#!/usr/bin/env python3 """Generate test data for PSA cryptographic mechanisms. With no arguments, generate all test data. With non-option arguments, generate only the specified files. """ # Copyright The Mbed TLS Contributors # SPDX-License-Identifier: Apache-2.0 # # 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 # # http://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. import argparse import enum import os import posixpath import re import sys from typing import Callable, Dict, FrozenSet, Iterable, Iterator, List, Optional, TypeVar import scripts_path # pylint: disable=unused-import from mbedtls_dev import build_tree from mbedtls_dev import crypto_knowledge from mbedtls_dev import macro_collector from mbedtls_dev import psa_storage from mbedtls_dev import test_case T = TypeVar('T') #pylint: disable=invalid-name def psa_want_symbol(name: str) -> str: """Return the PSA_WANT_xxx symbol associated with a PSA crypto feature.""" if name.startswith('PSA_'): return name[:4] + 'WANT_' + name[4:] else: raise ValueError('Unable to determine the PSA_WANT_ symbol for ' + name) def finish_family_dependency(dep: str, bits: int) -> str: """Finish dep if it's a family dependency symbol prefix. A family dependency symbol prefix is a PSA_WANT_ symbol that needs to be qualified by the key size. If dep is such a symbol, finish it by adjusting the prefix and appending the key size. Other symbols are left unchanged. """ return re.sub(r'_FAMILY_(.*)', r'_\1_' + str(bits), dep) def finish_family_dependencies(dependencies: List[str], bits: int) -> List[str]: """Finish any family dependency symbol prefixes. Apply `finish_family_dependency` to each element of `dependencies`. """ return [finish_family_dependency(dep, bits) for dep in dependencies] SYMBOLS_WITHOUT_DEPENDENCY = frozenset([ 'PSA_ALG_AEAD_WITH_AT_LEAST_THIS_LENGTH_TAG', # modifier, only in policies 'PSA_ALG_AEAD_WITH_SHORTENED_TAG', # modifier 'PSA_ALG_ANY_HASH', # only in policies 'PSA_ALG_AT_LEAST_THIS_LENGTH_MAC', # modifier, only in policies 'PSA_ALG_KEY_AGREEMENT', # chaining 'PSA_ALG_TRUNCATED_MAC', # modifier ]) def automatic_dependencies(*expressions: str) -> List[str]: """Infer dependencies of a test case by looking for PSA_xxx symbols. The arguments are strings which should be C expressions. Do not use string literals or comments as this function is not smart enough to skip them. """ used = set() for expr in expressions: used.update(re.findall(r'PSA_(?:ALG|ECC_FAMILY|KEY_TYPE)_\w+', expr)) used.difference_update(SYMBOLS_WITHOUT_DEPENDENCY) return sorted(psa_want_symbol(name) for name in used) # A temporary hack: at the time of writing, not all dependency symbols # are implemented yet. Skip test cases for which the dependency symbols are # not available. Once all dependency symbols are available, this hack must # be removed so that a bug in the dependency symbols proprely leads to a test # failure. def read_implemented_dependencies(filename: str) -> FrozenSet[str]: return frozenset(symbol for line in open(filename) for symbol in re.findall(r'\bPSA_WANT_\w+\b', line)) _implemented_dependencies = None #type: Optional[FrozenSet[str]] #pylint: disable=invalid-name def hack_dependencies_not_implemented(dependencies: List[str]) -> None: global _implemented_dependencies #pylint: disable=global-statement,invalid-name if _implemented_dependencies is None: _implemented_dependencies = \ read_implemented_dependencies('include/psa/crypto_config.h') if not all((dep.lstrip('!') in _implemented_dependencies or 'PSA_WANT' not in dep) for dep in dependencies): dependencies.append('DEPENDENCY_NOT_IMPLEMENTED_YET') class Information: """Gather information about PSA constructors.""" def __init__(self) -> None: self.constructors = self.read_psa_interface() @staticmethod def remove_unwanted_macros( constructors: macro_collector.PSAMacroEnumerator ) -> None: # Mbed TLS doesn't support finite-field DH yet and will not support # finite-field DSA. Don't attempt to generate any related test case. constructors.key_types.discard('PSA_KEY_TYPE_DH_KEY_PAIR') constructors.key_types.discard('PSA_KEY_TYPE_DH_PUBLIC_KEY') constructors.key_types.discard('PSA_KEY_TYPE_DSA_KEY_PAIR') constructors.key_types.discard('PSA_KEY_TYPE_DSA_PUBLIC_KEY') def read_psa_interface(self) -> macro_collector.PSAMacroEnumerator: """Return the list of known key types, algorithms, etc.""" constructors = macro_collector.InputsForTest() header_file_names = ['include/psa/crypto_values.h', 'include/psa/crypto_extra.h'] test_suites = ['tests/suites/test_suite_psa_crypto_metadata.data'] for header_file_name in header_file_names: constructors.parse_header(header_file_name) for test_cases in test_suites: constructors.parse_test_cases(test_cases) self.remove_unwanted_macros(constructors) constructors.gather_arguments() return constructors def test_case_for_key_type_not_supported( verb: str, key_type: str, bits: int, dependencies: List[str], *args: str, param_descr: str = '' ) -> test_case.TestCase: """Return one test case exercising a key creation method for an unsupported key type or size. """ hack_dependencies_not_implemented(dependencies) tc = test_case.TestCase() short_key_type = crypto_knowledge.short_expression(key_type) adverb = 'not' if dependencies else 'never' if param_descr: adverb = param_descr + ' ' + adverb tc.set_description('PSA {} {} {}-bit {} supported' .format(verb, short_key_type, bits, adverb)) tc.set_dependencies(dependencies) tc.set_function(verb + '_not_supported') tc.set_arguments([key_type] + list(args)) return tc class NotSupported: """Generate test cases for when something is not supported.""" def __init__(self, info: Information) -> None: self.constructors = info.constructors ALWAYS_SUPPORTED = frozenset([ 'PSA_KEY_TYPE_DERIVE', 'PSA_KEY_TYPE_RAW_DATA', ]) def test_cases_for_key_type_not_supported( self, kt: crypto_knowledge.KeyType, param: Optional[int] = None, param_descr: str = '', ) -> Iterator[test_case.TestCase]: """Return test cases exercising key creation when the given type is unsupported. If param is present and not None, emit test cases conditioned on this parameter not being supported. If it is absent or None, emit test cases conditioned on the base type not being supported. """ if kt.name in self.ALWAYS_SUPPORTED: # Don't generate test cases for key types that are always supported. # They would be skipped in all configurations, which is noise. return import_dependencies = [('!' if param is None else '') + psa_want_symbol(kt.name)] if kt.params is not None: import_dependencies += [('!' if param == i else '') + psa_want_symbol(sym) for i, sym in enumerate(kt.params)] if kt.name.endswith('_PUBLIC_KEY'): generate_dependencies = [] else: generate_dependencies = import_dependencies for bits in kt.sizes_to_test(): yield test_case_for_key_type_not_supported( 'import', kt.expression, bits, finish_family_dependencies(import_dependencies, bits), test_case.hex_string(kt.key_material(bits)), param_descr=param_descr, ) if not generate_dependencies and param is not None: # If generation is impossible for this key type, rather than # supported or not depending on implementation capabilities, # only generate the test case once. continue # For public key we expect that key generation fails with # INVALID_ARGUMENT. It is handled by KeyGenerate class. if not kt.is_public(): yield test_case_for_key_type_not_supported( 'generate', kt.expression, bits, finish_family_dependencies(generate_dependencies, bits), str(bits), param_descr=param_descr, ) # To be added: derive ECC_KEY_TYPES = ('PSA_KEY_TYPE_ECC_KEY_PAIR', 'PSA_KEY_TYPE_ECC_PUBLIC_KEY') def test_cases_for_not_supported(self) -> Iterator[test_case.TestCase]: """Generate test cases that exercise the creation of keys of unsupported types.""" for key_type in sorted(self.constructors.key_types): if key_type in self.ECC_KEY_TYPES: continue kt = crypto_knowledge.KeyType(key_type) yield from self.test_cases_for_key_type_not_supported(kt) for curve_family in sorted(self.constructors.ecc_curves): for constr in self.ECC_KEY_TYPES: kt = crypto_knowledge.KeyType(constr, [curve_family]) yield from self.test_cases_for_key_type_not_supported( kt, param_descr='type') yield from self.test_cases_for_key_type_not_supported( kt, 0, param_descr='curve') def test_case_for_key_generation( key_type: str, bits: int, dependencies: List[str], *args: str, result: str = '' ) -> test_case.TestCase: """Return one test case exercising a key generation. """ hack_dependencies_not_implemented(dependencies) tc = test_case.TestCase() short_key_type = crypto_knowledge.short_expression(key_type) tc.set_description('PSA {} {}-bit' .format(short_key_type, bits)) tc.set_dependencies(dependencies) tc.set_function('generate_key') tc.set_arguments([key_type] + list(args) + [result]) return tc class KeyGenerate: """Generate positive and negative (invalid argument) test cases for key generation.""" def __init__(self, info: Information) -> None: self.constructors = info.constructors ECC_KEY_TYPES = ('PSA_KEY_TYPE_ECC_KEY_PAIR', 'PSA_KEY_TYPE_ECC_PUBLIC_KEY') @staticmethod def test_cases_for_key_type_key_generation( kt: crypto_knowledge.KeyType ) -> Iterator[test_case.TestCase]: """Return test cases exercising key generation. All key types can be generated except for public keys. For public key PSA_ERROR_INVALID_ARGUMENT status is expected. """ result = 'PSA_SUCCESS' import_dependencies = [psa_want_symbol(kt.name)] if kt.params is not None: import_dependencies += [psa_want_symbol(sym) for i, sym in enumerate(kt.params)] if kt.name.endswith('_PUBLIC_KEY'): # The library checks whether the key type is a public key generically, # before it reaches a point where it needs support for the specific key # type, so it returns INVALID_ARGUMENT for unsupported public key types. generate_dependencies = [] result = 'PSA_ERROR_INVALID_ARGUMENT' else: generate_dependencies = import_dependencies if kt.name == 'PSA_KEY_TYPE_RSA_KEY_PAIR': generate_dependencies.append("MBEDTLS_GENPRIME") for bits in kt.sizes_to_test(): yield test_case_for_key_generation( kt.expression, bits, finish_family_dependencies(generate_dependencies, bits), str(bits), result ) def test_cases_for_key_generation(self) -> Iterator[test_case.TestCase]: """Generate test cases that exercise the generation of keys.""" for key_type in sorted(self.constructors.key_types): if key_type in self.ECC_KEY_TYPES: continue kt = crypto_knowledge.KeyType(key_type) yield from self.test_cases_for_key_type_key_generation(kt) for curve_family in sorted(self.constructors.ecc_curves): for constr in self.ECC_KEY_TYPES: kt = crypto_knowledge.KeyType(constr, [curve_family]) yield from self.test_cases_for_key_type_key_generation(kt) class OpFail: """Generate test cases for operations that must fail.""" #pylint: disable=too-few-public-methods class Reason(enum.Enum): NOT_SUPPORTED = 0 INVALID = 1 INCOMPATIBLE = 2 PUBLIC = 3 def __init__(self, info: Information) -> None: self.constructors = info.constructors key_type_expressions = self.constructors.generate_expressions( sorted(self.constructors.key_types) ) self.key_types = [crypto_knowledge.KeyType(kt_expr) for kt_expr in key_type_expressions] def make_test_case( self, alg: crypto_knowledge.Algorithm, category: crypto_knowledge.AlgorithmCategory, reason: 'Reason', kt: Optional[crypto_knowledge.KeyType] = None, not_deps: FrozenSet[str] = frozenset(), ) -> test_case.TestCase: """Construct a failure test case for a one-key or keyless operation.""" #pylint: disable=too-many-arguments,too-many-locals tc = test_case.TestCase() pretty_alg = alg.short_expression() if reason == self.Reason.NOT_SUPPORTED: short_deps = [re.sub(r'PSA_WANT_ALG_', r'', dep) for dep in not_deps] pretty_reason = '!' + '&'.join(sorted(short_deps)) else: pretty_reason = reason.name.lower() if kt: key_type = kt.expression pretty_type = kt.short_expression() else: key_type = '' pretty_type = '' tc.set_description('PSA {} {}: {}{}' .format(category.name.lower(), pretty_alg, pretty_reason, ' with ' + pretty_type if pretty_type else '')) dependencies = automatic_dependencies(alg.base_expression, key_type) for i, dep in enumerate(dependencies): if dep in not_deps: dependencies[i] = '!' + dep tc.set_dependencies(dependencies) tc.set_function(category.name.lower() + '_fail') arguments = [] if kt: key_material = kt.key_material(kt.sizes_to_test()[0]) arguments += [key_type, test_case.hex_string(key_material)] arguments.append(alg.expression) if category.is_asymmetric(): arguments.append('1' if reason == self.Reason.PUBLIC else '0') error = ('NOT_SUPPORTED' if reason == self.Reason.NOT_SUPPORTED else 'INVALID_ARGUMENT') arguments.append('PSA_ERROR_' + error) tc.set_arguments(arguments) return tc def no_key_test_cases( self, alg: crypto_knowledge.Algorithm, category: crypto_knowledge.AlgorithmCategory, ) -> Iterator[test_case.TestCase]: """Generate failure test cases for keyless operations with the specified algorithm.""" if alg.can_do(category): # Compatible operation, unsupported algorithm for dep in automatic_dependencies(alg.base_expression): yield self.make_test_case(alg, category, self.Reason.NOT_SUPPORTED, not_deps=frozenset([dep])) else: # Incompatible operation, supported algorithm yield self.make_test_case(alg, category, self.Reason.INVALID) def one_key_test_cases( self, alg: crypto_knowledge.Algorithm, category: crypto_knowledge.AlgorithmCategory, ) -> Iterator[test_case.TestCase]: """Generate failure test cases for one-key operations with the specified algorithm.""" for kt in self.key_types: key_is_compatible = kt.can_do(alg) if key_is_compatible and alg.can_do(category): # Compatible key and operation, unsupported algorithm for dep in automatic_dependencies(alg.base_expression): yield self.make_test_case(alg, category, self.Reason.NOT_SUPPORTED, kt=kt, not_deps=frozenset([dep])) # Public key for a private-key operation if category.is_asymmetric() and kt.is_public(): yield self.make_test_case(alg, category, self.Reason.PUBLIC, kt=kt) elif key_is_compatible: # Compatible key, incompatible operation, supported algorithm yield self.make_test_case(alg, category, self.Reason.INVALID, kt=kt) elif alg.can_do(category): # Incompatible key, compatible operation, supported algorithm yield self.make_test_case(alg, category, self.Reason.INCOMPATIBLE, kt=kt) else: # Incompatible key and operation. Don't test cases where # multiple things are wrong, to keep the number of test # cases reasonable. pass def test_cases_for_algorithm( self, alg: crypto_knowledge.Algorithm, ) -> Iterator[test_case.TestCase]: """Generate operation failure test cases for the specified algorithm.""" for category in crypto_knowledge.AlgorithmCategory: if category == crypto_knowledge.AlgorithmCategory.PAKE: # PAKE operations are not implemented yet pass elif category.requires_key(): yield from self.one_key_test_cases(alg, category) else: yield from self.no_key_test_cases(alg, category) def all_test_cases(self) -> Iterator[test_case.TestCase]: """Generate all test cases for operations that must fail.""" algorithms = sorted(self.constructors.algorithms) for expr in self.constructors.generate_expressions(algorithms): alg = crypto_knowledge.Algorithm(expr) yield from self.test_cases_for_algorithm(alg) class StorageKey(psa_storage.Key): """Representation of a key for storage format testing.""" IMPLICIT_USAGE_FLAGS = { 'PSA_KEY_USAGE_SIGN_HASH': 'PSA_KEY_USAGE_SIGN_MESSAGE', 'PSA_KEY_USAGE_VERIFY_HASH': 'PSA_KEY_USAGE_VERIFY_MESSAGE' } #type: Dict[str, str] """Mapping of usage flags to the flags that they imply.""" def __init__( self, usage: Iterable[str], without_implicit_usage: Optional[bool] = False, **kwargs ) -> None: """Prepare to generate a key. * `usage` : The usage flags used for the key. * `without_implicit_usage`: Flag to defide to apply the usage extension """ usage_flags = set(usage) if not without_implicit_usage: for flag in sorted(usage_flags): if flag in self.IMPLICIT_USAGE_FLAGS: usage_flags.add(self.IMPLICIT_USAGE_FLAGS[flag]) if usage_flags: usage_expression = ' | '.join(sorted(usage_flags)) else: usage_expression = '0' super().__init__(usage=usage_expression, **kwargs) class StorageTestData(StorageKey): """Representation of test case data for storage format testing.""" def __init__( self, description: str, expected_usage: Optional[List[str]] = None, **kwargs ) -> None: """Prepare to generate test data * `description` : used for the the test case names * `expected_usage`: the usage flags generated as the expected usage flags in the test cases. CAn differ from the usage flags stored in the keys because of the usage flags extension. """ super().__init__(**kwargs) self.description = description #type: str if expected_usage is None: self.expected_usage = self.usage #type: psa_storage.Expr elif expected_usage: self.expected_usage = psa_storage.Expr(' | '.join(expected_usage)) else: self.expected_usage = psa_storage.Expr(0) class StorageFormat: """Storage format stability test cases.""" def __init__(self, info: Information, version: int, forward: bool) -> None: """Prepare to generate test cases for storage format stability. * `info`: information about the API. See the `Information` class. * `version`: the storage format version to generate test cases for. * `forward`: if true, generate forward compatibility test cases which save a key and check that its representation is as intended. Otherwise generate backward compatibility test cases which inject a key representation and check that it can be read and used. """ self.constructors = info.constructors #type: macro_collector.PSAMacroEnumerator self.version = version #type: int self.forward = forward #type: bool RSA_OAEP_RE = re.compile(r'PSA_ALG_RSA_OAEP\((.*)\)\Z') BRAINPOOL_RE = re.compile(r'PSA_KEY_TYPE_\w+\(PSA_ECC_FAMILY_BRAINPOOL_\w+\)\Z') @classmethod def exercise_key_with_algorithm( cls, key_type: psa_storage.Expr, bits: int, alg: psa_storage.Expr ) -> bool: """Whether to the given key with the given algorithm. Normally only the type and algorithm matter for compatibility, and this is handled in crypto_knowledge.KeyType.can_do(). This function exists to detect exceptional cases. Exceptional cases detected here are not tested in OpFail and should therefore have manually written test cases. """ # Some test keys have the RAW_DATA type and attributes that don't # necessarily make sense. We do this to validate numerical # encodings of the attributes. # Raw data keys have no useful exercise anyway so there is no # loss of test coverage. if key_type.string == 'PSA_KEY_TYPE_RAW_DATA': return False # OAEP requires room for two hashes plus wrapping m = cls.RSA_OAEP_RE.match(alg.string) if m: hash_alg = m.group(1) hash_length = crypto_knowledge.Algorithm.hash_length(hash_alg) key_length = (bits + 7) // 8 # Leave enough room for at least one byte of plaintext return key_length > 2 * hash_length + 2 # There's nothing wrong with ECC keys on Brainpool curves, # but operations with them are very slow. So we only exercise them # with a single algorithm, not with all possible hashes. We do # exercise other curves with all algorithms so test coverage is # perfectly adequate like this. m = cls.BRAINPOOL_RE.match(key_type.string) if m and alg.string != 'PSA_ALG_ECDSA_ANY': return False return True def make_test_case(self, key: StorageTestData) -> test_case.TestCase: """Construct a storage format test case for the given key. If ``forward`` is true, generate a forward compatibility test case: create a key and validate that it has the expected representation. Otherwise generate a backward compatibility test case: inject the key representation into storage and validate that it can be read correctly. """ verb = 'save' if self.forward else 'read' tc = test_case.TestCase() tc.set_description(verb + ' ' + key.description) dependencies = automatic_dependencies( key.lifetime.string, key.type.string, key.alg.string, key.alg2.string, ) dependencies = finish_family_dependencies(dependencies, key.bits) tc.set_dependencies(dependencies) tc.set_function('key_storage_' + verb) if self.forward: extra_arguments = [] else: flags = [] if self.exercise_key_with_algorithm(key.type, key.bits, key.alg): flags.append('TEST_FLAG_EXERCISE') if 'READ_ONLY' in key.lifetime.string: flags.append('TEST_FLAG_READ_ONLY') extra_arguments = [' | '.join(flags) if flags else '0'] tc.set_arguments([key.lifetime.string, key.type.string, str(key.bits), key.expected_usage.string, key.alg.string, key.alg2.string, '"' + key.material.hex() + '"', '"' + key.hex() + '"', *extra_arguments]) return tc def key_for_lifetime( self, lifetime: str, ) -> StorageTestData: """Construct a test key for the given lifetime.""" short = lifetime short = re.sub(r'PSA_KEY_LIFETIME_FROM_PERSISTENCE_AND_LOCATION', r'', short) short = crypto_knowledge.short_expression(short) description = 'lifetime: ' + short key = StorageTestData(version=self.version, id=1, lifetime=lifetime, type='PSA_KEY_TYPE_RAW_DATA', bits=8, usage=['PSA_KEY_USAGE_EXPORT'], alg=0, alg2=0, material=b'L', description=description) return key def all_keys_for_lifetimes(self) -> Iterator[StorageTestData]: """Generate test keys covering lifetimes.""" lifetimes = sorted(self.constructors.lifetimes) expressions = self.constructors.generate_expressions(lifetimes) for lifetime in expressions: # Don't attempt to create or load a volatile key in storage if 'VOLATILE' in lifetime: continue # Don't attempt to create a read-only key in storage, # but do attempt to load one. if 'READ_ONLY' in lifetime and self.forward: continue yield self.key_for_lifetime(lifetime) def key_for_usage_flags( self, usage_flags: List[str], short: Optional[str] = None, test_implicit_usage: Optional[bool] = True ) -> StorageTestData: """Construct a test key for the given key usage.""" extra_desc = ' without implication' if test_implicit_usage else '' description = 'usage' + extra_desc + ': ' key1 = StorageTestData(version=self.version, id=1, lifetime=0x00000001, type='PSA_KEY_TYPE_RAW_DATA', bits=8, expected_usage=usage_flags, without_implicit_usage=not test_implicit_usage, usage=usage_flags, alg=0, alg2=0, material=b'K', description=description) if short is None: usage_expr = key1.expected_usage.string key1.description += crypto_knowledge.short_expression(usage_expr) else: key1.description += short return key1 def generate_keys_for_usage_flags(self, **kwargs) -> Iterator[StorageTestData]: """Generate test keys covering usage flags.""" known_flags = sorted(self.constructors.key_usage_flags) yield self.key_for_usage_flags(['0'], **kwargs) for usage_flag in known_flags: yield self.key_for_usage_flags([usage_flag], **kwargs) for flag1, flag2 in zip(known_flags, known_flags[1:] + [known_flags[0]]): yield self.key_for_usage_flags([flag1, flag2], **kwargs) def generate_key_for_all_usage_flags(self) -> Iterator[StorageTestData]: known_flags = sorted(self.constructors.key_usage_flags) yield self.key_for_usage_flags(known_flags, short='all known') def all_keys_for_usage_flags(self) -> Iterator[StorageTestData]: yield from self.generate_keys_for_usage_flags() yield from self.generate_key_for_all_usage_flags() def key_for_type_and_alg( self, kt: crypto_knowledge.KeyType, bits: int, alg: Optional[crypto_knowledge.Algorithm] = None, ) -> StorageTestData: """Construct a test key of the given type. If alg is not None, this key allows it. """ usage_flags = ['PSA_KEY_USAGE_EXPORT'] alg1 = 0 #type: psa_storage.Exprable alg2 = 0 if alg is not None: alg1 = alg.expression usage_flags += alg.usage_flags(public=kt.is_public()) key_material = kt.key_material(bits) description = 'type: {} {}-bit'.format(kt.short_expression(1), bits) if alg is not None: description += ', ' + alg.short_expression(1) key = StorageTestData(version=self.version, id=1, lifetime=0x00000001, type=kt.expression, bits=bits, usage=usage_flags, alg=alg1, alg2=alg2, material=key_material, description=description) return key def keys_for_type( self, key_type: str, all_algorithms: List[crypto_knowledge.Algorithm], ) -> Iterator[StorageTestData]: """Generate test keys for the given key type.""" kt = crypto_knowledge.KeyType(key_type) for bits in kt.sizes_to_test(): # Test a non-exercisable key, as well as exercisable keys for # each compatible algorithm. # To do: test reading a key from storage with an incompatible # or unsupported algorithm. yield self.key_for_type_and_alg(kt, bits) compatible_algorithms = [alg for alg in all_algorithms if kt.can_do(alg)] for alg in compatible_algorithms: yield self.key_for_type_and_alg(kt, bits, alg) def all_keys_for_types(self) -> Iterator[StorageTestData]: """Generate test keys covering key types and their representations.""" key_types = sorted(self.constructors.key_types) all_algorithms = [crypto_knowledge.Algorithm(alg) for alg in self.constructors.generate_expressions( sorted(self.constructors.algorithms) )] for key_type in self.constructors.generate_expressions(key_types): yield from self.keys_for_type(key_type, all_algorithms) def keys_for_algorithm(self, alg: str) -> Iterator[StorageTestData]: """Generate test keys for the encoding of the specified algorithm.""" # These test cases only validate the encoding of algorithms, not # whether the key read from storage is suitable for an operation. # `keys_for_types` generate read tests with an algorithm and a # compatible key. descr = crypto_knowledge.short_expression(alg, 1) usage = ['PSA_KEY_USAGE_EXPORT'] key1 = StorageTestData(version=self.version, id=1, lifetime=0x00000001, type='PSA_KEY_TYPE_RAW_DATA', bits=8, usage=usage, alg=alg, alg2=0, material=b'K', description='alg: ' + descr) yield key1 key2 = StorageTestData(version=self.version, id=1, lifetime=0x00000001, type='PSA_KEY_TYPE_RAW_DATA', bits=8, usage=usage, alg=0, alg2=alg, material=b'L', description='alg2: ' + descr) yield key2 def all_keys_for_algorithms(self) -> Iterator[StorageTestData]: """Generate test keys covering algorithm encodings.""" algorithms = sorted(self.constructors.algorithms) for alg in self.constructors.generate_expressions(algorithms): yield from self.keys_for_algorithm(alg) def generate_all_keys(self) -> Iterator[StorageTestData]: """Generate all keys for the test cases.""" yield from self.all_keys_for_lifetimes() yield from self.all_keys_for_usage_flags() yield from self.all_keys_for_types() yield from self.all_keys_for_algorithms() def all_test_cases(self) -> Iterator[test_case.TestCase]: """Generate all storage format test cases.""" # First build a list of all keys, then construct all the corresponding # test cases. This allows all required information to be obtained in # one go, which is a significant performance gain as the information # includes numerical values obtained by compiling a C program. all_keys = list(self.generate_all_keys()) for key in all_keys: if key.location_value() != 0: # Skip keys with a non-default location, because they # require a driver and we currently have no mechanism to # determine whether a driver is available. continue yield self.make_test_case(key) class StorageFormatForward(StorageFormat): """Storage format stability test cases for forward compatibility.""" def __init__(self, info: Information, version: int) -> None: super().__init__(info, version, True) class StorageFormatV0(StorageFormat): """Storage format stability test cases for version 0 compatibility.""" def __init__(self, info: Information) -> None: super().__init__(info, 0, False) def all_keys_for_usage_flags(self) -> Iterator[StorageTestData]: """Generate test keys covering usage flags.""" yield from super().all_keys_for_usage_flags() yield from self.generate_keys_for_usage_flags(test_implicit_usage=False) def keys_for_implicit_usage( self, implyer_usage: str, alg: str, key_type: crypto_knowledge.KeyType ) -> StorageTestData: # pylint: disable=too-many-locals """Generate test keys for the specified implicit usage flag, algorithm and key type combination. """ bits = key_type.sizes_to_test()[0] implicit_usage = StorageKey.IMPLICIT_USAGE_FLAGS[implyer_usage] usage_flags = ['PSA_KEY_USAGE_EXPORT'] material_usage_flags = usage_flags + [implyer_usage] expected_usage_flags = material_usage_flags + [implicit_usage] alg2 = 0 key_material = key_type.key_material(bits) usage_expression = crypto_knowledge.short_expression(implyer_usage, 1) alg_expression = crypto_knowledge.short_expression(alg, 1) key_type_expression = key_type.short_expression(1) description = 'implied by {}: {} {} {}-bit'.format( usage_expression, alg_expression, key_type_expression, bits) key = StorageTestData(version=self.version, id=1, lifetime=0x00000001, type=key_type.expression, bits=bits, usage=material_usage_flags, expected_usage=expected_usage_flags, without_implicit_usage=True, alg=alg, alg2=alg2, material=key_material, description=description) return key def gather_key_types_for_sign_alg(self) -> Dict[str, List[str]]: # pylint: disable=too-many-locals """Match possible key types for sign algorithms.""" # To create a valid combinaton both the algorithms and key types # must be filtered. Pair them with keywords created from its names. incompatible_alg_keyword = frozenset(['RAW', 'ANY', 'PURE']) incompatible_key_type_keywords = frozenset(['MONTGOMERY']) keyword_translation = { 'ECDSA': 'ECC', 'ED[0-9]*.*' : 'EDWARDS' } exclusive_keywords = { 'EDWARDS': 'ECC' } key_types = set(self.constructors.generate_expressions(self.constructors.key_types)) algorithms = set(self.constructors.generate_expressions(self.constructors.sign_algorithms)) alg_with_keys = {} #type: Dict[str, List[str]] translation_table = str.maketrans('(', '_', ')') for alg in algorithms: # Generate keywords from the name of the algorithm alg_keywords = set(alg.partition('(')[0].split(sep='_')[2:]) # Translate keywords for better matching with the key types for keyword in alg_keywords.copy(): for pattern, replace in keyword_translation.items(): if re.match(pattern, keyword): alg_keywords.remove(keyword) alg_keywords.add(replace) # Filter out incompatible algortihms if not alg_keywords.isdisjoint(incompatible_alg_keyword): continue for key_type in key_types: # Generate keywords from the of the key type key_type_keywords = set(key_type.translate(translation_table).split(sep='_')[3:]) # Remove ambigious keywords for keyword1, keyword2 in exclusive_keywords.items(): if keyword1 in key_type_keywords: key_type_keywords.remove(keyword2) if key_type_keywords.isdisjoint(incompatible_key_type_keywords) and\ not key_type_keywords.isdisjoint(alg_keywords): if alg in alg_with_keys: alg_with_keys[alg].append(key_type) else: alg_with_keys[alg] = [key_type] return alg_with_keys def all_keys_for_implicit_usage(self) -> Iterator[StorageTestData]: """Generate test keys for usage flag extensions.""" # Generate a key type and algorithm pair for each extendable usage # flag to generate a valid key for exercising. The key is generated # without usage extension to check the extension compatiblity. alg_with_keys = self.gather_key_types_for_sign_alg() for usage in sorted(StorageKey.IMPLICIT_USAGE_FLAGS, key=str): for alg in sorted(alg_with_keys): for key_type in sorted(alg_with_keys[alg]): # The key types must be filtered to fit the specific usage flag. kt = crypto_knowledge.KeyType(key_type) if kt.is_public() and '_SIGN_' in usage: # Can't sign with a public key continue yield self.keys_for_implicit_usage(usage, alg, kt) def generate_all_keys(self) -> Iterator[StorageTestData]: yield from super().generate_all_keys() yield from self.all_keys_for_implicit_usage() class TestGenerator: """Generate test data.""" def __init__(self, options) -> None: self.test_suite_directory = self.get_option(options, 'directory', 'tests/suites') self.info = Information() @staticmethod def get_option(options, name: str, default: T) -> T: value = getattr(options, name, None) return default if value is None else value def filename_for(self, basename: str) -> str: """The location of the data file with the specified base name.""" return posixpath.join(self.test_suite_directory, basename + '.data') def write_test_data_file(self, basename: str, test_cases: Iterable[test_case.TestCase]) -> None: """Write the test cases to a .data file. The output file is ``basename + '.data'`` in the test suite directory. """ filename = self.filename_for(basename) test_case.write_data_file(filename, test_cases) # Note that targets whose name containns 'test_format' have their content # validated by `abi_check.py`. TARGETS = { 'test_suite_psa_crypto_generate_key.generated': lambda info: KeyGenerate(info).test_cases_for_key_generation(), 'test_suite_psa_crypto_not_supported.generated': lambda info: NotSupported(info).test_cases_for_not_supported(), 'test_suite_psa_crypto_op_fail.generated': lambda info: OpFail(info).all_test_cases(), 'test_suite_psa_crypto_storage_format.current': lambda info: StorageFormatForward(info, 0).all_test_cases(), 'test_suite_psa_crypto_storage_format.v0': lambda info: StorageFormatV0(info).all_test_cases(), } #type: Dict[str, Callable[[Information], Iterable[test_case.TestCase]]] def generate_target(self, name: str) -> None: test_cases = self.TARGETS[name](self.info) self.write_test_data_file(name, test_cases) def main(args): """Command line entry point.""" parser = argparse.ArgumentParser(description=__doc__) parser.add_argument('--list', action='store_true', help='List available targets and exit') parser.add_argument('--list-for-cmake', action='store_true', help='Print \';\'-separated list of available targets and exit') parser.add_argument('--directory', metavar='DIR', help='Output directory (default: tests/suites)') parser.add_argument('targets', nargs='*', metavar='TARGET', help='Target file to generate (default: all; "-": none)') options = parser.parse_args(args) build_tree.chdir_to_root() generator = TestGenerator(options) if options.list: for name in sorted(generator.TARGETS): print(generator.filename_for(name)) return # List in a cmake list format (i.e. ';'-separated) if options.list_for_cmake: print(';'.join(generator.filename_for(name) for name in sorted(generator.TARGETS)), end='') return if options.targets: # Allow "-" as a special case so you can run # ``generate_psa_tests.py - $targets`` and it works uniformly whether # ``$targets`` is empty or not. options.targets = [os.path.basename(re.sub(r'\.data\Z', r'', target)) for target in options.targets if target != '-'] else: options.targets = sorted(generator.TARGETS) for target in options.targets: generator.generate_target(target) if __name__ == '__main__': main(sys.argv[1:])