Documentation ¶
Overview ¶
Package crypto collects common cryptographic constants.
Index ¶
Constants ¶
This section is empty.
Variables ¶
This section is empty.
Functions ¶
func RegisterHash ¶
RegisterHash registers a function that returns a new instance of the given hash function. This is intended to be called from the init function in packages that implement hash functions.
Types ¶
type Decrypter ¶
type Decrypter interface { // Public returns the public key corresponding to the opaque, // private key. Public() PublicKey // Decrypt decrypts msg. The opts argument should be appropriate for // the primitive used. See the documentation in each implementation for // details. Decrypt(rand io.Reader, msg []byte, opts DecrypterOpts) (plaintext []byte, err error) }
Decrypter is an interface for an opaque private key that can be used for asymmetric decryption operations. An example would be an RSA key kept in a hardware module.
type DecrypterOpts ¶
type DecrypterOpts any
type Hash ¶
type Hash uint
Hash identifies a cryptographic hash function that is implemented in another package.
const ( MD4 Hash = 1 + iota // import golang.org/x/crypto/md4 MD5 // import crypto/md5 SHA1 // import crypto/sha1 SHA224 // import crypto/sha256 SHA256 // import crypto/sha256 SHA384 // import crypto/sha512 SHA512 // import crypto/sha512 MD5SHA1 // no implementation; MD5+SHA1 used for TLS RSA RIPEMD160 // import golang.org/x/crypto/ripemd160 SHA3_224 // import golang.org/x/crypto/sha3 SHA3_256 // import golang.org/x/crypto/sha3 SHA3_384 // import golang.org/x/crypto/sha3 SHA3_512 // import golang.org/x/crypto/sha3 SHA512_224 // import crypto/sha512 SHA512_256 // import crypto/sha512 BLAKE2s_256 // import golang.org/x/crypto/blake2s BLAKE2b_256 // import golang.org/x/crypto/blake2b BLAKE2b_384 // import golang.org/x/crypto/blake2b BLAKE2b_512 // import golang.org/x/crypto/blake2b )
func (Hash) Available ¶
Available reports whether the given hash function is linked into the binary.
func (Hash) New ¶
New returns a new hash.Hash calculating the given hash function. New panics if the hash function is not linked into the binary.
type PrivateKey ¶
type PrivateKey any
PrivateKey represents a private key using an unspecified algorithm.
Although this type is an empty interface for backwards compatibility reasons, all private key types in the standard library implement the following interface
interface{ Public() crypto.PublicKey Equal(x crypto.PrivateKey) bool }
as well as purposespecific interfaces such as Signer and Decrypter, which can be used for increased type safety within applications.
type PublicKey ¶
type PublicKey any
PublicKey represents a public key using an unspecified algorithm.
Although this type is an empty interface for backwards compatibility reasons, all public key types in the standard library implement the following interface
interface{ Equal(x crypto.PublicKey) bool }
which can be used for increased type safety within applications.
type Signer ¶
type Signer interface { // Public returns the public key corresponding to the opaque, // private key. Public() PublicKey // Sign signs digest with the private key, possibly using entropy from // rand. For an RSA key, the resulting signature should be either a // PKCS #1 v1.5 or PSS signature (as indicated by opts). For an (EC)DSA // key, it should be a DERserialised, ASN.1 signature structure. // // Hash implements the SignerOpts interface and, in most cases, one can // simply pass in the hash function used as opts. Sign may also attempt // to type assert opts to other types in order to obtain algorithm // specific values. See the documentation in each package for details. // // Note that when a signature of a hash of a larger message is needed, // the caller is responsible for hashing the larger message and passing // the hash (as digest) and the hash function (as opts) to Sign. Sign(rand io.Reader, digest []byte, opts SignerOpts) (signature []byte, err error) }
Signer is an interface for an opaque private key that can be used for signing operations. For example, an RSA key kept in a hardware module.
type SignerOpts ¶
type SignerOpts interface { // HashFunc returns an identifier for the hash function used to produce // the message passed to Signer.Sign, or else zero to indicate that no // hashing was done. HashFunc() Hash }
SignerOpts contains options for signing with a Signer.
Directories ¶
Path  Synopsis 

Package aes implements AES encryption (formerly Rijndael), as defined in U.S. Federal Information Processing Standards Publication 197.

Package aes implements AES encryption (formerly Rijndael), as defined in U.S. Federal Information Processing Standards Publication 197. 
Package cipher implements standard block cipher modes that can be wrapped around lowlevel block cipher implementations.

Package cipher implements standard block cipher modes that can be wrapped around lowlevel block cipher implementations. 
Package des implements the Data Encryption Standard (DES) and the Triple Data Encryption Algorithm (TDEA) as defined in U.S. Federal Information Processing Standards Publication 463.

Package des implements the Data Encryption Standard (DES) and the Triple Data Encryption Algorithm (TDEA) as defined in U.S. Federal Information Processing Standards Publication 463. 
Package dsa implements the Digital Signature Algorithm, as defined in FIPS 1863.

Package dsa implements the Digital Signature Algorithm, as defined in FIPS 1863. 
Package ecdh implements Elliptic Curve DiffieHellman over NIST curves and Curve25519.

Package ecdh implements Elliptic Curve DiffieHellman over NIST curves and Curve25519. 
Package ecdsa implements the Elliptic Curve Digital Signature Algorithm, as defined in FIPS 1864 and SEC 1, Version 2.0.

Package ecdsa implements the Elliptic Curve Digital Signature Algorithm, as defined in FIPS 1864 and SEC 1, Version 2.0. 
Package ed25519 implements the Ed25519 signature algorithm.

Package ed25519 implements the Ed25519 signature algorithm. 
Package elliptic implements the standard NIST P224, P256, P384, and P521 elliptic curves over prime fields.

Package elliptic implements the standard NIST P224, P256, P384, and P521 elliptic curves over prime fields. 
Package hmac implements the KeyedHash Message Authentication Code (HMAC) as defined in U.S. Federal Information Processing Standards Publication 198.

Package hmac implements the KeyedHash Message Authentication Code (HMAC) as defined in U.S. Federal Information Processing Standards Publication 198. 
internal


alias
Package alias implements memory aliasing tests.

Package alias implements memory aliasing tests. 
boring
Package boring provides access to BoringCrypto implementation functions.

Package boring provides access to BoringCrypto implementation functions. 
boring/bcache
Package bcache implements a GCfriendly cache (see [Cache]) for BoringCrypto.

Package bcache implements a GCfriendly cache (see [Cache]) for BoringCrypto. 
boring/sig
Package sig holds “code signatures” that can be called and will result in certain code sequences being linked into the final binary.

Package sig holds “code signatures” that can be called and will result in certain code sequences being linked into the final binary. 
edwards25519
Package edwards25519 implements group logic for the twisted Edwards curve

Package edwards25519 implements group logic for the twisted Edwards curve 
edwards25519/field
Package field implements fast arithmetic modulo 2^25519.

Package field implements fast arithmetic modulo 2^25519. 
nistec
Package nistec implements the NIST P elliptic curves from FIPS 1864.

Package nistec implements the NIST P elliptic curves from FIPS 1864. 
randutil
Package randutil contains internal randomness utilities for various crypto packages.

Package randutil contains internal randomness utilities for various crypto packages. 
Package md5 implements the MD5 hash algorithm as defined in RFC 1321.

Package md5 implements the MD5 hash algorithm as defined in RFC 1321. 
Package rand implements a cryptographically secure random number generator.

Package rand implements a cryptographically secure random number generator. 
Package rc4 implements RC4 encryption, as defined in Bruce Schneier's Applied Cryptography.

Package rc4 implements RC4 encryption, as defined in Bruce Schneier's Applied Cryptography. 
Package rsa implements RSA encryption as specified in PKCS #1 and RFC 8017.

Package rsa implements RSA encryption as specified in PKCS #1 and RFC 8017. 
Package sha1 implements the SHA1 hash algorithm as defined in RFC 3174.

Package sha1 implements the SHA1 hash algorithm as defined in RFC 3174. 
Package sha256 implements the SHA224 and SHA256 hash algorithms as defined in FIPS 1804.

Package sha256 implements the SHA224 and SHA256 hash algorithms as defined in FIPS 1804. 
Package sha512 implements the SHA384, SHA512, SHA512/224, and SHA512/256 hash algorithms as defined in FIPS 1804.

Package sha512 implements the SHA384, SHA512, SHA512/224, and SHA512/256 hash algorithms as defined in FIPS 1804. 
Package subtle implements functions that are often useful in cryptographic code but require careful thought to use correctly.

Package subtle implements functions that are often useful in cryptographic code but require careful thought to use correctly. 
Package tls partially implements TLS 1.2, as specified in RFC 5246, and TLS 1.3, as specified in RFC 8446.

Package tls partially implements TLS 1.2, as specified in RFC 5246, and TLS 1.3, as specified in RFC 8446. 
Package x509 implements a subset of the X.509 standard.

Package x509 implements a subset of the X.509 standard. 
internal/macos
Package macOS provides cgoless wrappers for Core Foundation and Security.framework, similarly to how package syscall provides access to libSystem.dylib.

Package macOS provides cgoless wrappers for Core Foundation and Security.framework, similarly to how package syscall provides access to libSystem.dylib. 
pkix
Package pkix contains shared, low level structures used for ASN.1 parsing and serialization of X.509 certificates, CRL and OCSP.

Package pkix contains shared, low level structures used for ASN.1 parsing and serialization of X.509 certificates, CRL and OCSP. 