linux-kernelorg-stable/scripts/crypto/gen-hash-testvecs.py

#!/usr/bin/env python3
# SPDX-License-Identifier: GPL-2.0-or-later
#
# Script that generates test vectors for the given cryptographic hash function.
#
# Copyright 2025 Google LLC

import hashlib
import hmac
import sys

DATA_LENS = [0, 1, 2, 3, 16, 32, 48, 49, 63, 64, 65, 127, 128, 129, 256, 511,
             513, 1000, 3333, 4096, 4128, 4160, 4224, 16384]

# Generate the given number of random bytes, using the length itself as the seed
# for a simple linear congruential generator (LCG).  The C test code uses the
# same LCG with the same seeding strategy to reconstruct the data, ensuring
# reproducibility without explicitly storing the data in the test vectors.
def rand_bytes(length):
    seed = length
    out = []
    for _ in range(length):
        seed = (seed * 25214903917 + 11) % 2**48
        out.append((seed >> 16) % 256)
    return bytes(out)

def hash_init(alg):
    return hashlib.new(alg)

def hash_update(ctx, data):
    ctx.update(data)

def hash_final(ctx):
    return ctx.digest()

def compute_hash(alg, data):
    ctx = hash_init(alg)
    hash_update(ctx, data)
    return hash_final(ctx)

def print_bytes(prefix, value, bytes_per_line):
    for i in range(0, len(value), bytes_per_line):
        line = prefix + ''.join(f'0x{b:02x}, ' for b in value[i:i+bytes_per_line])
        print(f'{line.rstrip()}')

def print_static_u8_array_definition(name, value):
    print('')
    print(f'static const u8 {name} = {{')
    print_bytes('\t', value, 8)
    print('};')

def print_c_struct_u8_array_field(name, value):
    print(f'\t\t.{name} = {{')
    print_bytes('\t\t\t', value, 8)
    print('\t\t},')

def gen_unkeyed_testvecs(alg):
    print('')
    print('static const struct {')
    print('\tsize_t data_len;')
    print(f'\tu8 digest[{alg.upper()}_DIGEST_SIZE];')
    print('} hash_testvecs[] = {')
    for data_len in DATA_LENS:
        data = rand_bytes(data_len)
        print('\t{')
        print(f'\t\t.data_len = {data_len},')
        print_c_struct_u8_array_field('digest', compute_hash(alg, data))
        print('\t},')
    print('};')

    data = rand_bytes(4096)
    ctx = hash_init(alg)
    for data_len in range(len(data) + 1):
        hash_update(ctx, compute_hash(alg, data[:data_len]))
    print_static_u8_array_definition(
            f'hash_testvec_consolidated[{alg.upper()}_DIGEST_SIZE]',
            hash_final(ctx))

def gen_hmac_testvecs(alg):
    ctx = hmac.new(rand_bytes(32), digestmod=alg)
    data = rand_bytes(4096)
    for data_len in range(len(data) + 1):
        ctx.update(data[:data_len])
        key_len = data_len % 293
        key = rand_bytes(key_len)
        mac = hmac.digest(key, data[:data_len], alg)
        ctx.update(mac)
    print_static_u8_array_definition(
            f'hmac_testvec_consolidated[{alg.upper()}_DIGEST_SIZE]',
            ctx.digest())

if len(sys.argv) != 2:
    sys.stderr.write('Usage: gen-hash-testvecs.py ALGORITHM\n')
    sys.stderr.write('ALGORITHM may be any supported by Python hashlib.\n')
    sys.stderr.write('Example: gen-hash-testvecs.py sha512\n')
    sys.exit(1)

alg = sys.argv[1]
print('/* SPDX-License-Identifier: GPL-2.0-or-later */')
print(f'/* This file was generated by: {sys.argv[0]} {" ".join(sys.argv[1:])} */')
gen_unkeyed_testvecs(alg)
gen_hmac_testvecs(alg)
lib/crypto: tests: Add hash-test-template.h and gen-hash-testvecs.py Add hash-test-template.h which generates the following KUnit test cases for hash functions: test_hash_test_vectors test_hash_all_lens_up_to_4096 test_hash_incremental_updates test_hash_buffer_overruns test_hash_overlaps test_hash_alignment_consistency test_hash_ctx_zeroization test_hash_interrupt_context_1 test_hash_interrupt_context_2 test_hmac (when HMAC is supported) benchmark_hash (when CONFIG_CRYPTO_LIB_BENCHMARK=y) The initial use cases for this will be sha224_kunit, sha256_kunit, sha384_kunit, sha512_kunit, and poly1305_kunit. Add a Python script gen-hash-testvecs.py which generates the test vectors required by test_hash_test_vectors, test_hash_all_lens_up_to_4096, and test_hmac. Acked-by: Ard Biesheuvel <ardb@kernel.org> Link: https://lore.kernel.org/r/20250709200112.258500-2-ebiggers@kernel.org Signed-off-by: Eric Biggers <ebiggers@kernel.org> 2025-07-09 20:01:09 +00:00			`#!/usr/bin/env python3`
			`# SPDX-License-Identifier: GPL-2.0-or-later`
			`#`
			`# Script that generates test vectors for the given cryptographic hash function.`
			`#`
			`# Copyright 2025 Google LLC`

			`import hashlib`
			`import hmac`
			`import sys`

			`DATA_LENS = [0, 1, 2, 3, 16, 32, 48, 49, 63, 64, 65, 127, 128, 129, 256, 511,`
			`513, 1000, 3333, 4096, 4128, 4160, 4224, 16384]`

			`# Generate the given number of random bytes, using the length itself as the seed`
			`# for a simple linear congruential generator (LCG). The C test code uses the`
			`# same LCG with the same seeding strategy to reconstruct the data, ensuring`
			`# reproducibility without explicitly storing the data in the test vectors.`
			`def rand_bytes(length):`
			`seed = length`
			`out = []`
			`for _ in range(length):`
			`seed = (seed * 25214903917 + 11) % 2**48`
			`out.append((seed >> 16) % 256)`
			`return bytes(out)`

			`def hash_init(alg):`
			`return hashlib.new(alg)`

			`def hash_update(ctx, data):`
			`ctx.update(data)`

			`def hash_final(ctx):`
			`return ctx.digest()`

			`def compute_hash(alg, data):`
			`ctx = hash_init(alg)`
			`hash_update(ctx, data)`
			`return hash_final(ctx)`

			`def print_bytes(prefix, value, bytes_per_line):`
			`for i in range(0, len(value), bytes_per_line):`
			`line = prefix + ''.join(f'0x{b:02x}, ' for b in value[i:i+bytes_per_line])`
			`print(f'{line.rstrip()}')`

			`def print_static_u8_array_definition(name, value):`
			`print('')`
			`print(f'static const u8 {name} = {{')`
			`print_bytes('\t', value, 8)`
			`print('};')`

			`def print_c_struct_u8_array_field(name, value):`
			`print(f'\t\t.{name} = {{')`
			`print_bytes('\t\t\t', value, 8)`
			`print('\t\t},')`

			`def gen_unkeyed_testvecs(alg):`
			`print('')`
			`print('static const struct {')`
			`print('\tsize_t data_len;')`
			`print(f'\tu8 digest[{alg.upper()}_DIGEST_SIZE];')`
			`print('} hash_testvecs[] = {')`
			`for data_len in DATA_LENS:`
			`data = rand_bytes(data_len)`
			`print('\t{')`
			`print(f'\t\t.data_len = {data_len},')`
			`print_c_struct_u8_array_field('digest', compute_hash(alg, data))`
			`print('\t},')`
			`print('};')`

			`data = rand_bytes(4096)`
			`ctx = hash_init(alg)`
			`for data_len in range(len(data) + 1):`
			`hash_update(ctx, compute_hash(alg, data[:data_len]))`
			`print_static_u8_array_definition(`
			`f'hash_testvec_consolidated[{alg.upper()}_DIGEST_SIZE]',`
			`hash_final(ctx))`

			`def gen_hmac_testvecs(alg):`
			`ctx = hmac.new(rand_bytes(32), digestmod=alg)`
			`data = rand_bytes(4096)`
			`for data_len in range(len(data) + 1):`
			`ctx.update(data[:data_len])`
			`key_len = data_len % 293`
			`key = rand_bytes(key_len)`
			`mac = hmac.digest(key, data[:data_len], alg)`
			`ctx.update(mac)`
			`print_static_u8_array_definition(`
			`f'hmac_testvec_consolidated[{alg.upper()}_DIGEST_SIZE]',`
			`ctx.digest())`

			`if len(sys.argv) != 2:`
			`sys.stderr.write('Usage: gen-hash-testvecs.py ALGORITHM\n')`
			`sys.stderr.write('ALGORITHM may be any supported by Python hashlib.\n')`
			`sys.stderr.write('Example: gen-hash-testvecs.py sha512\n')`
			`sys.exit(1)`

			`alg = sys.argv[1]`
			`print('/* SPDX-License-Identifier: GPL-2.0-or-later */')`
			`print(f'/* This file was generated by: {sys.argv[0]} {" ".join(sys.argv[1:])} */')`
			`gen_unkeyed_testvecs(alg)`
			`gen_hmac_testvecs(alg)`