// SPDX-License-Identifier: GPL-2.0-or-later /* * Copyright 2026 Google LLC */ #include #include "ghash-testvecs.h" /* * A fixed key used when presenting GHASH as an unkeyed hash function in order * to reuse hash-test-template.h. At the beginning of the test suite, this is * initialized to a key prepared from bytes generated from a fixed seed. */ static struct ghash_key test_key; static void ghash_init_withtestkey(struct ghash_ctx *ctx) { ghash_init(ctx, &test_key); } static void ghash_withtestkey(const u8 *data, size_t len, u8 out[GHASH_BLOCK_SIZE]) { ghash(&test_key, data, len, out); } /* Generate the HASH_KUNIT_CASES using hash-test-template.h. */ #define HASH ghash_withtestkey #define HASH_CTX ghash_ctx #define HASH_SIZE GHASH_BLOCK_SIZE #define HASH_INIT ghash_init_withtestkey #define HASH_UPDATE ghash_update #define HASH_FINAL ghash_final #include "hash-test-template.h" /* * Test a key and messages containing all one bits. This is useful to detect * overflow bugs in implementations that emulate carryless multiplication using * a series of standard multiplications with the bits spread out. */ static void test_ghash_allones_key_and_message(struct kunit *test) { struct ghash_key key; struct ghash_ctx hashofhashes_ctx; u8 hash[GHASH_BLOCK_SIZE]; static_assert(TEST_BUF_LEN >= 4096); memset(test_buf, 0xff, 4096); ghash_preparekey(&key, test_buf); ghash_init(&hashofhashes_ctx, &key); for (size_t len = 0; len <= 4096; len += 16) { ghash(&key, test_buf, len, hash); ghash_update(&hashofhashes_ctx, hash, sizeof(hash)); } ghash_final(&hashofhashes_ctx, hash); KUNIT_ASSERT_MEMEQ(test, hash, ghash_allones_hashofhashes, sizeof(hash)); } #define MAX_LEN_FOR_KEY_CHECK 1024 /* * Given two prepared keys which should be identical (but may differ in * alignment and/or whether they are followed by a guard page or not), verify * that they produce consistent results on various data lengths. */ static void check_key_consistency(struct kunit *test, const struct ghash_key *key1, const struct ghash_key *key2) { u8 *data = test_buf; u8 hash1[GHASH_BLOCK_SIZE]; u8 hash2[GHASH_BLOCK_SIZE]; rand_bytes(data, MAX_LEN_FOR_KEY_CHECK); KUNIT_ASSERT_MEMEQ(test, key1, key2, sizeof(*key1)); for (int i = 0; i < 100; i++) { size_t len = rand_length(MAX_LEN_FOR_KEY_CHECK); ghash(key1, data, len, hash1); ghash(key2, data, len, hash2); KUNIT_ASSERT_MEMEQ(test, hash1, hash2, sizeof(hash1)); } } /* Test that no buffer overreads occur on either raw_key or ghash_key. */ static void test_ghash_with_guarded_key(struct kunit *test) { u8 raw_key[GHASH_BLOCK_SIZE]; u8 *guarded_raw_key = &test_buf[TEST_BUF_LEN - sizeof(raw_key)]; struct ghash_key key1, key2; struct ghash_key *guarded_key = (struct ghash_key *)&test_buf[TEST_BUF_LEN - sizeof(key1)]; /* Prepare with regular buffers. */ rand_bytes(raw_key, sizeof(raw_key)); ghash_preparekey(&key1, raw_key); /* Prepare with guarded raw_key, then check that it works. */ memcpy(guarded_raw_key, raw_key, sizeof(raw_key)); ghash_preparekey(&key2, guarded_raw_key); check_key_consistency(test, &key1, &key2); /* Prepare guarded ghash_key, then check that it works. */ ghash_preparekey(guarded_key, raw_key); check_key_consistency(test, &key1, guarded_key); } /* * Test that ghash_key only needs to be aligned to * __alignof__(struct ghash_key), i.e. 8 bytes. The assembly code may prefer * 16-byte or higher alignment, but it mustn't require it. */ static void test_ghash_with_minimally_aligned_key(struct kunit *test) { u8 raw_key[GHASH_BLOCK_SIZE]; struct ghash_key key; struct ghash_key *minaligned_key = (struct ghash_key *)&test_buf[MAX_LEN_FOR_KEY_CHECK + __alignof__(struct ghash_key)]; KUNIT_ASSERT_TRUE(test, IS_ALIGNED((uintptr_t)minaligned_key, __alignof__(struct ghash_key))); KUNIT_ASSERT_TRUE(test, !IS_ALIGNED((uintptr_t)minaligned_key, 2 * __alignof__(struct ghash_key))); rand_bytes(raw_key, sizeof(raw_key)); ghash_preparekey(&key, raw_key); ghash_preparekey(minaligned_key, raw_key); check_key_consistency(test, &key, minaligned_key); } struct ghash_irq_test_state { struct ghash_key expected_key; u8 raw_key[GHASH_BLOCK_SIZE]; }; static bool ghash_irq_test_func(void *state_) { struct ghash_irq_test_state *state = state_; struct ghash_key key; ghash_preparekey(&key, state->raw_key); return memcmp(&key, &state->expected_key, sizeof(key)) == 0; } /* * Test that ghash_preparekey() produces the same output regardless of whether * FPU or vector registers are usable when it is called. */ static void test_ghash_preparekey_in_irqs(struct kunit *test) { struct ghash_irq_test_state state; rand_bytes(state.raw_key, sizeof(state.raw_key)); ghash_preparekey(&state.expected_key, state.raw_key); kunit_run_irq_test(test, ghash_irq_test_func, 200000, &state); } static int ghash_suite_init(struct kunit_suite *suite) { u8 raw_key[GHASH_BLOCK_SIZE]; rand_bytes_seeded_from_len(raw_key, sizeof(raw_key)); ghash_preparekey(&test_key, raw_key); return hash_suite_init(suite); } static void ghash_suite_exit(struct kunit_suite *suite) { hash_suite_exit(suite); } static struct kunit_case ghash_test_cases[] = { HASH_KUNIT_CASES, KUNIT_CASE(test_ghash_allones_key_and_message), KUNIT_CASE(test_ghash_with_guarded_key), KUNIT_CASE(test_ghash_with_minimally_aligned_key), KUNIT_CASE(test_ghash_preparekey_in_irqs), KUNIT_CASE(benchmark_hash), {}, }; static struct kunit_suite ghash_test_suite = { .name = "ghash", .test_cases = ghash_test_cases, .suite_init = ghash_suite_init, .suite_exit = ghash_suite_exit, }; kunit_test_suite(ghash_test_suite); MODULE_DESCRIPTION("KUnit tests and benchmark for GHASH"); MODULE_LICENSE("GPL");