// Copyright 2020 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package netip_test import ( "bytes" "encoding/json" "flag" "fmt" "internal/intern" "net" . "net/netip" "reflect" "sort" "strings" "testing" ) var long = flag.Bool("long", false, "run long tests") type uint128 = Uint128 var ( mustPrefix = MustParsePrefix mustIP = MustParseAddr mustIPPort = MustParseAddrPort ) func TestParseAddr(t *testing.T) { var validIPs = []struct { in string ip Addr // output of ParseAddr() str string // output of String(). If "", use in. wantErr string }{ // Basic zero IPv4 address. { in: "0.0.0.0", ip: MkAddr(Mk128(0, 0xffff00000000), Z4), }, // Basic non-zero IPv4 address. { in: "192.168.140.255", ip: MkAddr(Mk128(0, 0xffffc0a88cff), Z4), }, // IPv4 address in windows-style "print all the digits" form. { in: "010.000.015.001", wantErr: `ParseAddr("010.000.015.001"): IPv4 field has octet with leading zero`, }, // IPv4 address with a silly amount of leading zeros. { in: "000001.00000002.00000003.000000004", wantErr: `ParseAddr("000001.00000002.00000003.000000004"): IPv4 field has octet with leading zero`, }, // 4-in-6 with octet with leading zero { in: "::ffff:1.2.03.4", wantErr: `ParseAddr("::ffff:1.2.03.4"): ParseAddr("1.2.03.4"): IPv4 field has octet with leading zero (at "1.2.03.4")`, }, // Basic zero IPv6 address. { in: "::", ip: MkAddr(Mk128(0, 0), Z6noz), }, // Localhost IPv6. { in: "::1", ip: MkAddr(Mk128(0, 1), Z6noz), }, // Fully expanded IPv6 address. { in: "fd7a:115c:a1e0:ab12:4843:cd96:626b:430b", ip: MkAddr(Mk128(0xfd7a115ca1e0ab12, 0x4843cd96626b430b), Z6noz), }, // IPv6 with elided fields in the middle. { in: "fd7a:115c::626b:430b", ip: MkAddr(Mk128(0xfd7a115c00000000, 0x00000000626b430b), Z6noz), }, // IPv6 with elided fields at the end. { in: "fd7a:115c:a1e0:ab12:4843:cd96::", ip: MkAddr(Mk128(0xfd7a115ca1e0ab12, 0x4843cd9600000000), Z6noz), }, // IPv6 with single elided field at the end. { in: "fd7a:115c:a1e0:ab12:4843:cd96:626b::", ip: MkAddr(Mk128(0xfd7a115ca1e0ab12, 0x4843cd96626b0000), Z6noz), str: "fd7a:115c:a1e0:ab12:4843:cd96:626b:0", }, // IPv6 with single elided field in the middle. { in: "fd7a:115c:a1e0::4843:cd96:626b:430b", ip: MkAddr(Mk128(0xfd7a115ca1e00000, 0x4843cd96626b430b), Z6noz), str: "fd7a:115c:a1e0:0:4843:cd96:626b:430b", }, // IPv6 with the trailing 32 bits written as IPv4 dotted decimal. (4in6) { in: "::ffff:192.168.140.255", ip: MkAddr(Mk128(0, 0x0000ffffc0a88cff), Z6noz), str: "::ffff:192.168.140.255", }, // IPv6 with a zone specifier. { in: "fd7a:115c:a1e0:ab12:4843:cd96:626b:430b%eth0", ip: MkAddr(Mk128(0xfd7a115ca1e0ab12, 0x4843cd96626b430b), intern.Get("eth0")), }, // IPv6 with dotted decimal and zone specifier. { in: "1:2::ffff:192.168.140.255%eth1", ip: MkAddr(Mk128(0x0001000200000000, 0x0000ffffc0a88cff), intern.Get("eth1")), str: "1:2::ffff:c0a8:8cff%eth1", }, // 4-in-6 with zone { in: "::ffff:192.168.140.255%eth1", ip: MkAddr(Mk128(0, 0x0000ffffc0a88cff), intern.Get("eth1")), str: "::ffff:192.168.140.255%eth1", }, // IPv6 with capital letters. { in: "FD9E:1A04:F01D::1", ip: MkAddr(Mk128(0xfd9e1a04f01d0000, 0x1), Z6noz), str: "fd9e:1a04:f01d::1", }, } for _, test := range validIPs { t.Run(test.in, func(t *testing.T) { got, err := ParseAddr(test.in) if err != nil { if err.Error() == test.wantErr { return } t.Fatal(err) } if test.wantErr != "" { t.Fatalf("wanted error %q; got none", test.wantErr) } if got != test.ip { t.Errorf("got %#v, want %#v", got, test.ip) } // Check that ParseAddr is a pure function. got2, err := ParseAddr(test.in) if err != nil { t.Fatal(err) } if got != got2 { t.Errorf("ParseAddr(%q) got 2 different results: %#v, %#v", test.in, got, got2) } // Check that ParseAddr(ip.String()) is the identity function. s := got.String() got3, err := ParseAddr(s) if err != nil { t.Fatal(err) } if got != got3 { t.Errorf("ParseAddr(%q) != ParseAddr(ParseIP(%q).String()). Got %#v, want %#v", test.in, test.in, got3, got) } // Check that the slow-but-readable parser produces the same result. slow, err := parseIPSlow(test.in) if err != nil { t.Fatal(err) } if got != slow { t.Errorf("ParseAddr(%q) = %#v, parseIPSlow(%q) = %#v", test.in, got, test.in, slow) } // Check that the parsed IP formats as expected. s = got.String() wants := test.str if wants == "" { wants = test.in } if s != wants { t.Errorf("ParseAddr(%q).String() got %q, want %q", test.in, s, wants) } // Check that AppendTo matches MarshalText. TestAppendToMarshal(t, got) // Check that MarshalText/UnmarshalText work similarly to // ParseAddr/String (see TestIPMarshalUnmarshal for // marshal-specific behavior that's not common with // ParseAddr/String). js := `"` + test.in + `"` var jsgot Addr if err := json.Unmarshal([]byte(js), &jsgot); err != nil { t.Fatal(err) } if jsgot != got { t.Errorf("json.Unmarshal(%q) = %#v, want %#v", test.in, jsgot, got) } jsb, err := json.Marshal(jsgot) if err != nil { t.Fatal(err) } jswant := `"` + wants + `"` jsback := string(jsb) if jsback != jswant { t.Errorf("Marshal(Unmarshal(%q)) = %s, want %s", test.in, jsback, jswant) } }) } var invalidIPs = []string{ // Empty string "", // Garbage non-IP "bad", // Single number. Some parsers accept this as an IPv4 address in // big-endian uint32 form, but we don't. "1234", // IPv4 with a zone specifier "1.2.3.4%eth0", // IPv4 field must have at least one digit ".1.2.3", "1.2.3.", "1..2.3", // IPv4 address too long "1.2.3.4.5", // IPv4 in dotted octal form "0300.0250.0214.0377", // IPv4 in dotted hex form "0xc0.0xa8.0x8c.0xff", // IPv4 in class B form "192.168.12345", // IPv4 in class B form, with a small enough number to be // parseable as a regular dotted decimal field. "127.0.1", // IPv4 in class A form "192.1234567", // IPv4 in class A form, with a small enough number to be // parseable as a regular dotted decimal field. "127.1", // IPv4 field has value >255 "192.168.300.1", // IPv4 with too many fields "192.168.0.1.5.6", // IPv6 with not enough fields "1:2:3:4:5:6:7", // IPv6 with too many fields "1:2:3:4:5:6:7:8:9", // IPv6 with 8 fields and a :: expander "1:2:3:4::5:6:7:8", // IPv6 with a field bigger than 2b "fe801::1", // IPv6 with non-hex values in field "fe80:tail:scal:e::", // IPv6 with a zone delimiter but no zone. "fe80::1%", // IPv6 (without ellipsis) with too many fields for trailing embedded IPv4. "ffff:ffff:ffff:ffff:ffff:ffff:ffff:192.168.140.255", // IPv6 (with ellipsis) with too many fields for trailing embedded IPv4. "ffff::ffff:ffff:ffff:ffff:ffff:ffff:192.168.140.255", // IPv6 with invalid embedded IPv4. "::ffff:192.168.140.bad", // IPv6 with multiple ellipsis ::. "fe80::1::1", // IPv6 with invalid non hex/colon character. "fe80:1?:1", // IPv6 with truncated bytes after single colon. "fe80:", } for _, s := range invalidIPs { t.Run(s, func(t *testing.T) { got, err := ParseAddr(s) if err == nil { t.Errorf("ParseAddr(%q) = %#v, want error", s, got) } slow, err := parseIPSlow(s) if err == nil { t.Errorf("parseIPSlow(%q) = %#v, want error", s, slow) } std := net.ParseIP(s) if std != nil { t.Errorf("net.ParseIP(%q) = %#v, want error", s, std) } if s == "" { // Don't test unmarshaling of "" here, do it in // IPMarshalUnmarshal. return } var jsgot Addr js := []byte(`"` + s + `"`) if err := json.Unmarshal(js, &jsgot); err == nil { t.Errorf("json.Unmarshal(%q) = %#v, want error", s, jsgot) } }) } } func TestIPv4Constructors(t *testing.T) { if AddrFrom4([4]byte{1, 2, 3, 4}) != MustParseAddr("1.2.3.4") { t.Errorf("don't match") } } func TestAddrMarshalUnmarshalBinary(t *testing.T) { tests := []struct { ip string wantSize int }{ {"", 0}, // zero IP {"1.2.3.4", 4}, {"fd7a:115c:a1e0:ab12:4843:cd96:626b:430b", 16}, {"::ffff:c000:0280", 16}, {"::ffff:c000:0280%eth0", 20}, } for _, tc := range tests { var ip Addr if len(tc.ip) > 0 { ip = mustIP(tc.ip) } b, err := ip.MarshalBinary() if err != nil { t.Fatal(err) } if len(b) != tc.wantSize { t.Fatalf("%q encoded to size %d; want %d", tc.ip, len(b), tc.wantSize) } var ip2 Addr if err := ip2.UnmarshalBinary(b); err != nil { t.Fatal(err) } if ip != ip2 { t.Fatalf("got %v; want %v", ip2, ip) } } // Cannot unmarshal from unexpected IP length. for _, n := range []int{3, 5} { var ip2 Addr if err := ip2.UnmarshalBinary(bytes.Repeat([]byte{1}, n)); err == nil { t.Fatalf("unmarshaled from unexpected IP length %d", n) } } } func TestAddrPortMarshalTextString(t *testing.T) { tests := []struct { in AddrPort want string }{ {mustIPPort("1.2.3.4:80"), "1.2.3.4:80"}, {mustIPPort("[1::CAFE]:80"), "[1::cafe]:80"}, {mustIPPort("[1::CAFE%en0]:80"), "[1::cafe%en0]:80"}, {mustIPPort("[::FFFF:192.168.140.255]:80"), "[::ffff:192.168.140.255]:80"}, {mustIPPort("[::FFFF:192.168.140.255%en0]:80"), "[::ffff:192.168.140.255%en0]:80"}, } for i, tt := range tests { if got := tt.in.String(); got != tt.want { t.Errorf("%d. for (%v, %v) String = %q; want %q", i, tt.in.Addr(), tt.in.Port(), got, tt.want) } mt, err := tt.in.MarshalText() if err != nil { t.Errorf("%d. for (%v, %v) MarshalText error: %v", i, tt.in.Addr(), tt.in.Port(), err) continue } if string(mt) != tt.want { t.Errorf("%d. for (%v, %v) MarshalText = %q; want %q", i, tt.in.Addr(), tt.in.Port(), mt, tt.want) } } } func TestAddrPortMarshalUnmarshalBinary(t *testing.T) { tests := []struct { ipport string wantSize int }{ {"1.2.3.4:51820", 4 + 2}, {"[fd7a:115c:a1e0:ab12:4843:cd96:626b:430b]:80", 16 + 2}, {"[::ffff:c000:0280]:65535", 16 + 2}, {"[::ffff:c000:0280%eth0]:1", 20 + 2}, } for _, tc := range tests { var ipport AddrPort if len(tc.ipport) > 0 { ipport = mustIPPort(tc.ipport) } b, err := ipport.MarshalBinary() if err != nil { t.Fatal(err) } if len(b) != tc.wantSize { t.Fatalf("%q encoded to size %d; want %d", tc.ipport, len(b), tc.wantSize) } var ipport2 AddrPort if err := ipport2.UnmarshalBinary(b); err != nil { t.Fatal(err) } if ipport != ipport2 { t.Fatalf("got %v; want %v", ipport2, ipport) } } // Cannot unmarshal from unexpected lengths. for _, n := range []int{3, 7} { var ipport2 AddrPort if err := ipport2.UnmarshalBinary(bytes.Repeat([]byte{1}, n)); err == nil { t.Fatalf("unmarshaled from unexpected length %d", n) } } } func TestPrefixMarshalTextString(t *testing.T) { tests := []struct { in Prefix want string }{ {mustPrefix("1.2.3.4/24"), "1.2.3.4/24"}, {mustPrefix("fd7a:115c:a1e0:ab12:4843:cd96:626b:430b/118"), "fd7a:115c:a1e0:ab12:4843:cd96:626b:430b/118"}, {mustPrefix("::ffff:c000:0280/96"), "::ffff:192.0.2.128/96"}, {mustPrefix("::ffff:c000:0280%eth0/37"), "::ffff:192.0.2.128/37"}, // Zone should be stripped {mustPrefix("::ffff:192.168.140.255/8"), "::ffff:192.168.140.255/8"}, } for i, tt := range tests { if got := tt.in.String(); got != tt.want { t.Errorf("%d. for %v String = %q; want %q", i, tt.in, got, tt.want) } mt, err := tt.in.MarshalText() if err != nil { t.Errorf("%d. for %v MarshalText error: %v", i, tt.in, err) continue } if string(mt) != tt.want { t.Errorf("%d. for %v MarshalText = %q; want %q", i, tt.in, mt, tt.want) } } } func TestPrefixMarshalUnmarshalBinary(t *testing.T) { type testCase struct { prefix Prefix wantSize int } tests := []testCase{ {mustPrefix("1.2.3.4/24"), 4 + 1}, {mustPrefix("fd7a:115c:a1e0:ab12:4843:cd96:626b:430b/118"), 16 + 1}, {mustPrefix("::ffff:c000:0280/96"), 16 + 1}, {mustPrefix("::ffff:c000:0280%eth0/37"), 16 + 1}, // Zone should be stripped } tests = append(tests, testCase{PrefixFrom(tests[0].prefix.Addr(), 33), tests[0].wantSize}, testCase{PrefixFrom(tests[1].prefix.Addr(), 129), tests[1].wantSize}) for _, tc := range tests { prefix := tc.prefix b, err := prefix.MarshalBinary() if err != nil { t.Fatal(err) } if len(b) != tc.wantSize { t.Fatalf("%q encoded to size %d; want %d", tc.prefix, len(b), tc.wantSize) } var prefix2 Prefix if err := prefix2.UnmarshalBinary(b); err != nil { t.Fatal(err) } if prefix != prefix2 { t.Fatalf("got %v; want %v", prefix2, prefix) } } // Cannot unmarshal from unexpected lengths. for _, n := range []int{3, 6} { var prefix2 Prefix if err := prefix2.UnmarshalBinary(bytes.Repeat([]byte{1}, n)); err == nil { t.Fatalf("unmarshaled from unexpected length %d", n) } } } func TestAddrMarshalUnmarshal(t *testing.T) { // This only tests the cases where Marshal/Unmarshal diverges from // the behavior of ParseAddr/String. For the rest of the test cases, // see TestParseAddr above. orig := `""` var ip Addr if err := json.Unmarshal([]byte(orig), &ip); err != nil { t.Fatalf("Unmarshal(%q) got error %v", orig, err) } if ip != (Addr{}) { t.Errorf("Unmarshal(%q) is not the zero Addr", orig) } jsb, err := json.Marshal(ip) if err != nil { t.Fatalf("Marshal(%v) got error %v", ip, err) } back := string(jsb) if back != orig { t.Errorf("Marshal(Unmarshal(%q)) got %q, want %q", orig, back, orig) } } func TestAddrFrom16(t *testing.T) { tests := []struct { name string in [16]byte want Addr }{ { name: "v6-raw", in: [...]byte{15: 1}, want: MkAddr(Mk128(0, 1), Z6noz), }, { name: "v4-raw", in: [...]byte{10: 0xff, 11: 0xff, 12: 1, 13: 2, 14: 3, 15: 4}, want: MkAddr(Mk128(0, 0xffff01020304), Z6noz), }, } for _, tt := range tests { t.Run(tt.name, func(t *testing.T) { got := AddrFrom16(tt.in) if got != tt.want { t.Errorf("got %#v; want %#v", got, tt.want) } }) } } func TestIPProperties(t *testing.T) { var ( nilIP Addr unicast4 = mustIP("192.0.2.1") unicast6 = mustIP("2001:db8::1") unicastZone6 = mustIP("2001:db8::1%eth0") unicast6Unassigned = mustIP("4000::1") // not in 2000::/3. multicast4 = mustIP("224.0.0.1") multicast6 = mustIP("ff02::1") multicastZone6 = mustIP("ff02::1%eth0") llu4 = mustIP("169.254.0.1") llu6 = mustIP("fe80::1") llu6Last = mustIP("febf:ffff:ffff:ffff:ffff:ffff:ffff:ffff") lluZone6 = mustIP("fe80::1%eth0") loopback4 = mustIP("127.0.0.1") loopback6 = mustIP("::1") ilm6 = mustIP("ff01::1") ilmZone6 = mustIP("ff01::1%eth0") private4a = mustIP("10.0.0.1") private4b = mustIP("172.16.0.1") private4c = mustIP("192.168.1.1") private6 = mustIP("fd00::1") unspecified4 = AddrFrom4([4]byte{}) unspecified6 = IPv6Unspecified() ) tests := []struct { name string ip Addr globalUnicast bool interfaceLocalMulticast bool linkLocalMulticast bool linkLocalUnicast bool loopback bool multicast bool private bool unspecified bool }{ { name: "nil", ip: nilIP, }, { name: "unicast v4Addr", ip: unicast4, globalUnicast: true, }, { name: "unicast v6Addr", ip: unicast6, globalUnicast: true, }, { name: "unicast v6AddrZone", ip: unicastZone6, globalUnicast: true, }, { name: "unicast v6Addr unassigned", ip: unicast6Unassigned, globalUnicast: true, }, { name: "multicast v4Addr", ip: multicast4, linkLocalMulticast: true, multicast: true, }, { name: "multicast v6Addr", ip: multicast6, linkLocalMulticast: true, multicast: true, }, { name: "multicast v6AddrZone", ip: multicastZone6, linkLocalMulticast: true, multicast: true, }, { name: "link-local unicast v4Addr", ip: llu4, linkLocalUnicast: true, }, { name: "link-local unicast v6Addr", ip: llu6, linkLocalUnicast: true, }, { name: "link-local unicast v6Addr upper bound", ip: llu6Last, linkLocalUnicast: true, }, { name: "link-local unicast v6AddrZone", ip: lluZone6, linkLocalUnicast: true, }, { name: "loopback v4Addr", ip: loopback4, loopback: true, }, { name: "loopback v6Addr", ip: loopback6, loopback: true, }, { name: "interface-local multicast v6Addr", ip: ilm6, interfaceLocalMulticast: true, multicast: true, }, { name: "interface-local multicast v6AddrZone", ip: ilmZone6, interfaceLocalMulticast: true, multicast: true, }, { name: "private v4Addr 10/8", ip: private4a, globalUnicast: true, private: true, }, { name: "private v4Addr 172.16/12", ip: private4b, globalUnicast: true, private: true, }, { name: "private v4Addr 192.168/16", ip: private4c, globalUnicast: true, private: true, }, { name: "private v6Addr", ip: private6, globalUnicast: true, private: true, }, { name: "unspecified v4Addr", ip: unspecified4, unspecified: true, }, { name: "unspecified v6Addr", ip: unspecified6, unspecified: true, }, } for _, tt := range tests { t.Run(tt.name, func(t *testing.T) { gu := tt.ip.IsGlobalUnicast() if gu != tt.globalUnicast { t.Errorf("IsGlobalUnicast(%v) = %v; want %v", tt.ip, gu, tt.globalUnicast) } ilm := tt.ip.IsInterfaceLocalMulticast() if ilm != tt.interfaceLocalMulticast { t.Errorf("IsInterfaceLocalMulticast(%v) = %v; want %v", tt.ip, ilm, tt.interfaceLocalMulticast) } llu := tt.ip.IsLinkLocalUnicast() if llu != tt.linkLocalUnicast { t.Errorf("IsLinkLocalUnicast(%v) = %v; want %v", tt.ip, llu, tt.linkLocalUnicast) } llm := tt.ip.IsLinkLocalMulticast() if llm != tt.linkLocalMulticast { t.Errorf("IsLinkLocalMulticast(%v) = %v; want %v", tt.ip, llm, tt.linkLocalMulticast) } lo := tt.ip.IsLoopback() if lo != tt.loopback { t.Errorf("IsLoopback(%v) = %v; want %v", tt.ip, lo, tt.loopback) } multicast := tt.ip.IsMulticast() if multicast != tt.multicast { t.Errorf("IsMulticast(%v) = %v; want %v", tt.ip, multicast, tt.multicast) } private := tt.ip.IsPrivate() if private != tt.private { t.Errorf("IsPrivate(%v) = %v; want %v", tt.ip, private, tt.private) } unspecified := tt.ip.IsUnspecified() if unspecified != tt.unspecified { t.Errorf("IsUnspecified(%v) = %v; want %v", tt.ip, unspecified, tt.unspecified) } }) } } func TestAddrWellKnown(t *testing.T) { tests := []struct { name string ip Addr std net.IP }{ { name: "IPv6 link-local all nodes", ip: IPv6LinkLocalAllNodes(), std: net.IPv6linklocalallnodes, }, { name: "IPv6 unspecified", ip: IPv6Unspecified(), std: net.IPv6unspecified, }, } for _, tt := range tests { t.Run(tt.name, func(t *testing.T) { want := tt.std.String() got := tt.ip.String() if got != want { t.Fatalf("got %s, want %s", got, want) } }) } } func TestLessCompare(t *testing.T) { tests := []struct { a, b Addr want bool }{ {Addr{}, Addr{}, false}, {Addr{}, mustIP("1.2.3.4"), true}, {mustIP("1.2.3.4"), Addr{}, false}, {mustIP("1.2.3.4"), mustIP("0102:0304::0"), true}, {mustIP("0102:0304::0"), mustIP("1.2.3.4"), false}, {mustIP("1.2.3.4"), mustIP("1.2.3.4"), false}, {mustIP("::1"), mustIP("::2"), true}, {mustIP("::1"), mustIP("::1%foo"), true}, {mustIP("::1%foo"), mustIP("::2"), true}, {mustIP("::2"), mustIP("::3"), true}, {mustIP("::"), mustIP("0.0.0.0"), false}, {mustIP("0.0.0.0"), mustIP("::"), true}, {mustIP("::1%a"), mustIP("::1%b"), true}, {mustIP("::1%a"), mustIP("::1%a"), false}, {mustIP("::1%b"), mustIP("::1%a"), false}, } for _, tt := range tests { got := tt.a.Less(tt.b) if got != tt.want { t.Errorf("Less(%q, %q) = %v; want %v", tt.a, tt.b, got, tt.want) } cmp := tt.a.Compare(tt.b) if got && cmp != -1 { t.Errorf("Less(%q, %q) = true, but Compare = %v (not -1)", tt.a, tt.b, cmp) } if cmp < -1 || cmp > 1 { t.Errorf("bogus Compare return value %v", cmp) } if cmp == 0 && tt.a != tt.b { t.Errorf("Compare(%q, %q) = 0; but not equal", tt.a, tt.b) } if cmp == 1 && !tt.b.Less(tt.a) { t.Errorf("Compare(%q, %q) = 1; but b.Less(a) isn't true", tt.a, tt.b) } // Also check inverse. if got == tt.want && got { got2 := tt.b.Less(tt.a) if got2 { t.Errorf("Less(%q, %q) was correctly %v, but so was Less(%q, %q)", tt.a, tt.b, got, tt.b, tt.a) } } } // And just sort. values := []Addr{ mustIP("::1"), mustIP("::2"), Addr{}, mustIP("1.2.3.4"), mustIP("8.8.8.8"), mustIP("::1%foo"), } sort.Slice(values, func(i, j int) bool { return values[i].Less(values[j]) }) got := fmt.Sprintf("%s", values) want := `[invalid IP 1.2.3.4 8.8.8.8 ::1 ::1%foo ::2]` if got != want { t.Errorf("unexpected sort\n got: %s\nwant: %s\n", got, want) } } func TestIPStringExpanded(t *testing.T) { tests := []struct { ip Addr s string }{ { ip: Addr{}, s: "invalid IP", }, { ip: mustIP("192.0.2.1"), s: "192.0.2.1", }, { ip: mustIP("::ffff:192.0.2.1"), s: "0000:0000:0000:0000:0000:ffff:c000:0201", }, { ip: mustIP("2001:db8::1"), s: "2001:0db8:0000:0000:0000:0000:0000:0001", }, { ip: mustIP("2001:db8::1%eth0"), s: "2001:0db8:0000:0000:0000:0000:0000:0001%eth0", }, } for _, tt := range tests { t.Run(tt.ip.String(), func(t *testing.T) { want := tt.s got := tt.ip.StringExpanded() if got != want { t.Fatalf("got %s, want %s", got, want) } }) } } func TestPrefixMasking(t *testing.T) { type subtest struct { ip Addr bits uint8 p Prefix ok bool } // makeIPv6 produces a set of IPv6 subtests with an optional zone identifier. makeIPv6 := func(zone string) []subtest { if zone != "" { zone = "%" + zone } return []subtest{ { ip: mustIP(fmt.Sprintf("2001:db8::1%s", zone)), bits: 255, }, { ip: mustIP(fmt.Sprintf("2001:db8::1%s", zone)), bits: 32, p: mustPrefix(fmt.Sprintf("2001:db8::%s/32", zone)), ok: true, }, { ip: mustIP(fmt.Sprintf("fe80::dead:beef:dead:beef%s", zone)), bits: 96, p: mustPrefix(fmt.Sprintf("fe80::dead:beef:0:0%s/96", zone)), ok: true, }, { ip: mustIP(fmt.Sprintf("aaaa::%s", zone)), bits: 4, p: mustPrefix(fmt.Sprintf("a000::%s/4", zone)), ok: true, }, { ip: mustIP(fmt.Sprintf("::%s", zone)), bits: 63, p: mustPrefix(fmt.Sprintf("::%s/63", zone)), ok: true, }, } } tests := []struct { family string subtests []subtest }{ { family: "nil", subtests: []subtest{ { bits: 255, ok: true, }, { bits: 16, ok: true, }, }, }, { family: "IPv4", subtests: []subtest{ { ip: mustIP("192.0.2.0"), bits: 255, }, { ip: mustIP("192.0.2.0"), bits: 16, p: mustPrefix("192.0.0.0/16"), ok: true, }, { ip: mustIP("255.255.255.255"), bits: 20, p: mustPrefix("255.255.240.0/20"), ok: true, }, { // Partially masking one byte that contains both // 1s and 0s on either side of the mask limit. ip: mustIP("100.98.156.66"), bits: 10, p: mustPrefix("100.64.0.0/10"), ok: true, }, }, }, { family: "IPv6", subtests: makeIPv6(""), }, { family: "IPv6 zone", subtests: makeIPv6("eth0"), }, } for _, tt := range tests { t.Run(tt.family, func(t *testing.T) { for _, st := range tt.subtests { t.Run(st.p.String(), func(t *testing.T) { // Ensure st.ip is not mutated. orig := st.ip.String() p, err := st.ip.Prefix(int(st.bits)) if st.ok && err != nil { t.Fatalf("failed to produce prefix: %v", err) } if !st.ok && err == nil { t.Fatal("expected an error, but none occurred") } if err != nil { t.Logf("err: %v", err) return } if !reflect.DeepEqual(p, st.p) { t.Errorf("prefix = %q, want %q", p, st.p) } if got := st.ip.String(); got != orig { t.Errorf("IP was mutated: %q, want %q", got, orig) } }) } }) } } func TestPrefixMarshalUnmarshal(t *testing.T) { tests := []string{ "", "1.2.3.4/32", "0.0.0.0/0", "::/0", "::1/128", "2001:db8::/32", } for _, s := range tests { t.Run(s, func(t *testing.T) { // Ensure that JSON (and by extension, text) marshaling is // sane by entering quoted input. orig := `"` + s + `"` var p Prefix if err := json.Unmarshal([]byte(orig), &p); err != nil { t.Fatalf("failed to unmarshal: %v", err) } pb, err := json.Marshal(p) if err != nil { t.Fatalf("failed to marshal: %v", err) } back := string(pb) if orig != back { t.Errorf("Marshal = %q; want %q", back, orig) } }) } } func TestPrefixMarshalUnmarshalZone(t *testing.T) { orig := `"fe80::1cc0:3e8c:119f:c2e1%ens18/128"` unzoned := `"fe80::1cc0:3e8c:119f:c2e1/128"` var p Prefix if err := json.Unmarshal([]byte(orig), &p); err != nil { t.Fatalf("failed to unmarshal: %v", err) } pb, err := json.Marshal(p) if err != nil { t.Fatalf("failed to marshal: %v", err) } back := string(pb) if back != unzoned { t.Errorf("Marshal = %q; want %q", back, unzoned) } } func TestPrefixUnmarshalTextNonZero(t *testing.T) { ip := mustPrefix("fe80::/64") if err := ip.UnmarshalText([]byte("xxx")); err == nil { t.Fatal("unmarshaled into non-empty Prefix") } } func TestIs4AndIs6(t *testing.T) { tests := []struct { ip Addr is4 bool is6 bool }{ {Addr{}, false, false}, {mustIP("1.2.3.4"), true, false}, {mustIP("127.0.0.2"), true, false}, {mustIP("::1"), false, true}, {mustIP("::ffff:192.0.2.128"), false, true}, {mustIP("::fffe:c000:0280"), false, true}, {mustIP("::1%eth0"), false, true}, } for _, tt := range tests { got4 := tt.ip.Is4() if got4 != tt.is4 { t.Errorf("Is4(%q) = %v; want %v", tt.ip, got4, tt.is4) } got6 := tt.ip.Is6() if got6 != tt.is6 { t.Errorf("Is6(%q) = %v; want %v", tt.ip, got6, tt.is6) } } } func TestIs4In6(t *testing.T) { tests := []struct { ip Addr want bool wantUnmap Addr }{ {Addr{}, false, Addr{}}, {mustIP("::ffff:c000:0280"), true, mustIP("192.0.2.128")}, {mustIP("::ffff:192.0.2.128"), true, mustIP("192.0.2.128")}, {mustIP("::ffff:192.0.2.128%eth0"), true, mustIP("192.0.2.128")}, {mustIP("::fffe:c000:0280"), false, mustIP("::fffe:c000:0280")}, {mustIP("::ffff:127.1.2.3"), true, mustIP("127.1.2.3")}, {mustIP("::ffff:7f01:0203"), true, mustIP("127.1.2.3")}, {mustIP("0:0:0:0:0000:ffff:127.1.2.3"), true, mustIP("127.1.2.3")}, {mustIP("0:0:0:0:000000:ffff:127.1.2.3"), true, mustIP("127.1.2.3")}, {mustIP("0:0:0:0::ffff:127.1.2.3"), true, mustIP("127.1.2.3")}, {mustIP("::1"), false, mustIP("::1")}, {mustIP("1.2.3.4"), false, mustIP("1.2.3.4")}, } for _, tt := range tests { got := tt.ip.Is4In6() if got != tt.want { t.Errorf("Is4In6(%q) = %v; want %v", tt.ip, got, tt.want) } u := tt.ip.Unmap() if u != tt.wantUnmap { t.Errorf("Unmap(%q) = %v; want %v", tt.ip, u, tt.wantUnmap) } } } func TestPrefixMasked(t *testing.T) { tests := []struct { prefix Prefix masked Prefix }{ { prefix: mustPrefix("192.168.0.255/24"), masked: mustPrefix("192.168.0.0/24"), }, { prefix: mustPrefix("2100::/3"), masked: mustPrefix("2000::/3"), }, { prefix: PrefixFrom(mustIP("2000::"), 129), masked: Prefix{}, }, { prefix: PrefixFrom(mustIP("1.2.3.4"), 33), masked: Prefix{}, }, } for _, test := range tests { t.Run(test.prefix.String(), func(t *testing.T) { got := test.prefix.Masked() if got != test.masked { t.Errorf("Masked=%s, want %s", got, test.masked) } }) } } func TestPrefix(t *testing.T) { tests := []struct { prefix string ip Addr bits int str string contains []Addr notContains []Addr }{ { prefix: "192.168.0.0/24", ip: mustIP("192.168.0.0"), bits: 24, contains: mustIPs("192.168.0.1", "192.168.0.55"), notContains: mustIPs("192.168.1.1", "1.1.1.1"), }, { prefix: "192.168.1.1/32", ip: mustIP("192.168.1.1"), bits: 32, contains: mustIPs("192.168.1.1"), notContains: mustIPs("192.168.1.2"), }, { prefix: "100.64.0.0/10", // CGNAT range; prefix not multiple of 8 ip: mustIP("100.64.0.0"), bits: 10, contains: mustIPs("100.64.0.0", "100.64.0.1", "100.81.251.94", "100.100.100.100", "100.127.255.254", "100.127.255.255"), notContains: mustIPs("100.63.255.255", "100.128.0.0"), }, { prefix: "2001:db8::/96", ip: mustIP("2001:db8::"), bits: 96, contains: mustIPs("2001:db8::aaaa:bbbb", "2001:db8::1"), notContains: mustIPs("2001:db8::1:aaaa:bbbb", "2001:db9::"), }, { prefix: "0.0.0.0/0", ip: mustIP("0.0.0.0"), bits: 0, contains: mustIPs("192.168.0.1", "1.1.1.1"), notContains: append(mustIPs("2001:db8::1"), Addr{}), }, { prefix: "::/0", ip: mustIP("::"), bits: 0, contains: mustIPs("::1", "2001:db8::1"), notContains: mustIPs("192.0.2.1"), }, { prefix: "2000::/3", ip: mustIP("2000::"), bits: 3, contains: mustIPs("2001:db8::1"), notContains: mustIPs("fe80::1"), }, { prefix: "::%0/00/80", ip: mustIP("::"), bits: 80, str: "::/80", contains: mustIPs("::"), notContains: mustIPs("ff::%0/00", "ff::%1/23", "::%0/00", "::%1/23"), }, } for _, test := range tests { t.Run(test.prefix, func(t *testing.T) { prefix, err := ParsePrefix(test.prefix) if err != nil { t.Fatal(err) } if prefix.Addr() != test.ip { t.Errorf("IP=%s, want %s", prefix.Addr(), test.ip) } if prefix.Bits() != test.bits { t.Errorf("bits=%d, want %d", prefix.Bits(), test.bits) } for _, ip := range test.contains { if !prefix.Contains(ip) { t.Errorf("does not contain %s", ip) } } for _, ip := range test.notContains { if prefix.Contains(ip) { t.Errorf("contains %s", ip) } } want := test.str if want == "" { want = test.prefix } if got := prefix.String(); got != want { t.Errorf("prefix.String()=%q, want %q", got, want) } TestAppendToMarshal(t, prefix) }) } } func TestPrefixFromInvalidBits(t *testing.T) { v4 := MustParseAddr("1.2.3.4") v6 := MustParseAddr("66::66") tests := []struct { ip Addr in, want int }{ {v4, 0, 0}, {v6, 0, 0}, {v4, 1, 1}, {v4, 33, -1}, {v6, 33, 33}, {v6, 127, 127}, {v6, 128, 128}, {v4, 254, -1}, {v4, 255, -1}, {v4, -1, -1}, {v6, -1, -1}, {v4, -5, -1}, {v6, -5, -1}, } for _, tt := range tests { p := PrefixFrom(tt.ip, tt.in) if got := p.Bits(); got != tt.want { t.Errorf("for (%v, %v), Bits out = %v; want %v", tt.ip, tt.in, got, tt.want) } } } func TestParsePrefixAllocs(t *testing.T) { tests := []struct { ip string slash string }{ {"192.168.1.0", "/24"}, {"aaaa:bbbb:cccc::", "/24"}, } for _, test := range tests { prefix := test.ip + test.slash t.Run(prefix, func(t *testing.T) { ipAllocs := int(testing.AllocsPerRun(5, func() { ParseAddr(test.ip) })) prefixAllocs := int(testing.AllocsPerRun(5, func() { ParsePrefix(prefix) })) if got := prefixAllocs - ipAllocs; got != 0 { t.Errorf("allocs=%d, want 0", got) } }) } } func TestParsePrefixError(t *testing.T) { tests := []struct { prefix string errstr string }{ { prefix: "192.168.0.0", errstr: "no '/'", }, { prefix: "1.257.1.1/24", errstr: "value >255", }, { prefix: "1.1.1.0/q", errstr: "bad bits", }, { prefix: "1.1.1.0/-1", errstr: "out of range", }, { prefix: "1.1.1.0/33", errstr: "out of range", }, { prefix: "2001::/129", errstr: "out of range", }, } for _, test := range tests { t.Run(test.prefix, func(t *testing.T) { _, err := ParsePrefix(test.prefix) if err == nil { t.Fatal("no error") } if got := err.Error(); !strings.Contains(got, test.errstr) { t.Errorf("error is missing substring %q: %s", test.errstr, got) } }) } } func TestPrefixIsSingleIP(t *testing.T) { tests := []struct { ipp Prefix want bool }{ {ipp: mustPrefix("127.0.0.1/32"), want: true}, {ipp: mustPrefix("127.0.0.1/31"), want: false}, {ipp: mustPrefix("127.0.0.1/0"), want: false}, {ipp: mustPrefix("::1/128"), want: true}, {ipp: mustPrefix("::1/127"), want: false}, {ipp: mustPrefix("::1/0"), want: false}, {ipp: Prefix{}, want: false}, } for _, tt := range tests { got := tt.ipp.IsSingleIP() if got != tt.want { t.Errorf("IsSingleIP(%v) = %v want %v", tt.ipp, got, tt.want) } } } func mustIPs(strs ...string) []Addr { var res []Addr for _, s := range strs { res = append(res, mustIP(s)) } return res } func BenchmarkBinaryMarshalRoundTrip(b *testing.B) { b.ReportAllocs() tests := []struct { name string ip string }{ {"ipv4", "1.2.3.4"}, {"ipv6", "2001:db8::1"}, {"ipv6+zone", "2001:db8::1%eth0"}, } for _, tc := range tests { b.Run(tc.name, func(b *testing.B) { ip := mustIP(tc.ip) for i := 0; i < b.N; i++ { bt, err := ip.MarshalBinary() if err != nil { b.Fatal(err) } var ip2 Addr if err := ip2.UnmarshalBinary(bt); err != nil { b.Fatal(err) } } }) } } func BenchmarkStdIPv4(b *testing.B) { b.ReportAllocs() ips := []net.IP{} for i := 0; i < b.N; i++ { ip := net.IPv4(8, 8, 8, 8) ips = ips[:0] for i := 0; i < 100; i++ { ips = append(ips, ip) } } } func BenchmarkIPv4(b *testing.B) { b.ReportAllocs() ips := []Addr{} for i := 0; i < b.N; i++ { ip := IPv4(8, 8, 8, 8) ips = ips[:0] for i := 0; i < 100; i++ { ips = append(ips, ip) } } } // ip4i was one of the possible representations of IP that came up in // discussions, inlining IPv4 addresses, but having an "overflow" // interface for IPv6 or IPv6 + zone. This is here for benchmarking. type ip4i struct { ip4 [4]byte flags1 byte flags2 byte flags3 byte flags4 byte ipv6 any } func newip4i_v4(a, b, c, d byte) ip4i { return ip4i{ip4: [4]byte{a, b, c, d}} } // BenchmarkIPv4_inline benchmarks the candidate representation, ip4i. func BenchmarkIPv4_inline(b *testing.B) { b.ReportAllocs() ips := []ip4i{} for i := 0; i < b.N; i++ { ip := newip4i_v4(8, 8, 8, 8) ips = ips[:0] for i := 0; i < 100; i++ { ips = append(ips, ip) } } } func BenchmarkStdIPv6(b *testing.B) { b.ReportAllocs() ips := []net.IP{} for i := 0; i < b.N; i++ { ip := net.ParseIP("2001:db8::1") ips = ips[:0] for i := 0; i < 100; i++ { ips = append(ips, ip) } } } func BenchmarkIPv6(b *testing.B) { b.ReportAllocs() ips := []Addr{} for i := 0; i < b.N; i++ { ip := mustIP("2001:db8::1") ips = ips[:0] for i := 0; i < 100; i++ { ips = append(ips, ip) } } } func BenchmarkIPv4Contains(b *testing.B) { b.ReportAllocs() prefix := PrefixFrom(IPv4(192, 168, 1, 0), 24) ip := IPv4(192, 168, 1, 1) for i := 0; i < b.N; i++ { prefix.Contains(ip) } } func BenchmarkIPv6Contains(b *testing.B) { b.ReportAllocs() prefix := MustParsePrefix("::1/128") ip := MustParseAddr("::1") for i := 0; i < b.N; i++ { prefix.Contains(ip) } } var parseBenchInputs = []struct { name string ip string }{ {"v4", "192.168.1.1"}, {"v6", "fd7a:115c:a1e0:ab12:4843:cd96:626b:430b"}, {"v6_ellipsis", "fd7a:115c::626b:430b"}, {"v6_v4", "::ffff:192.168.140.255"}, {"v6_zone", "1:2::ffff:192.168.140.255%eth1"}, } func BenchmarkParseAddr(b *testing.B) { sinkInternValue = intern.Get("eth1") // Pin to not benchmark the intern package for _, test := range parseBenchInputs { b.Run(test.name, func(b *testing.B) { b.ReportAllocs() for i := 0; i < b.N; i++ { sinkIP, _ = ParseAddr(test.ip) } }) } } func BenchmarkStdParseIP(b *testing.B) { for _, test := range parseBenchInputs { b.Run(test.name, func(b *testing.B) { b.ReportAllocs() for i := 0; i < b.N; i++ { sinkStdIP = net.ParseIP(test.ip) } }) } } func BenchmarkIPString(b *testing.B) { for _, test := range parseBenchInputs { ip := MustParseAddr(test.ip) b.Run(test.name, func(b *testing.B) { b.ReportAllocs() for i := 0; i < b.N; i++ { sinkString = ip.String() } }) } } func BenchmarkIPStringExpanded(b *testing.B) { for _, test := range parseBenchInputs { ip := MustParseAddr(test.ip) b.Run(test.name, func(b *testing.B) { b.ReportAllocs() for i := 0; i < b.N; i++ { sinkString = ip.StringExpanded() } }) } } func BenchmarkIPMarshalText(b *testing.B) { b.ReportAllocs() ip := MustParseAddr("66.55.44.33") for i := 0; i < b.N; i++ { sinkBytes, _ = ip.MarshalText() } } func BenchmarkAddrPortString(b *testing.B) { for _, test := range parseBenchInputs { ip := MustParseAddr(test.ip) ipp := AddrPortFrom(ip, 60000) b.Run(test.name, func(b *testing.B) { b.ReportAllocs() for i := 0; i < b.N; i++ { sinkString = ipp.String() } }) } } func BenchmarkAddrPortMarshalText(b *testing.B) { for _, test := range parseBenchInputs { ip := MustParseAddr(test.ip) ipp := AddrPortFrom(ip, 60000) b.Run(test.name, func(b *testing.B) { b.ReportAllocs() for i := 0; i < b.N; i++ { sinkBytes, _ = ipp.MarshalText() } }) } } func BenchmarkPrefixMasking(b *testing.B) { tests := []struct { name string ip Addr bits int }{ { name: "IPv4 /32", ip: IPv4(192, 0, 2, 0), bits: 32, }, { name: "IPv4 /17", ip: IPv4(192, 0, 2, 0), bits: 17, }, { name: "IPv4 /0", ip: IPv4(192, 0, 2, 0), bits: 0, }, { name: "IPv6 /128", ip: mustIP("2001:db8::1"), bits: 128, }, { name: "IPv6 /65", ip: mustIP("2001:db8::1"), bits: 65, }, { name: "IPv6 /0", ip: mustIP("2001:db8::1"), bits: 0, }, { name: "IPv6 zone /128", ip: mustIP("2001:db8::1%eth0"), bits: 128, }, { name: "IPv6 zone /65", ip: mustIP("2001:db8::1%eth0"), bits: 65, }, { name: "IPv6 zone /0", ip: mustIP("2001:db8::1%eth0"), bits: 0, }, } for _, tt := range tests { b.Run(tt.name, func(b *testing.B) { b.ReportAllocs() for i := 0; i < b.N; i++ { sinkPrefix, _ = tt.ip.Prefix(tt.bits) } }) } } func BenchmarkPrefixMarshalText(b *testing.B) { b.ReportAllocs() ipp := MustParsePrefix("66.55.44.33/22") for i := 0; i < b.N; i++ { sinkBytes, _ = ipp.MarshalText() } } func BenchmarkParseAddrPort(b *testing.B) { for _, test := range parseBenchInputs { var ipp string if strings.HasPrefix(test.name, "v6") { ipp = fmt.Sprintf("[%s]:1234", test.ip) } else { ipp = fmt.Sprintf("%s:1234", test.ip) } b.Run(test.name, func(b *testing.B) { b.ReportAllocs() for i := 0; i < b.N; i++ { sinkAddrPort, _ = ParseAddrPort(ipp) } }) } } func TestAs4(t *testing.T) { tests := []struct { ip Addr want [4]byte wantPanic bool }{ { ip: mustIP("1.2.3.4"), want: [4]byte{1, 2, 3, 4}, }, { ip: AddrFrom16(mustIP("1.2.3.4").As16()), // IPv4-in-IPv6 want: [4]byte{1, 2, 3, 4}, }, { ip: mustIP("0.0.0.0"), want: [4]byte{0, 0, 0, 0}, }, { ip: Addr{}, wantPanic: true, }, { ip: mustIP("::1"), wantPanic: true, }, } as4 := func(ip Addr) (v [4]byte, gotPanic bool) { defer func() { if recover() != nil { gotPanic = true return } }() v = ip.As4() return } for i, tt := range tests { got, gotPanic := as4(tt.ip) if gotPanic != tt.wantPanic { t.Errorf("%d. panic on %v = %v; want %v", i, tt.ip, gotPanic, tt.wantPanic) continue } if got != tt.want { t.Errorf("%d. %v = %v; want %v", i, tt.ip, got, tt.want) } } } func TestPrefixOverlaps(t *testing.T) { pfx := mustPrefix tests := []struct { a, b Prefix want bool }{ {Prefix{}, pfx("1.2.0.0/16"), false}, // first zero {pfx("1.2.0.0/16"), Prefix{}, false}, // second zero {pfx("::0/3"), pfx("0.0.0.0/3"), false}, // different families {pfx("1.2.0.0/16"), pfx("1.2.0.0/16"), true}, // equal {pfx("1.2.0.0/16"), pfx("1.2.3.0/24"), true}, {pfx("1.2.3.0/24"), pfx("1.2.0.0/16"), true}, {pfx("1.2.0.0/16"), pfx("1.2.3.0/32"), true}, {pfx("1.2.3.0/32"), pfx("1.2.0.0/16"), true}, // Match /0 either order {pfx("1.2.3.0/32"), pfx("0.0.0.0/0"), true}, {pfx("0.0.0.0/0"), pfx("1.2.3.0/32"), true}, {pfx("1.2.3.0/32"), pfx("5.5.5.5/0"), true}, // normalization not required; /0 means true // IPv6 overlapping {pfx("5::1/128"), pfx("5::0/8"), true}, {pfx("5::0/8"), pfx("5::1/128"), true}, // IPv6 not overlapping {pfx("1::1/128"), pfx("2::2/128"), false}, {pfx("0100::0/8"), pfx("::1/128"), false}, // v6-mapped v4 should not overlap with IPv4. {PrefixFrom(AddrFrom16(mustIP("1.2.0.0").As16()), 16), pfx("1.2.3.0/24"), false}, // Invalid prefixes {PrefixFrom(mustIP("1.2.3.4"), 33), pfx("1.2.3.0/24"), false}, {PrefixFrom(mustIP("2000::"), 129), pfx("2000::/64"), false}, } for i, tt := range tests { if got := tt.a.Overlaps(tt.b); got != tt.want { t.Errorf("%d. (%v).Overlaps(%v) = %v; want %v", i, tt.a, tt.b, got, tt.want) } // Overlaps is commutative if got := tt.b.Overlaps(tt.a); got != tt.want { t.Errorf("%d. (%v).Overlaps(%v) = %v; want %v", i, tt.b, tt.a, got, tt.want) } } } // Sink variables are here to force the compiler to not elide // seemingly useless work in benchmarks and allocation tests. If you // were to just `_ = foo()` within a test function, the compiler could // correctly deduce that foo() does nothing and doesn't need to be // called. By writing results to a global variable, we hide that fact // from the compiler and force it to keep the code under test. var ( sinkIP Addr sinkStdIP net.IP sinkAddrPort AddrPort sinkPrefix Prefix sinkPrefixSlice []Prefix sinkInternValue *intern.Value sinkIP16 [16]byte sinkIP4 [4]byte sinkBool bool sinkString string sinkBytes []byte sinkUDPAddr = &net.UDPAddr{IP: make(net.IP, 0, 16)} ) func TestNoAllocs(t *testing.T) { // Wrappers that panic on error, to prove that our alloc-free // methods are returning successfully. panicIP := func(ip Addr, err error) Addr { if err != nil { panic(err) } return ip } panicPfx := func(pfx Prefix, err error) Prefix { if err != nil { panic(err) } return pfx } panicIPP := func(ipp AddrPort, err error) AddrPort { if err != nil { panic(err) } return ipp } test := func(name string, f func()) { t.Run(name, func(t *testing.T) { n := testing.AllocsPerRun(1000, f) if n != 0 { t.Fatalf("allocs = %d; want 0", int(n)) } }) } // IP constructors test("IPv4", func() { sinkIP = IPv4(1, 2, 3, 4) }) test("AddrFrom4", func() { sinkIP = AddrFrom4([4]byte{1, 2, 3, 4}) }) test("AddrFrom16", func() { sinkIP = AddrFrom16([16]byte{}) }) test("ParseAddr/4", func() { sinkIP = panicIP(ParseAddr("1.2.3.4")) }) test("ParseAddr/6", func() { sinkIP = panicIP(ParseAddr("::1")) }) test("MustParseAddr", func() { sinkIP = MustParseAddr("1.2.3.4") }) test("IPv6LinkLocalAllNodes", func() { sinkIP = IPv6LinkLocalAllNodes() }) test("IPv6Unspecified", func() { sinkIP = IPv6Unspecified() }) // IP methods test("IP.IsZero", func() { sinkBool = MustParseAddr("1.2.3.4").IsZero() }) test("IP.BitLen", func() { sinkBool = MustParseAddr("1.2.3.4").BitLen() == 8 }) test("IP.Zone/4", func() { sinkBool = MustParseAddr("1.2.3.4").Zone() == "" }) test("IP.Zone/6", func() { sinkBool = MustParseAddr("fe80::1").Zone() == "" }) test("IP.Zone/6zone", func() { sinkBool = MustParseAddr("fe80::1%zone").Zone() == "" }) test("IP.Compare", func() { a := MustParseAddr("1.2.3.4") b := MustParseAddr("2.3.4.5") sinkBool = a.Compare(b) == 0 }) test("IP.Less", func() { a := MustParseAddr("1.2.3.4") b := MustParseAddr("2.3.4.5") sinkBool = a.Less(b) }) test("IP.Is4", func() { sinkBool = MustParseAddr("1.2.3.4").Is4() }) test("IP.Is6", func() { sinkBool = MustParseAddr("fe80::1").Is6() }) test("IP.Is4In6", func() { sinkBool = MustParseAddr("fe80::1").Is4In6() }) test("IP.Unmap", func() { sinkIP = MustParseAddr("ffff::2.3.4.5").Unmap() }) test("IP.WithZone", func() { sinkIP = MustParseAddr("fe80::1").WithZone("") }) test("IP.IsGlobalUnicast", func() { sinkBool = MustParseAddr("2001:db8::1").IsGlobalUnicast() }) test("IP.IsInterfaceLocalMulticast", func() { sinkBool = MustParseAddr("fe80::1").IsInterfaceLocalMulticast() }) test("IP.IsLinkLocalMulticast", func() { sinkBool = MustParseAddr("fe80::1").IsLinkLocalMulticast() }) test("IP.IsLinkLocalUnicast", func() { sinkBool = MustParseAddr("fe80::1").IsLinkLocalUnicast() }) test("IP.IsLoopback", func() { sinkBool = MustParseAddr("fe80::1").IsLoopback() }) test("IP.IsMulticast", func() { sinkBool = MustParseAddr("fe80::1").IsMulticast() }) test("IP.IsPrivate", func() { sinkBool = MustParseAddr("fd00::1").IsPrivate() }) test("IP.IsUnspecified", func() { sinkBool = IPv6Unspecified().IsUnspecified() }) test("IP.Prefix/4", func() { sinkPrefix = panicPfx(MustParseAddr("1.2.3.4").Prefix(20)) }) test("IP.Prefix/6", func() { sinkPrefix = panicPfx(MustParseAddr("fe80::1").Prefix(64)) }) test("IP.As16", func() { sinkIP16 = MustParseAddr("1.2.3.4").As16() }) test("IP.As4", func() { sinkIP4 = MustParseAddr("1.2.3.4").As4() }) test("IP.Next", func() { sinkIP = MustParseAddr("1.2.3.4").Next() }) test("IP.Prev", func() { sinkIP = MustParseAddr("1.2.3.4").Prev() }) // AddrPort constructors test("AddrPortFrom", func() { sinkAddrPort = AddrPortFrom(IPv4(1, 2, 3, 4), 22) }) test("ParseAddrPort", func() { sinkAddrPort = panicIPP(ParseAddrPort("[::1]:1234")) }) test("MustParseAddrPort", func() { sinkAddrPort = MustParseAddrPort("[::1]:1234") }) // Prefix constructors test("PrefixFrom", func() { sinkPrefix = PrefixFrom(IPv4(1, 2, 3, 4), 32) }) test("ParsePrefix/4", func() { sinkPrefix = panicPfx(ParsePrefix("1.2.3.4/20")) }) test("ParsePrefix/6", func() { sinkPrefix = panicPfx(ParsePrefix("fe80::1/64")) }) test("MustParsePrefix", func() { sinkPrefix = MustParsePrefix("1.2.3.4/20") }) // Prefix methods test("Prefix.Contains", func() { sinkBool = MustParsePrefix("1.2.3.0/24").Contains(MustParseAddr("1.2.3.4")) }) test("Prefix.Overlaps", func() { a, b := MustParsePrefix("1.2.3.0/24"), MustParsePrefix("1.2.0.0/16") sinkBool = a.Overlaps(b) }) test("Prefix.IsZero", func() { sinkBool = MustParsePrefix("1.2.0.0/16").IsZero() }) test("Prefix.IsSingleIP", func() { sinkBool = MustParsePrefix("1.2.3.4/32").IsSingleIP() }) test("IPPRefix.Masked", func() { sinkPrefix = MustParsePrefix("1.2.3.4/16").Masked() }) } func TestPrefixString(t *testing.T) { tests := []struct { ipp Prefix want string }{ {Prefix{}, "invalid Prefix"}, {PrefixFrom(Addr{}, 8), "invalid Prefix"}, {PrefixFrom(MustParseAddr("1.2.3.4"), 88), "invalid Prefix"}, } for _, tt := range tests { if got := tt.ipp.String(); got != tt.want { t.Errorf("(%#v).String() = %q want %q", tt.ipp, got, tt.want) } } } func TestInvalidAddrPortString(t *testing.T) { tests := []struct { ipp AddrPort want string }{ {AddrPort{}, "invalid AddrPort"}, {AddrPortFrom(Addr{}, 80), "invalid AddrPort"}, } for _, tt := range tests { if got := tt.ipp.String(); got != tt.want { t.Errorf("(%#v).String() = %q want %q", tt.ipp, got, tt.want) } } } func TestAsSlice(t *testing.T) { tests := []struct { in Addr want []byte }{ {in: Addr{}, want: nil}, {in: mustIP("1.2.3.4"), want: []byte{1, 2, 3, 4}}, {in: mustIP("ffff::1"), want: []byte{0xff, 0xff, 15: 1}}, } for _, test := range tests { got := test.in.AsSlice() if !bytes.Equal(got, test.want) { t.Errorf("%v.AsSlice() = %v want %v", test.in, got, test.want) } } } var sink16 [16]byte func BenchmarkAs16(b *testing.B) { addr := MustParseAddr("1::10") for i := 0; i < b.N; i++ { sink16 = addr.As16() } }