1
0
mirror of https://github.com/trezor/trezor-firmware.git synced 2024-12-21 13:58:08 +00:00
trezor-firmware/tests/fido_tests/u2f-tests-hid/U2FTest.cc
2019-09-13 12:47:28 +02:00

385 lines
10 KiB
C++

// Copyright 2014 Google Inc. All rights reserved.
//
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file or at
// https://developers.google.com/open-source/licenses/bsd
// U2F register / sign compliance test.
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <time.h>
#include <iostream>
#include <iomanip>
#ifdef __OS_WIN
#include <winsock2.h> // ntohl, htonl
#else
#include <arpa/inet.h> // ntohl, htonl
#endif
#include "u2f.h"
#include "u2f_util.h"
#include "dsa_sig.h"
#include "p256.h"
#include "p256_ecdsa.h"
#include "sha256.h"
using namespace std;
int arg_Verbose = 0; // default
bool arg_Pause = false; // default
bool arg_Abort = true; // default
static
void pause(const string& prompt) {
printf("\n%s", prompt.c_str());
getchar();
printf("\n");
}
static
void checkPause(const string& prompt) {
if (arg_Pause) pause(prompt);
}
static
void AbortOrNot() {
checkPause("Hit enter to continue..");
if (arg_Abort) exit(3);
cerr << "(continuing -a)" << endl;
}
void WaitForUserPresence(struct U2Fob* device, bool hasButton) {
int touched = DEV_touch(device);
U2Fob_close(device);
if (!touched) {
pause(string(hasButton ? "Touch" : "Re-insert") + " device and hit enter..");
}
CHECK_EQ(0, U2Fob_reopen(device));
CHECK_EQ(0, U2Fob_init(device));
}
struct U2Fob* device;
U2F_REGISTER_REQ regReq;
U2F_REGISTER_RESP regRsp;
U2F_AUTHENTICATE_REQ authReq;
void test_Version() {
string rsp;
int res = U2Fob_apdu(device, 0, U2F_INS_VERSION, 0, 0, "", &rsp);
if (res == 0x9000) {
CHECK_EQ(rsp, "U2F_V2");
return;
}
// Non-ISO 7816-4 compliant U2F_INS_VERSION "APDU" that includes Lc value 0,
// for compatibility with older devices.
uint8_t buf[4 + 3 + 2];
buf[0] = 0; // CLA
buf[1] = U2F_INS_VERSION; // INS
buf[2] = 0; // P1
buf[3] = 0; // P2
buf[4] = 0; // extended length
buf[5] = 0; // Lc = 0 (Not ISO 7816-4 compliant)
buf[6] = 0; // Lc = 0 (Not ISO 7816-4 compliant)
buf[7] = 0; // Le = 0
buf[8] = 0; // Le = 0
CHECK_EQ(0x9000, U2Fob_exchange_apdu_buffer(device, buf, sizeof(buf), &rsp));
CHECK_EQ(rsp, "U2F_V2");
}
void test_UnknownINS() {
string rsp;
CHECK_EQ(0x6D00, U2Fob_apdu(device, 0, 0 /* not U2F INS */,
0, 0, "", &rsp));
CHECK_EQ(rsp.empty(), true);
}
void test_BadCLA() {
string rsp;
CHECK_EQ(0x6E00, U2Fob_apdu(device, 1 /* not U2F CLA, 0x00 */,
U2F_INS_VERSION, 0, 0, "abc", &rsp));
CHECK_EQ(rsp.empty(), true);
}
void test_WrongLength_U2F_VERSION() {
string rsp;
// U2F_VERSION does not take any input.
CHECK_EQ(0x6700, U2Fob_apdu(device, 0, U2F_INS_VERSION, 0, 0, "abc", &rsp));
CHECK_EQ(rsp.empty(), true);
}
void test_WrongLength_U2F_REGISTER() {
string rsp;
// U2F_REGISTER does expect input.
CHECK_EQ(0x6700, U2Fob_apdu(device, 0, U2F_INS_REGISTER, 0, 0, "abc", &rsp));
CHECK_EQ(rsp.empty(), true);
}
void test_Enroll(int expectedSW12 = 0x9000) {
uint64_t t = 0; U2Fob_deltaTime(&t);
string rsp;
CHECK_EQ(expectedSW12,
U2Fob_apdu(device, 0, U2F_INS_REGISTER, U2F_AUTH_ENFORCE, 0,
string(reinterpret_cast<char*>(&regReq),
sizeof(regReq)),
&rsp));
if (expectedSW12 != 0x9000) {
CHECK_EQ(true, rsp.empty());
return;
}
CHECK_NE(rsp.empty(), true);
CHECK_LE(rsp.size(), sizeof(U2F_REGISTER_RESP));
memcpy(&regRsp, rsp.data(), rsp.size());
CHECK_EQ(regRsp.registerId, U2F_REGISTER_ID);
CHECK_EQ(regRsp.pubKey.format, UNCOMPRESSED_POINT);
INFO << "Enroll: " << rsp.size() << " bytes in "
<< U2Fob_deltaTime(&t) << "s";
// Check crypto of enroll response.
string cert;
CHECK_EQ(getCertificate(regRsp, &cert), true);
INFO << "cert: " << b2a(cert);
string pk;
CHECK_EQ(getSubjectPublicKey(cert, &pk), true);
INFO << "pk : " << b2a(pk);
string sig;
CHECK_EQ(getSignature(regRsp, &sig), true);
INFO << "sig : " << b2a(sig);
// Parse signature into two integers.
p256_int sig_r, sig_s;
CHECK_EQ(1, dsa_sig_unpack((uint8_t*) (sig.data()), sig.size(),
&sig_r, &sig_s));
// Compute hash as integer.
p256_int h;
SHA256_CTX sha;
SHA256_init(&sha);
uint8_t rfu = 0;
SHA256_update(&sha, &rfu, sizeof(rfu)); // 0x00
SHA256_update(&sha, regReq.appId, sizeof(regReq.appId)); // O
SHA256_update(&sha, regReq.nonce, sizeof(regReq.nonce)); // d
SHA256_update(&sha, regRsp.keyHandleCertSig, regRsp.keyHandleLen); // hk
SHA256_update(&sha, &regRsp.pubKey, sizeof(regRsp.pubKey)); // pk
p256_from_bin(SHA256_final(&sha), &h);
// Parse subject public key into two integers.
CHECK_EQ(pk.size(), P256_POINT_SIZE);
p256_int pk_x, pk_y;
p256_from_bin((uint8_t*) pk.data() + 1, &pk_x);
p256_from_bin((uint8_t*) pk.data() + 1 + P256_SCALAR_SIZE, &pk_y);
// Verify signature.
CHECK_EQ(1, p256_ecdsa_verify(&pk_x, &pk_y, &h, &sig_r, &sig_s));
#if 0
// Check for standard U2F self-signed certificate.
// Implementations without batch attestation should use this minimalist
// self-signed certificate for enroll.
// Conforming to a standard self-signed certficate format and attributes
// bins all such fobs into a single large batch, which helps privacy.
string selfSigned = a2b(
"3081B3A003020102020101300A06082A8648CE3D040302300E310C300A060355040A0C035532463022180F32303030303130313030303030305A180F32303939313233313233353935395A300E310C300A060355040313035532463059301306072A8648CE3D020106082A8648CE3D030107034200") + pk;
SHA256_init(&sha);
SHA256_update(&sha, selfSigned.data(), selfSigned.size());
p256_from_bin(SHA256_final(&sha), &h);
string certSig;
CHECK_EQ(getCertSignature(cert, &certSig), true);
INFO << "certSig : " << b2a(certSig);
CHECK_EQ(1, dsa_sig_unpack((uint8_t*) (certSig.data()), certSig.size(),
&sig_r, &sig_s));
// Verify cert signature.
CHECK_EQ(1, p256_ecdsa_verify(&pk_x, &pk_y, &h, &sig_r, &sig_s));
#endif
}
// returns ctr
uint32_t test_Sign(int expectedSW12 = 0x9000, bool checkOnly = false) {
memcpy(authReq.appId, regReq.appId, sizeof(authReq.appId));
authReq.keyHandleLen = regRsp.keyHandleLen;
memcpy(authReq.keyHandle, regRsp.keyHandleCertSig, authReq.keyHandleLen);
uint64_t t = 0; U2Fob_deltaTime(&t);
string rsp;
CHECK_EQ(expectedSW12,
U2Fob_apdu(device, 0, U2F_INS_AUTHENTICATE,
checkOnly ? U2F_AUTH_CHECK_ONLY : U2F_AUTH_ENFORCE, 0,
string(reinterpret_cast<char*>(&authReq),
U2F_NONCE_SIZE + U2F_APPID_SIZE + 1 +
authReq.keyHandleLen),
&rsp));
if (expectedSW12 != 0x9000) {
CHECK_EQ(true, rsp.empty());
return 0;
}
CHECK_NE(rsp.empty(), true);
CHECK_LE(rsp.size(), sizeof(U2F_AUTHENTICATE_RESP));
U2F_AUTHENTICATE_RESP resp;
memcpy(&resp, rsp.data(), rsp.size());
CHECK_EQ(resp.flags, 0x01);
INFO << "Sign: " << rsp.size() << " bytes in "
<< U2Fob_deltaTime(&t) << "s";
// Parse signature from authenticate response.
p256_int sig_r, sig_s;
CHECK_EQ(1, dsa_sig_unpack(resp.sig,
rsp.size() - sizeof(resp.flags) - sizeof(resp.ctr),
&sig_r, &sig_s));
// Compute hash as integer.
p256_int h;
SHA256_CTX sha;
SHA256_init(&sha);
SHA256_update(&sha, regReq.appId, sizeof(regReq.appId)); // O
SHA256_update(&sha, &resp.flags, sizeof(resp.flags)); // T
SHA256_update(&sha, &resp.ctr, sizeof(resp.ctr)); // CTR
SHA256_update(&sha, authReq.nonce, sizeof(authReq.nonce)); // d
p256_from_bin(SHA256_final(&sha), &h);
// Parse public key from registration response.
p256_int pk_x, pk_y;
p256_from_bin(regRsp.pubKey.x, &pk_x);
p256_from_bin(regRsp.pubKey.y, &pk_y);
// Verify signature.
CHECK_EQ(1, p256_ecdsa_verify(&pk_x, &pk_y, &h, &sig_r, &sig_s));
return ntohl(resp.ctr);
}
void check_Compilation() {
// Couple of sanity checks.
CHECK_EQ(sizeof(P256_POINT), 65);
CHECK_EQ(sizeof(U2F_REGISTER_REQ), 64);
}
int main(int argc, char* argv[]) {
if (argc < 2) {
cerr << "Usage: " << argv[0]
<< " <device-path> [-a] [-v] [-V] [-p] [-b]" << endl;
return -1;
}
device = U2Fob_create();
char* arg_DeviceName = argv[1];
bool arg_hasButton = true; // fob has button
while (--argc > 1) {
if (!strncmp(argv[argc], "-v", 2)) {
// Log INFO.
arg_Verbose |= 1;
}
if (!strncmp(argv[argc], "-V", 2)) {
// Log everything.
arg_Verbose |= 2;
U2Fob_setLog(device, stdout, -1);
}
if (!strncmp(argv[argc], "-a", 2)) {
// Don't abort, try continue;
arg_Abort = false;
}
if (!strncmp(argv[argc], "-p", 2)) {
// Pause at abort
arg_Pause = true;
}
if (!strncmp(argv[argc], "-b", 2)) {
// Fob does not have button
arg_hasButton = false;
}
}
srand((unsigned int) time(NULL));
CHECK_EQ(0, U2Fob_open(device, arg_DeviceName));
CHECK_EQ(0, U2Fob_init(device));
PASS(check_Compilation());
PASS(test_Version());
PASS(test_UnknownINS());
PASS(test_WrongLength_U2F_VERSION());
PASS(test_WrongLength_U2F_REGISTER());
PASS(test_BadCLA());
// pick random origin and challenge.
for (size_t i = 0; i < sizeof(regReq.nonce); ++i)
regReq.nonce[i] = rand();
for (size_t i = 0; i < sizeof(regReq.appId); ++i)
regReq.appId[i] = rand();
// Fob with button should need touch.
if (arg_hasButton) PASS(test_Enroll(0x6985));
WaitForUserPresence(device, arg_hasButton);
PASS(test_Enroll(0x9000));
// pick random challenge and use registered appId.
for (size_t i = 0; i < sizeof(authReq.nonce); ++i)
authReq.nonce[i] = rand();
// Fob with button should have consumed touch.
if (arg_hasButton) PASS(test_Sign(0x6985));
// Sign with check only should not produce signature.
PASS(test_Sign(0x6985, true));
// Sign with wrong hk.
regRsp.keyHandleCertSig[0] ^= 0x55;
PASS(test_Sign(0x6a80));
regRsp.keyHandleCertSig[0] ^= 0x55;
// Sign with wrong appid.
regReq.appId[0] ^= 0xaa;
PASS(test_Sign(0x6a80));
regReq.appId[0] ^= 0xaa;
WaitForUserPresence(device, arg_hasButton);
// Sign with check only should not produce signature.
PASS(test_Sign(0x6985, true));
uint32_t ctr1;
PASS(ctr1 = test_Sign(0x9000));
PASS(test_Sign(0x6985));
WaitForUserPresence(device, arg_hasButton);
uint32_t ctr2;
PASS(ctr2 = test_Sign(0x9000));
// Ctr should have incremented by 1.
CHECK_EQ(ctr2, ctr1 + 1);
regRsp.keyHandleLen -= 8; // perturb keyhandle length
PASS(test_Sign(0x6a80, false));
U2Fob_destroy(device);
return 0;
}