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qmk_firmware/tests/secure/test_secure.cpp
Stefan Kerkmann c2b13bd77b
Introduce VERIFY_AND_CLEAR shorthand (#19370)
Which is just a syntactic sugar for
testing::Mock::VerifyAndClearExpectations to reduce the visual clutter
in unit-tests.
2022-12-18 21:55:14 +01:00

261 lines
7.6 KiB
C++

/* Copyright 2021 Stefan Kerkmann
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include "gtest/gtest.h"
#include "keyboard_report_util.hpp"
#include "test_common.hpp"
using testing::_;
using testing::AnyNumber;
using testing::InSequence;
class Secure : public TestFixture {
public:
void SetUp() override {
secure_lock();
}
};
TEST_F(Secure, test_lock) {
TestDriver driver;
// Don't allow empty reports.
EXPECT_NO_REPORT(driver);
EXPECT_FALSE(secure_is_unlocked());
secure_unlock();
EXPECT_TRUE(secure_is_unlocked());
run_one_scan_loop();
EXPECT_TRUE(secure_is_unlocked());
secure_lock();
EXPECT_FALSE(secure_is_unlocked());
VERIFY_AND_CLEAR(driver);
}
TEST_F(Secure, test_unlock_timeout) {
TestDriver driver;
// Don't allow empty reports.
EXPECT_NO_REPORT(driver);
EXPECT_FALSE(secure_is_unlocked());
secure_unlock();
EXPECT_TRUE(secure_is_unlocked());
idle_for(SECURE_IDLE_TIMEOUT + 1);
EXPECT_FALSE(secure_is_unlocked());
VERIFY_AND_CLEAR(driver);
}
TEST_F(Secure, test_unlock_request) {
TestDriver driver;
auto key_mo = KeymapKey(0, 0, 0, MO(1));
auto key_a = KeymapKey(0, 1, 0, KC_A);
auto key_b = KeymapKey(0, 2, 0, KC_B);
auto key_c = KeymapKey(0, 3, 0, KC_C);
auto key_d = KeymapKey(0, 4, 0, KC_D);
set_keymap({key_mo, key_a, key_b, key_c, key_d});
// Don't allow empty reports.
EXPECT_NO_REPORT(driver);
EXPECT_TRUE(secure_is_locked());
secure_request_unlock();
EXPECT_TRUE(secure_is_unlocking());
tap_keys(key_a, key_b, key_c, key_d);
EXPECT_TRUE(secure_is_unlocked());
VERIFY_AND_CLEAR(driver);
}
TEST_F(Secure, test_unlock_request_fail) {
TestDriver driver;
auto key_e = KeymapKey(0, 0, 0, KC_E);
auto key_a = KeymapKey(0, 1, 0, KC_A);
auto key_b = KeymapKey(0, 2, 0, KC_B);
auto key_c = KeymapKey(0, 3, 0, KC_C);
auto key_d = KeymapKey(0, 4, 0, KC_D);
set_keymap({key_e, key_a, key_b, key_c, key_d});
// Allow any number of empty reports.
EXPECT_EMPTY_REPORT(driver).Times(AnyNumber());
{ // Expect the following reports in this order.
InSequence s;
EXPECT_REPORT(driver, (KC_A));
EXPECT_REPORT(driver, (KC_B));
EXPECT_REPORT(driver, (KC_C));
EXPECT_REPORT(driver, (KC_D));
}
EXPECT_TRUE(secure_is_locked());
secure_request_unlock();
EXPECT_TRUE(secure_is_unlocking());
tap_keys(key_e, key_a, key_b, key_c, key_d);
EXPECT_FALSE(secure_is_unlocked());
VERIFY_AND_CLEAR(driver);
}
TEST_F(Secure, test_unlock_request_timeout) {
TestDriver driver;
// Don't allow empty reports.
EXPECT_NO_REPORT(driver);
EXPECT_FALSE(secure_is_unlocked());
secure_request_unlock();
EXPECT_TRUE(secure_is_unlocking());
idle_for(SECURE_UNLOCK_TIMEOUT + 1);
EXPECT_FALSE(secure_is_unlocking());
EXPECT_FALSE(secure_is_unlocked());
VERIFY_AND_CLEAR(driver);
}
TEST_F(Secure, test_unlock_request_fail_mid) {
TestDriver driver;
auto key_e = KeymapKey(0, 0, 0, KC_E);
auto key_a = KeymapKey(0, 1, 0, KC_A);
auto key_b = KeymapKey(0, 2, 0, KC_B);
auto key_c = KeymapKey(0, 3, 0, KC_C);
auto key_d = KeymapKey(0, 4, 0, KC_D);
set_keymap({key_e, key_a, key_b, key_c, key_d});
// Allow any number of empty reports.
EXPECT_EMPTY_REPORT(driver).Times(AnyNumber());
{ // Expect the following reports in this order.
InSequence s;
EXPECT_REPORT(driver, (KC_C));
EXPECT_REPORT(driver, (KC_D));
}
EXPECT_FALSE(secure_is_unlocked());
secure_request_unlock();
EXPECT_TRUE(secure_is_unlocking());
tap_keys(key_a, key_b, key_e, key_c, key_d);
EXPECT_FALSE(secure_is_unlocking());
EXPECT_FALSE(secure_is_unlocked());
VERIFY_AND_CLEAR(driver);
}
TEST_F(Secure, test_unlock_request_fail_out_of_order) {
TestDriver driver;
auto key_e = KeymapKey(0, 0, 0, KC_E);
auto key_a = KeymapKey(0, 1, 0, KC_A);
auto key_b = KeymapKey(0, 2, 0, KC_B);
auto key_c = KeymapKey(0, 3, 0, KC_C);
auto key_d = KeymapKey(0, 4, 0, KC_D);
set_keymap({key_e, key_a, key_b, key_c, key_d});
// Allow any number of empty reports.
EXPECT_EMPTY_REPORT(driver).Times(AnyNumber());
{ // Expect the following reports in this order.
InSequence s;
EXPECT_REPORT(driver, (KC_B));
EXPECT_REPORT(driver, (KC_C));
}
EXPECT_FALSE(secure_is_unlocked());
secure_request_unlock();
EXPECT_TRUE(secure_is_unlocking());
tap_keys(key_a, key_d, key_b, key_c);
EXPECT_TRUE(secure_is_locked());
EXPECT_FALSE(secure_is_unlocking());
EXPECT_FALSE(secure_is_unlocked());
VERIFY_AND_CLEAR(driver);
}
TEST_F(Secure, test_unlock_request_on_layer) {
TestDriver driver;
auto key_mo = KeymapKey(0, 0, 0, MO(1));
auto key_a = KeymapKey(0, 1, 0, KC_A);
auto key_b = KeymapKey(0, 2, 0, KC_B);
auto key_c = KeymapKey(0, 3, 0, KC_C);
auto key_d = KeymapKey(0, 4, 0, KC_D);
set_keymap({key_mo, key_a, key_b, key_c, key_d});
// Don't allow empty reports.
EXPECT_NO_REPORT(driver);
EXPECT_TRUE(secure_is_locked());
key_mo.press();
run_one_scan_loop();
secure_request_unlock();
key_mo.release();
run_one_scan_loop();
EXPECT_TRUE(secure_is_unlocking());
tap_keys(key_a, key_b, key_c, key_d);
EXPECT_TRUE(secure_is_unlocked());
EXPECT_FALSE(layer_state_is(1));
VERIFY_AND_CLEAR(driver);
}
TEST_F(Secure, test_unlock_request_mid_stroke) {
TestDriver driver;
auto key_e = KeymapKey(0, 0, 0, KC_E);
auto key_a = KeymapKey(0, 1, 0, KC_A);
auto key_b = KeymapKey(0, 2, 0, KC_B);
auto key_c = KeymapKey(0, 3, 0, KC_C);
auto key_d = KeymapKey(0, 4, 0, KC_D);
set_keymap({key_e, key_a, key_b, key_c, key_d});
EXPECT_REPORT(driver, (KC_E));
EXPECT_EMPTY_REPORT(driver);
EXPECT_TRUE(secure_is_locked());
key_e.press();
run_one_scan_loop();
secure_request_unlock();
key_e.release();
run_one_scan_loop();
EXPECT_TRUE(secure_is_unlocking());
tap_keys(key_a, key_b, key_c, key_d);
EXPECT_TRUE(secure_is_unlocked());
VERIFY_AND_CLEAR(driver);
}
TEST_F(Secure, test_unlock_request_mods) {
TestDriver driver;
auto key_lsft = KeymapKey(0, 0, 0, KC_LSFT);
auto key_a = KeymapKey(0, 1, 0, KC_A);
auto key_b = KeymapKey(0, 2, 0, KC_B);
auto key_c = KeymapKey(0, 3, 0, KC_C);
auto key_d = KeymapKey(0, 4, 0, KC_D);
set_keymap({key_lsft, key_a, key_b, key_c, key_d});
EXPECT_REPORT(driver, (key_lsft.report_code));
EXPECT_EMPTY_REPORT(driver);
EXPECT_TRUE(secure_is_locked());
key_lsft.press();
run_one_scan_loop();
secure_request_unlock();
key_lsft.release();
run_one_scan_loop();
EXPECT_TRUE(secure_is_unlocking());
tap_keys(key_a, key_b, key_c, key_d);
EXPECT_TRUE(secure_is_unlocked());
VERIFY_AND_CLEAR(driver);
}