mbedtls/scripts/mbedtls_dev/bignum_mod_raw.py

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"""Framework classes for generation of bignum mod_raw test cases."""
# 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.
from typing import Iterator, List
from . import test_case
from . import test_data_generation
from . import bignum_common
from .bignum_data import ONLY_PRIME_MODULI
class BignumModRawTarget(test_data_generation.BaseTarget):
#pylint: disable=abstract-method, too-few-public-methods
"""Target for bignum mod_raw test case generation."""
target_basename = 'test_suite_bignum_mod_raw.generated'
class BignumModRawSub(bignum_common.ModOperationCommon,
BignumModRawTarget):
"""Test cases for bignum mpi_mod_raw_sub()."""
symbol = "-"
test_function = "mpi_mod_raw_sub"
test_name = "mbedtls_mpi_mod_raw_sub"
input_style = "fixed"
arity = 2
def arguments(self) -> List[str]:
return [bignum_common.quote_str(n) for n in [self.arg_a,
self.arg_b,
self.arg_n]
] + self.result()
def result(self) -> List[str]:
result = (self.int_a - self.int_b) % self.int_n
return [self.format_result(result)]
class BignumModRawFixQuasiReduction(bignum_common.ModOperationCommon,
BignumModRawTarget):
"""Test cases for ecp quasi_reduction()."""
symbol = "-"
test_function = "mpi_mod_raw_fix_quasi_reduction"
test_name = "fix_quasi_reduction"
input_style = "fixed"
arity = 1
# Extend the default values with n < x < 2n
input_values = bignum_common.ModOperationCommon.input_values + [
"73",
# First number generated by random.getrandbits(1024) - seed(3,2)
"ea7b5bf55eb561a4216363698b529b4a97b750923ceb3ffd",
# First number generated by random.getrandbits(1024) - seed(1,2)
("cd447e35b8b6d8fe442e3d437204e52db2221a58008a05a6c4647159c324c985"
"9b810e766ec9d28663ca828dd5f4b3b2e4b06ce60741c7a87ce42c8218072e8c"
"35bf992dc9e9c616612e7696a6cecc1b78e510617311d8a3c2ce6f447ed4d57b"
"1e2feb89414c343c1027c4d1c386bbc4cd613e30d8f16adf91b7584a2265b1f5")
] # type: List[str]
def result(self) -> List[str]:
result = self.int_a % self.int_n
return [self.format_result(result)]
@property
def is_valid(self) -> bool:
return bool(self.int_a < 2 * self.int_n)
class BignumModRawMul(bignum_common.ModOperationCommon,
BignumModRawTarget):
"""Test cases for bignum mpi_mod_raw_mul()."""
symbol = "*"
test_function = "mpi_mod_raw_mul"
test_name = "mbedtls_mpi_mod_raw_mul"
input_style = "arch_split"
arity = 2
def arguments(self) -> List[str]:
return [self.format_result(self.to_montgomery(self.int_a)),
self.format_result(self.to_montgomery(self.int_b)),
bignum_common.quote_str(self.arg_n)
] + self.result()
def result(self) -> List[str]:
result = (self.int_a * self.int_b) % self.int_n
return [self.format_result(self.to_montgomery(result))]
class BignumModRawInvPrime(bignum_common.ModOperationCommon,
BignumModRawTarget):
"""Test cases for bignum mpi_mod_raw_inv_prime()."""
moduli = ONLY_PRIME_MODULI
symbol = "^ -1"
test_function = "mpi_mod_raw_inv_prime"
test_name = "mbedtls_mpi_mod_raw_inv_prime (Montgomery form only)"
input_style = "arch_split"
arity = 1
suffix = True
montgomery_form_a = True
disallow_zero_a = True
def result(self) -> List[str]:
result = bignum_common.invmod_positive(self.int_a, self.int_n)
mont_result = self.to_montgomery(result)
return [self.format_result(mont_result)]
class BignumModRawAdd(bignum_common.ModOperationCommon,
BignumModRawTarget):
"""Test cases for bignum mpi_mod_raw_add()."""
symbol = "+"
test_function = "mpi_mod_raw_add"
test_name = "mbedtls_mpi_mod_raw_add"
input_style = "fixed"
arity = 2
def result(self) -> List[str]:
result = (self.int_a + self.int_b) % self.int_n
return [self.format_result(result)]
class BignumModRawConvertRep(bignum_common.ModOperationCommon,
BignumModRawTarget):
# This is an abstract class, it's ok to have unimplemented methods.
#pylint: disable=abstract-method
"""Test cases for representation conversion."""
symbol = ""
input_style = "arch_split"
arity = 1
rep = bignum_common.ModulusRepresentation.INVALID
def set_representation(self, r: bignum_common.ModulusRepresentation) -> None:
self.rep = r
def arguments(self) -> List[str]:
return ([bignum_common.quote_str(self.arg_n), self.rep.symbol(),
bignum_common.quote_str(self.arg_a)] +
self.result())
def description(self) -> str:
base = super().description()
mod_with_rep = 'mod({})'.format(self.rep.name)
return base.replace('mod', mod_with_rep, 1)
@classmethod
def test_cases_for_values(cls, rep: bignum_common.ModulusRepresentation,
n: str, a: str) -> Iterator[test_case.TestCase]:
"""Emit test cases for the given values (if any).
This may emit no test cases if a isn't valid for the modulus n,
or multiple test cases if rep requires different data depending
on the limb size.
"""
for bil in cls.limb_sizes:
test_object = cls(n, a, bits_in_limb=bil)
test_object.set_representation(rep)
# The class is set to having separate test cases for each limb
# size, because the Montgomery representation requires it.
# But other representations don't require it. So for other
# representations, emit a single test case with no dependency
# on the limb size.
if rep is not bignum_common.ModulusRepresentation.MONTGOMERY:
test_object.dependencies = \
[dep for dep in test_object.dependencies
if not dep.startswith('MBEDTLS_HAVE_INT')]
if test_object.is_valid:
yield test_object.create_test_case()
if rep is not bignum_common.ModulusRepresentation.MONTGOMERY:
# A single test case (emitted, or skipped due to invalidity)
# is enough, since this test case doesn't depend on the
# limb size.
break
# The parent class doesn't support non-bignum parameters. So we override
# test generation, in order to have the representation as a parameter.
@classmethod
def generate_function_tests(cls) -> Iterator[test_case.TestCase]:
for rep in bignum_common.ModulusRepresentation.supported_representations():
for n in cls.moduli:
for a in cls.input_values:
yield from cls.test_cases_for_values(rep, n, a)
class BignumModRawCanonicalToModulusRep(BignumModRawConvertRep):
"""Test cases for mpi_mod_raw_canonical_to_modulus_rep."""
test_function = "mpi_mod_raw_canonical_to_modulus_rep"
test_name = "Rep canon->mod"
def result(self) -> List[str]:
return [self.format_result(self.convert_from_canonical(self.int_a, self.rep))]
class BignumModRawModulusToCanonicalRep(BignumModRawConvertRep):
"""Test cases for mpi_mod_raw_modulus_to_canonical_rep."""
test_function = "mpi_mod_raw_modulus_to_canonical_rep"
test_name = "Rep mod->canon"
@property
def arg_a(self) -> str:
return self.format_arg("{:x}".format(self.convert_from_canonical(self.int_a, self.rep)))
def result(self) -> List[str]:
return [self.format_result(self.int_a)]
class BignumModRawConvertToMont(bignum_common.ModOperationCommon,
BignumModRawTarget):
""" Test cases for mpi_mod_raw_to_mont_rep(). """
test_function = "mpi_mod_raw_to_mont_rep"
test_name = "Convert into Mont: "
symbol = "R *"
input_style = "arch_split"
arity = 1
def result(self) -> List[str]:
result = self.to_montgomery(self.int_a)
return [self.format_result(result)]
class BignumModRawConvertFromMont(bignum_common.ModOperationCommon,
BignumModRawTarget):
""" Test cases for mpi_mod_raw_from_mont_rep(). """
test_function = "mpi_mod_raw_from_mont_rep"
test_name = "Convert from Mont: "
symbol = "1/R *"
input_style = "arch_split"
arity = 1
def result(self) -> List[str]:
result = self.from_montgomery(self.int_a)
return [self.format_result(result)]
class BignumModRawModNegate(bignum_common.ModOperationCommon,
BignumModRawTarget):
""" Test cases for mpi_mod_raw_neg(). """
test_function = "mpi_mod_raw_neg"
test_name = "Modular negation: "
symbol = "-"
input_style = "arch_split"
arity = 1
def result(self) -> List[str]:
result = (self.int_n - self.int_a) % self.int_n
return [self.format_result(result)]