robocar-steering-tflite-edg.../vendor/github.com/opencontainers/go-digest/algorithm.go

194 lines
5.7 KiB
Go

// Copyright 2019, 2020 OCI Contributors
// Copyright 2017 Docker, Inc.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// https://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
package digest
import (
"crypto"
"fmt"
"hash"
"io"
"regexp"
)
// Algorithm identifies and implementation of a digester by an identifier.
// Note the that this defines both the hash algorithm used and the string
// encoding.
type Algorithm string
// supported digest types
const (
SHA256 Algorithm = "sha256" // sha256 with hex encoding (lower case only)
SHA384 Algorithm = "sha384" // sha384 with hex encoding (lower case only)
SHA512 Algorithm = "sha512" // sha512 with hex encoding (lower case only)
// Canonical is the primary digest algorithm used with the distribution
// project. Other digests may be used but this one is the primary storage
// digest.
Canonical = SHA256
)
var (
// TODO(stevvooe): Follow the pattern of the standard crypto package for
// registration of digests. Effectively, we are a registerable set and
// common symbol access.
// algorithms maps values to hash.Hash implementations. Other algorithms
// may be available but they cannot be calculated by the digest package.
algorithms = map[Algorithm]crypto.Hash{
SHA256: crypto.SHA256,
SHA384: crypto.SHA384,
SHA512: crypto.SHA512,
}
// anchoredEncodedRegexps contains anchored regular expressions for hex-encoded digests.
// Note that /A-F/ disallowed.
anchoredEncodedRegexps = map[Algorithm]*regexp.Regexp{
SHA256: regexp.MustCompile(`^[a-f0-9]{64}$`),
SHA384: regexp.MustCompile(`^[a-f0-9]{96}$`),
SHA512: regexp.MustCompile(`^[a-f0-9]{128}$`),
}
)
// Available returns true if the digest type is available for use. If this
// returns false, Digester and Hash will return nil.
func (a Algorithm) Available() bool {
h, ok := algorithms[a]
if !ok {
return false
}
// check availability of the hash, as well
return h.Available()
}
func (a Algorithm) String() string {
return string(a)
}
// Size returns number of bytes returned by the hash.
func (a Algorithm) Size() int {
h, ok := algorithms[a]
if !ok {
return 0
}
return h.Size()
}
// Set implemented to allow use of Algorithm as a command line flag.
func (a *Algorithm) Set(value string) error {
if value == "" {
*a = Canonical
} else {
// just do a type conversion, support is queried with Available.
*a = Algorithm(value)
}
if !a.Available() {
return ErrDigestUnsupported
}
return nil
}
// Digester returns a new digester for the specified algorithm. If the algorithm
// does not have a digester implementation, nil will be returned. This can be
// checked by calling Available before calling Digester.
func (a Algorithm) Digester() Digester {
return &digester{
alg: a,
hash: a.Hash(),
}
}
// Hash returns a new hash as used by the algorithm. If not available, the
// method will panic. Check Algorithm.Available() before calling.
func (a Algorithm) Hash() hash.Hash {
if !a.Available() {
// Empty algorithm string is invalid
if a == "" {
panic(fmt.Sprintf("empty digest algorithm, validate before calling Algorithm.Hash()"))
}
// NOTE(stevvooe): A missing hash is usually a programming error that
// must be resolved at compile time. We don't import in the digest
// package to allow users to choose their hash implementation (such as
// when using stevvooe/resumable or a hardware accelerated package).
//
// Applications that may want to resolve the hash at runtime should
// call Algorithm.Available before call Algorithm.Hash().
panic(fmt.Sprintf("%v not available (make sure it is imported)", a))
}
return algorithms[a].New()
}
// Encode encodes the raw bytes of a digest, typically from a hash.Hash, into
// the encoded portion of the digest.
func (a Algorithm) Encode(d []byte) string {
// TODO(stevvooe): Currently, all algorithms use a hex encoding. When we
// add support for back registration, we can modify this accordingly.
return fmt.Sprintf("%x", d)
}
// FromReader returns the digest of the reader using the algorithm.
func (a Algorithm) FromReader(rd io.Reader) (Digest, error) {
digester := a.Digester()
if _, err := io.Copy(digester.Hash(), rd); err != nil {
return "", err
}
return digester.Digest(), nil
}
// FromBytes digests the input and returns a Digest.
func (a Algorithm) FromBytes(p []byte) Digest {
digester := a.Digester()
if _, err := digester.Hash().Write(p); err != nil {
// Writes to a Hash should never fail. None of the existing
// hash implementations in the stdlib or hashes vendored
// here can return errors from Write. Having a panic in this
// condition instead of having FromBytes return an error value
// avoids unnecessary error handling paths in all callers.
panic("write to hash function returned error: " + err.Error())
}
return digester.Digest()
}
// FromString digests the string input and returns a Digest.
func (a Algorithm) FromString(s string) Digest {
return a.FromBytes([]byte(s))
}
// Validate validates the encoded portion string
func (a Algorithm) Validate(encoded string) error {
r, ok := anchoredEncodedRegexps[a]
if !ok {
return ErrDigestUnsupported
}
// Digests much always be hex-encoded, ensuring that their hex portion will
// always be size*2
if a.Size()*2 != len(encoded) {
return ErrDigestInvalidLength
}
if r.MatchString(encoded) {
return nil
}
return ErrDigestInvalidFormat
}