# frozen_string_literal: true require_relative 'utils' if defined?(OpenSSL) && defined?(OpenSSL::PKey::EC) class OpenSSL::TestEC < OpenSSL::PKeyTestCase def test_ec_key builtin_curves = OpenSSL::PKey::EC.builtin_curves assert_not_empty builtin_curves builtin_curves.each do |curve_name, comment| # Oakley curves and X25519 are not suitable for signing and causes # FIPS-selftest failure on some environment, so skip for now. next if ["Oakley", "X25519"].any? { |n| curve_name.start_with?(n) } key = OpenSSL::PKey::EC.new(curve_name) key.generate_key! assert_predicate key, :private? assert_predicate key, :public? assert_nothing_raised { key.check_key } end key1 = OpenSSL::PKey::EC.new("prime256v1").generate_key! key2 = OpenSSL::PKey::EC.new key2.group = key1.group key2.private_key = key1.private_key key2.public_key = key1.public_key assert_equal key1.to_der, key2.to_der key3 = OpenSSL::PKey::EC.new(key1) assert_equal key1.to_der, key3.to_der key4 = OpenSSL::PKey::EC.new(key1.to_der) assert_equal key1.to_der, key4.to_der key5 = key1.dup assert_equal key1.to_der, key5.to_der key_tmp = OpenSSL::PKey::EC.new("prime256v1").generate_key! key5.private_key = key_tmp.private_key key5.public_key = key_tmp.public_key assert_not_equal key1.to_der, key5.to_der end def test_generate assert_raise(OpenSSL::PKey::ECError) { OpenSSL::PKey::EC.generate("non-existent") } g = OpenSSL::PKey::EC::Group.new("prime256v1") ec = OpenSSL::PKey::EC.generate(g) assert_equal(true, ec.private?) ec = OpenSSL::PKey::EC.generate("prime256v1") assert_equal(true, ec.private?) end def test_check_key key = OpenSSL::PKey::EC.new("prime256v1").generate_key! assert_equal(true, key.check_key) assert_equal(true, key.private?) assert_equal(true, key.public?) key2 = OpenSSL::PKey::EC.new(key.group) assert_equal(false, key2.private?) assert_equal(false, key2.public?) key2.public_key = key.public_key assert_equal(false, key2.private?) assert_equal(true, key2.public?) key2.private_key = key.private_key assert_equal(true, key2.private?) assert_equal(true, key2.public?) assert_equal(true, key2.check_key) key2.private_key += 1 assert_raise(OpenSSL::PKey::ECError) { key2.check_key } end def test_sign_verify p256 = Fixtures.pkey("p256") data = "Sign me!" signature = p256.sign("SHA1", data) assert_equal true, p256.verify("SHA1", signature, data) signature0 = (<<~'end;').unpack("m")[0] MEQCIEOTY/hD7eI8a0qlzxkIt8LLZ8uwiaSfVbjX2dPAvN11AiAQdCYx56Fq QdBp1B4sxJoA8jvODMMklMyBKVmudboA6A== end; assert_equal true, p256.verify("SHA256", signature0, data) signature1 = signature0.succ assert_equal false, p256.verify("SHA256", signature1, data) end def test_dsa_sign_verify data1 = "foo" data2 = "bar" key = OpenSSL::PKey::EC.new("prime256v1").generate_key! sig = key.dsa_sign_asn1(data1) assert_equal true, key.dsa_verify_asn1(data1, sig) assert_equal false, key.dsa_verify_asn1(data2, sig) end def test_dsa_sign_asn1_FIPS186_3 key = OpenSSL::PKey::EC.new("prime256v1").generate_key! size = key.group.order.num_bits / 8 + 1 dgst = (1..size).to_a.pack('C*') sig = key.dsa_sign_asn1(dgst) # dgst is auto-truncated according to FIPS186-3 after openssl-0.9.8m assert(key.dsa_verify_asn1(dgst + "garbage", sig)) end def test_dh_compute_key key_a = OpenSSL::PKey::EC.new("prime256v1").generate_key! key_b = OpenSSL::PKey::EC.new(key_a.group).generate_key! pub_a = key_a.public_key pub_b = key_b.public_key a = key_a.dh_compute_key(pub_b) b = key_b.dh_compute_key(pub_a) assert_equal a, b end def test_ECPrivateKey p256 = Fixtures.pkey("p256") asn1 = OpenSSL::ASN1::Sequence([ OpenSSL::ASN1::Integer(1), OpenSSL::ASN1::OctetString(p256.private_key.to_s(2)), OpenSSL::ASN1::ObjectId("prime256v1", 0, :EXPLICIT), OpenSSL::ASN1::BitString(p256.public_key.to_octet_string(:uncompressed), 1, :EXPLICIT) ]) key = OpenSSL::PKey::EC.new(asn1.to_der) assert_predicate key, :private? assert_same_ec p256, key pem = <<~EOF -----BEGIN EC PRIVATE KEY----- MHcCAQEEIID49FDqcf1O1eO8saTgG70UbXQw9Fqwseliit2aWhH1oAoGCCqGSM49 AwEHoUQDQgAEFglk2c+oVUIKQ64eZG9bhLNPWB7lSZ/ArK41eGy5wAzU/0G51Xtt CeBUl+MahZtn9fO1JKdF4qJmS39dXnpENg== -----END EC PRIVATE KEY----- EOF key = OpenSSL::PKey::EC.new(pem) assert_same_ec p256, key assert_equal asn1.to_der, p256.to_der assert_equal pem, p256.export end def test_ECPrivateKey_encrypted p256 = Fixtures.pkey("p256") # key = abcdef pem = <<~EOF -----BEGIN EC PRIVATE KEY----- Proc-Type: 4,ENCRYPTED DEK-Info: AES-128-CBC,85743EB6FAC9EA76BF99D9328AFD1A66 nhsP1NHxb53aeZdzUe9umKKyr+OIwQq67eP0ONM6E1vFTIcjkDcFLR6PhPFufF4m y7E2HF+9uT1KPQhlE+D63i1m1Mvez6PWfNM34iOQp2vEhaoHHKlR3c43lLyzaZDI 0/dGSU5SzFG+iT9iFXCwCvv+bxyegkBOyALFje1NAsM= -----END EC PRIVATE KEY----- EOF key = OpenSSL::PKey::EC.new(pem, "abcdef") assert_same_ec p256, key key = OpenSSL::PKey::EC.new(pem) { "abcdef" } assert_same_ec p256, key cipher = OpenSSL::Cipher.new("aes-128-cbc") exported = p256.to_pem(cipher, "abcdef\0\1") assert_same_ec p256, OpenSSL::PKey::EC.new(exported, "abcdef\0\1") assert_raise(OpenSSL::PKey::ECError) { OpenSSL::PKey::EC.new(exported, "abcdef") } end def test_PUBKEY p256 = Fixtures.pkey("p256") asn1 = OpenSSL::ASN1::Sequence([ OpenSSL::ASN1::Sequence([ OpenSSL::ASN1::ObjectId("id-ecPublicKey"), OpenSSL::ASN1::ObjectId("prime256v1") ]), OpenSSL::ASN1::BitString( p256.public_key.to_octet_string(:uncompressed) ) ]) key = OpenSSL::PKey::EC.new(asn1.to_der) assert_not_predicate key, :private? assert_same_ec dup_public(p256), key pem = <<~EOF -----BEGIN PUBLIC KEY----- MFkwEwYHKoZIzj0CAQYIKoZIzj0DAQcDQgAEFglk2c+oVUIKQ64eZG9bhLNPWB7l SZ/ArK41eGy5wAzU/0G51XttCeBUl+MahZtn9fO1JKdF4qJmS39dXnpENg== -----END PUBLIC KEY----- EOF key = OpenSSL::PKey::EC.new(pem) assert_same_ec dup_public(p256), key assert_equal asn1.to_der, dup_public(p256).to_der assert_equal pem, dup_public(p256).export end def test_ec_group group1 = OpenSSL::PKey::EC::Group.new("prime256v1") key1 = OpenSSL::PKey::EC.new(group1) assert_equal group1, key1.group group2 = OpenSSL::PKey::EC::Group.new(group1) assert_equal group1.to_der, group2.to_der assert_equal group1, group2 group2.asn1_flag ^=OpenSSL::PKey::EC::NAMED_CURVE assert_not_equal group1.to_der, group2.to_der assert_equal group1, group2 group3 = group1.dup assert_equal group1.to_der, group3.to_der assert group1.asn1_flag & OpenSSL::PKey::EC::NAMED_CURVE # our default der = group1.to_der group4 = OpenSSL::PKey::EC::Group.new(der) group1.point_conversion_form = group4.point_conversion_form = :uncompressed assert_equal :uncompressed, group1.point_conversion_form assert_equal :uncompressed, group4.point_conversion_form assert_equal group1, group4 assert_equal group1.curve_name, group4.curve_name assert_equal group1.generator.to_octet_string(:uncompressed), group4.generator.to_octet_string(:uncompressed) assert_equal group1.order, group4.order assert_equal group1.cofactor, group4.cofactor assert_equal group1.seed, group4.seed assert_equal group1.degree, group4.degree end def test_ec_point group = OpenSSL::PKey::EC::Group.new("prime256v1") key = OpenSSL::PKey::EC.new(group).generate_key! point = key.public_key point2 = OpenSSL::PKey::EC::Point.new(group, point.to_bn) assert_equal point, point2 assert_equal point.to_bn, point2.to_bn assert_equal point.to_octet_string(:uncompressed), point2.to_octet_string(:uncompressed) point3 = OpenSSL::PKey::EC::Point.new(group, point.to_octet_string(:uncompressed)) assert_equal point, point3 assert_equal point.to_bn, point3.to_bn assert_equal point.to_octet_string(:uncompressed), point3.to_octet_string(:uncompressed) point2.invert! point3.invert! assert_not_equal point.to_octet_string(:uncompressed), point2.to_octet_string(:uncompressed) assert_equal point2.to_octet_string(:uncompressed), point3.to_octet_string(:uncompressed) begin group = OpenSSL::PKey::EC::Group.new(:GFp, 17, 2, 2) group.point_conversion_form = :uncompressed generator = OpenSSL::PKey::EC::Point.new(group, B(%w{ 04 05 01 })) group.set_generator(generator, 19, 1) point = OpenSSL::PKey::EC::Point.new(group, B(%w{ 04 06 03 })) rescue OpenSSL::PKey::EC::Group::Error pend "Patched OpenSSL rejected curve" if /unsupported field/ =~ $!.message raise end assert_equal 0x040603.to_bn, point.to_bn assert_equal 0x040603.to_bn, point.to_bn(:uncompressed) assert_equal 0x0306.to_bn, point.to_bn(:compressed) assert_equal 0x070603.to_bn, point.to_bn(:hybrid) group2 = group.dup; group2.point_conversion_form = :compressed point2 = OpenSSL::PKey::EC::Point.new(group2, B(%w{ 04 06 03 })) assert_equal 0x0306.to_bn, point2.to_bn assert_equal B(%w{ 04 06 03 }), point.to_octet_string(:uncompressed) assert_equal B(%w{ 03 06 }), point.to_octet_string(:compressed) assert_equal B(%w{ 07 06 03 }), point.to_octet_string(:hybrid) assert_equal true, point.on_curve? point.invert! # 8.5 assert_equal B(%w{ 04 06 0E }), point.to_octet_string(:uncompressed) assert_equal true, point.on_curve? assert_equal false, point.infinity? point.set_to_infinity! assert_equal true, point.infinity? assert_equal 0.to_bn, point.to_bn assert_equal B(%w{ 00 }), point.to_octet_string(:uncompressed) assert_equal true, point.on_curve? end def test_ec_point_add begin group = OpenSSL::PKey::EC::Group.new(:GFp, 17, 2, 2) group.point_conversion_form = :uncompressed gen = OpenSSL::PKey::EC::Point.new(group, B(%w{ 04 05 01 })) group.set_generator(gen, 19, 1) point_a = OpenSSL::PKey::EC::Point.new(group, B(%w{ 04 06 03 })) point_b = OpenSSL::PKey::EC::Point.new(group, B(%w{ 04 10 0D })) rescue OpenSSL::PKey::EC::Group::Error pend "Patched OpenSSL rejected curve" if /unsupported field/ =~ $!.message raise end result = point_a.add(point_b) assert_equal B(%w{ 04 0D 07 }), result.to_octet_string(:uncompressed) assert_raise(TypeError) { point_a.add(nil) } assert_raise(ArgumentError) { point_a.add } end def test_ec_point_mul begin # y^2 = x^3 + 2x + 2 over F_17 # generator is (5, 1) group = OpenSSL::PKey::EC::Group.new(:GFp, 17, 2, 2) group.point_conversion_form = :uncompressed gen = OpenSSL::PKey::EC::Point.new(group, B(%w{ 04 05 01 })) group.set_generator(gen, 19, 1) # 3 * (6, 3) = (16, 13) point_a = OpenSSL::PKey::EC::Point.new(group, B(%w{ 04 06 03 })) result_a1 = point_a.mul(3) assert_equal B(%w{ 04 10 0D }), result_a1.to_octet_string(:uncompressed) # 3 * (6, 3) + 3 * (5, 1) = (7, 6) result_a2 = point_a.mul(3, 3) assert_equal B(%w{ 04 07 06 }), result_a2.to_octet_string(:uncompressed) # 3 * point_a = 3 * (6, 3) = (16, 13) result_b1 = point_a.mul([3], []) assert_equal B(%w{ 04 10 0D }), result_b1.to_octet_string(:uncompressed) # 3 * point_a + 2 * point_a = 3 * (6, 3) + 2 * (6, 3) = (7, 11) begin result_b1 = point_a.mul([3, 2], [point_a]) rescue OpenSSL::PKey::EC::Point::Error # LibreSSL doesn't support multiple entries in first argument raise if $!.message !~ /called a function you should not call/ else assert_equal B(%w{ 04 07 0B }), result_b1.to_octet_string(:uncompressed) end # 3 * point_a + 5 * point_a.group.generator = 3 * (6, 3) + 5 * (5, 1) = (13, 10) result_b1 = point_a.mul([3], [], 5) assert_equal B(%w{ 04 0D 0A }), result_b1.to_octet_string(:uncompressed) rescue OpenSSL::PKey::EC::Group::Error # CentOS patches OpenSSL to reject curves defined over Fp where p < 256 bits raise if $!.message !~ /unsupported field/ end p256_key = Fixtures.pkey("p256") p256_g = p256_key.group assert_equal(p256_key.public_key, p256_g.generator.mul(p256_key.private_key)) # invalid argument point = p256_key.public_key assert_raise(TypeError) { point.mul(nil) } assert_raise(ArgumentError) { point.mul([1], [point]) } assert_raise(TypeError) { point.mul([1], nil) } assert_raise(TypeError) { point.mul([nil], []) } end # test Group: asn1_flag, point_conversion private def B(ary) [Array(ary).join].pack("H*") end def assert_same_ec(expected, key) check_component(expected, key, [:group, :public_key, :private_key]) end end end