)
}
// clone returns a new evpHash object that is a deep clone of itself.
// The duplicate object contains all state and data contained in the
// original object at the point of duplication.
func (h *evpHash) clone() (*evpHash, error) {
ctx := C.go_openssl_EVP_MD_CTX_new()
if ctx == nil {
return nil, newOpenSSLError("EVP_MD_CTX_new")
}
if C.go_openssl_EVP_MD_CTX_copy_ex(ctx, h.ctx) != 1 {
C.go_openssl_EVP_MD_CTX_free(ctx)
return nil, newOpenSSLError("EVP_MD_CTX_copy")
}
ctx2 := C.go_openssl_EVP_MD_CTX_new()
if ctx2 == nil {
C.go_openssl_EVP_MD_CTX_free(ctx)
return nil, newOpenSSLError("EVP_MD_CTX_new")
}
cloned := &evpHash{
ctx: ctx,
ctx2: ctx2,
size: h.size,
blockSize: h.blockSize,
marshallable: h.marshallable,
}
runtime.SetFinalizer(cloned, (*evpHash).finalize)
return cloned, nil
}
// hashState returns a pointer to the internal hash structure.
//
// The EVP_MD_CTX memory layout has changed in OpenSSL 3
// and the property holding the internal structure is no longer md_data but algctx.
func (h *evpHash) hashState() unsafe.Pointer {
if !h.marshallable {
panic("openssl: hash state is not marshallable")
}
switch vMajor {
case 1:
// https://github.com/openssl/openssl/blob/0418e993c717a6863f206feaa40673a261de7395/crypto/evp/evp_local.h#L12.
type mdCtx struct {
_ [2]unsafe.Pointer
_ C.ulong
md_data unsafe.Pointer
}
return (*mdCtx)(unsafe.Pointer(h.ctx)).md_data
case 3:
// https://github.com/openssl/openssl/blob/5675a5aaf6a2e489022bcfc18330dae9263e598e/crypto/evp/evp_local.h#L16.
type mdCtx struct {
_ [3]unsafe.Pointer
_ C.ulong
_ [3]unsafe.Pointer
algctx unsafe.Pointer
}
return (*mdCtx)(unsafe.Pointer(h.ctx)).algctx
default:
panic(errUnsupportedVersion())
}
}
// NewMD4 returns a new MD4 hash.
// The returned hash doesn't implement encoding.BinaryMarshaler and
// encoding.BinaryUnmarshaler.
func NewMD4() hash.Hash {
return &md4Hash{
evpHash: newEvpHash(crypto.MD4),
}
}
type md4Hash struct {
*evpHash
out [16]byte
}
func (h *md4Hash) Sum(in []byte) []byte {
h.sum(h.out[:])
return append(in, h.out[:]...)
}
// Clone returns a new [hash.Hash] object that is a deep clone of itself.
// The duplicate object contains all state and data contained in the
// original object at the point of duplication.
func (h *md4Hash) Clone() (hash.Hash, error) {
c, err := h.clone()
if err != nil {
return nil, err
}
return &md4Hash{evpHash: c}, nil
}
// NewMD5 returns a new MD5 hash.
func NewMD5() hash.Hash {
h := md5Hash{evpHash: newEvpHash(crypto.MD5)}
if h.marshallable {
return &md5Marshal{h}
}
return &h
}
// md5State layout is taken from
// https://github.com/openssl/openssl/blob/0418e993c717a6863f206feaa40673a261de7395/include/openssl/md5.h#L33.
type md5State struct {
h [4]uint32
nl, nh uint32
x [64]byte
nx uint32
}
type md5Hash struct {
*evpHash
out [16]byte
}
func (h *md5Hash) Sum(in []byte) []byte {
h.sum(h.out[:])
return append(in, h.out[:]...)
}
// Clone returns a new [hash.Hash] object that is a deep clone of itself.
// The duplicate object contains all state and data contained in the
// original object at the point of duplication.
func (h *md5Hash) Clone() (hash.Hash, error) {
c, err := h.clone()
if err != nil {
return nil, err
}
return &md5Hash{evpHash: c}, nil
}
const (
md5Magic = "md5\x01"
md5MarshaledSize = len(md5Magic) + 4*4 + 64 + 8
)
type md5Marshal struct {
md5Hash
}
func (h *md5Marshal) MarshalBinary() ([]byte, error) {
buf := make([]byte, 0, md5MarshaledSize)
return h.AppendBinary(buf)
}
func (h *md5Marshal) UnmarshalBinary(b []byte) error {
if len(b) < len(md5Magic) || string(b[:len(md5Magic)]) != md5Magic {
return errors.New("crypto/md5: invalid hash state identifier")
}
if len(b) != md5MarshaledSize {
return errors.New("crypto/md5: invalid hash state size")
}
d := (*md5State)(h.hashState())
if d == nil {
return errors.New("crypto/md5: can't retrieve hash state")
}
b = b[len(md5Magic):]
b, d.h[0] = consumeUint32(b)
b, d.h[1] = consumeUint32(b)
b, d.h[2] = consumeUint32(b)
b, d.h[3] = consumeUint32(b)
b = b[copy(d.x[:], b):]
_, n := consumeUint64(b)
d.nl = uint32(n << 3)
d.nh = uint32(n >> 29)
d.nx = uint32(n) % 64
return nil
}
func (h *md5Marshal) AppendBinary(buf []byte) ([]byte, error) {
d := (*md5State)(h.hashState())
if d == nil {
return nil, errors.New("crypto/md5: can't retrieve hash state")
}
buf = append(buf, md5Magic...)
buf = appendUint32(buf, d.h[0])
buf = appendUint32(buf, d.h[1])
buf = appendUint32(buf, d.h[2])
buf = appendUint32(buf, d.h[3])
buf = append(buf, d.x[:d.nx]...)
buf = append(buf, make([]byte, len(d.x)-int(d.nx))...)
buf = appendUint64(buf, uint64(d.nl)>>3|uint64(d.nh)<<29)
return buf, nil
}
// NewSHA1 returns a new SHA1 hash.
func NewSHA1() hash.Hash {
h := sha1Hash{evpHash: newEvpHash(crypto.SHA1)}
if h.marshallable {
return &sha1Marshal{h}
}
return &h
}
type sha1Hash struct {
*evpHash
out [20]byte
}
func (h *sha1Hash) Sum(in []byte) []byte {
h.sum(h.out[:])
return append(in, h.out[:]...)
}
// Clone returns a new [hash.Hash] object that is a deep clone of itself.
// The duplicate object contains all state and data contained in the
// original object at the point of duplication.
func (h *sha1Hash) Clone() (hash.Hash, error) {
c, err := h.clone()
if err != nil {
return nil, err
}
return &sha1Hash{evpHash: c}, nil
}
// sha1State layout is taken from
// https://github.com/openssl/openssl/blob/0418e993c717a6863f206feaa40673a261de7395/include/openssl/sha.h#L34.
type sha1State struct {
h [5]uint32
nl, nh uint32
x [64]byte
nx uint32
}
const (
sha1Magic = "sha\x01"
sha1MarshaledSize = len(sha1Magic) + 5*4 + 64 + 8
)
type sha1Marshal struct {
sha1Hash
}
func (h *sha1Marshal) MarshalBinary() ([]byte, error) {
buf := make([]byte, 0, sha1MarshaledSize)
return h.AppendBinary(buf)
}
func (h *sha1Marshal) UnmarshalBinary(b []byte) error {
if len(b) < len(sha1Magic) || string(b[:len(sha1Magic)]) != sha1Magic {
return errors.New("crypto/sha1: invalid hash state identifier")
}
if len(b) != sha1MarshaledSize {
return errors.New("crypto/sha1: invalid hash state size")
}
d := (*sha1State)(h.hashState())
if d == nil {
return errors.New("crypto/sha1: can't retrieve hash state")
}
b = b[len(sha1Magic):]
b, d.h[0] = consumeUint32(b)
b, d.h[1] = consumeUint32(b)
b, d.h[2] = consumeUint32(b)
b, d.h[3] = consumeUint32(b)
b, d.h[4] = consumeUint32(b)
b = b[copy(d.x[:], b):]
_, n := consumeUint64(b)
d.nl = uint32(n << 3)
d.nh = uint32(n >> 29)
d.nx = uint32(n) % 64
return nil
}
func (h *sha1Marshal) AppendBinary(buf []byte) ([]byte, error) {
d := (*sha1State)(h.hashState())
if d == nil {
return nil, errors.New("crypto/sha1: can't retrieve hash state")
}
buf = append(buf, sha1Magic...)
buf = appendUint32(buf, d.h[0])
buf = appendUint32(buf, d.h[1])
buf = appendUint32(buf, d.h[2])
buf = appendUint32(buf, d.h[3])
buf = appendUint32(buf, d.h[4])
buf = append(buf, d.x[:d.nx]...)
buf = append(buf, make([]byte, len(d.x)-int(d.nx))...)
buf = appendUint64(buf, uint64(d.nl)>>3|uint64(d.nh)<<29)
return buf, nil
}
// NewSHA224 returns a new SHA224 hash.
func NewSHA224() hash.Hash {
h := sha224Hash{evpHash: newEvpHash(crypto.SHA224)}
if h.marshallable {
return &sha224Marshal{h}
}
return &h
}
type sha224Hash struct {
*evpHash
out [224 / 8]byte
}
func (h *sha224Hash) Sum(in []byte) []byte {
h.sum(h.out[:])
return append(in, h.out[:]...)
}
// Clone returns a new [hash.Hash] object that is a deep clone of itself.
// The duplicate object contains all state and data contained in the
// original object at the point of duplication.
func (h *sha224Hash) Clone() (hash.Hash, error) {
c, err := h.clone()
if err != nil {
return nil, err
}
return &sha224Hash{evpHash: c}, nil
}
// NewSHA256 returns a new SHA256 hash.
func NewSHA256() hash.Hash {
h := sha256Hash{evpHash: newEvpHash(crypto.SHA256)}
if h.marshallable {
return &sha256Marshal{h}
}
return &h
}
type sha256Hash struct {
*evpHash
out [256 / 8]byte
}
func (h *sha256Hash) Sum(in []byte) []byte {
h.sum(h.out[:])
return append(in, h.out[:]...)
}
// Clone returns a new [hash.Hash] object that is a deep clone of itself.
// The duplicate object contains all state and data contained in the
// original object at the point of duplication.
func (h *sha256Hash) Clone() (hash.Hash, error) {
c, err := h.clone()
if err != nil {
return nil, err
}
return &sha256Hash{evpHash: c}, nil
}
const (
magic224 = "sha\x02"
magic256 = "sha\x03"
marshaledSize256 = len(magic256) + 8*4 + 64 + 8
)
// sha256State layout is taken from
// https://github.com/openssl/openssl/blob/0418e993c717a6863f206feaa40673a261de7395/include/openssl/sha.h#L51.
type sha256State struct {
h [8]uint32
nl, nh uint32
x [64]byte
nx uint32
}
type sha224Marshal struct {
sha224Hash
}
type sha256Marshal struct {
sha256Hash
}
func (h *sha224Marshal) MarshalBinary() ([]byte, error) {
buf := make([]byte, 0, marshaledSize256)
return h.AppendBinary(buf)
}
func (h *sha256Marshal) MarshalBinary() ([]byte, error) {
buf := make([]byte, 0, marshaledSize256)
return h.AppendBinary(buf)
}
func (h *sha224Marshal) UnmarshalBinary(b []byte) error {
if len(b) < len(magic224) || string(b[:len(magic224)]) != magic224 {
return errors.New("crypto/sha256: invalid hash state identifier")
}
if len(b) != marshaledSize256 {
return errors.New("crypto/sha256: invalid hash state size")
}
d := (*sha256State)(h.hashState())
if d == nil {
return errors.New("crypto/sha256: can't retrieve hash state")
}
b = b[len(magic224):]
b, d.h[0] = consumeUint32(b)
b, d.h[1] = consumeUint32(b)
b, d.h[2] = consumeUint32(b)
b, d.h[3] = consumeUint32(b)
b, d.h[4] = consumeUint32(b)
b, d.h[5] = consumeUint32(b)
b, d.h[6] = consumeUint32(b)
b, d.h[7] = consumeUint32(b)
b = b[copy(d.x[:], b):]
_, n := consumeUint64(b)
d.nl = uint32(n << 3)
d.nh = uint32(n >> 29)
d.nx = uint32(n) % 64
return nil
}
func (h *sha256Marshal) UnmarshalBinary(b []byte) error {
if len(b) < len(magic256) || string(b[:len(magic256)]) != magic256 {
return errors.New("crypto/sha256: invalid hash state identifier")
}
if len(b) != marshaledSize256 {
return errors.New("crypto/sha256: invalid hash state size")
}
d := (*sha256State)(h.hashState())
if d == nil {
return errors.New("crypto/sha256: can't retrieve hash state")
}
b = b[len(magic256):]
b, d.h[0] = consumeUint32(b)
b, d.h[1] = consumeUint32(b)
b, d.h[2] = consumeUint32(b)
b, d.h[3] = consumeUint32(b)
b, d.h[4] = consumeUint32(b)
b, d.h[5] = consumeUint32(b)
b, d.h[6] = consumeUint32(b)
b, d.h[7] = consumeUint32(b)
b = b[copy(d.x[:], b):]
_, n := consumeUint64(b)
d.nl = uint32(n << 3)
d.nh = uint32(n >> 29)
d.nx = uint32(n) % 64
return nil
}
func (h *sha224Marshal) AppendBinary(buf []byte) ([]byte, error) {
d := (*sha256State)(h.hashState())
if d == nil {
return nil, errors.New("crypto/sha256: can't retrieve hash state")
}
buf = append(buf, magic224...)
buf = appendUint32(buf, d.h[0])
buf = appendUint32(buf, d.h[1])
buf = appendUint32(buf, d.h[2])
buf = appendUint32(buf, d.h[3])
buf = appendUint32(buf, d.h[4])
buf = appendUint32(buf, d.h[5])
buf = appendUint32(buf, d.h[6])
buf = appendUint32(buf, d.h[7])
buf = append(buf, d.x[:d.nx]...)
buf = append(buf, make([]byte, len(d.x)-int(d.nx))...)
buf = appendUint64(buf, uint64(d.nl)>>3|uint64(d.nh)<<29)
return buf, nil
}
func (h *sha256Marshal) AppendBinary(buf []byte) ([]byte, error) {
d := (*sha256State)(h.hashState())
if d == nil {
return nil, errors.New("crypto/sha256: can't retrieve hash state")
}
buf = append(buf, magic256...)
buf = appendUint32(buf, d.h[0])
buf = appendUint32(buf, d.h[1])
buf = appendUint32(buf, d.h[2])
buf = appendUint32(buf, d.h[3])
buf = appendUint32(buf, d.h[4])
buf = appendUint32(buf, d.h[5])
buf = appendUint32(buf, d.h[6])
buf = appendUint32(buf, d.h[7])
buf = append(buf, d.x[:d.nx]...)
buf = append(buf, make([]byte, len(d.x)-int(d.nx))...)
buf = appendUint64(buf, uint64(d.nl)>>3|uint64(d.nh)<<29)
return buf, nil
}
// NewSHA384 returns a new SHA384 hash.
func NewSHA384() hash.Hash {
h := sha384Hash{evpHash: newEvpHash(crypto.SHA384)}
if h.marshallable {
return &sha384Marshal{h}
}
return &h
}
type sha384Hash struct {
*evpHash
out [384 / 8]byte
}
func (h *sha384Hash) Sum(in []byte) []byte {
h.sum(h.out[:])
return append(in, h.out[:]...)
}
// Clone returns a new [hash.Hash] object that is a deep clone of itself.
// The duplicate object contains all state and data contained in the
// original object at the point of duplication.
func (h *sha384Hash) Clone() (hash.Hash, error) {
c, err := h.clone()
if err != nil {
return nil, err
}
return &sha384Hash{evpHash: c}, nil
}
// NewSHA512 returns a new SHA512 hash.
func NewSHA512() hash.Hash {
h := sha512Hash{evpHash: newEvpHash(crypto.SHA512)}
if h.marshallable {
return &sha512Marshal{h}
}
return &h
}
type sha512Hash struct {
*evpHash
out [512 / 8]byte
}
func (h *sha512Hash) Sum(in []byte) []byte {
h.sum(h.out[:])
return append(in, h.out[:]...)
}
// Clone returns a new [hash.Hash] object that is a deep clone of itself.
// The duplicate object contains all state and data contained in the
// original object at the point of duplication.
func (h *sha512Hash) Clone() (hash.Hash, error) {
c, err := h.clone()
if err != nil {
return nil, err
}
return &sha512Hash{evpHash: c}, nil
}
// sha512State layout is taken from
// https://github.com/openssl/openssl/blob/0418e993c717a6863f206feaa40673a261de7395/include/openssl/sha.h#L95.
type sha512State struct {
h [8]uint64
nl, nh uint64
x [128]byte
nx uint32
}
const (
magic384 = "sha\x04"
magic512_224 = "sha\x05"
magic512_256 = "sha\x06"
magic512 = "sha\x07"
marshaledSize512 = len(magic512) + 8*8 + 128 + 8
)
type sha384Marshal struct {
sha384Hash
}
type sha512Marshal struct {
sha512Hash
}
func (h *sha384Marshal) MarshalBinary() ([]byte, error) {
buf := make([]byte, 0, marshaledSize512)
return h.AppendBinary(buf)
}
func (h *sha512Marshal) MarshalBinary() ([]byte, error) {
buf := make([]byte, 0, marshaledSize512)
return h.AppendBinary(buf)
}
func (h *sha384Marshal) UnmarshalBinary(b []byte) error {
if len(b) < len(magic512) {
return errors.New("crypto/sha512: invalid hash state identifier")
}
if string(b[:len(magic384)]) != magic384 {
return errors.New("crypto/sha512: invalid hash state identifier")
}
if len(b) != marshaledSize512 {
return errors.New("crypto/sha512: invalid hash state size")
}
d := (*sha512State)(h.hashState())
if d == nil {
return errors.New("crypto/sha512: can't retrieve hash state")
}
b = b[len(magic512):]
b, d.h[0] = consumeUint64(b)
b, d.h[1] = consumeUint64(b)
b, d.h[2] = consumeUint64(b)
b, d.h[3] = consumeUint64(b)
b, d.h[4] = consumeUint64(b)
b, d.h[5] = consumeUint64(b)
b, d.h[6] = consumeUint64(b)
b, d.h[7] = consumeUint64(b)
b = b[copy(d.x[:], b):]
_, n := consumeUint64(b)
d.nl = n << 3
d.nh = n >> 61
d.nx = uint32(n) % 128
return nil
}
func (h *sha512Marshal) UnmarshalBinary(b []byte) error {
if len(b) < len(magic512) {
return errors.New("crypto/sha512: invalid hash state identifier")
}
if string(b[:len(magic512)]) != magic512 {
return errors.New("crypto/sha512: invalid hash state identifier")
}
if len(b) != marshaledSize512 {
return errors.New("crypto/sha512: invalid hash state size")
}
d := (*sha512State)(h.hashState())
if d == nil {
return errors.New("crypto/sha512: can't retrieve hash state")
}
b = b[len(magic512):]
b, d.h[0] = consumeUint64(b)
b, d.h[1] = consumeUint64(b)
b, d.h[2] = consumeUint64(b)
b, d.h[3] = consumeUint64(b)
b, d.h[4] = consumeUint64(b)
b, d.h[5] = consumeUint64(b)
b, d.h[6] = consumeUint64(b)
b, d.h[7] = consumeUint64(b)
b = b[copy(d.x[:], b):]
_, n := consumeUint64(b)
d.nl = n << 3
d.nh = n >> 61
d.nx = uint32(n) % 128
return nil
}
func (h *sha384Marshal) AppendBinary(buf []byte) ([]byte, error) {
d := (*sha512State)(h.hashState())
if d == nil {
return nil, errors.New("crypto/sha512: can't retrieve hash state")
}
buf = append(buf, magic384...)
buf = appendUint64(buf, d.h[0])
buf = appendUint64(buf, d.h[1])
buf = appendUint64(buf, d.h[2])
buf = appendUint64(buf, d.h[3])
buf = appendUint64(buf, d.h[4])
buf = appendUint64(buf, d.h[5])
buf = appendUint64(buf, d.h[6])
buf = appendUint64(buf, d.h[7])
buf = append(buf, d.x[:d.nx]...)
buf = append(buf, make([]byte, len(d.x)-int(d.nx))...)
buf = appendUint64(buf, d.nl>>3|d.nh<<61)
return buf, nil
}
func (h *sha512Marshal) AppendBinary(buf []byte) ([]byte, error) {
d := (*sha512State)(h.hashState())
if d == nil {
return nil, errors.New("crypto/sha512: can't retrieve hash state")
}
buf = append(buf, magic512...)
buf = appendUint64(buf, d.h[0])
buf = appendUint64(buf, d.h[1])
buf = appendUint64(buf, d.h[2])
buf = appendUint64(buf, d.h[3])
buf = appendUint64(buf, d.h[4])
buf = appendUint64(buf, d.h[5])
buf = appendUint64(buf, d.h[6])
buf = appendUint64(buf, d.h[7])
buf = append(buf, d.x[:d.nx]...)
buf = append(buf, make([]byte, len(d.x)-int(d.nx))...)
buf = appendUint64(buf, d.nl>>3|d.nh<<61)
return buf, nil
}
// NewSHA3_224 returns a new SHA3-224 hash.
func NewSHA3_224() hash.Hash {
return &sha3_224Hash{
evpHash: newEvpHash(crypto.SHA3_224),
}
}
type sha3_224Hash struct {
*evpHash
out [224 / 8]byte
}
func (h *sha3_224Hash) Sum(in []byte) []byte {
h.sum(h.out[:])
return append(in, h.out[:]...)
}
// Clone returns a new [hash.Hash] object that is a deep clone of itself.
// The duplicate object contains all state and data contained in the
// original object at the point of duplication.
func (h *sha3_224Hash) Clone() (hash.Hash, error) {
c, err := h.clone()
if err != nil {
return nil, err
}
return &sha3_224Hash{evpHash: c}, nil
}
// NewSHA3_256 returns a new SHA3-256 hash.
func NewSHA3_256() hash.Hash {
return &sha3_256Hash{
evpHash: newEvpHash(crypto.SHA3_256),
}
}
type sha3_256Hash struct {
*evpHash
out [256 / 8]byte
}
func (h *sha3_256Hash) Sum(in []byte) []byte {
h.sum(h.out[:])
return append(in, h.out[:]...)
}
// Clone returns a new [hash.Hash] object that is a deep clone of itself.
// The duplicate object contains all state and data contained in the
// original object at the point of duplication.
func (h *sha3_256Hash) Clone() (hash.Hash, error) {
c, err := h.clone()
if err != nil {
return nil, err
}
return &sha3_256Hash{evpHash: c}, nil
}
// NewSHA3_384 returns a new SHA3-384 hash.
func NewSHA3_384() hash.Hash {
return &sha3_384Hash{
evpHash: newEvpHash(crypto.SHA3_384),
}
}
type sha3_384Hash struct {
*evpHash
out [384 / 8]byte
}
func (h *sha3_384Hash) Sum(in []byte) []byte {
h.sum(h.out[:])
return append(in, h.out[:]...)
}
// Clone returns a new [hash.Hash] object that is a deep clone of itself.
// The duplicate object contains all state and data contained in the
// original object at the point of duplication.
func (h *sha3_384Hash) Clone() (hash.Hash, error) {
c, err := h.clone()
if err != nil {
return nil, err
}
return &sha3_384Hash{evpHash: c}, nil
}
// NewSHA3_512 returns a new SHA3-512 hash.
func NewSHA3_512() hash.Hash {
return &sha3_512Hash{
evpHash: newEvpHash(crypto.SHA3_512),
}
}
type sha3_512Hash struct {
*evpHash
out [512 / 8]byte
}
func (h *sha3_512Hash) Sum(in []byte) []byte {
h.sum(h.out[:])
return append(in, h.out[:]...)
}
// Clone returns a new [hash.Hash] object that is a deep clone of itself.
// The duplicate object contains all state and data contained in the
// original object at the point of duplication.