/* * (C) 2007 Falko Strenzke * 2007 Manuel Hartl * 2009,2015 Jack Lloyd * * Botan is released under the Simplified BSD License (see license.txt) */ #include "tests.h" #if defined(BOTAN_HAS_ECC_GROUP) #include #include #include #include #include #include #include #include #include #include #include #include #endif namespace Botan_Tests { namespace { #if defined(BOTAN_HAS_ECC_GROUP) const std::vector ec_groups = { "brainpool160r1", "brainpool192r1", "brainpool224r1", "brainpool256r1", "brainpool320r1", "brainpool384r1", "brainpool512r1", "gost_256A", "secp160k1", "secp160r1", "secp160r2", "secp192k1", "secp192r1", "secp224k1", "secp224r1", "secp256k1", "secp256r1", "secp384r1", "secp521r1", "x962_p192v2", "x962_p192v3", "x962_p239v1", "x962_p239v2", "x962_p239v3", "sm2p256v1", "frp256v1" }; Botan::BigInt test_integer(Botan::RandomNumberGenerator& rng, size_t bits, BigInt max) { /* Produces integers with long runs of ones and zeros, for testing for carry handling problems. */ Botan::BigInt x = 0; auto flip_prob = [](size_t i) -> double { if(i % 64 == 0) { return .5; } if(i % 32 == 0) { return .4; } if(i % 8 == 0) { return .05; } return .01; }; bool active = rng.next_byte() % 2; for(size_t i = 0; i != bits; ++i) { x <<= 1; x += static_cast(active); const double prob = flip_prob(i); const double sample = double(rng.next_byte() % 100) / 100.0; // biased if(sample < prob) { active = !active; } } if(max > 0) { while(x >= max) { const size_t b = x.bits() - 1; BOTAN_ASSERT(x.get_bit(b) == true, "Set"); x.clear_bit(b); } } return x; } Botan::PointGFp create_random_point(Botan::RandomNumberGenerator& rng, const Botan::CurveGFp& curve) { const Botan::BigInt& p = curve.get_p(); Botan::Modular_Reducer mod_p(p); while(true) { const Botan::BigInt x = Botan::BigInt::random_integer(rng, 1, p); const Botan::BigInt x3 = mod_p.multiply(x, mod_p.square(x)); const Botan::BigInt ax = mod_p.multiply(curve.get_a(), x); const Botan::BigInt y = mod_p.reduce(x3 + ax + curve.get_b()); const Botan::BigInt sqrt_y = ressol(y, p); if(sqrt_y > 1) { BOTAN_ASSERT_EQUAL(mod_p.square(sqrt_y), y, "Square root is correct"); Botan::PointGFp point(curve, x, sqrt_y); return point; } } } class ECC_Randomized_Tests final : public Test { public: std::vector run() override; }; std::vector ECC_Randomized_Tests::run() { std::vector results; for(auto const& group_name : ec_groups) { Test::Result result("ECC randomized " + group_name); result.start_timer(); Botan::EC_Group group(group_name); const Botan::PointGFp& base_point = group.get_base_point(); const Botan::BigInt& group_order = group.get_order(); const Botan::PointGFp inf = base_point * group_order; result.test_eq("infinite order correct", inf.is_zero(), true); result.test_eq("infinity on the curve", inf.on_the_curve(), true); try { const size_t trials = (Test::run_long_tests() ? 10 : 3); for(size_t i = 0; i < trials; ++i) { const size_t h = 1 + (Test::rng().next_byte() % 8); Botan::Blinded_Point_Multiply blind(base_point, group_order, h); const Botan::BigInt a = Botan::BigInt::random_integer(Test::rng(), 2, group_order); const Botan::BigInt b = Botan::BigInt::random_integer(Test::rng(), 2, group_order); const Botan::BigInt c = a + b; const Botan::PointGFp P = base_point * a; const Botan::PointGFp Q = base_point * b; const Botan::PointGFp R = base_point * c; const Botan::PointGFp P1 = blind.blinded_multiply(a, Test::rng()); const Botan::PointGFp Q1 = blind.blinded_multiply(b, Test::rng()); const Botan::PointGFp R1 = blind.blinded_multiply(c, Test::rng()); const Botan::PointGFp A1 = P + Q; const Botan::PointGFp A2 = Q + P; result.test_eq("p + q", A1, R); result.test_eq("q + p", A2, R); result.test_eq("p on the curve", P.on_the_curve(), true); result.test_eq("q on the curve", Q.on_the_curve(), true); result.test_eq("r on the curve", R.on_the_curve(), true); result.test_eq("P1", P1, P); result.test_eq("Q1", Q1, Q); result.test_eq("R1", R1, R); } } catch(std::exception& e) { result.test_failure(group_name, e.what()); } result.end_timer(); results.push_back(result); } return results; } BOTAN_REGISTER_TEST("ecc_randomized", ECC_Randomized_Tests); class NIST_Curve_Reduction_Tests final : public Test { public: typedef std::function&)> reducer_fn; std::vector run() override { std::vector results; #if defined(BOTAN_HAS_NIST_PRIME_REDUCERS_W32) results.push_back(random_redc_test("P-384", Botan::prime_p384(), Botan::redc_p384)); results.push_back(random_redc_test("P-256", Botan::prime_p256(), Botan::redc_p256)); results.push_back(random_redc_test("P-224", Botan::prime_p224(), Botan::redc_p224)); results.push_back(random_redc_test("P-192", Botan::prime_p192(), Botan::redc_p192)); #endif results.push_back(random_redc_test("P-521", Botan::prime_p521(), Botan::redc_p521)); return results; } Test::Result random_redc_test(const std::string& prime_name, const Botan::BigInt& p, reducer_fn redc_fn) { const Botan::BigInt p2 = p * p; const size_t p_bits = p.bits(); Botan::Modular_Reducer p_redc(p); Botan::secure_vector ws; Test::Result result("NIST " + prime_name + " reduction"); result.start_timer(); const size_t trials = (Test::run_long_tests() ? 128 : 16); for(size_t i = 0; i <= trials; ++i) { const Botan::BigInt x = test_integer(Test::rng(), 2 * p_bits, p2); // TODO: time and report all three approaches const Botan::BigInt v1 = x % p; const Botan::BigInt v2 = p_redc.reduce(x); Botan::BigInt v3 = x; redc_fn(v3, ws); if(!result.test_eq("reference redc", v1, v2) || !result.test_eq("specialized redc", v2, v3)) { result.test_note("failing input" + Botan::hex_encode(Botan::BigInt::encode(x))); } } result.end_timer(); return result; } }; BOTAN_REGISTER_TEST("nist_redc", NIST_Curve_Reduction_Tests); Test::Result test_coordinates() { Test::Result result("ECC Unit"); const Botan::BigInt exp_affine_x("16984103820118642236896513183038186009872590470"); const Botan::BigInt exp_affine_y("1373093393927139016463695321221277758035357890939"); // precalculation const Botan::EC_Group secp160r1(Botan::OIDS::lookup("secp160r1")); const Botan::CurveGFp& curve = secp160r1.get_curve(); const Botan::PointGFp& p_G = secp160r1.get_base_point(); const Botan::PointGFp p0 = p_G; const Botan::PointGFp p1 = p_G * 2; const Botan::PointGFp point_exp(curve, exp_affine_x, exp_affine_y); result.confirm("Point is on the curve", point_exp.on_the_curve()); result.test_eq("Point affine x", p1.get_affine_x(), exp_affine_x); result.test_eq("Point affine y", p1.get_affine_y(), exp_affine_y); return result; } /** Test point multiplication according to -------- SEC 2: Test Vectors for SEC 1 Certicom Research Working Draft September, 1999 Version 0.3; Section 2.1.2 -------- */ Test::Result test_point_transformation() { Test::Result result("ECC Unit"); // get a valid point Botan::EC_Group dom_pars(Botan::OID("1.3.132.0.8")); Botan::PointGFp p = dom_pars.get_base_point() * Test::rng().next_nonzero_byte(); // get a copy Botan::PointGFp q = p; p.randomize_repr(Test::rng()); q.randomize_repr(Test::rng()); result.test_eq("affine x after copy", p.get_affine_x(), q.get_affine_x()); result.test_eq("affine y after copy", p.get_affine_y(), q.get_affine_y()); return result; } Test::Result test_point_mult() { Test::Result result("ECC Unit"); Botan::EC_Group secp160r1(Botan::OIDS::lookup("secp160r1")); const Botan::PointGFp& p_G = secp160r1.get_base_point(); Botan::BigInt d_U("0xaa374ffc3ce144e6b073307972cb6d57b2a4e982"); Botan::PointGFp Q_U = d_U * p_G; result.test_eq("affine x", Q_U.get_affine_x(), Botan::BigInt("466448783855397898016055842232266600516272889280")); result.test_eq("affine y", Q_U.get_affine_y(), Botan::BigInt("1110706324081757720403272427311003102474457754220")); return result; } Test::Result test_point_negative() { Test::Result result("ECC Unit"); Botan::EC_Group secp160r1(Botan::OIDS::lookup("secp160r1")); const Botan::PointGFp& p_G = secp160r1.get_base_point(); const Botan::PointGFp p1 = p_G * 2; result.test_eq("affine x", p1.get_affine_x(), Botan::BigInt("16984103820118642236896513183038186009872590470")); result.test_eq("affine y", p1.get_affine_y(), Botan::BigInt("1373093393927139016463695321221277758035357890939")); const Botan::PointGFp p1_neg = -p1; result.test_eq("affine x", p1_neg.get_affine_x(), p1.get_affine_x()); result.test_eq("affine y", p1_neg.get_affine_y(), Botan::BigInt("88408243403763901739989511495005261618427168388")); return result; } Test::Result test_zeropoint() { Test::Result result("ECC Unit"); Botan::EC_Group secp160r1(Botan::OIDS::lookup("secp160r1")); const Botan::CurveGFp& curve = secp160r1.get_curve(); Botan::PointGFp p1(curve, Botan::BigInt("16984103820118642236896513183038186009872590470"), Botan::BigInt("1373093393927139016463695321221277758035357890939")); result.confirm("point is on the curve", p1.on_the_curve()); p1 -= p1; result.confirm("p - q with q = p results in zero", p1.is_zero()); return result; } Test::Result test_zeropoint_enc_dec() { Test::Result result("ECC Unit"); Botan::EC_Group secp160r1(Botan::OIDS::lookup("secp160r1")); const Botan::CurveGFp& curve = secp160r1.get_curve(); Botan::PointGFp p(curve); result.confirm("zero point is zero", p.is_zero()); std::vector sv_p = unlock(EC2OSP(p, Botan::PointGFp::UNCOMPRESSED)); result.test_eq("encoded/decode rt works", OS2ECP(sv_p, curve), p); sv_p = unlock(EC2OSP(p, Botan::PointGFp::COMPRESSED)); result.test_eq("encoded/decode compressed rt works", OS2ECP(sv_p, curve), p); sv_p = unlock(EC2OSP(p, Botan::PointGFp::HYBRID)); result.test_eq("encoded/decode hybrid rt works", OS2ECP(sv_p, curve), p); return result; } Test::Result test_calc_with_zeropoint() { Test::Result result("ECC Unit"); Botan::EC_Group secp160r1(Botan::OIDS::lookup("secp160r1")); const Botan::CurveGFp& curve = secp160r1.get_curve(); Botan::PointGFp p(curve, Botan::BigInt("16984103820118642236896513183038186009872590470"), Botan::BigInt("1373093393927139016463695321221277758035357890939")); result.confirm("point is on the curve", p.on_the_curve()); result.confirm("point is not zero", !p.is_zero()); Botan::PointGFp zero(curve); result.confirm("zero point is zero", zero.is_zero()); Botan::PointGFp res = p + zero; result.test_eq("point + 0 equals the point", p, res); res = p - zero; result.test_eq("point - 0 equals the point", p, res); res = zero * 32432243; result.confirm("point * 0 is the zero point", res.is_zero()); return result; } Test::Result test_add_point() { Test::Result result("ECC Unit"); // precalculation Botan::EC_Group secp160r1(Botan::OIDS::lookup("secp160r1")); const Botan::CurveGFp& curve = secp160r1.get_curve(); const Botan::PointGFp& p_G = secp160r1.get_base_point(); Botan::PointGFp p0 = p_G; Botan::PointGFp p1 = p_G * 2; p1 += p0; Botan::PointGFp expected(curve, Botan::BigInt("704859595002530890444080436569091156047721708633"), Botan::BigInt("1147993098458695153857594941635310323215433166682")); result.test_eq("point addition", p1, expected); return result; } Test::Result test_sub_point() { Test::Result result("ECC Unit"); Botan::EC_Group secp160r1(Botan::OIDS::lookup("secp160r1")); const Botan::CurveGFp& curve = secp160r1.get_curve(); const Botan::PointGFp& p_G = secp160r1.get_base_point(); Botan::PointGFp p0 = p_G; Botan::PointGFp p1 = p_G * 2; p1 -= p0; Botan::PointGFp expected(curve, Botan::BigInt("425826231723888350446541592701409065913635568770"), Botan::BigInt("203520114162904107873991457957346892027982641970")); result.test_eq("point subtraction", p1, expected); return result; } Test::Result test_mult_point() { Test::Result result("ECC Unit"); Botan::EC_Group secp160r1(Botan::OIDS::lookup("secp160r1")); const Botan::CurveGFp& curve = secp160r1.get_curve(); const Botan::PointGFp& p_G = secp160r1.get_base_point(); Botan::PointGFp p0 = p_G; Botan::PointGFp p1 = p_G * 2; p1 *= p0.get_affine_x(); const Botan::BigInt exp_mult_x(std::string("967697346845926834906555988570157345422864716250")); const Botan::BigInt exp_mult_y(std::string("512319768365374654866290830075237814703869061656")); Botan::PointGFp expected(curve, exp_mult_x, exp_mult_y); result.test_eq("point mult", p1, expected); return result; } Test::Result test_basic_operations() { Test::Result result("ECC Unit"); // precalculation Botan::EC_Group secp160r1(Botan::OIDS::lookup("secp160r1")); const Botan::CurveGFp& curve = secp160r1.get_curve(); const Botan::PointGFp& p_G = secp160r1.get_base_point(); const Botan::PointGFp p0 = p_G; const Botan::PointGFp p1 = p_G * 2; result.test_eq("p1 affine x", p1.get_affine_x(), Botan::BigInt("16984103820118642236896513183038186009872590470")); result.test_eq("p1 affine y", p1.get_affine_y(), Botan::BigInt("1373093393927139016463695321221277758035357890939")); const Botan::PointGFp simplePlus = p1 + p0; const Botan::PointGFp exp_simplePlus(curve, Botan::BigInt("704859595002530890444080436569091156047721708633"), Botan::BigInt("1147993098458695153857594941635310323215433166682")); result.test_eq("point addition", simplePlus, exp_simplePlus); const Botan::PointGFp simpleMinus = p1 - p0; const Botan::PointGFp exp_simpleMinus(curve, Botan::BigInt("425826231723888350446541592701409065913635568770"), Botan::BigInt("203520114162904107873991457957346892027982641970")); result.test_eq("point subtraction", simpleMinus, exp_simpleMinus); const Botan::PointGFp simpleMult = p1 * 123456789; result.test_eq("point mult affine x", simpleMult.get_affine_x(), Botan::BigInt("43638877777452195295055270548491599621118743290")); result.test_eq("point mult affine y", simpleMult.get_affine_y(), Botan::BigInt("56841378500012376527163928510402662349220202981")); return result; } Test::Result test_enc_dec_compressed_160() { Test::Result result("ECC Unit"); // Test for compressed conversion (02/03) 160bit Botan::EC_Group secp160r1(Botan::OIDS::lookup("secp160r1")); const Botan::CurveGFp& curve = secp160r1.get_curve(); const std::vector G_comp = Botan::hex_decode("024A96B5688EF573284664698968C38BB913CBFC82"); const Botan::PointGFp p = Botan::OS2ECP(G_comp, curve); std::vector sv_result = unlock(Botan::EC2OSP(p, Botan::PointGFp::COMPRESSED)); result.test_eq("result", sv_result, G_comp); return result; } Test::Result test_enc_dec_compressed_256() { Test::Result result("ECC Unit"); // Test for compressed conversion (02/03) 256bit std::string p_secp = "ffffffff00000001000000000000000000000000ffffffffffffffffffffffff"; std::string a_secp = "ffffffff00000001000000000000000000000000ffffffffffffffffffffffFC"; std::string b_secp = "5AC635D8AA3A93E7B3EBBD55769886BC651D06B0CC53B0F63BCE3C3E27D2604B"; std::string G_secp_comp = "036B17D1F2E12C4247F8BCE6E563A440F277037D812DEB33A0F4A13945D898C296"; std::vector sv_p_secp = Botan::hex_decode(p_secp); std::vector sv_a_secp = Botan::hex_decode(a_secp); std::vector sv_b_secp = Botan::hex_decode(b_secp); std::vector sv_G_secp_comp = Botan::hex_decode(G_secp_comp); Botan::BigInt bi_p_secp = Botan::BigInt::decode(sv_p_secp.data(), sv_p_secp.size()); Botan::BigInt bi_a_secp = Botan::BigInt::decode(sv_a_secp.data(), sv_a_secp.size()); Botan::BigInt bi_b_secp = Botan::BigInt::decode(sv_b_secp.data(), sv_b_secp.size()); Botan::CurveGFp curve(bi_p_secp, bi_a_secp, bi_b_secp); Botan::PointGFp p_G = OS2ECP(sv_G_secp_comp, curve); std::vector sv_result = unlock(EC2OSP(p_G, Botan::PointGFp::COMPRESSED)); result.test_eq("compressed_256", sv_result, sv_G_secp_comp); return result; } Test::Result test_enc_dec_uncompressed_112() { Test::Result result("ECC Unit"); // Test for uncompressed conversion (04) 112bit std::string p_secp = "db7c2abf62e35e668076bead208b"; std::string a_secp = "6127C24C05F38A0AAAF65C0EF02C"; std::string b_secp = "51DEF1815DB5ED74FCC34C85D709"; std::string G_secp_uncomp = "044BA30AB5E892B4E1649DD0928643ADCD46F5882E3747DEF36E956E97"; std::vector sv_p_secp = Botan::hex_decode(p_secp); std::vector sv_a_secp = Botan::hex_decode(a_secp); std::vector sv_b_secp = Botan::hex_decode(b_secp); std::vector sv_G_secp_uncomp = Botan::hex_decode(G_secp_uncomp); Botan::BigInt bi_p_secp = Botan::BigInt::decode(sv_p_secp.data(), sv_p_secp.size()); Botan::BigInt bi_a_secp = Botan::BigInt::decode(sv_a_secp.data(), sv_a_secp.size()); Botan::BigInt bi_b_secp = Botan::BigInt::decode(sv_b_secp.data(), sv_b_secp.size()); Botan::CurveGFp curve(bi_p_secp, bi_a_secp, bi_b_secp); Botan::PointGFp p_G = OS2ECP(sv_G_secp_uncomp, curve); std::vector sv_result = unlock(EC2OSP(p_G, Botan::PointGFp::UNCOMPRESSED)); result.test_eq("uncompressed_112", sv_result, sv_G_secp_uncomp); return result; } Test::Result test_enc_dec_uncompressed_521() { Test::Result result("ECC Unit"); // Test for uncompressed conversion(04) with big values(521 bit) std::string p_secp = "01ffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff"; std::string a_secp = "01ffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffFC"; std::string b_secp = "0051953EB9618E1C9A1F929A21A0B68540EEA2DA725B99B315F3B8B489918EF109E156193951EC7E937B1652C0BD3BB1BF073573DF883D2C34F1EF451FD46B503F00"; std::string G_secp_uncomp = "0400C6858E06B70404E9CD9E3ECB662395B4429C648139053FB521F828AF606B4D3DBAA14B5E77EFE75928FE1DC127A2ffA8DE3348B3C1856A429BF97E7E31C2E5BD66011839296A789A3BC0045C8A5FB42C7D1BD998F54449579B446817AFBD17273E662C97EE72995EF42640C550B9013FAD0761353C7086A272C24088BE94769FD16650"; std::vector sv_p_secp = Botan::hex_decode(p_secp); std::vector sv_a_secp = Botan::hex_decode(a_secp); std::vector sv_b_secp = Botan::hex_decode(b_secp); std::vector sv_G_secp_uncomp = Botan::hex_decode(G_secp_uncomp); Botan::BigInt bi_p_secp = Botan::BigInt::decode(sv_p_secp.data(), sv_p_secp.size()); Botan::BigInt bi_a_secp = Botan::BigInt::decode(sv_a_secp.data(), sv_a_secp.size()); Botan::BigInt bi_b_secp = Botan::BigInt::decode(sv_b_secp.data(), sv_b_secp.size()); Botan::CurveGFp curve(bi_p_secp, bi_a_secp, bi_b_secp); Botan::PointGFp p_G = Botan::OS2ECP(sv_G_secp_uncomp, curve); std::vector sv_result = unlock(EC2OSP(p_G, Botan::PointGFp::UNCOMPRESSED)); result.test_eq("expected", sv_result, sv_G_secp_uncomp); return result; } Test::Result test_enc_dec_uncompressed_521_prime_too_large() { Test::Result result("ECC Unit"); // Test for uncompressed conversion(04) with big values(521 bit) std::string p_secp = "01ffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffff"; // length increased by "ff" std::string a_secp = "01ffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffffFC"; std::string b_secp = "0051953EB9618E1C9A1F929A21A0B68540EEA2DA725B99B315F3B8B489918EF109E156193951EC7E937B1652C0BD3BB1BF073573DF883D2C34F1EF451FD46B503F00"; std::string G_secp_uncomp = "0400C6858E06B70404E9CD9E3ECB662395B4429C648139053FB521F828AF606B4D3DBAA14B5E77EFE75928FE1DC127A2ffA8DE3348B3C1856A429BF97E7E31C2E5BD66011839296A789A3BC0045C8A5FB42C7D1BD998F54449579B446817AFBD17273E662C97EE72995EF42640C550B9013FAD0761353C7086A272C24088BE94769FD16650"; std::vector sv_p_secp = Botan::hex_decode(p_secp); std::vector sv_a_secp = Botan::hex_decode(a_secp); std::vector sv_b_secp = Botan::hex_decode(b_secp); std::vector sv_G_secp_uncomp = Botan::hex_decode(G_secp_uncomp); Botan::BigInt bi_p_secp = Botan::BigInt::decode(sv_p_secp.data(), sv_p_secp.size()); Botan::BigInt bi_a_secp = Botan::BigInt::decode(sv_a_secp.data(), sv_a_secp.size()); Botan::BigInt bi_b_secp = Botan::BigInt::decode(sv_b_secp.data(), sv_b_secp.size()); Botan::CurveGFp secp521r1(bi_p_secp, bi_a_secp, bi_b_secp); std::unique_ptr p_G; try { p_G = std::unique_ptr(new Botan::PointGFp(Botan::OS2ECP(sv_G_secp_uncomp, secp521r1))); result.test_failure("point decoding with too large value accepted"); } catch(std::exception&) { result.test_note("rejected invalid point"); } return result; } Test::Result test_gfp_store_restore() { Test::Result result("ECC Unit"); // generate point Botan::EC_Group dom_pars(Botan::OID("1.3.132.0.8")); Botan::PointGFp p = dom_pars.get_base_point(); std::vector sv_mes = unlock(EC2OSP(p, Botan::PointGFp::COMPRESSED)); Botan::PointGFp new_p = Botan::OS2ECP(sv_mes, dom_pars.get_curve()); result.test_eq("original and restored points are same", p, new_p); return result; } // maybe move this test Test::Result test_cdc_curve_33() { Test::Result result("ECC Unit"); std::string G_secp_uncomp = "04081523d03d4f12cd02879dea4bf6a4f3a7df26ed888f10c5b2235a1274c386a2f218300dee6ed217841164533bcdc903f07a096f9fbf4ee95bac098a111f296f5830fe5c35b3e344d5df3a2256985f64fbe6d0edcc4c61d18bef681dd399df3d0194c5a4315e012e0245ecea56365baa9e8be1f7"; std::vector sv_G_uncomp = Botan::hex_decode(G_secp_uncomp); Botan::BigInt bi_p_secp = Botan::BigInt("2117607112719756483104013348936480976596328609518055062007450442679169492999007105354629105748524349829824407773719892437896937279095106809"); Botan::BigInt bi_a_secp("0xa377dede6b523333d36c78e9b0eaa3bf48ce93041f6d4fc34014d08f6833807498deedd4290101c5866e8dfb589485d13357b9e78c2d7fbe9fe"); Botan::BigInt bi_b_secp("0xa9acf8c8ba617777e248509bcb4717d4db346202bf9e352cd5633731dd92a51b72a4dc3b3d17c823fcc8fbda4da08f25dea89046087342595a7"); Botan::CurveGFp curve(bi_p_secp, bi_a_secp, bi_b_secp); Botan::PointGFp p_G = Botan::OS2ECP(sv_G_uncomp, curve); result.confirm("point is on the curve", p_G.on_the_curve()); return result; } Test::Result test_more_zeropoint() { Test::Result result("ECC Unit"); // by Falko Botan::EC_Group secp160r1(Botan::OIDS::lookup("secp160r1")); const Botan::CurveGFp& curve = secp160r1.get_curve(); Botan::PointGFp p1(curve, Botan::BigInt("16984103820118642236896513183038186009872590470"), Botan::BigInt("1373093393927139016463695321221277758035357890939")); result.confirm("point is on the curve", p1.on_the_curve()); Botan::PointGFp minus_p1 = -p1; result.confirm("point is on the curve", minus_p1.on_the_curve()); Botan::PointGFp shouldBeZero = p1 + minus_p1; result.confirm("point is on the curve", shouldBeZero.on_the_curve()); result.confirm("point is zero", shouldBeZero.is_zero()); Botan::BigInt y1 = p1.get_affine_y(); y1 = curve.get_p() - y1; result.test_eq("minus point x", minus_p1.get_affine_x(), p1.get_affine_x()); result.test_eq("minus point y", minus_p1.get_affine_y(), y1); Botan::PointGFp zero(curve); result.confirm("zero point is on the curve", zero.on_the_curve()); result.test_eq("addition of zero does nothing", p1, p1 + zero); return result; } Test::Result test_mult_by_order() { Test::Result result("ECC Unit"); // generate point Botan::EC_Group dom_pars(Botan::OID("1.3.132.0.8")); Botan::PointGFp p = dom_pars.get_base_point(); Botan::PointGFp shouldBeZero = p * dom_pars.get_order(); result.confirm("G * order = 0", shouldBeZero.is_zero()); return result; } Test::Result test_point_swap() { Test::Result result("ECC Unit"); Botan::EC_Group dom_pars(Botan::OID("1.3.132.0.8")); Botan::PointGFp a(create_random_point(Test::rng(), dom_pars.get_curve())); Botan::PointGFp b(create_random_point(Test::rng(), dom_pars.get_curve())); b *= Botan::BigInt(Test::rng(), 20); Botan::PointGFp c(a); Botan::PointGFp d(b); d.swap(c); result.test_eq("swap correct", a, d); result.test_eq("swap correct", b, c); return result; } /** * This test verifies that the side channel attack resistant multiplication function * yields the same result as the normal (insecure) multiplication via operator*= */ Test::Result test_mult_sec_mass() { Test::Result result("ECC Unit"); Botan::EC_Group dom_pars(Botan::OID("1.3.132.0.8")); for(int i = 0; i < 50; i++) { try { Botan::PointGFp a(create_random_point(Test::rng(), dom_pars.get_curve())); Botan::BigInt scal(Botan::BigInt(Test::rng(), 40)); Botan::PointGFp b = a * scal; Botan::PointGFp c(a); c *= scal; result.test_eq("same result", b, c); } catch(std::exception& e) { result.test_failure("mult_sec_mass", e.what()); } } return result; } Test::Result test_curve_cp_ctor() { Test::Result result("ECC Unit"); try { Botan::EC_Group dom_pars(Botan::OID("1.3.132.0.8")); Botan::CurveGFp curve(dom_pars.get_curve()); } catch(std::exception& e) { result.test_failure("curve_cp_ctor", e.what()); } return result; } class ECC_Unit_Tests final : public Test { public: std::vector run() override { std::vector results; results.push_back(test_coordinates()); results.push_back(test_point_transformation()); results.push_back(test_point_mult()); results.push_back(test_point_negative()); results.push_back(test_zeropoint()); results.push_back(test_zeropoint_enc_dec()); results.push_back(test_calc_with_zeropoint()); results.push_back(test_add_point()); results.push_back(test_sub_point()); results.push_back(test_mult_point()); results.push_back(test_basic_operations()); results.push_back(test_enc_dec_compressed_160()); results.push_back(test_enc_dec_compressed_256()); results.push_back(test_enc_dec_uncompressed_112()); results.push_back(test_enc_dec_uncompressed_521()); results.push_back(test_enc_dec_uncompressed_521_prime_too_large()); results.push_back(test_gfp_store_restore()); results.push_back(test_cdc_curve_33()); results.push_back(test_more_zeropoint()); results.push_back(test_mult_by_order()); results.push_back(test_point_swap()); results.push_back(test_mult_sec_mass()); results.push_back(test_curve_cp_ctor()); return results; } }; BOTAN_REGISTER_TEST("ecc_unit", ECC_Unit_Tests); #if defined(BOTAN_HAS_ECDSA) class ECC_Invalid_Key_Tests final : public Text_Based_Test { public: ECC_Invalid_Key_Tests() : Text_Based_Test("pubkey/ecc_invalid.vec", "SubjectPublicKey") {} bool clear_between_callbacks() const override { return false; } Test::Result run_one_test(const std::string&, const VarMap& vars) override { Test::Result result("ECC invalid keys"); const std::string encoded = get_req_str(vars, "SubjectPublicKey"); Botan::DataSource_Memory key_data(Botan::hex_decode(encoded)); std::unique_ptr key(Botan::X509::load_key(key_data)); result.test_eq("public key fails check", key->check_key(Test::rng(), false), false); return result; } }; BOTAN_REGISTER_TEST("ecc_invalid", ECC_Invalid_Key_Tests); #endif #endif } }