const std = @import("std"); const ascii = std.ascii; const base32 = @import("base32.zig"); const crc16 = @import("crc16.zig"); const crypto = std.crypto; const Ed25519 = crypto.sign.Ed25519; const mem = std.mem; const testing = std.testing; pub const InvalidPrefixByteError = error{InvalidPrefixByte}; pub const InvalidEncodingError = error{InvalidEncoding}; pub const InvalidPrivateKeyError = error{InvalidPrivateKey}; pub const InvalidSeedError = error{InvalidSeed}; pub const InvalidSignatureError = error{InvalidSignature}; pub const NoNkeySeedFoundError = error{NoNkeySeedFound}; pub const NoNkeyUserSeedFoundError = error{NoNkeyUserSeedFound}; pub const DecodeError = InvalidPrefixByteError || base32.DecodeError || crc16.InvalidChecksumError || crypto.errors.NonCanonicalError; pub const SeedDecodeError = DecodeError || InvalidSeedError || crypto.errors.IdentityElementError; pub const PrivateKeyDecodeError = DecodeError || InvalidPrivateKeyError || crypto.errors.EncodingError || crypto.errors.NonCanonicalError || crypto.errors.IdentityElementError; pub const SignError = crypto.errors.IdentityElementError || crypto.errors.NonCanonicalError || crypto.errors.KeyMismatchError || crypto.errors.WeakPublicKeyError; pub const prefix_byte_account = 0; // A pub const prefix_byte_cluster = 2 << 3; // C pub const prefix_byte_operator = 14 << 3; // O pub const prefix_byte_private = 15 << 3; // P pub const prefix_byte_seed = 18 << 3; // S pub const prefix_byte_server = 13 << 3; // N pub const prefix_byte_user = 20 << 3; // U pub fn prefixByteToLetter(prefix_byte: u8) ?u8 { return switch (prefix_byte) { prefix_byte_account => 'A', prefix_byte_cluster => 'C', prefix_byte_operator => 'O', prefix_byte_private => 'P', prefix_byte_seed => 'S', prefix_byte_server => 'N', prefix_byte_user => 'U', else => null, }; } pub fn prefixByteFromLetter(letter: u8) ?u8 { return switch (letter) { 'A' => prefix_byte_account, 'C' => prefix_byte_cluster, 'O' => prefix_byte_operator, 'P' => prefix_byte_private, 'S' => prefix_byte_seed, 'N' => prefix_byte_server, 'U' => prefix_byte_user, else => null, }; } pub const Role = enum(u8) { const Self = @This(); account, cluster, operator, server, user, pub fn fromPublicPrefixByte(b: u8) ?Self { return switch (b) { prefix_byte_account => .account, prefix_byte_cluster => .cluster, prefix_byte_operator => .operator, prefix_byte_server => .server, prefix_byte_user => .user, else => null, }; } pub fn publicPrefixByte(self: Self) u8 { return switch (self) { .account => prefix_byte_account, .cluster => prefix_byte_cluster, .operator => prefix_byte_operator, .server => prefix_byte_server, .user => prefix_byte_user, }; } pub fn letter(self: Self) u8 { return prefixByteToLetter(self.publicPrefixByte()) orelse unreachable; } }; // One prefix byte, two CRC bytes const binary_private_size = 1 + Ed25519.SecretKey.encoded_length + 2; // One prefix byte, two CRC bytes const binary_public_size = 1 + Ed25519.PublicKey.encoded_length + 2; // Two prefix bytes, two CRC bytes const binary_seed_size = 2 + Ed25519.KeyPair.seed_length + 2; pub const text_private_len = base32.Encoder.calcSize(binary_private_size); pub const text_public_len = base32.Encoder.calcSize(binary_public_size); pub const text_seed_len = base32.Encoder.calcSize(binary_seed_size); pub const text_private = [text_private_len]u8; pub const text_public = [text_public_len]u8; pub const text_seed = [text_seed_len]u8; pub const SeedKeyPair = struct { const Self = @This(); role: Role, kp: Ed25519.KeyPair, pub fn generate(role: Role) crypto.errors.IdentityElementError!Self { var raw_seed: [Ed25519.KeyPair.seed_length]u8 = undefined; crypto.random.bytes(&raw_seed); defer wipeBytes(&raw_seed); return Self{ .role = role, .kp = try Ed25519.KeyPair.create(raw_seed) }; } pub fn generateWithCustomEntropy(role: Role, reader: anytype) !Self { var raw_seed: [Ed25519.KeyPair.seed_length]u8 = undefined; try reader.readNoEof(&raw_seed); defer wipeBytes(&raw_seed); return Self{ .role = role, .kp = try Ed25519.KeyPair.create(raw_seed) }; } pub fn fromTextSeed(text: *const text_seed) SeedDecodeError!Self { var decoded = try decode(2, Ed25519.KeyPair.seed_length, text); defer decoded.wipe(); // gets copied const key_ty_prefix = decoded.prefix[0] & 0b11111000; const role_prefix = (decoded.prefix[0] << 5) | (decoded.prefix[1] >> 3); if (key_ty_prefix != prefix_byte_seed) return error.InvalidSeed; const role = Role.fromPublicPrefixByte(role_prefix) orelse return error.InvalidPrefixByte; return fromRawSeed(role, &decoded.data); } pub fn fromRawSeed( role: Role, raw_seed: *const [Ed25519.KeyPair.seed_length]u8, ) crypto.errors.IdentityElementError!Self { return Self{ .role = role, .kp = try Ed25519.KeyPair.create(raw_seed.*) }; } pub fn sign(self: *const Self, msg: []const u8) SignError!Ed25519.Signature { return self.kp.sign(msg, null); } pub fn verify(self: *const Self, msg: []const u8, sig: Ed25519.Signature) InvalidSignatureError!void { sig.verify(msg, self.kp.public_key) catch return error.InvalidSignature; } pub fn seedText(self: *const Self) text_seed { const public_prefix = self.role.publicPrefixByte(); const full_prefix = &[_]u8{ prefix_byte_seed | (public_prefix >> 5), (public_prefix & 0b00011111) << 3, }; const seed = self.kp.secret_key.seed(); return encode(full_prefix.len, seed.len, full_prefix, &seed); } pub fn privateKeyText(self: *const Self) text_private { return encode(1, Ed25519.SecretKey.encoded_length, &.{prefix_byte_private}, &self.kp.secret_key.toBytes()); } pub fn publicKeyText(self: *const Self) text_public { return encode(1, Ed25519.PublicKey.encoded_length, &.{self.role.publicPrefixByte()}, &self.kp.public_key.toBytes()); } pub fn intoPublicKey(self: *const Self) PublicKey { return .{ .role = self.role, .key = self.kp.public_key, }; } pub fn intoPrivateKey(self: *const Self) PrivateKey { return .{ .kp = self.kp }; } pub fn wipe(self: *Self) void { self.role = .account; wipeKeyPair(&self.kp); } }; pub const PublicKey = struct { const Self = @This(); role: Role, key: Ed25519.PublicKey, pub fn fromTextPublicKey(text: *const text_public) DecodeError!Self { var decoded = try decode(1, Ed25519.PublicKey.encoded_length, text); defer decoded.wipe(); // gets copied return PublicKey{ .role = Role.fromPublicPrefixByte(decoded.prefix[0]) orelse return error.InvalidPrefixByte, .key = try Ed25519.PublicKey.fromBytes(decoded.data), }; } pub fn fromRawPublicKey(role: Role, raw_key: *const Ed25519.PublicKey) Self { return .{ .role = role, .key = raw_key.* }; } pub fn publicKeyText(self: *const Self) text_public { return encode(1, Ed25519.PublicKey.encoded_length, &.{self.role.publicPrefixByte()}, &self.key.toBytes()); } pub fn verify(self: *const Self, msg: []const u8, sig: Ed25519.Signature) InvalidSignatureError!void { // TODO: maybe propagate errors better herer sig.verify(msg, self.key) catch return error.InvalidSignature; } pub fn wipe(self: *Self) void { self.role = .account; wipeBytes(&self.key.bytes); } }; pub const PrivateKey = struct { const Self = @This(); kp: Ed25519.KeyPair, pub fn fromTextPrivateKey(text: *const text_private) PrivateKeyDecodeError!Self { var decoded = try decode(1, Ed25519.SecretKey.encoded_length, text); defer decoded.wipe(); // gets copied if (decoded.prefix[0] != prefix_byte_private) return error.InvalidPrivateKey; var secret_key = Ed25519.SecretKey.fromBytes(decoded.data) catch unreachable; return fromRawPrivateKey(&secret_key); } pub fn fromRawPrivateKey( raw_key: *const Ed25519.SecretKey, ) (crypto.errors.NonCanonicalError || crypto.errors.EncodingError || crypto.errors.IdentityElementError)!Self { return .{ .kp = try Ed25519.KeyPair.fromSecretKey(raw_key.*) }; } pub fn intoSeedKeyPair(self: *const Self, role: Role) SeedKeyPair { return .{ .role = role, .kp = self.kp, }; } pub fn intoPublicKey(self: *const Self, role: Role) PublicKey { return .{ .role = role, .key = self.kp.public_key, }; } pub fn privateKeyText(self: *const Self) text_private { return encode(1, Ed25519.SecretKey.encoded_length, &.{prefix_byte_private}, &self.kp.secret_key.toBytes()); } pub fn sign(self: *const Self, msg: []const u8) SignError!Ed25519.Signature { return self.kp.sign(msg, null); } pub fn verify(self: *const Self, msg: []const u8, sig: Ed25519.Signature) InvalidSignatureError!void { sig.verify(msg, self.kp.public_key) catch return error.InvalidSignature; } pub fn wipe(self: *Self) void { wipeKeyPair(&self.kp); } }; fn encoded_key(comptime prefix_len: usize, comptime data_len: usize) type { return [base32.Encoder.calcSize(prefix_len + data_len + 2)]u8; } fn encode( comptime prefix_len: usize, comptime data_len: usize, prefix: *const [prefix_len]u8, data: *const [data_len]u8, ) encoded_key(prefix_len, data_len) { var buf: [prefix_len + data_len + 2]u8 = undefined; defer wipeBytes(&buf); mem.copyForwards(u8, &buf, prefix[0..]); mem.copyForwards(u8, buf[prefix_len..], data[0..]); const off = prefix_len + data_len; const checksum = crc16.make(buf[0..off]); mem.writeInt(u16, buf[buf.len - 2 .. buf.len], checksum, .little); var text: encoded_key(prefix_len, data_len) = undefined; std.debug.assert(base32.Encoder.encode(&text, &buf).len == text.len); return text; } fn DecodedNkey(comptime prefix_len: usize, comptime data_len: usize) type { return struct { const Self = @This(); prefix: [prefix_len]u8, data: [data_len]u8, pub fn wipe(self: *Self) void { self.prefix[0] = Role.account.publicPrefixByte(); wipeBytes(&self.data); } }; } fn decode( comptime prefix_len: usize, comptime data_len: usize, text: *const [base32.Encoder.calcSize(prefix_len + data_len + 2)]u8, ) (base32.DecodeError || crc16.InvalidChecksumError)!DecodedNkey(prefix_len, data_len) { var raw: [prefix_len + data_len + 2]u8 = undefined; defer wipeBytes(&raw); std.debug.assert((try base32.Decoder.decode(&raw, text[0..])).len == raw.len); const checksum = mem.readInt(u16, raw[raw.len - 2 .. raw.len], .little); try crc16.validate(raw[0 .. raw.len - 2], checksum); return DecodedNkey(prefix_len, data_len){ .prefix = raw[0..prefix_len].*, .data = raw[prefix_len .. raw.len - 2].*, }; } pub fn isValidEncoding(text: []const u8) bool { if (text.len < 4) return false; var made_crc: u16 = 0; var dec = base32.Decoder.init(text); var crc_buf: [2]u8 = undefined; var crc_buf_len: u8 = 0; const expect_len: usize = base32.Decoder.calcSize(text.len); var wrote_n_total: usize = 0; while (dec.next() catch return false) |b| { wrote_n_total += 1; if (crc_buf_len == 2) made_crc = crc16.update(made_crc, &.{crc_buf[0]}); crc_buf[0] = crc_buf[1]; crc_buf[1] = b; if (crc_buf_len != 2) crc_buf_len += 1; } std.debug.assert(wrote_n_total == expect_len); if (crc_buf_len != 2) unreachable; const got_crc = mem.readInt(u16, &crc_buf, .little); return made_crc == got_crc; } pub fn isValidSeed(text: []const u8, with_role: ?Role) bool { if (text.len < text_seed_len) return false; var res = SeedKeyPair.fromTextSeed(text[0..text_seed_len]) catch return false; defer res.wipe(); return if (with_role) |role| res.role == role else true; } pub fn isValidPublicKey(text: []const u8, with_role: ?Role) bool { if (text.len < text_public_len) return false; var res = PublicKey.fromTextPublicKey(text[0..text_public_len]) catch return false; defer res.wipe(); return if (with_role) |role| res.role == role else true; } pub fn isValidPrivateKey(text: []const u8) bool { if (text.len < text_private_len) return false; var res = PrivateKey.fromTextPrivateKey(text[0..text_private_len]) catch return false; res.wipe(); return true; } // `line` must not contain CR or LF characters. pub fn isKeySectionBarrier(line: []const u8, opening: bool) bool { if (line.len < 6) return false; const start = mem.indexOf(u8, line, "---") orelse return false; if (!opening and start != 0) return false; if (line.len - start < 6) return false; return mem.endsWith(u8, line, "---"); } const allowed_creds_section_chars_table: [256]bool = allowed: { var table = [_]bool{false} ** 256; const chars = "abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ0123456789_-.="; for (chars) |char| table[char] = true; break :allowed table; }; pub fn areKeySectionContentsValid(contents: []const u8) bool { for (contents) |c| if (!allowed_creds_section_chars_table[c]) return false; return true; } pub fn findKeySection(line_it: *std.mem.SplitIterator(u8, .scalar)) ?[]const u8 { while (true) { const opening_line = line_it.next() orelse return null; if (!isKeySectionBarrier(opening_line, true)) continue; const contents_line = line_it.next() orelse return null; if (!areKeySectionContentsValid(contents_line)) continue; const closing_line = line_it.next() orelse return null; if (!isKeySectionBarrier(closing_line, false)) continue; return contents_line; } } pub fn parseDecoratedJwt(contents: []const u8) []const u8 { var line_it = mem.splitScalar(u8, contents, '\n'); return findKeySection(&line_it) orelse return contents; } pub fn parseDecoratedNkey(contents: []const u8) NoNkeySeedFoundError!SeedKeyPair { var line_it = mem.splitScalar(u8, contents, '\n'); var seed: ?[]const u8 = null; if (findKeySection(&line_it) != null) seed = findKeySection(&line_it); if (seed == null) seed = findNkey(contents) orelse return error.NoNkeySeedFound; if (!isValidCredsNkey(seed.?)) return error.NoNkeySeedFound; return SeedKeyPair.fromTextSeed(seed.?[0..text_seed_len]) catch return error.NoNkeySeedFound; } pub fn parseDecoratedUserNkey(contents: []const u8) (NoNkeySeedFoundError || NoNkeyUserSeedFoundError)!SeedKeyPair { var key = try parseDecoratedNkey(contents); if (!mem.startsWith(u8, &key.seedText(), "SU")) return error.NoNkeyUserSeedFound; defer key.wipe(); return key; } fn isValidCredsNkey(text: []const u8) bool { const valid_prefix = mem.startsWith(u8, text, "SO") or mem.startsWith(u8, text, "SA") or mem.startsWith(u8, text, "SU"); const valid_len = text.len >= text_seed_len; return valid_prefix and valid_len; } fn findNkey(text: []const u8) ?[]const u8 { var line_it = std.mem.split(u8, text, "\n"); while (line_it.next()) |line| { for (line, 0..) |c, i| { if (!ascii.isWhitespace(c)) { if (isValidCredsNkey(line[i..])) return line[i..]; break; } } } return null; } fn wipeKeyPair(kp: *Ed25519.KeyPair) void { wipeBytes(&kp.public_key.bytes); wipeBytes(&kp.secret_key.bytes); } fn wipeBytes(bs: []u8) void { for (bs) |*b| b.* = 0; } test "reference all declarations" { testing.refAllDecls(@This()); testing.refAllDecls(Role); testing.refAllDecls(SeedKeyPair); testing.refAllDecls(PublicKey); testing.refAllDecls(PrivateKey); } test "key conversions" { var key_pair = try SeedKeyPair.generate(.server); var decoded_seed = try SeedKeyPair.fromTextSeed(&key_pair.seedText()); try testing.expect(isValidEncoding(&decoded_seed.seedText())); var pub_key_str_a = key_pair.publicKeyText(); var priv_key_str_a = key_pair.privateKeyText(); try testing.expect(pub_key_str_a.len != 0); try testing.expect(priv_key_str_a.len != 0); try testing.expect(isValidEncoding(&pub_key_str_a)); try testing.expect(isValidEncoding(&priv_key_str_a)); var pub_key = key_pair.intoPublicKey(); var pub_key_str_b = pub_key.publicKeyText(); try testing.expectEqualStrings(&pub_key_str_a, &pub_key_str_b); var priv_key = key_pair.intoPrivateKey(); var priv_key_str_b = priv_key.privateKeyText(); try testing.expectEqualStrings(&priv_key_str_a, &priv_key_str_b); } test "decode" { const kp = try SeedKeyPair.generate(.account); const seed_text = kp.seedText(); const pub_key_text = kp.publicKeyText(); const priv_key_text = kp.privateKeyText(); _ = try SeedKeyPair.fromTextSeed(&seed_text); _ = try PublicKey.fromTextPublicKey(&pub_key_text); _ = try PrivateKey.fromTextPrivateKey(&priv_key_text); try testing.expectError(error.InvalidChecksum, PublicKey.fromTextPublicKey(seed_text[0..text_public_len])); try testing.expectError(error.InvalidChecksum, SeedKeyPair.fromTextSeed(priv_key_text[0..text_seed_len])); } test "seed" { inline for (@typeInfo(Role).Enum.fields) |field| { const role = @field(Role, field.name); const kp = try SeedKeyPair.generate(role); const decoded = try SeedKeyPair.fromTextSeed(&kp.seedText()); if (decoded.role != role) { std.debug.print("expected role {}, found role {}\n", .{ role, decoded.role }); return error.TestUnexpectedError; } } } test "public key" { inline for (@typeInfo(Role).Enum.fields) |field| { const role = @field(Role, field.name); const kp = try SeedKeyPair.generate(role); const decoded_pub_key = try PublicKey.fromTextPublicKey(&kp.publicKeyText()); if (decoded_pub_key.role != role) { std.debug.print("expected role {}, found role {}\n", .{ role, decoded_pub_key.role }); return error.TestUnexpectedError; } } } test "different key types" { inline for (@typeInfo(Role).Enum.fields) |field| { const role = @field(Role, field.name); const kp = try SeedKeyPair.generate(role); _ = try SeedKeyPair.fromTextSeed(&kp.seedText()); const pub_key_str = kp.publicKeyText(); try testing.expect(pub_key_str[0] == role.letter()); try testing.expect(isValidPublicKey(&pub_key_str, role)); const priv_key_str = kp.privateKeyText(); try testing.expect(priv_key_str[0] == 'P'); try testing.expect(isValidPrivateKey(&priv_key_str)); const data = "Hello, world!"; const sig = try kp.sign(data); try testing.expect(sig.toBytes().len == Ed25519.Signature.encoded_length); try kp.verify(data, sig); } } test "validation" { const roles = @typeInfo(Role).Enum.fields; inline for (roles, 0..) |field, i| { const role = @field(Role, field.name); const next_role = next: { const next_field_i = if (i == roles.len - 1) 0 else i + 1; std.debug.assert(next_field_i != i); break :next @field(Role, roles[next_field_i].name); }; const kp = try SeedKeyPair.generate(role); const seed_str = kp.seedText(); const pub_key_str = kp.publicKeyText(); const priv_key_str = kp.privateKeyText(); try testing.expect(isValidSeed(&seed_str, role)); try testing.expect(isValidSeed(&seed_str, null)); try testing.expect(isValidPublicKey(&pub_key_str, null)); try testing.expect(isValidPublicKey(&pub_key_str, role)); try testing.expect(isValidPrivateKey(&priv_key_str)); try testing.expect(!isValidSeed(&seed_str, next_role)); try testing.expect(!isValidSeed(&pub_key_str, null)); try testing.expect(!isValidSeed(&priv_key_str, null)); try testing.expect(!isValidPublicKey(&pub_key_str, next_role)); try testing.expect(!isValidPublicKey(&seed_str, null)); try testing.expect(!isValidPublicKey(&priv_key_str, null)); try testing.expect(!isValidPrivateKey(&seed_str)); try testing.expect(!isValidPrivateKey(&pub_key_str)); } try testing.expect(!isValidSeed("seed", null)); try testing.expect(!isValidPublicKey("public key", null)); try testing.expect(!isValidPrivateKey("private key")); } test "from seed" { const kp = try SeedKeyPair.generate(.account); const kp_from_raw = try SeedKeyPair.fromRawSeed(kp.role, &kp.kp.secret_key.seed()); try testing.expect(std.meta.eql(kp, kp_from_raw)); const data = "Hello, World!"; const sig = try kp.sign(data); const seed = kp.seedText(); try testing.expect(mem.startsWith(u8, &seed, "SA")); const kp2 = try SeedKeyPair.fromTextSeed(&seed); try kp2.verify(data, sig); } test "from public key" { const kp = try SeedKeyPair.generate(.user); const pk_text = kp.publicKeyText(); const pk_text_clone = kp.publicKeyText(); try testing.expectEqualStrings(&pk_text, &pk_text_clone); const pk = try PublicKey.fromTextPublicKey(&pk_text); const pk_text_clone_2 = pk.publicKeyText(); try testing.expect(std.meta.eql(pk, kp.intoPublicKey())); try testing.expect(std.meta.eql(pk, PublicKey.fromRawPublicKey(kp.role, &kp.kp.public_key))); try testing.expectEqualStrings(&pk_text, &pk_text_clone_2); const data = "Hello, world!"; const sig = try kp.sign(data); try pk.verify(data, sig); // Create another user to sign and make sure verification fails const kp2 = try SeedKeyPair.generate(.user); const sig2 = try kp2.sign(data); try testing.expectError(error.InvalidSignature, pk.verify(data, sig2)); } test "from private key" { const kp = try SeedKeyPair.generate(.account); const pk_text = kp.privateKeyText(); const pk_text_clone = kp.privateKeyText(); try testing.expectEqualStrings(&pk_text, &pk_text_clone); const pk = try PrivateKey.fromTextPrivateKey(&pk_text); const pk_text_clone_2 = pk.privateKeyText(); try testing.expect(std.meta.eql(pk, kp.intoPrivateKey())); try testing.expect(std.meta.eql(kp, pk.intoSeedKeyPair(.account))); try testing.expect(std.meta.eql(pk, try PrivateKey.fromRawPrivateKey(&kp.kp.secret_key))); try testing.expectEqualStrings(&pk_text, &pk_text_clone_2); const data = "Hello, World!"; const sig0 = try kp.sign(data); const sig1 = try pk.sign(data); try testing.expectEqualSlices(u8, &sig0.toBytes(), &sig1.toBytes()); try pk.verify(data, sig0); try kp.verify(data, sig1); const kp2 = try SeedKeyPair.generate(.account); const sig2 = try kp2.sign(data); try testing.expectError(error.InvalidSignature, pk.verify(data, sig2)); } test "bad decode" { const kp = try SeedKeyPair.fromTextSeed("SAAHPQF3GOP4IP5SHKHCNBOHD5TMGSW4QQL6RTZAPEEYOQ2NRBIAKCCLQA"); var bad_seed = kp.seedText(); bad_seed[1] = 'S'; try testing.expectError(error.InvalidChecksum, SeedKeyPair.fromTextSeed(&bad_seed)); var bad_pub_key = kp.publicKeyText(); bad_pub_key[bad_pub_key.len - 1] = 'O'; bad_pub_key[bad_pub_key.len - 2] = 'O'; try testing.expectError(error.InvalidChecksum, PublicKey.fromTextPublicKey(&bad_pub_key)); var bad_priv_key = kp.privateKeyText(); bad_priv_key[bad_priv_key.len - 1] = 'O'; bad_priv_key[bad_priv_key.len - 2] = 'O'; try testing.expectError(error.InvalidChecksum, PrivateKey.fromTextPrivateKey(&bad_priv_key)); } test "wipe" { const kp = try SeedKeyPair.generate(.account); const pub_key = kp.intoPublicKey(); const priv_key = kp.intoPrivateKey(); var kp_clone = kp; kp_clone.wipe(); try testing.expect(!std.meta.eql(kp_clone.kp, kp.kp)); var pub_key_clone = pub_key; pub_key_clone.wipe(); try testing.expect(!std.meta.eql(pub_key_clone.key, pub_key.key)); var priv_key_clone = priv_key; priv_key_clone.wipe(); try testing.expect(!std.meta.eql(priv_key_clone.kp, priv_key.kp)); } test "parse decorated JWT (bad)" { try testing.expectEqualStrings("foo", parseDecoratedJwt("foo")); } test "parse decorated seed (bad)" { try testing.expectError(error.NoNkeySeedFound, parseDecoratedNkey("foo")); } test "parse decorated seed and JWT" { const creds = \\-----BEGIN NATS USER JWT----- \\eyJ0eXAiOiJKV1QiLCJhbGciOiJlZDI1NTE5LW5rZXkifQ.eyJqdGkiOiJUWEg1TUxDNTdPTUJUQURYNUJNU0RLWkhSQUtXUFM0TkdHRFFPVlJXRzUyRFdaUlFFVERBIiwiaWF0IjoxNjIxNTgyOTU1LCJpc3MiOiJBQ1ZUQVZMQlFKTklQRjdNWFZWSlpZUFhaTkdFQUZMWVpTUjJSNVRZNk9ESjNSTTRYV0FDNUVFRiIsIm5hbWUiOiJ0ZXN0Iiwic3ViIjoiVUJHSlhLRkVWUlFEM05LM0lDRVc1Q0lDSzM1NkdESVZORkhaRUU0SzdMMkRYWTdORVNQVlFVNEwiLCJuYXRzIjp7InB1YiI6e30sInN1YiI6e30sInN1YnMiOi0xLCJkYXRhIjotMSwicGF5bG9hZCI6LTEsInR5cGUiOiJ1c2VyIiwidmVyc2lvbiI6Mn19.OhPLDZflyJ_keg2xBRDHZZhG5x_Qf_Yb61k9eHLs9zLRf0_ETwMd0PNZI_isuBhXYevobXHVoYA3oxvMVGlDCQ \\------END NATS USER JWT------ \\ \\************************* IMPORTANT ************************* \\NKEY Seed printed below can be used to sign and prove identity. \\NKEYs are sensitive and should be treated as secrets. \\ \\-----BEGIN USER NKEY SEED----- \\SUAGIEYODKBBTUMOB666Z5KA4FCWAZV7HWSGRHOD7MK6UM5IYLWLACH7DQ \\------END USER NKEY SEED------ \\ \\************************************************************* ; const jwt = "eyJ0eXAiOiJKV1QiLCJhbGciOiJlZDI1NTE5LW5rZXkifQ.eyJqdGkiOiJUWEg1TUxDNTdPTUJUQURYNUJNU0RLWkhSQUtXUFM0TkdHRFFPVlJXRzUyRFdaUlFFVERBIiwiaWF0IjoxNjIxNTgyOTU1LCJpc3MiOiJBQ1ZUQVZMQlFKTklQRjdNWFZWSlpZUFhaTkdFQUZMWVpTUjJSNVRZNk9ESjNSTTRYV0FDNUVFRiIsIm5hbWUiOiJ0ZXN0Iiwic3ViIjoiVUJHSlhLRkVWUlFEM05LM0lDRVc1Q0lDSzM1NkdESVZORkhaRUU0SzdMMkRYWTdORVNQVlFVNEwiLCJuYXRzIjp7InB1YiI6e30sInN1YiI6e30sInN1YnMiOi0xLCJkYXRhIjotMSwicGF5bG9hZCI6LTEsInR5cGUiOiJ1c2VyIiwidmVyc2lvbiI6Mn19.OhPLDZflyJ_keg2xBRDHZZhG5x_Qf_Yb61k9eHLs9zLRf0_ETwMd0PNZI_isuBhXYevobXHVoYA3oxvMVGlDCQ"; const seed = "SUAGIEYODKBBTUMOB666Z5KA4FCWAZV7HWSGRHOD7MK6UM5IYLWLACH7DQ"; var got_kp = try parseDecoratedUserNkey(creds); try testing.expectEqualStrings(seed, &got_kp.seedText()); got_kp = try parseDecoratedNkey(creds); try testing.expectEqualStrings(seed, &got_kp.seedText()); const got_jwt = parseDecoratedJwt(creds); try testing.expectEqualStrings(jwt, got_jwt); }