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boringssl / boringssl / 298ac78507178d1e7d058eee1e52333f760eb0c1 / . / crypto / spake2plus / spake2plus_test.cc
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// Copyright 2024 The BoringSSL Authors
//
// 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
//
// https://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.
#include <openssl/base.h>
#include <string>
#include <unordered_map>
#include <utility>
#include <vector>
#include <stdint.h>
#include <stdio.h>
#include <string.h>
#include <openssl/bn.h>
#include <openssl/span.h>
#include <gtest/gtest.h>
#include "../internal.h"
#include "../test/test_util.h"
#include "./internal.h"
BSSL_NAMESPACE_BEGIN
namespace {
using namespace spake2plus;
std::vector<uint8_t> HexToBytes(const char *str) {
std::vector<uint8_t> ret;
if (!DecodeHex(&ret, str)) {
abort();
}
return ret;
}
class RegistrationCache {
public:
struct Result {
std::vector<uint8_t> w0, w1, record;
};
const Result &Get(const std::pair<std::string, std::string> &names,
const std::string &pw) {
CacheKey key{names.first, names.second, pw};
auto it = cache.find(key);
if (it != cache.end()) {
return it->second;
}
Result output;
output.w0.resize(kVerifierSize);
output.w1.resize(kVerifierSize);
output.record.resize(kRegistrationRecordSize);
if (!Register(Span(output.w0), Span(output.w1), Span(output.record),
StringAsBytes(pw), StringAsBytes(names.first),
StringAsBytes(names.second))) {
abort();
}
return cache.emplace(std::move(key), std::move(output)).first->second;
}
private:
struct CacheKey {
std::string id_prover, id_verifier, password;
bool operator==(const CacheKey &other) const {
return std::tie(id_prover, id_verifier, password) ==
std::tie(other.id_prover, other.id_verifier, other.password);
}
};
struct KeyHash {
std::size_t operator()(const CacheKey &k) const {
return std::hash<std::string>()(k.id_prover) ^
std::hash<std::string>()(k.id_verifier) ^
std::hash<std::string>()(k.password);
}
};
std::unordered_map<CacheKey, Result, KeyHash> cache;
};
RegistrationCache &GlobalRegistrationCache() {
static RegistrationCache cache;
return cache;
}
struct SPAKEPLUSRun {
bool Run() {
const RegistrationCache::Result &registration =
GlobalRegistrationCache().Get(prover_names, pw);
Prover prover;
if (!prover.Init(StringAsBytes(context), StringAsBytes(prover_names.first),
StringAsBytes(prover_names.second), registration.w0,
registration.w1)) {
return false;
}
std::vector<uint8_t> verifier_registration_record = registration.record;
if (verifier_corrupt_record) {
verifier_registration_record[verifier_registration_record.size() - 1] ^=
0xFF;
}
Verifier verifier;
if (!verifier.Init(StringAsBytes(context),
StringAsBytes(verifier_names.first),
StringAsBytes(verifier_names.second), registration.w0,
verifier_registration_record)) {
return false;
}
uint8_t prover_share[kShareSize];
if (!prover.GenerateShare(prover_share)) {
return false;
}
if (repeat_invocations && prover.GenerateShare(prover_share)) {
return false;
}
if (prover_corrupt_msg_bit &&
*prover_corrupt_msg_bit < 8 * sizeof(prover_share)) {
prover_share[*prover_corrupt_msg_bit / 8] ^=
1 << (*prover_corrupt_msg_bit & 7);
}
uint8_t verifier_share[kShareSize];
uint8_t verifier_confirm[kConfirmSize];
uint8_t verifier_secret[kSecretSize];
if (!verifier.ProcessProverShare(verifier_share, verifier_confirm,
verifier_secret, prover_share)) {
return false;
}
if (repeat_invocations &&
verifier.ProcessProverShare(verifier_share, verifier_confirm,
verifier_secret, prover_share)) {
return false;
}
uint8_t prover_confirm[kConfirmSize];
uint8_t prover_secret[kSecretSize];
if (!prover.ComputeConfirmation(prover_confirm, prover_secret,
verifier_share, verifier_confirm)) {
return false;
}
if (repeat_invocations && //
prover.ComputeConfirmation(prover_confirm, prover_secret,
verifier_share, verifier_confirm)) {
return false;
}
if (prover_corrupt_confirm_bit &&
*prover_corrupt_confirm_bit < 8 * sizeof(prover_confirm)) {
prover_confirm[*prover_corrupt_confirm_bit / 8] ^=
1 << (*prover_corrupt_confirm_bit & 7);
}
if (!verifier.VerifyProverConfirmation(prover_confirm)) {
return false;
}
if (repeat_invocations &&
verifier.VerifyProverConfirmation(prover_confirm)) {
return false;
}
key_matches_ = Span(prover_secret) == Span(verifier_secret);
return true;
}
bool key_matches() const { return key_matches_; }
std::string context =
"SPAKE2+-P256-SHA256-HKDF-SHA256-HMAC-SHA256 Test Vectors";
std::string pw = "password";
std::pair<std::string, std::string> prover_names = {"client", "server"};
std::pair<std::string, std::string> verifier_names = {"client", "server"};
bool verifier_corrupt_record = false;
bool repeat_invocations = false;
std::optional<size_t> prover_corrupt_msg_bit;
std::optional<size_t> prover_corrupt_confirm_bit;
private:
bool key_matches_ = false;
};
TEST(SPAKEPLUSTest, TestVectors) {
// https://datatracker.ietf.org/doc/html/rfc9383#appendix-C
// SPAKE2+-P256-SHA256-HKDF-SHA256-HMAC-SHA256 Test Vectors
const char w0_str[] =
"bb8e1bbcf3c48f62c08db243652ae55d3e5586053fca77102994f23ad95491b3";
const char w1_str[] =
"7e945f34d78785b8a3ef44d0df5a1a97d6b3b460409a345ca7830387a74b1dba";
const char L_str[] =
"04eb7c9db3d9a9eb1f8adab81b5794c1f13ae3e225efbe91ea487425854c7fc00f00bfed"
"cbd09b2400142d40a14f2064ef31dfaa903b91d1faea7093d835966efd";
const char x_str[] =
"d1232c8e8693d02368976c174e2088851b8365d0d79a9eee709c6a05a2fad539";
const char share_p_str[] =
"04ef3bd051bf78a2234ec0df197f7828060fe9856503579bb1733009042c15c0c1de1277"
"27f418b5966afadfdd95a6e4591d171056b333dab97a79c7193e341727";
const char y_str[] =
"717a72348a182085109c8d3917d6c43d59b224dc6a7fc4f0483232fa6516d8b3";
const char share_v_str[] =
"04c0f65da0d11927bdf5d560c69e1d7d939a05b0e88291887d679fcadea75810fb5cc1ca"
"7494db39e82ff2f50665255d76173e09986ab46742c798a9a68437b048";
const char confirm_p_str[] =
"926cc713504b9b4d76c9162ded04b5493e89109f6d89462cd33adc46fda27527";
const char confirm_v_str[] =
"9747bcc4f8fe9f63defee53ac9b07876d907d55047e6ff2def2e7529089d3e68";
const char secret_str[] =
"0c5f8ccd1413423a54f6c1fb26ff01534a87f893779c6e68666d772bfd91f3e7";
const std::string context =
"SPAKE2+-P256-SHA256-HKDF-SHA256-HMAC-SHA256 Test Vectors";
const std::pair<std::string, std::string> prover_names = {"client", "server"};
const std::pair<std::string, std::string> verifier_names = {"client",
"server"};
std::vector<uint8_t> w0 = HexToBytes(w0_str);
std::vector<uint8_t> w1 = HexToBytes(w1_str);
std::vector<uint8_t> registration_record = HexToBytes(L_str);
std::vector<uint8_t> x = HexToBytes(x_str);
std::vector<uint8_t> y = HexToBytes(y_str);
Prover prover;
ASSERT_TRUE(prover.Init(StringAsBytes(context),
StringAsBytes(prover_names.first),
StringAsBytes(prover_names.second), MakeConstSpan(w0),
MakeConstSpan(w1), x));
Verifier verifier;
ASSERT_TRUE(
verifier.Init(StringAsBytes(context), StringAsBytes(prover_names.first),
StringAsBytes(prover_names.second), MakeConstSpan(w0),
MakeConstSpan(registration_record), y));
uint8_t prover_share[kShareSize];
ASSERT_TRUE(prover.GenerateShare(prover_share));
std::vector<uint8_t> share_p = HexToBytes(share_p_str);
ASSERT_TRUE(
OPENSSL_memcmp(share_p.data(), prover_share, sizeof(prover_share)) == 0);
uint8_t verifier_share[kShareSize];
uint8_t verifier_confirm[kConfirmSize];
uint8_t verifier_secret[kSecretSize];
ASSERT_TRUE(verifier.ProcessProverShare(verifier_share, verifier_confirm,
verifier_secret, prover_share));
std::vector<uint8_t> share_v = HexToBytes(share_v_str);
ASSERT_TRUE(OPENSSL_memcmp(share_v.data(), verifier_share,
sizeof(verifier_share)) == 0);
std::vector<uint8_t> confirm_v = HexToBytes(confirm_v_str);
ASSERT_TRUE(OPENSSL_memcmp(confirm_v.data(), verifier_confirm,
sizeof(verifier_confirm)) == 0);
uint8_t prover_confirm[kConfirmSize];
uint8_t prover_secret[kSecretSize];
ASSERT_TRUE(prover.ComputeConfirmation(prover_confirm, prover_secret,
verifier_share, verifier_confirm));
std::vector<uint8_t> confirm_p = HexToBytes(confirm_p_str);
ASSERT_TRUE(OPENSSL_memcmp(confirm_p.data(), prover_confirm,
sizeof(prover_confirm)) == 0);
ASSERT_TRUE(verifier.VerifyProverConfirmation(prover_confirm));
std::vector<uint8_t> expected_secret = HexToBytes(secret_str);
static_assert(sizeof(verifier_secret) == sizeof(prover_secret));
ASSERT_TRUE(OPENSSL_memcmp(prover_secret, verifier_secret,
sizeof(prover_secret)) == 0);
ASSERT_TRUE(OPENSSL_memcmp(expected_secret.data(), verifier_secret,
sizeof(verifier_secret)) == 0);
}
TEST(SPAKEPLUSTest, SPAKEPLUS) {
for (unsigned i = 0; i < 20; i++) {
SPAKEPLUSRun spake2;
ASSERT_TRUE(spake2.Run());
EXPECT_TRUE(spake2.key_matches());
}
}
TEST(SPAKEPLUSTest, WrongPassword) {
SPAKEPLUSRun spake2;
spake2.verifier_corrupt_record = true;
ASSERT_FALSE(spake2.Run());
}
TEST(SPAKEPLUSTest, WrongNames) {
SPAKEPLUSRun spake2;
spake2.prover_names.second = "alice";
spake2.verifier_names.second = "bob";
ASSERT_FALSE(spake2.Run());
}
TEST(SPAKEPLUSTest, CorruptMessages) {
for (size_t i = 0; i < 8 * kShareSize; i++) {
SPAKEPLUSRun spake2;
spake2.prover_corrupt_msg_bit = i;
EXPECT_FALSE(spake2.Run())
<< "Passed after corrupting Prover's key share message, bit " << i;
}
for (size_t i = 0; i < 8 * kConfirmSize; i++) {
SPAKEPLUSRun spake2;
spake2.prover_corrupt_confirm_bit = i;
EXPECT_FALSE(spake2.Run())
<< "Passed after corrupting Verifier's confirmation message, bit " << i;
}
}
TEST(SPAKEPLUSTest, StateMachine) {
SPAKEPLUSRun spake2;
spake2.repeat_invocations = true;
ASSERT_TRUE(spake2.Run());
}
} // namespace
BSSL_NAMESPACE_END