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"""JSON Web Algorithms. https://tools.ietf.org/html/draft-ietf-jose-json-web-algorithms-40 """ import abc import logging from typing import Dict, Any, Callable import cryptography.exceptions from cryptography.hazmat.backends import default_backend from cryptography.hazmat.primitives import hashes from cryptography.hazmat.primitives import hmac from cryptography.hazmat.primitives.asymmetric import padding, ec, rsa from cryptography.hazmat.primitives.asymmetric.utils import decode_dss_signature from cryptography.hazmat.primitives.asymmetric.utils import encode_dss_signature from cryptography.hazmat.primitives.hashes import HashAlgorithm from josepy import errors, interfaces, jwk from collections.abc import Hashable logger = logging.getLogger(__name__) class JWA(interfaces.JSONDeSerializable): # pylint: disable=abstract-method # pylint: disable=too-few-public-methods # for some reason disable=abstract-method has to be on the line # above... """JSON Web Algorithm.""" class JWASignature(JWA, Hashable): """Base class for JSON Web Signature Algorithms.""" SIGNATURES: Dict[str, 'JWASignature'] = {} kty: Any def __init__(self, name: str) -> None: self.name = name def __eq__(self, other: Any) -> bool: if not isinstance(other, JWASignature): return NotImplemented return self.name == other.name def __hash__(self) -> int: return hash((self.__class__, self.name)) @classmethod def register(cls, signature_cls: 'JWASignature') -> 'JWASignature': """Register class for JSON deserialization.""" cls.SIGNATURES[signature_cls.name] = signature_cls return signature_cls def to_partial_json(self) -> Any: return self.name @classmethod def from_json(cls, jobj: Any) -> 'JWASignature': return cls.SIGNATURES[jobj] @abc.abstractmethod def sign(self, key: Any, msg: bytes) -> bytes: # pragma: no cover """Sign the ``msg`` using ``key``.""" raise NotImplementedError() @abc.abstractmethod def verify(self, key: Any, msg: bytes, sig: bytes) -> bool: # pragma: no cover """Verify the ``msg`` and ``sig`` using ``key``.""" raise NotImplementedError() def __repr__(self) -> str: return self.name class _JWAHS(JWASignature): kty = jwk.JWKOct def __init__(self, name: str, hash_: Callable[[], HashAlgorithm]): super().__init__(name) self.hash = hash_() def sign(self, key: bytes, msg: bytes) -> bytes: signer = hmac.HMAC(key, self.hash, backend=default_backend()) signer.update(msg) return signer.finalize() def verify(self, key: bytes, msg: bytes, sig: bytes) -> bool: verifier = hmac.HMAC(key, self.hash, backend=default_backend()) verifier.update(msg) try: verifier.verify(sig) except cryptography.exceptions.InvalidSignature as error: logger.debug(error, exc_info=True) return False else: return True class _JWARSA: kty = jwk.JWKRSA padding: Any = NotImplemented hash: HashAlgorithm = NotImplemented def sign(self, key: rsa.RSAPrivateKey, msg: bytes) -> bytes: """Sign the ``msg`` using ``key``.""" # If cryptography library supports new style api (v1.4 and later) new_api = hasattr(key, "sign") try: if new_api: return key.sign(msg, self.padding, self.hash) signer = key.signer(self.padding, self.hash) except AttributeError as error: logger.debug(error, exc_info=True) raise errors.Error("Public key cannot be used for signing") except ValueError as error: # digest too large logger.debug(error, exc_info=True) raise errors.Error(str(error)) signer.update(msg) try: return signer.finalize() except ValueError as error: logger.debug(error, exc_info=True) raise errors.Error(str(error)) def verify(self, key: rsa.RSAPublicKey, msg: bytes, sig: bytes) -> bool: """Verify the ``msg` and ``sig`` using ``key``.""" # If cryptography library supports new style api (v1.4 and later) new_api = hasattr(key, "verify") if not new_api: verifier = key.verifier(sig, self.padding, self.hash) verifier.update(msg) try: if new_api: key.verify(sig, msg, self.padding, self.hash) else: verifier.verify() except cryptography.exceptions.InvalidSignature as error: logger.debug(error, exc_info=True) return False else: return True class _JWARS(_JWARSA, JWASignature): def __init__(self, name: str, hash_: Callable[[], HashAlgorithm]) -> None: super().__init__(name) self.padding = padding.PKCS1v15() self.hash = hash_() class _JWAPS(_JWARSA, JWASignature): def __init__(self, name: str, hash_: Callable[[], HashAlgorithm]) -> None: super().__init__(name) self.padding = padding.PSS( mgf=padding.MGF1(hash_()), salt_length=padding.PSS.MAX_LENGTH) self.hash = hash_() class _JWAEC(JWASignature): kty = jwk.JWKEC def __init__(self, name: str, hash_: Callable[[], HashAlgorithm]): super().__init__(name) self.hash = hash_() def sign(self, key: ec.EllipticCurvePrivateKey, msg: bytes) -> bytes: """Sign the ``msg`` using ``key``.""" sig = self._sign(key, msg) dr, ds = decode_dss_signature(sig) length = jwk.JWKEC.expected_length_for_curve(key.curve) return (dr.to_bytes(length=length, byteorder='big') + ds.to_bytes(length=length, byteorder='big')) def _sign(self, key: ec.EllipticCurvePrivateKey, msg: bytes) -> bytes: # If cryptography library supports new style api (v1.4 and later) new_api = hasattr(key, 'sign') try: if new_api: return key.sign(msg, ec.ECDSA(self.hash)) signer = key.signer(ec.ECDSA(self.hash)) except AttributeError as error: logger.debug(error, exc_info=True) raise errors.Error('Public key cannot be used for signing') except ValueError as error: # digest too large logger.debug(error, exc_info=True) raise errors.Error(str(error)) signer.update(msg) try: return signer.finalize() except ValueError as error: logger.debug(error, exc_info=True) raise errors.Error(str(error)) def verify(self, key: ec.EllipticCurvePublicKey, msg: bytes, sig: bytes) -> bool: """Verify the ``msg` and ``sig`` using ``key``.""" rlen = jwk.JWKEC.expected_length_for_curve(key.curve) if len(sig) != 2 * rlen: # Format error - rfc7518 - 3.4 … MUST NOT be shortened to omit any leading zero octets return False asn1sig = encode_dss_signature( int.from_bytes(sig[0:rlen], byteorder='big'), int.from_bytes(sig[rlen:], byteorder='big') ) return self._verify(key, msg, asn1sig) def _verify(self, key: ec.EllipticCurvePublicKey, msg: bytes, asn1sig: bytes) -> bool: # If cryptography library supports new style api (v1.4 and later) new_api = hasattr(key, 'verify') if not new_api: verifier = key.verifier(asn1sig, ec.ECDSA(self.hash)) verifier.update(msg) try: if new_api: key.verify(asn1sig, msg, ec.ECDSA(self.hash)) else: verifier.verify() except cryptography.exceptions.InvalidSignature as error: logger.debug(error, exc_info=True) return False else: return True #: HMAC using SHA-256 HS256 = JWASignature.register(_JWAHS('HS256', hashes.SHA256)) #: HMAC using SHA-384 HS384 = JWASignature.register(_JWAHS('HS384', hashes.SHA384)) #: HMAC using SHA-512 HS512 = JWASignature.register(_JWAHS('HS512', hashes.SHA512)) #: RSASSA-PKCS-v1_5 using SHA-256 RS256 = JWASignature.register(_JWARS('RS256', hashes.SHA256)) #: RSASSA-PKCS-v1_5 using SHA-384 RS384 = JWASignature.register(_JWARS('RS384', hashes.SHA384)) #: RSASSA-PKCS-v1_5 using SHA-512 RS512 = JWASignature.register(_JWARS('RS512', hashes.SHA512)) #: RSASSA-PSS using SHA-256 and MGF1 with SHA-256 PS256 = JWASignature.register(_JWAPS('PS256', hashes.SHA256)) #: RSASSA-PSS using SHA-384 and MGF1 with SHA-384 PS384 = JWASignature.register(_JWAPS('PS384', hashes.SHA384)) #: RSASSA-PSS using SHA-512 and MGF1 with SHA-512 PS512 = JWASignature.register(_JWAPS('PS512', hashes.SHA512)) #: ECDSA using P-256 and SHA-256 ES256 = JWASignature.register(_JWAEC('ES256', hashes.SHA256)) #: ECDSA using P-384 and SHA-384 ES384 = JWASignature.register(_JWAEC('ES384', hashes.SHA384)) #: ECDSA using P-521 and SHA-512 ES512 = JWASignature.register(_JWAEC('ES512', hashes.SHA512))