/* * Copyright (c) 2021, Peter Bocan * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include #include #include static Crypto::UnsignedBigInteger bigint_fibonacci(size_t n) { Crypto::UnsignedBigInteger num1(0); Crypto::UnsignedBigInteger num2(1); for (size_t i = 0; i < n; ++i) { Crypto::UnsignedBigInteger t = num1.plus(num2); num2 = num1; num1 = t; } return num1; } static Crypto::SignedBigInteger bigint_signed_fibonacci(size_t n) { Crypto::SignedBigInteger num1(0); Crypto::SignedBigInteger num2(1); for (size_t i = 0; i < n; ++i) { Crypto::SignedBigInteger t = num1.plus(num2); num2 = num1; num1 = t; } return num1; } TEST_CASE(test_bigint_fib500) { Vector result { 315178285, 505575602, 1883328078, 125027121, 3649625763, 347570207, 74535262, 3832543808, 2472133297, 1600064941, 65273441 }; EXPECT_EQ(bigint_fibonacci(500).words(), result); } TEST_CASE(test_unsigned_bigint_addition_initialization) { Crypto::UnsignedBigInteger num1; Crypto::UnsignedBigInteger num2(70); Crypto::UnsignedBigInteger num3 = num1.plus(num2); bool pass = (num3 == num2); pass &= (num1 == Crypto::UnsignedBigInteger(0)); EXPECT(pass); } TEST_CASE(test_unsigned_bigint_addition_borrow_with_zero) { Crypto::UnsignedBigInteger num1({ UINT32_MAX - 3, UINT32_MAX }); Crypto::UnsignedBigInteger num2({ UINT32_MAX - 2, 0 }); Vector expected_result { 4294967289, 0, 1 }; EXPECT_EQ(num1.plus(num2).words(), expected_result); } TEST_CASE(test_unsigned_bigint_basic_add_to_accumulator) { Crypto::UnsignedBigInteger num1(10); Crypto::UnsignedBigInteger num2(70); Crypto::UnsignedBigIntegerAlgorithms::add_into_accumulator_without_allocation(num1, num2); EXPECT_EQ(num1.words(), Vector { 80 }); } TEST_CASE(test_unsigned_bigint_basic_add_to_empty_accumulator) { Crypto::UnsignedBigInteger num1({}); Crypto::UnsignedBigInteger num2(10); Crypto::UnsignedBigIntegerAlgorithms::add_into_accumulator_without_allocation(num1, num2); EXPECT_EQ(num1.words(), Vector { 10 }); } TEST_CASE(test_unsigned_bigint_basic_add_to_smaller_accumulator) { Crypto::UnsignedBigInteger num1(10); Crypto::UnsignedBigInteger num2({ 10, 10 }); Crypto::UnsignedBigIntegerAlgorithms::add_into_accumulator_without_allocation(num1, num2); Vector expected_result { 20, 10 }; EXPECT_EQ(num1.words(), expected_result); } TEST_CASE(test_unsigned_bigint_add_to_accumulator_with_multiple_carry_levels) { Crypto::UnsignedBigInteger num1({ UINT32_MAX - 2, UINT32_MAX }); Crypto::UnsignedBigInteger num2(5); Crypto::UnsignedBigIntegerAlgorithms::add_into_accumulator_without_allocation(num1, num2); Vector expected_result { 2, 0, 1 }; EXPECT_EQ(num1.words(), expected_result); } TEST_CASE(test_unsigned_bigint_add_to_accumulator_with_leading_zero) { Crypto::UnsignedBigInteger num1(1); Crypto::UnsignedBigInteger num2({ 1, 0 }); Crypto::UnsignedBigIntegerAlgorithms::add_into_accumulator_without_allocation(num1, num2); EXPECT_EQ(num1.words(), Vector { 2 }); } TEST_CASE(test_unsigned_bigint_add_to_accumulator_with_carry_and_leading_zero) { Crypto::UnsignedBigInteger num1({ UINT32_MAX, 0, 0, 0 }); Crypto::UnsignedBigInteger num2({ 1, 0 }); Crypto::UnsignedBigIntegerAlgorithms::add_into_accumulator_without_allocation(num1, num2); Vector expected_result { 0, 1, 0, 0 }; EXPECT_EQ(num1.words(), expected_result); } TEST_CASE(test_unsigned_bigint_simple_subtraction) { Crypto::UnsignedBigInteger num1(80); Crypto::UnsignedBigInteger num2(70); EXPECT_EQ(num1.minus(num2), Crypto::UnsignedBigInteger(10)); } TEST_CASE(test_unsigned_bigint_simple_subtraction_invalid) { Crypto::UnsignedBigInteger num1(50); Crypto::UnsignedBigInteger num2(70); EXPECT(num1.minus(num2).is_invalid()); } TEST_CASE(test_unsigned_bigint_simple_subtraction_with_borrow) { Crypto::UnsignedBigInteger num1(UINT32_MAX); Crypto::UnsignedBigInteger num2(1); Crypto::UnsignedBigInteger num3 = num1.plus(num2); Crypto::UnsignedBigInteger result = num3.minus(num2); EXPECT_EQ(result, num1); } TEST_CASE(test_unsigned_bigint_subtraction_with_large_numbers) { Crypto::UnsignedBigInteger num1 = bigint_fibonacci(343); Crypto::UnsignedBigInteger num2 = bigint_fibonacci(218); Crypto::UnsignedBigInteger result = num1.minus(num2); Vector expected_result { 811430588, 2958904896, 1130908877, 2830569969, 3243275482, 3047460725, 774025231, 7990 }; EXPECT_EQ(result.plus(num2), num1); EXPECT_EQ(result.words(), expected_result); } TEST_CASE(test_unsigned_bigint_subtraction_with_large_numbers2) { Crypto::UnsignedBigInteger num1(Vector { 1483061863, 446680044, 1123294122, 191895498, 3347106536, 16, 0, 0, 0 }); Crypto::UnsignedBigInteger num2(Vector { 4196414175, 1117247942, 1123294122, 191895498, 3347106536, 16 }); Crypto::UnsignedBigInteger result = num1.minus(num2); // this test only verifies that we don't crash on an assertion } TEST_CASE(test_unsigned_bigint_subtraction_regression_1) { auto num = Crypto::UnsignedBigInteger { 1 }.shift_left(256); Vector expected_result { 4294967295, 4294967295, 4294967295, 4294967295, 4294967295, 4294967295, 4294967295, 4294967295, 0 }; EXPECT_EQ(num.minus(1).words(), expected_result); } TEST_CASE(test_unsigned_bigint_simple_multiplication) { Crypto::UnsignedBigInteger num1(8); Crypto::UnsignedBigInteger num2(251); Crypto::UnsignedBigInteger result = num1.multiplied_by(num2); EXPECT_EQ(result.words(), Vector { 2008 }); } TEST_CASE(test_unsigned_bigint_multiplication_with_big_numbers1) { Crypto::UnsignedBigInteger num1 = bigint_fibonacci(200); Crypto::UnsignedBigInteger num2(12345678); Crypto::UnsignedBigInteger result = num1.multiplied_by(num2); Vector expected_result { 669961318, 143970113, 4028714974, 3164551305, 1589380278, 2 }; EXPECT_EQ(result.words(), expected_result); } TEST_CASE(test_unsigned_bigint_multiplication_with_big_numbers2) { Crypto::UnsignedBigInteger num1 = bigint_fibonacci(200); Crypto::UnsignedBigInteger num2 = bigint_fibonacci(341); Crypto::UnsignedBigInteger result = num1.multiplied_by(num2); Vector expected_result { 3017415433, 2741793511, 1957755698, 3731653885, 3154681877, 785762127, 3200178098, 4260616581, 529754471, 3632684436, 1073347813, 2516430 }; EXPECT_EQ(result.words(), expected_result); } TEST_CASE(test_unsigned_bigint_simple_division) { Crypto::UnsignedBigInteger num1(27194); Crypto::UnsignedBigInteger num2(251); auto result = num1.divided_by(num2); Crypto::UnsignedDivisionResult expected = { Crypto::UnsignedBigInteger(108), Crypto::UnsignedBigInteger(86) }; EXPECT_EQ(result.quotient, expected.quotient); EXPECT_EQ(result.remainder, expected.remainder); } TEST_CASE(test_unsigned_bigint_division_with_big_numbers) { Crypto::UnsignedBigInteger num1 = bigint_fibonacci(386); Crypto::UnsignedBigInteger num2 = bigint_fibonacci(238); auto result = num1.divided_by(num2); Crypto::UnsignedDivisionResult expected = { Crypto::UnsignedBigInteger(Vector { 2300984486, 2637503534, 2022805584, 107 }), Crypto::UnsignedBigInteger(Vector { 1483061863, 446680044, 1123294122, 191895498, 3347106536, 16, 0, 0, 0 }) }; EXPECT_EQ(result.quotient, expected.quotient); EXPECT_EQ(result.remainder, expected.remainder); } TEST_CASE(test_unsigned_bigint_division_combined_test) { auto num1 = bigint_fibonacci(497); auto num2 = bigint_fibonacci(238); auto div_result = num1.divided_by(num2); EXPECT_EQ(div_result.quotient.multiplied_by(num2).plus(div_result.remainder), num1); } TEST_CASE(test_unsigned_bigint_base10_from_string) { auto result = Crypto::UnsignedBigInteger::from_base(10, "57195071295721390579057195715793"); Vector expected_result { 3806301393, 954919431, 3879607298, 721 }; EXPECT_EQ(result.words(), expected_result); } TEST_CASE(test_unsigned_bigint_base10_to_string) { auto result = Crypto::UnsignedBigInteger { Vector { 3806301393, 954919431, 3879607298, 721 } }.to_base(10); EXPECT_EQ(result, "57195071295721390579057195715793"); } TEST_CASE(test_bigint_modular_inverse) { auto result = Crypto::NumberTheory::ModularInverse(7, 87); EXPECT_EQ(result, 25); } TEST_CASE(test_bigint_even_simple_modular_power) { Crypto::UnsignedBigInteger base { 7 }; Crypto::UnsignedBigInteger exponent { 2 }; Crypto::UnsignedBigInteger modulo { 10 }; auto result = Crypto::NumberTheory::ModularPower(base, exponent, modulo); EXPECT_EQ(result.words(), Vector { 9 }); } TEST_CASE(test_bigint_odd_simple_modular_power) { Crypto::UnsignedBigInteger base { 10 }; Crypto::UnsignedBigInteger exponent { 2 }; Crypto::UnsignedBigInteger modulo { 9 }; auto result = Crypto::NumberTheory::ModularPower(base, exponent, modulo); EXPECT_EQ(result.words(), Vector { 1 }); } TEST_CASE(test_bigint_large_even_fibonacci_modular_power) { Crypto::UnsignedBigInteger base = bigint_fibonacci(200); Crypto::UnsignedBigInteger exponent = bigint_fibonacci(100); Crypto::UnsignedBigInteger modulo = bigint_fibonacci(150); // Result according to Wolfram Alpha : 7195284628716783672927396027925 auto result = Crypto::NumberTheory::ModularPower(base, exponent, modulo); Vector expected_result { 2042093077, 1351416233, 3510104665, 90 }; EXPECT_EQ(result.words(), expected_result); } TEST_CASE(test_bigint_large_odd_fibonacci_modular_power) { Crypto::UnsignedBigInteger base = bigint_fibonacci(200); Crypto::UnsignedBigInteger exponent = bigint_fibonacci(100); Crypto::UnsignedBigInteger modulo = bigint_fibonacci(149); // Result according to Wolfram Alpha : 1136278609611966596838389694992 auto result = Crypto::NumberTheory::ModularPower(base, exponent, modulo); Vector expected_result { 2106049040, 2169509253, 1468244710, 14 }; EXPECT_EQ(result.words(), expected_result); } TEST_CASE(test_bigint_large_odd_fibonacci_with_carry_modular_power) { Crypto::UnsignedBigInteger base = bigint_fibonacci(200); Crypto::UnsignedBigInteger exponent = bigint_fibonacci(100); Crypto::UnsignedBigInteger modulo = bigint_fibonacci(185); // Result according to Wolfram Alpha : 55094573983071006678665780782730672080 auto result = Crypto::NumberTheory::ModularPower(base, exponent, modulo); Vector expected_result { 1988720592, 2097784252, 347129583, 695391288 }; EXPECT_EQ(result.words(), expected_result); } TEST_CASE(test_bigint_modular_power_extra_tests) { struct { Crypto::UnsignedBigInteger base; Crypto::UnsignedBigInteger exp; Crypto::UnsignedBigInteger mod; Crypto::UnsignedBigInteger expected; } mod_pow_tests[] = { { "2988348162058574136915891421498819466320163312926952423791023078876139"_bigint, "2351399303373464486466122544523690094744975233415544072992656881240319"_bigint, "10000"_bigint, "3059"_bigint }, { "24231"_bigint, "12448"_bigint, "14679"_bigint, "4428"_bigint }, { "1005404"_bigint, "8352654"_bigint, "8161408"_bigint, "2605696"_bigint }, { "3665005778"_bigint, "3244425589"_bigint, "565668506"_bigint, "524766494"_bigint }, { "10662083169959689657"_bigint, "11605678468317533000"_bigint, "1896834583057209739"_bigint, "1292743154593945858"_bigint }, { "99667739213529524852296932424683448520"_bigint, "123394910770101395416306279070921784207"_bigint, "238026722756504133786938677233768788719"_bigint, "197165477545023317459748215952393063201"_bigint }, { "49368547511968178788919424448914214709244872098814465088945281575062739912239"_bigint, "25201856190991298572337188495596990852134236115562183449699512394891190792064"_bigint, "45950460777961491021589776911422805972195170308651734432277141467904883064645"_bigint, "39917885806532796066922509794537889114718612292469285403012781055544152450051"_bigint }, { "48399385336454791246880286907257136254351739111892925951016159217090949616810"_bigint, "5758661760571644379364752528081901787573279669668889744323710906207949658569"_bigint, "32812120644405991429173950312949738783216437173380339653152625840449006970808"_bigint, "7948464125034399875323770213514649646309423451213282653637296324080400293584"_bigint }, }; for (auto test_case : mod_pow_tests) { auto actual = Crypto::NumberTheory::ModularPower( test_case.base, test_case.exp, test_case.mod); EXPECT_EQ(actual, test_case.expected); } } TEST_CASE(test_bigint_primality_test) { struct { Crypto::UnsignedBigInteger candidate; bool expected_result; } primality_tests[] = { { "1180591620717411303424"_bigint, false }, // 2**70 { "620448401733239439360000"_bigint, false }, // 25! { "953962166440690129601298432"_bigint, false }, // 12**25 { "620448401733239439360000"_bigint, false }, // 25! { "147926426347074375"_bigint, false }, // 35! / 2**32 { "340282366920938429742726440690708343523"_bigint, false }, // 2 factors near 2^64 { "73"_bigint, true }, { "6967"_bigint, true }, { "787649"_bigint, true }, { "73513949"_bigint, true }, { "6691236901"_bigint, true }, { "741387182759"_bigint, true }, { "67466615915827"_bigint, true }, { "9554317039214687"_bigint, true }, { "533344522150170391"_bigint, true }, { "18446744073709551557"_bigint, true }, // just below 2**64 }; for (auto test_case : primality_tests) { bool actual_result = Crypto::NumberTheory::is_probably_prime(test_case.candidate); EXPECT_EQ(test_case.expected_result, actual_result); } } TEST_CASE(test_bigint_random_number_generation) { struct { Crypto::UnsignedBigInteger min; Crypto::UnsignedBigInteger max; } random_number_tests[] = { { "1"_bigint, "1000000"_bigint }, { "10000000000"_bigint, "20000000000"_bigint }, { "1000"_bigint, "200000000000000000"_bigint }, { "200000000000000000"_bigint, "200000000000010000"_bigint }, }; for (auto test_case : random_number_tests) { auto actual_result = Crypto::NumberTheory::random_number(test_case.min, test_case.max); EXPECT(!(actual_result < test_case.min)); EXPECT(actual_result < test_case.max); } } TEST_CASE(test_bigint_random_distribution) { auto actual_result = Crypto::NumberTheory::random_number( "1"_bigint, "100000000000000000000000000000"_bigint); // 10**29 if (actual_result < "100000000000000000000"_bigint) { // 10**20 FAIL("Too small"); outln("The generated number {} is extremely small. This *can* happen by pure chance, but should happen only once in a billion times. So it's probably an error.", actual_result.to_base(10)); } else if ("99999999900000000000000000000"_bigint < actual_result) { // 10**29 - 10**20 FAIL("Too large"); outln("The generated number {} is extremely large. This *can* happen by pure chance, but should happen only once in a billion times. So it's probably an error.", actual_result.to_base(10)); } } TEST_CASE(test_bigint_import_big_endian_decode_encode_roundtrip) { u8 random_bytes[128]; u8 target_buffer[128]; fill_with_random(random_bytes, 128); auto encoded = Crypto::UnsignedBigInteger::import_data(random_bytes, 128); encoded.export_data({ target_buffer, 128 }); EXPECT(memcmp(target_buffer, random_bytes, 128) == 0); } TEST_CASE(test_bigint_import_big_endian_encode_decode_roundtrip) { u8 target_buffer[128]; auto encoded = "12345678901234567890"_bigint; auto size = encoded.export_data({ target_buffer, 128 }); auto decoded = Crypto::UnsignedBigInteger::import_data(target_buffer, size); EXPECT_EQ(encoded, decoded); } TEST_CASE(test_bigint_big_endian_import) { auto number = Crypto::UnsignedBigInteger::import_data("hello"); EXPECT_EQ(number, "448378203247"_bigint); } TEST_CASE(test_bigint_big_endian_export) { auto number = "448378203247"_bigint; char exported[8] { 0 }; auto exported_length = number.export_data({ exported, 8 }, true); EXPECT_EQ(exported_length, 5u); EXPECT(memcmp(exported + 3, "hello", 5) == 0); } TEST_CASE(test_bigint_bitwise_or) { auto num1 = "1234567"_bigint; auto num2 = "1234567"_bigint; EXPECT_EQ(num1.bitwise_or(num2), num1); } TEST_CASE(test_bigint_bitwise_or_different_lengths) { auto num1 = "1234567"_bigint; auto num2 = "123456789012345678901234567890"_bigint; auto expected = "123456789012345678901234622167"_bigint; auto result = num1.bitwise_or(num2); EXPECT_EQ(result, expected); } TEST_CASE(test_signed_bigint_bitwise_or) { auto num1 = "-1234567"_sbigint; auto num2 = "1234567"_sbigint; EXPECT_EQ(num1.bitwise_or(num1), num1); EXPECT_EQ(num1.bitwise_or(num2), num1); EXPECT_EQ(num2.bitwise_or(num1), num1); EXPECT_EQ(num2.bitwise_or(num2), num2); } TEST_CASE(test_bigint_bitwise_and) { auto num1 = "1234567"_bigint; auto num2 = "1234561"_bigint; EXPECT_EQ(num1.bitwise_and(num2), "1234561"_bigint); } TEST_CASE(test_bigint_bitwise_and_different_lengths) { auto num1 = "1234567"_bigint; auto num2 = "123456789012345678901234567890"_bigint; EXPECT_EQ(num1.bitwise_and(num2), "1180290"_bigint); } TEST_CASE(test_signed_bigint_bitwise_and) { auto num1 = "-1234567"_sbigint; auto num2 = "1234567"_sbigint; EXPECT_EQ(num1.bitwise_and(num1), num1); EXPECT_EQ(num1.bitwise_and(num2), num2); EXPECT_EQ(num2.bitwise_and(num1), num2); EXPECT_EQ(num2.bitwise_and(num2), num2); } TEST_CASE(test_bigint_bitwise_xor) { auto num1 = "1234567"_bigint; auto num2 = "1234561"_bigint; EXPECT_EQ(num1.bitwise_xor(num2), 6); } TEST_CASE(test_bigint_bitwise_xor_different_lengths) { auto num1 = "1234567"_bigint; auto num2 = "123456789012345678901234567890"_bigint; EXPECT_EQ(num1.bitwise_xor(num2), "123456789012345678901233441877"_bigint); } TEST_CASE(test_signed_bigint_bitwise_xor) { auto num1 = "-3"_sbigint; auto num2 = "1"_sbigint; EXPECT_EQ(num1.bitwise_xor(num1), "0"_sbigint); EXPECT_EQ(num1.bitwise_xor(num2), "-2"_sbigint); EXPECT_EQ(num2.bitwise_xor(num1), "-2"_sbigint); EXPECT_EQ(num2.bitwise_xor(num2), "0"_sbigint); } TEST_CASE(test_signed_bigint_fibo500) { Vector expected_result { 315178285, 505575602, 1883328078, 125027121, 3649625763, 347570207, 74535262, 3832543808, 2472133297, 1600064941, 65273441 }; auto result = bigint_signed_fibonacci(500); EXPECT_EQ(result.unsigned_value().words(), expected_result); } TEST_CASE(test_signed_addition_edgecase_borrow_with_zero) { Crypto::SignedBigInteger num1 { Crypto::UnsignedBigInteger { { UINT32_MAX - 3, UINT32_MAX } }, false }; Crypto::SignedBigInteger num2 { Crypto::UnsignedBigInteger { UINT32_MAX - 2 }, false }; Vector expected_result { 4294967289, 0, 1 }; EXPECT_EQ(num1.plus(num2).unsigned_value().words(), expected_result); } TEST_CASE(test_signed_addition_edgecase_addition_to_other_sign) { Crypto::SignedBigInteger num1 = INT32_MAX; Crypto::SignedBigInteger num2 = num1; num2.negate(); EXPECT_EQ(num1.plus(num2), Crypto::SignedBigInteger { 0 }); } TEST_CASE(test_signed_subtraction_simple_subtraction_positive_result) { Crypto::SignedBigInteger num1(80); Crypto::SignedBigInteger num2(70); EXPECT_EQ(num1.minus(num2), Crypto::SignedBigInteger(10)); } TEST_CASE(test_signed_subtraction_simple_subtraction_negative_result) { Crypto::SignedBigInteger num1(50); Crypto::SignedBigInteger num2(70); EXPECT_EQ(num1.minus(num2), Crypto::SignedBigInteger { -20 }); } TEST_CASE(test_signed_subtraction_simple_subtraction_with_borrow) { Crypto::SignedBigInteger num1(Crypto::UnsignedBigInteger { UINT32_MAX }); Crypto::SignedBigInteger num2(1); Crypto::SignedBigInteger num3 = num1.plus(num2); Crypto::SignedBigInteger result = num2.minus(num3); num1.negate(); EXPECT_EQ(result, num1); } TEST_CASE(test_signed_subtraction_with_large_numbers) { Crypto::SignedBigInteger num1 = bigint_signed_fibonacci(343); Crypto::SignedBigInteger num2 = bigint_signed_fibonacci(218); Crypto::SignedBigInteger result = num2.minus(num1); auto expected = Crypto::UnsignedBigInteger { Vector { 811430588, 2958904896, 1130908877, 2830569969, 3243275482, 3047460725, 774025231, 7990 } }; EXPECT_EQ(result.plus(num1), num2); EXPECT_EQ(result.unsigned_value(), expected); } TEST_CASE(test_signed_subtraction_with_large_numbers_check_for_assertion) { Crypto::SignedBigInteger num1(Crypto::UnsignedBigInteger { Vector { 1483061863, 446680044, 1123294122, 191895498, 3347106536, 16, 0, 0, 0 } }); Crypto::SignedBigInteger num2(Crypto::UnsignedBigInteger { Vector { 4196414175, 1117247942, 1123294122, 191895498, 3347106536, 16 } }); Crypto::SignedBigInteger result = num1.minus(num2); // this test only verifies that we don't crash on an assertion } TEST_CASE(test_signed_multiplication_with_negative_number) { Crypto::SignedBigInteger num1(8); Crypto::SignedBigInteger num2(-251); Crypto::SignedBigInteger result = num1.multiplied_by(num2); EXPECT_EQ(result, Crypto::SignedBigInteger { -2008 }); } TEST_CASE(test_signed_multiplication_with_big_number) { Crypto::SignedBigInteger num1 = bigint_signed_fibonacci(200); Crypto::SignedBigInteger num2(-12345678); Crypto::SignedBigInteger result = num1.multiplied_by(num2); Vector expected_result { 669961318, 143970113, 4028714974, 3164551305, 1589380278, 2 }; EXPECT_EQ(result.unsigned_value().words(), expected_result); EXPECT(result.is_negative()); } TEST_CASE(test_signed_multiplication_with_two_big_numbers) { Crypto::SignedBigInteger num1 = bigint_signed_fibonacci(200); Crypto::SignedBigInteger num2 = bigint_signed_fibonacci(341); num1.negate(); Crypto::SignedBigInteger result = num1.multiplied_by(num2); Vector expected_results { 3017415433, 2741793511, 1957755698, 3731653885, 3154681877, 785762127, 3200178098, 4260616581, 529754471, 3632684436, 1073347813, 2516430 }; EXPECT_EQ(result.unsigned_value().words(), expected_results); EXPECT(result.is_negative()); }