850 lines
38 KiB
Python
Executable file
850 lines
38 KiB
Python
Executable file
#!/usr/bin/env python3
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"""Generate test data for PSA cryptographic mechanisms.
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With no arguments, generate all test data. With non-option arguments,
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generate only the specified files.
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"""
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# Copyright The Mbed TLS Contributors
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# SPDX-License-Identifier: Apache-2.0 OR GPL-2.0-or-later
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import enum
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import re
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import sys
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from typing import Callable, Dict, FrozenSet, Iterable, Iterator, List, Optional
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import scripts_path # pylint: disable=unused-import
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from mbedtls_dev import crypto_data_tests
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from mbedtls_dev import crypto_knowledge
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from mbedtls_dev import macro_collector #pylint: disable=unused-import
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from mbedtls_dev import psa_information
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from mbedtls_dev import psa_storage
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from mbedtls_dev import test_case
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from mbedtls_dev import test_data_generation
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def test_case_for_key_type_not_supported(
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verb: str, key_type: str, bits: int,
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dependencies: List[str],
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*args: str,
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param_descr: str = ''
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) -> test_case.TestCase:
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"""Return one test case exercising a key creation method
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for an unsupported key type or size.
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"""
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psa_information.hack_dependencies_not_implemented(dependencies)
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tc = test_case.TestCase()
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short_key_type = crypto_knowledge.short_expression(key_type)
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adverb = 'not' if dependencies else 'never'
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if param_descr:
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adverb = param_descr + ' ' + adverb
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tc.set_description('PSA {} {} {}-bit {} supported'
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.format(verb, short_key_type, bits, adverb))
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tc.set_dependencies(dependencies)
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tc.set_function(verb + '_not_supported')
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tc.set_arguments([key_type] + list(args))
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return tc
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class KeyTypeNotSupported:
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"""Generate test cases for when a key type is not supported."""
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def __init__(self, info: psa_information.Information) -> None:
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self.constructors = info.constructors
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ALWAYS_SUPPORTED = frozenset([
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'PSA_KEY_TYPE_DERIVE',
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'PSA_KEY_TYPE_PASSWORD',
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'PSA_KEY_TYPE_PASSWORD_HASH',
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'PSA_KEY_TYPE_RAW_DATA',
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'PSA_KEY_TYPE_HMAC'
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])
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def test_cases_for_key_type_not_supported(
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self,
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kt: crypto_knowledge.KeyType,
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param: Optional[int] = None,
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param_descr: str = '',
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) -> Iterator[test_case.TestCase]:
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"""Return test cases exercising key creation when the given type is unsupported.
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If param is present and not None, emit test cases conditioned on this
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parameter not being supported. If it is absent or None, emit test cases
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conditioned on the base type not being supported.
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"""
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if kt.name in self.ALWAYS_SUPPORTED:
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# Don't generate test cases for key types that are always supported.
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# They would be skipped in all configurations, which is noise.
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return
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import_dependencies = [('!' if param is None else '') +
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psa_information.psa_want_symbol(kt.name)]
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if kt.params is not None:
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import_dependencies += [('!' if param == i else '') +
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psa_information.psa_want_symbol(sym)
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for i, sym in enumerate(kt.params)]
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if kt.name.endswith('_PUBLIC_KEY'):
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generate_dependencies = []
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else:
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generate_dependencies = \
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psa_information.fix_key_pair_dependencies(import_dependencies, 'GENERATE')
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import_dependencies = \
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psa_information.fix_key_pair_dependencies(import_dependencies, 'BASIC')
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for bits in kt.sizes_to_test():
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yield test_case_for_key_type_not_supported(
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'import', kt.expression, bits,
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psa_information.finish_family_dependencies(import_dependencies, bits),
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test_case.hex_string(kt.key_material(bits)),
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param_descr=param_descr,
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)
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if not generate_dependencies and param is not None:
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# If generation is impossible for this key type, rather than
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# supported or not depending on implementation capabilities,
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# only generate the test case once.
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continue
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# For public key we expect that key generation fails with
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# INVALID_ARGUMENT. It is handled by KeyGenerate class.
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if not kt.is_public():
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yield test_case_for_key_type_not_supported(
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'generate', kt.expression, bits,
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psa_information.finish_family_dependencies(generate_dependencies, bits),
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str(bits),
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param_descr=param_descr,
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)
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# To be added: derive
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ECC_KEY_TYPES = ('PSA_KEY_TYPE_ECC_KEY_PAIR',
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'PSA_KEY_TYPE_ECC_PUBLIC_KEY')
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DH_KEY_TYPES = ('PSA_KEY_TYPE_DH_KEY_PAIR',
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'PSA_KEY_TYPE_DH_PUBLIC_KEY')
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def test_cases_for_not_supported(self) -> Iterator[test_case.TestCase]:
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"""Generate test cases that exercise the creation of keys of unsupported types."""
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for key_type in sorted(self.constructors.key_types):
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if key_type in self.ECC_KEY_TYPES:
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continue
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if key_type in self.DH_KEY_TYPES:
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continue
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kt = crypto_knowledge.KeyType(key_type)
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yield from self.test_cases_for_key_type_not_supported(kt)
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for curve_family in sorted(self.constructors.ecc_curves):
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for constr in self.ECC_KEY_TYPES:
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kt = crypto_knowledge.KeyType(constr, [curve_family])
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yield from self.test_cases_for_key_type_not_supported(
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kt, param_descr='type')
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yield from self.test_cases_for_key_type_not_supported(
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kt, 0, param_descr='curve')
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for dh_family in sorted(self.constructors.dh_groups):
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for constr in self.DH_KEY_TYPES:
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kt = crypto_knowledge.KeyType(constr, [dh_family])
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yield from self.test_cases_for_key_type_not_supported(
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kt, param_descr='type')
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yield from self.test_cases_for_key_type_not_supported(
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kt, 0, param_descr='group')
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def test_case_for_key_generation(
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key_type: str, bits: int,
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dependencies: List[str],
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*args: str,
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result: str = ''
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) -> test_case.TestCase:
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"""Return one test case exercising a key generation.
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"""
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psa_information.hack_dependencies_not_implemented(dependencies)
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tc = test_case.TestCase()
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short_key_type = crypto_knowledge.short_expression(key_type)
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tc.set_description('PSA {} {}-bit'
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.format(short_key_type, bits))
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tc.set_dependencies(dependencies)
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tc.set_function('generate_key')
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tc.set_arguments([key_type] + list(args) + [result])
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return tc
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class KeyGenerate:
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"""Generate positive and negative (invalid argument) test cases for key generation."""
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def __init__(self, info: psa_information.Information) -> None:
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self.constructors = info.constructors
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ECC_KEY_TYPES = ('PSA_KEY_TYPE_ECC_KEY_PAIR',
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'PSA_KEY_TYPE_ECC_PUBLIC_KEY')
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DH_KEY_TYPES = ('PSA_KEY_TYPE_DH_KEY_PAIR',
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'PSA_KEY_TYPE_DH_PUBLIC_KEY')
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@staticmethod
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def test_cases_for_key_type_key_generation(
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kt: crypto_knowledge.KeyType
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) -> Iterator[test_case.TestCase]:
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"""Return test cases exercising key generation.
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All key types can be generated except for public keys. For public key
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PSA_ERROR_INVALID_ARGUMENT status is expected.
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"""
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result = 'PSA_SUCCESS'
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import_dependencies = [psa_information.psa_want_symbol(kt.name)]
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if kt.params is not None:
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import_dependencies += [psa_information.psa_want_symbol(sym)
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for i, sym in enumerate(kt.params)]
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if kt.name.endswith('_PUBLIC_KEY'):
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# The library checks whether the key type is a public key generically,
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# before it reaches a point where it needs support for the specific key
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# type, so it returns INVALID_ARGUMENT for unsupported public key types.
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generate_dependencies = []
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result = 'PSA_ERROR_INVALID_ARGUMENT'
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else:
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generate_dependencies = \
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psa_information.fix_key_pair_dependencies(import_dependencies, 'GENERATE')
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for bits in kt.sizes_to_test():
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if kt.name == 'PSA_KEY_TYPE_RSA_KEY_PAIR':
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size_dependency = "PSA_VENDOR_RSA_GENERATE_MIN_KEY_BITS <= " + str(bits)
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test_dependencies = generate_dependencies + [size_dependency]
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else:
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test_dependencies = generate_dependencies
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yield test_case_for_key_generation(
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kt.expression, bits,
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psa_information.finish_family_dependencies(test_dependencies, bits),
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str(bits),
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result
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)
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def test_cases_for_key_generation(self) -> Iterator[test_case.TestCase]:
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"""Generate test cases that exercise the generation of keys."""
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for key_type in sorted(self.constructors.key_types):
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if key_type in self.ECC_KEY_TYPES:
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continue
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if key_type in self.DH_KEY_TYPES:
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continue
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kt = crypto_knowledge.KeyType(key_type)
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yield from self.test_cases_for_key_type_key_generation(kt)
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for curve_family in sorted(self.constructors.ecc_curves):
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for constr in self.ECC_KEY_TYPES:
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kt = crypto_knowledge.KeyType(constr, [curve_family])
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yield from self.test_cases_for_key_type_key_generation(kt)
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for dh_family in sorted(self.constructors.dh_groups):
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for constr in self.DH_KEY_TYPES:
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kt = crypto_knowledge.KeyType(constr, [dh_family])
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yield from self.test_cases_for_key_type_key_generation(kt)
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class OpFail:
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"""Generate test cases for operations that must fail."""
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#pylint: disable=too-few-public-methods
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class Reason(enum.Enum):
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NOT_SUPPORTED = 0
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INVALID = 1
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INCOMPATIBLE = 2
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PUBLIC = 3
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def __init__(self, info: psa_information.Information) -> None:
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self.constructors = info.constructors
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key_type_expressions = self.constructors.generate_expressions(
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sorted(self.constructors.key_types)
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)
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self.key_types = [crypto_knowledge.KeyType(kt_expr)
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for kt_expr in key_type_expressions]
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def make_test_case(
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self,
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alg: crypto_knowledge.Algorithm,
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category: crypto_knowledge.AlgorithmCategory,
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reason: 'Reason',
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kt: Optional[crypto_knowledge.KeyType] = None,
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not_deps: FrozenSet[str] = frozenset(),
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) -> test_case.TestCase:
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"""Construct a failure test case for a one-key or keyless operation."""
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#pylint: disable=too-many-arguments,too-many-locals
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tc = test_case.TestCase()
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pretty_alg = alg.short_expression()
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if reason == self.Reason.NOT_SUPPORTED:
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short_deps = [re.sub(r'PSA_WANT_ALG_', r'', dep)
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for dep in not_deps]
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pretty_reason = '!' + '&'.join(sorted(short_deps))
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else:
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pretty_reason = reason.name.lower()
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if kt:
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key_type = kt.expression
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pretty_type = kt.short_expression()
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else:
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key_type = ''
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pretty_type = ''
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tc.set_description('PSA {} {}: {}{}'
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.format(category.name.lower(),
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pretty_alg,
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pretty_reason,
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' with ' + pretty_type if pretty_type else ''))
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dependencies = psa_information.automatic_dependencies(alg.base_expression, key_type)
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dependencies = psa_information.fix_key_pair_dependencies(dependencies, 'BASIC')
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for i, dep in enumerate(dependencies):
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if dep in not_deps:
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dependencies[i] = '!' + dep
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tc.set_dependencies(dependencies)
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tc.set_function(category.name.lower() + '_fail')
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arguments = [] # type: List[str]
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if kt:
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key_material = kt.key_material(kt.sizes_to_test()[0])
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arguments += [key_type, test_case.hex_string(key_material)]
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arguments.append(alg.expression)
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if category.is_asymmetric():
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arguments.append('1' if reason == self.Reason.PUBLIC else '0')
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error = ('NOT_SUPPORTED' if reason == self.Reason.NOT_SUPPORTED else
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'INVALID_ARGUMENT')
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arguments.append('PSA_ERROR_' + error)
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tc.set_arguments(arguments)
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return tc
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def no_key_test_cases(
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self,
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alg: crypto_knowledge.Algorithm,
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category: crypto_knowledge.AlgorithmCategory,
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) -> Iterator[test_case.TestCase]:
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"""Generate failure test cases for keyless operations with the specified algorithm."""
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if alg.can_do(category):
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# Compatible operation, unsupported algorithm
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for dep in psa_information.automatic_dependencies(alg.base_expression):
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yield self.make_test_case(alg, category,
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self.Reason.NOT_SUPPORTED,
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not_deps=frozenset([dep]))
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else:
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# Incompatible operation, supported algorithm
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yield self.make_test_case(alg, category, self.Reason.INVALID)
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def one_key_test_cases(
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self,
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alg: crypto_knowledge.Algorithm,
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category: crypto_knowledge.AlgorithmCategory,
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) -> Iterator[test_case.TestCase]:
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"""Generate failure test cases for one-key operations with the specified algorithm."""
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for kt in self.key_types:
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key_is_compatible = kt.can_do(alg)
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if key_is_compatible and alg.can_do(category):
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# Compatible key and operation, unsupported algorithm
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for dep in psa_information.automatic_dependencies(alg.base_expression):
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yield self.make_test_case(alg, category,
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self.Reason.NOT_SUPPORTED,
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kt=kt, not_deps=frozenset([dep]))
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# Public key for a private-key operation
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if category.is_asymmetric() and kt.is_public():
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yield self.make_test_case(alg, category,
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self.Reason.PUBLIC,
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kt=kt)
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elif key_is_compatible:
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# Compatible key, incompatible operation, supported algorithm
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yield self.make_test_case(alg, category,
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self.Reason.INVALID,
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kt=kt)
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elif alg.can_do(category):
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# Incompatible key, compatible operation, supported algorithm
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yield self.make_test_case(alg, category,
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self.Reason.INCOMPATIBLE,
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kt=kt)
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else:
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# Incompatible key and operation. Don't test cases where
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# multiple things are wrong, to keep the number of test
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# cases reasonable.
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pass
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def test_cases_for_algorithm(
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self,
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alg: crypto_knowledge.Algorithm,
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) -> Iterator[test_case.TestCase]:
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"""Generate operation failure test cases for the specified algorithm."""
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for category in crypto_knowledge.AlgorithmCategory:
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if category == crypto_knowledge.AlgorithmCategory.PAKE:
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# PAKE operations are not implemented yet
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pass
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elif category.requires_key():
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yield from self.one_key_test_cases(alg, category)
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else:
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yield from self.no_key_test_cases(alg, category)
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def all_test_cases(self) -> Iterator[test_case.TestCase]:
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"""Generate all test cases for operations that must fail."""
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algorithms = sorted(self.constructors.algorithms)
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for expr in self.constructors.generate_expressions(algorithms):
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alg = crypto_knowledge.Algorithm(expr)
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yield from self.test_cases_for_algorithm(alg)
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class StorageKey(psa_storage.Key):
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"""Representation of a key for storage format testing."""
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IMPLICIT_USAGE_FLAGS = {
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'PSA_KEY_USAGE_SIGN_HASH': 'PSA_KEY_USAGE_SIGN_MESSAGE',
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'PSA_KEY_USAGE_VERIFY_HASH': 'PSA_KEY_USAGE_VERIFY_MESSAGE'
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} #type: Dict[str, str]
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"""Mapping of usage flags to the flags that they imply."""
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def __init__(
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self,
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usage: Iterable[str],
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without_implicit_usage: Optional[bool] = False,
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**kwargs
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) -> None:
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"""Prepare to generate a key.
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* `usage` : The usage flags used for the key.
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* `without_implicit_usage`: Flag to define to apply the usage extension
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"""
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usage_flags = set(usage)
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if not without_implicit_usage:
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for flag in sorted(usage_flags):
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if flag in self.IMPLICIT_USAGE_FLAGS:
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usage_flags.add(self.IMPLICIT_USAGE_FLAGS[flag])
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if usage_flags:
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usage_expression = ' | '.join(sorted(usage_flags))
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else:
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usage_expression = '0'
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super().__init__(usage=usage_expression, **kwargs)
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class StorageTestData(StorageKey):
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"""Representation of test case data for storage format testing."""
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def __init__(
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self,
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description: str,
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expected_usage: Optional[List[str]] = None,
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**kwargs
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) -> None:
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"""Prepare to generate test data
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* `description` : used for the test case names
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* `expected_usage`: the usage flags generated as the expected usage flags
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in the test cases. CAn differ from the usage flags
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stored in the keys because of the usage flags extension.
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"""
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super().__init__(**kwargs)
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self.description = description #type: str
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if expected_usage is None:
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self.expected_usage = self.usage #type: psa_storage.Expr
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elif expected_usage:
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self.expected_usage = psa_storage.Expr(' | '.join(expected_usage))
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else:
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self.expected_usage = psa_storage.Expr(0)
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class StorageFormat:
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"""Storage format stability test cases."""
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def __init__(self, info: psa_information.Information, version: int, forward: bool) -> None:
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"""Prepare to generate test cases for storage format stability.
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* `info`: information about the API. See the `Information` class.
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* `version`: the storage format version to generate test cases for.
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* `forward`: if true, generate forward compatibility test cases which
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save a key and check that its representation is as intended. Otherwise
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generate backward compatibility test cases which inject a key
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representation and check that it can be read and used.
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"""
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self.constructors = info.constructors #type: macro_collector.PSAMacroEnumerator
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self.version = version #type: int
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self.forward = forward #type: bool
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RSA_OAEP_RE = re.compile(r'PSA_ALG_RSA_OAEP\((.*)\)\Z')
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BRAINPOOL_RE = re.compile(r'PSA_KEY_TYPE_\w+\(PSA_ECC_FAMILY_BRAINPOOL_\w+\)\Z')
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@classmethod
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def exercise_key_with_algorithm(
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cls,
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key_type: psa_storage.Expr, bits: int,
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alg: psa_storage.Expr
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) -> bool:
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"""Whether to exercise the given key with the given algorithm.
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Normally only the type and algorithm matter for compatibility, and
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this is handled in crypto_knowledge.KeyType.can_do(). This function
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exists to detect exceptional cases. Exceptional cases detected here
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are not tested in OpFail and should therefore have manually written
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test cases.
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"""
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# Some test keys have the RAW_DATA type and attributes that don't
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# necessarily make sense. We do this to validate numerical
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# 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 = psa_information.automatic_dependencies(
|
|
key.lifetime.string, key.type.string,
|
|
key.alg.string, key.alg2.string,
|
|
)
|
|
dependencies = psa_information.finish_family_dependencies(dependencies, key.bits)
|
|
dependencies += psa_information.generate_deps_from_description(key.description)
|
|
dependencies = psa_information.fix_key_pair_dependencies(dependencies, 'BASIC')
|
|
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: psa_information.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: psa_information.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 combination 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 algorithms
|
|
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 ambiguous 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 compatibility.
|
|
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 PSATestGenerator(test_data_generation.TestGenerator):
|
|
"""Test generator subclass including PSA targets and info."""
|
|
# Note that targets whose names contain '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: KeyTypeNotSupported(info).test_cases_for_not_supported(),
|
|
'test_suite_psa_crypto_low_hash.generated':
|
|
lambda info: crypto_data_tests.HashPSALowLevel(info).all_test_cases(),
|
|
'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[[psa_information.Information], Iterable[test_case.TestCase]]]
|
|
|
|
def __init__(self, options):
|
|
super().__init__(options)
|
|
self.info = psa_information.Information()
|
|
|
|
def generate_target(self, name: str, *target_args) -> None:
|
|
super().generate_target(name, self.info)
|
|
|
|
|
|
if __name__ == '__main__':
|
|
test_data_generation.main(sys.argv[1:], __doc__, PSATestGenerator)
|