Naveen Sampath | 04696f7 | 2022-06-13 15:19:14 +0530 | [diff] [blame^] | 1 | // Copyright 2012 Google, Inc. All rights reserved. |
| 2 | // |
| 3 | // Use of this source code is governed by a BSD-style license |
| 4 | // that can be found in the LICENSE file in the root of the source |
| 5 | // tree. |
| 6 | |
| 7 | package gopacket |
| 8 | |
| 9 | import ( |
| 10 | "bytes" |
| 11 | "encoding/hex" |
| 12 | "errors" |
| 13 | "fmt" |
| 14 | "io" |
| 15 | "net" |
| 16 | "os" |
| 17 | "reflect" |
| 18 | "runtime/debug" |
| 19 | "strings" |
| 20 | "syscall" |
| 21 | "time" |
| 22 | ) |
| 23 | |
| 24 | // CaptureInfo provides standardized information about a packet captured off |
| 25 | // the wire or read from a file. |
| 26 | type CaptureInfo struct { |
| 27 | // Timestamp is the time the packet was captured, if that is known. |
| 28 | Timestamp time.Time |
| 29 | // CaptureLength is the total number of bytes read off of the wire. |
| 30 | CaptureLength int |
| 31 | // Length is the size of the original packet. Should always be >= |
| 32 | // CaptureLength. |
| 33 | Length int |
| 34 | // InterfaceIndex |
| 35 | InterfaceIndex int |
| 36 | // The packet source can place ancillary data of various types here. |
| 37 | // For example, the afpacket source can report the VLAN of captured |
| 38 | // packets this way. |
| 39 | AncillaryData []interface{} |
| 40 | } |
| 41 | |
| 42 | // PacketMetadata contains metadata for a packet. |
| 43 | type PacketMetadata struct { |
| 44 | CaptureInfo |
| 45 | // Truncated is true if packet decoding logic detects that there are fewer |
| 46 | // bytes in the packet than are detailed in various headers (for example, if |
| 47 | // the number of bytes in the IPv4 contents/payload is less than IPv4.Length). |
| 48 | // This is also set automatically for packets captured off the wire if |
| 49 | // CaptureInfo.CaptureLength < CaptureInfo.Length. |
| 50 | Truncated bool |
| 51 | } |
| 52 | |
| 53 | // Packet is the primary object used by gopacket. Packets are created by a |
| 54 | // Decoder's Decode call. A packet is made up of a set of Data, which |
| 55 | // is broken into a number of Layers as it is decoded. |
| 56 | type Packet interface { |
| 57 | //// Functions for outputting the packet as a human-readable string: |
| 58 | //// ------------------------------------------------------------------ |
| 59 | // String returns a human-readable string representation of the packet. |
| 60 | // It uses LayerString on each layer to output the layer. |
| 61 | String() string |
| 62 | // Dump returns a verbose human-readable string representation of the packet, |
| 63 | // including a hex dump of all layers. It uses LayerDump on each layer to |
| 64 | // output the layer. |
| 65 | Dump() string |
| 66 | |
| 67 | //// Functions for accessing arbitrary packet layers: |
| 68 | //// ------------------------------------------------------------------ |
| 69 | // Layers returns all layers in this packet, computing them as necessary |
| 70 | Layers() []Layer |
| 71 | // Layer returns the first layer in this packet of the given type, or nil |
| 72 | Layer(LayerType) Layer |
| 73 | // LayerClass returns the first layer in this packet of the given class, |
| 74 | // or nil. |
| 75 | LayerClass(LayerClass) Layer |
| 76 | |
| 77 | //// Functions for accessing specific types of packet layers. These functions |
| 78 | //// return the first layer of each type found within the packet. |
| 79 | //// ------------------------------------------------------------------ |
| 80 | // LinkLayer returns the first link layer in the packet |
| 81 | LinkLayer() LinkLayer |
| 82 | // NetworkLayer returns the first network layer in the packet |
| 83 | NetworkLayer() NetworkLayer |
| 84 | // TransportLayer returns the first transport layer in the packet |
| 85 | TransportLayer() TransportLayer |
| 86 | // ApplicationLayer returns the first application layer in the packet |
| 87 | ApplicationLayer() ApplicationLayer |
| 88 | // ErrorLayer is particularly useful, since it returns nil if the packet |
| 89 | // was fully decoded successfully, and non-nil if an error was encountered |
| 90 | // in decoding and the packet was only partially decoded. Thus, its output |
| 91 | // can be used to determine if the entire packet was able to be decoded. |
| 92 | ErrorLayer() ErrorLayer |
| 93 | |
| 94 | //// Functions for accessing data specific to the packet: |
| 95 | //// ------------------------------------------------------------------ |
| 96 | // Data returns the set of bytes that make up this entire packet. |
| 97 | Data() []byte |
| 98 | // Metadata returns packet metadata associated with this packet. |
| 99 | Metadata() *PacketMetadata |
| 100 | } |
| 101 | |
| 102 | // packet contains all the information we need to fulfill the Packet interface, |
| 103 | // and its two "subclasses" (yes, no such thing in Go, bear with me), |
| 104 | // eagerPacket and lazyPacket, provide eager and lazy decoding logic around the |
| 105 | // various functions needed to access this information. |
| 106 | type packet struct { |
| 107 | // data contains the entire packet data for a packet |
| 108 | data []byte |
| 109 | // initialLayers is space for an initial set of layers already created inside |
| 110 | // the packet. |
| 111 | initialLayers [6]Layer |
| 112 | // layers contains each layer we've already decoded |
| 113 | layers []Layer |
| 114 | // last is the last layer added to the packet |
| 115 | last Layer |
| 116 | // metadata is the PacketMetadata for this packet |
| 117 | metadata PacketMetadata |
| 118 | |
| 119 | decodeOptions DecodeOptions |
| 120 | |
| 121 | // Pointers to the various important layers |
| 122 | link LinkLayer |
| 123 | network NetworkLayer |
| 124 | transport TransportLayer |
| 125 | application ApplicationLayer |
| 126 | failure ErrorLayer |
| 127 | } |
| 128 | |
| 129 | func (p *packet) SetTruncated() { |
| 130 | p.metadata.Truncated = true |
| 131 | } |
| 132 | |
| 133 | func (p *packet) SetLinkLayer(l LinkLayer) { |
| 134 | if p.link == nil { |
| 135 | p.link = l |
| 136 | } |
| 137 | } |
| 138 | |
| 139 | func (p *packet) SetNetworkLayer(l NetworkLayer) { |
| 140 | if p.network == nil { |
| 141 | p.network = l |
| 142 | } |
| 143 | } |
| 144 | |
| 145 | func (p *packet) SetTransportLayer(l TransportLayer) { |
| 146 | if p.transport == nil { |
| 147 | p.transport = l |
| 148 | } |
| 149 | } |
| 150 | |
| 151 | func (p *packet) SetApplicationLayer(l ApplicationLayer) { |
| 152 | if p.application == nil { |
| 153 | p.application = l |
| 154 | } |
| 155 | } |
| 156 | |
| 157 | func (p *packet) SetErrorLayer(l ErrorLayer) { |
| 158 | if p.failure == nil { |
| 159 | p.failure = l |
| 160 | } |
| 161 | } |
| 162 | |
| 163 | func (p *packet) AddLayer(l Layer) { |
| 164 | p.layers = append(p.layers, l) |
| 165 | p.last = l |
| 166 | } |
| 167 | |
| 168 | func (p *packet) DumpPacketData() { |
| 169 | fmt.Fprint(os.Stderr, p.packetDump()) |
| 170 | os.Stderr.Sync() |
| 171 | } |
| 172 | |
| 173 | func (p *packet) Metadata() *PacketMetadata { |
| 174 | return &p.metadata |
| 175 | } |
| 176 | |
| 177 | func (p *packet) Data() []byte { |
| 178 | return p.data |
| 179 | } |
| 180 | |
| 181 | func (p *packet) DecodeOptions() *DecodeOptions { |
| 182 | return &p.decodeOptions |
| 183 | } |
| 184 | |
| 185 | func (p *packet) addFinalDecodeError(err error, stack []byte) { |
| 186 | fail := &DecodeFailure{err: err, stack: stack} |
| 187 | if p.last == nil { |
| 188 | fail.data = p.data |
| 189 | } else { |
| 190 | fail.data = p.last.LayerPayload() |
| 191 | } |
| 192 | p.AddLayer(fail) |
| 193 | p.SetErrorLayer(fail) |
| 194 | } |
| 195 | |
| 196 | func (p *packet) recoverDecodeError() { |
| 197 | if !p.decodeOptions.SkipDecodeRecovery { |
| 198 | if r := recover(); r != nil { |
| 199 | p.addFinalDecodeError(fmt.Errorf("%v", r), debug.Stack()) |
| 200 | } |
| 201 | } |
| 202 | } |
| 203 | |
| 204 | // LayerString outputs an individual layer as a string. The layer is output |
| 205 | // in a single line, with no trailing newline. This function is specifically |
| 206 | // designed to do the right thing for most layers... it follows the following |
| 207 | // rules: |
| 208 | // * If the Layer has a String function, just output that. |
| 209 | // * Otherwise, output all exported fields in the layer, recursing into |
| 210 | // exported slices and structs. |
| 211 | // NOTE: This is NOT THE SAME AS fmt's "%#v". %#v will output both exported |
| 212 | // and unexported fields... many times packet layers contain unexported stuff |
| 213 | // that would just mess up the output of the layer, see for example the |
| 214 | // Payload layer and it's internal 'data' field, which contains a large byte |
| 215 | // array that would really mess up formatting. |
| 216 | func LayerString(l Layer) string { |
| 217 | return fmt.Sprintf("%v\t%s", l.LayerType(), layerString(reflect.ValueOf(l), false, false)) |
| 218 | } |
| 219 | |
| 220 | // Dumper dumps verbose information on a value. If a layer type implements |
| 221 | // Dumper, then its LayerDump() string will include the results in its output. |
| 222 | type Dumper interface { |
| 223 | Dump() string |
| 224 | } |
| 225 | |
| 226 | // LayerDump outputs a very verbose string representation of a layer. Its |
| 227 | // output is a concatenation of LayerString(l) and hex.Dump(l.LayerContents()). |
| 228 | // It contains newlines and ends with a newline. |
| 229 | func LayerDump(l Layer) string { |
| 230 | var b bytes.Buffer |
| 231 | b.WriteString(LayerString(l)) |
| 232 | b.WriteByte('\n') |
| 233 | if d, ok := l.(Dumper); ok { |
| 234 | dump := d.Dump() |
| 235 | if dump != "" { |
| 236 | b.WriteString(dump) |
| 237 | if dump[len(dump)-1] != '\n' { |
| 238 | b.WriteByte('\n') |
| 239 | } |
| 240 | } |
| 241 | } |
| 242 | b.WriteString(hex.Dump(l.LayerContents())) |
| 243 | return b.String() |
| 244 | } |
| 245 | |
| 246 | // layerString outputs, recursively, a layer in a "smart" way. See docs for |
| 247 | // LayerString for more details. |
| 248 | // |
| 249 | // Params: |
| 250 | // i - value to write out |
| 251 | // anonymous: if we're currently recursing an anonymous member of a struct |
| 252 | // writeSpace: if we've already written a value in a struct, and need to |
| 253 | // write a space before writing more. This happens when we write various |
| 254 | // anonymous values, and need to keep writing more. |
| 255 | func layerString(v reflect.Value, anonymous bool, writeSpace bool) string { |
| 256 | // Let String() functions take precedence. |
| 257 | if v.CanInterface() { |
| 258 | if s, ok := v.Interface().(fmt.Stringer); ok { |
| 259 | return s.String() |
| 260 | } |
| 261 | } |
| 262 | // Reflect, and spit out all the exported fields as key=value. |
| 263 | switch v.Type().Kind() { |
| 264 | case reflect.Interface, reflect.Ptr: |
| 265 | if v.IsNil() { |
| 266 | return "nil" |
| 267 | } |
| 268 | r := v.Elem() |
| 269 | return layerString(r, anonymous, writeSpace) |
| 270 | case reflect.Struct: |
| 271 | var b bytes.Buffer |
| 272 | typ := v.Type() |
| 273 | if !anonymous { |
| 274 | b.WriteByte('{') |
| 275 | } |
| 276 | for i := 0; i < v.NumField(); i++ { |
| 277 | // Check if this is upper-case. |
| 278 | ftype := typ.Field(i) |
| 279 | f := v.Field(i) |
| 280 | if ftype.Anonymous { |
| 281 | anonStr := layerString(f, true, writeSpace) |
| 282 | writeSpace = writeSpace || anonStr != "" |
| 283 | b.WriteString(anonStr) |
| 284 | } else if ftype.PkgPath == "" { // exported |
| 285 | if writeSpace { |
| 286 | b.WriteByte(' ') |
| 287 | } |
| 288 | writeSpace = true |
| 289 | fmt.Fprintf(&b, "%s=%s", typ.Field(i).Name, layerString(f, false, writeSpace)) |
| 290 | } |
| 291 | } |
| 292 | if !anonymous { |
| 293 | b.WriteByte('}') |
| 294 | } |
| 295 | return b.String() |
| 296 | case reflect.Slice: |
| 297 | var b bytes.Buffer |
| 298 | b.WriteByte('[') |
| 299 | if v.Len() > 4 { |
| 300 | fmt.Fprintf(&b, "..%d..", v.Len()) |
| 301 | } else { |
| 302 | for j := 0; j < v.Len(); j++ { |
| 303 | if j != 0 { |
| 304 | b.WriteString(", ") |
| 305 | } |
| 306 | b.WriteString(layerString(v.Index(j), false, false)) |
| 307 | } |
| 308 | } |
| 309 | b.WriteByte(']') |
| 310 | return b.String() |
| 311 | } |
| 312 | return fmt.Sprintf("%v", v.Interface()) |
| 313 | } |
| 314 | |
| 315 | const ( |
| 316 | longBytesLength = 128 |
| 317 | ) |
| 318 | |
| 319 | // LongBytesGoString returns a string representation of the byte slice shortened |
| 320 | // using the format '<type>{<truncated slice> ... (<n> bytes)}' if it |
| 321 | // exceeds a predetermined length. Can be used to avoid filling the display with |
| 322 | // very long byte strings. |
| 323 | func LongBytesGoString(buf []byte) string { |
| 324 | if len(buf) < longBytesLength { |
| 325 | return fmt.Sprintf("%#v", buf) |
| 326 | } |
| 327 | s := fmt.Sprintf("%#v", buf[:longBytesLength-1]) |
| 328 | s = strings.TrimSuffix(s, "}") |
| 329 | return fmt.Sprintf("%s ... (%d bytes)}", s, len(buf)) |
| 330 | } |
| 331 | |
| 332 | func baseLayerString(value reflect.Value) string { |
| 333 | t := value.Type() |
| 334 | content := value.Field(0) |
| 335 | c := make([]byte, content.Len()) |
| 336 | for i := range c { |
| 337 | c[i] = byte(content.Index(i).Uint()) |
| 338 | } |
| 339 | payload := value.Field(1) |
| 340 | p := make([]byte, payload.Len()) |
| 341 | for i := range p { |
| 342 | p[i] = byte(payload.Index(i).Uint()) |
| 343 | } |
| 344 | return fmt.Sprintf("%s{Contents:%s, Payload:%s}", t.String(), |
| 345 | LongBytesGoString(c), |
| 346 | LongBytesGoString(p)) |
| 347 | } |
| 348 | |
| 349 | func layerGoString(i interface{}, b *bytes.Buffer) { |
| 350 | if s, ok := i.(fmt.GoStringer); ok { |
| 351 | b.WriteString(s.GoString()) |
| 352 | return |
| 353 | } |
| 354 | |
| 355 | var v reflect.Value |
| 356 | var ok bool |
| 357 | if v, ok = i.(reflect.Value); !ok { |
| 358 | v = reflect.ValueOf(i) |
| 359 | } |
| 360 | switch v.Kind() { |
| 361 | case reflect.Ptr, reflect.Interface: |
| 362 | if v.Kind() == reflect.Ptr { |
| 363 | b.WriteByte('&') |
| 364 | } |
| 365 | layerGoString(v.Elem().Interface(), b) |
| 366 | case reflect.Struct: |
| 367 | t := v.Type() |
| 368 | b.WriteString(t.String()) |
| 369 | b.WriteByte('{') |
| 370 | for i := 0; i < v.NumField(); i++ { |
| 371 | if i > 0 { |
| 372 | b.WriteString(", ") |
| 373 | } |
| 374 | if t.Field(i).Name == "BaseLayer" { |
| 375 | fmt.Fprintf(b, "BaseLayer:%s", baseLayerString(v.Field(i))) |
| 376 | } else if v.Field(i).Kind() == reflect.Struct { |
| 377 | fmt.Fprintf(b, "%s:", t.Field(i).Name) |
| 378 | layerGoString(v.Field(i), b) |
| 379 | } else if v.Field(i).Kind() == reflect.Ptr { |
| 380 | b.WriteByte('&') |
| 381 | layerGoString(v.Field(i), b) |
| 382 | } else { |
| 383 | fmt.Fprintf(b, "%s:%#v", t.Field(i).Name, v.Field(i)) |
| 384 | } |
| 385 | } |
| 386 | b.WriteByte('}') |
| 387 | default: |
| 388 | fmt.Fprintf(b, "%#v", i) |
| 389 | } |
| 390 | } |
| 391 | |
| 392 | // LayerGoString returns a representation of the layer in Go syntax, |
| 393 | // taking care to shorten "very long" BaseLayer byte slices |
| 394 | func LayerGoString(l Layer) string { |
| 395 | b := new(bytes.Buffer) |
| 396 | layerGoString(l, b) |
| 397 | return b.String() |
| 398 | } |
| 399 | |
| 400 | func (p *packet) packetString() string { |
| 401 | var b bytes.Buffer |
| 402 | fmt.Fprintf(&b, "PACKET: %d bytes", len(p.Data())) |
| 403 | if p.metadata.Truncated { |
| 404 | b.WriteString(", truncated") |
| 405 | } |
| 406 | if p.metadata.Length > 0 { |
| 407 | fmt.Fprintf(&b, ", wire length %d cap length %d", p.metadata.Length, p.metadata.CaptureLength) |
| 408 | } |
| 409 | if !p.metadata.Timestamp.IsZero() { |
| 410 | fmt.Fprintf(&b, " @ %v", p.metadata.Timestamp) |
| 411 | } |
| 412 | b.WriteByte('\n') |
| 413 | for i, l := range p.layers { |
| 414 | fmt.Fprintf(&b, "- Layer %d (%02d bytes) = %s\n", i+1, len(l.LayerContents()), LayerString(l)) |
| 415 | } |
| 416 | return b.String() |
| 417 | } |
| 418 | |
| 419 | func (p *packet) packetDump() string { |
| 420 | var b bytes.Buffer |
| 421 | fmt.Fprintf(&b, "-- FULL PACKET DATA (%d bytes) ------------------------------------\n%s", len(p.data), hex.Dump(p.data)) |
| 422 | for i, l := range p.layers { |
| 423 | fmt.Fprintf(&b, "--- Layer %d ---\n%s", i+1, LayerDump(l)) |
| 424 | } |
| 425 | return b.String() |
| 426 | } |
| 427 | |
| 428 | // eagerPacket is a packet implementation that does eager decoding. Upon |
| 429 | // initial construction, it decodes all the layers it can from packet data. |
| 430 | // eagerPacket implements Packet and PacketBuilder. |
| 431 | type eagerPacket struct { |
| 432 | packet |
| 433 | } |
| 434 | |
| 435 | var errNilDecoder = errors.New("NextDecoder passed nil decoder, probably an unsupported decode type") |
| 436 | |
| 437 | func (p *eagerPacket) NextDecoder(next Decoder) error { |
| 438 | if next == nil { |
| 439 | return errNilDecoder |
| 440 | } |
| 441 | if p.last == nil { |
| 442 | return errors.New("NextDecoder called, but no layers added yet") |
| 443 | } |
| 444 | d := p.last.LayerPayload() |
| 445 | if len(d) == 0 { |
| 446 | return nil |
| 447 | } |
| 448 | // Since we're eager, immediately call the next decoder. |
| 449 | return next.Decode(d, p) |
| 450 | } |
| 451 | func (p *eagerPacket) initialDecode(dec Decoder) { |
| 452 | defer p.recoverDecodeError() |
| 453 | err := dec.Decode(p.data, p) |
| 454 | if err != nil { |
| 455 | p.addFinalDecodeError(err, nil) |
| 456 | } |
| 457 | } |
| 458 | func (p *eagerPacket) LinkLayer() LinkLayer { |
| 459 | return p.link |
| 460 | } |
| 461 | func (p *eagerPacket) NetworkLayer() NetworkLayer { |
| 462 | return p.network |
| 463 | } |
| 464 | func (p *eagerPacket) TransportLayer() TransportLayer { |
| 465 | return p.transport |
| 466 | } |
| 467 | func (p *eagerPacket) ApplicationLayer() ApplicationLayer { |
| 468 | return p.application |
| 469 | } |
| 470 | func (p *eagerPacket) ErrorLayer() ErrorLayer { |
| 471 | return p.failure |
| 472 | } |
| 473 | func (p *eagerPacket) Layers() []Layer { |
| 474 | return p.layers |
| 475 | } |
| 476 | func (p *eagerPacket) Layer(t LayerType) Layer { |
| 477 | for _, l := range p.layers { |
| 478 | if l.LayerType() == t { |
| 479 | return l |
| 480 | } |
| 481 | } |
| 482 | return nil |
| 483 | } |
| 484 | func (p *eagerPacket) LayerClass(lc LayerClass) Layer { |
| 485 | for _, l := range p.layers { |
| 486 | if lc.Contains(l.LayerType()) { |
| 487 | return l |
| 488 | } |
| 489 | } |
| 490 | return nil |
| 491 | } |
| 492 | func (p *eagerPacket) String() string { return p.packetString() } |
| 493 | func (p *eagerPacket) Dump() string { return p.packetDump() } |
| 494 | |
| 495 | // lazyPacket does lazy decoding on its packet data. On construction it does |
| 496 | // no initial decoding. For each function call, it decodes only as many layers |
| 497 | // as are necessary to compute the return value for that function. |
| 498 | // lazyPacket implements Packet and PacketBuilder. |
| 499 | type lazyPacket struct { |
| 500 | packet |
| 501 | next Decoder |
| 502 | } |
| 503 | |
| 504 | func (p *lazyPacket) NextDecoder(next Decoder) error { |
| 505 | if next == nil { |
| 506 | return errNilDecoder |
| 507 | } |
| 508 | p.next = next |
| 509 | return nil |
| 510 | } |
| 511 | func (p *lazyPacket) decodeNextLayer() { |
| 512 | if p.next == nil { |
| 513 | return |
| 514 | } |
| 515 | d := p.data |
| 516 | if p.last != nil { |
| 517 | d = p.last.LayerPayload() |
| 518 | } |
| 519 | next := p.next |
| 520 | p.next = nil |
| 521 | // We've just set p.next to nil, so if we see we have no data, this should be |
| 522 | // the final call we get to decodeNextLayer if we return here. |
| 523 | if len(d) == 0 { |
| 524 | return |
| 525 | } |
| 526 | defer p.recoverDecodeError() |
| 527 | err := next.Decode(d, p) |
| 528 | if err != nil { |
| 529 | p.addFinalDecodeError(err, nil) |
| 530 | } |
| 531 | } |
| 532 | func (p *lazyPacket) LinkLayer() LinkLayer { |
| 533 | for p.link == nil && p.next != nil { |
| 534 | p.decodeNextLayer() |
| 535 | } |
| 536 | return p.link |
| 537 | } |
| 538 | func (p *lazyPacket) NetworkLayer() NetworkLayer { |
| 539 | for p.network == nil && p.next != nil { |
| 540 | p.decodeNextLayer() |
| 541 | } |
| 542 | return p.network |
| 543 | } |
| 544 | func (p *lazyPacket) TransportLayer() TransportLayer { |
| 545 | for p.transport == nil && p.next != nil { |
| 546 | p.decodeNextLayer() |
| 547 | } |
| 548 | return p.transport |
| 549 | } |
| 550 | func (p *lazyPacket) ApplicationLayer() ApplicationLayer { |
| 551 | for p.application == nil && p.next != nil { |
| 552 | p.decodeNextLayer() |
| 553 | } |
| 554 | return p.application |
| 555 | } |
| 556 | func (p *lazyPacket) ErrorLayer() ErrorLayer { |
| 557 | for p.failure == nil && p.next != nil { |
| 558 | p.decodeNextLayer() |
| 559 | } |
| 560 | return p.failure |
| 561 | } |
| 562 | func (p *lazyPacket) Layers() []Layer { |
| 563 | for p.next != nil { |
| 564 | p.decodeNextLayer() |
| 565 | } |
| 566 | return p.layers |
| 567 | } |
| 568 | func (p *lazyPacket) Layer(t LayerType) Layer { |
| 569 | for _, l := range p.layers { |
| 570 | if l.LayerType() == t { |
| 571 | return l |
| 572 | } |
| 573 | } |
| 574 | numLayers := len(p.layers) |
| 575 | for p.next != nil { |
| 576 | p.decodeNextLayer() |
| 577 | for _, l := range p.layers[numLayers:] { |
| 578 | if l.LayerType() == t { |
| 579 | return l |
| 580 | } |
| 581 | } |
| 582 | numLayers = len(p.layers) |
| 583 | } |
| 584 | return nil |
| 585 | } |
| 586 | func (p *lazyPacket) LayerClass(lc LayerClass) Layer { |
| 587 | for _, l := range p.layers { |
| 588 | if lc.Contains(l.LayerType()) { |
| 589 | return l |
| 590 | } |
| 591 | } |
| 592 | numLayers := len(p.layers) |
| 593 | for p.next != nil { |
| 594 | p.decodeNextLayer() |
| 595 | for _, l := range p.layers[numLayers:] { |
| 596 | if lc.Contains(l.LayerType()) { |
| 597 | return l |
| 598 | } |
| 599 | } |
| 600 | numLayers = len(p.layers) |
| 601 | } |
| 602 | return nil |
| 603 | } |
| 604 | func (p *lazyPacket) String() string { p.Layers(); return p.packetString() } |
| 605 | func (p *lazyPacket) Dump() string { p.Layers(); return p.packetDump() } |
| 606 | |
| 607 | // DecodeOptions tells gopacket how to decode a packet. |
| 608 | type DecodeOptions struct { |
| 609 | // Lazy decoding decodes the minimum number of layers needed to return data |
| 610 | // for a packet at each function call. Be careful using this with concurrent |
| 611 | // packet processors, as each call to packet.* could mutate the packet, and |
| 612 | // two concurrent function calls could interact poorly. |
| 613 | Lazy bool |
| 614 | // NoCopy decoding doesn't copy its input buffer into storage that's owned by |
| 615 | // the packet. If you can guarantee that the bytes underlying the slice |
| 616 | // passed into NewPacket aren't going to be modified, this can be faster. If |
| 617 | // there's any chance that those bytes WILL be changed, this will invalidate |
| 618 | // your packets. |
| 619 | NoCopy bool |
| 620 | // SkipDecodeRecovery skips over panic recovery during packet decoding. |
| 621 | // Normally, when packets decode, if a panic occurs, that panic is captured |
| 622 | // by a recover(), and a DecodeFailure layer is added to the packet detailing |
| 623 | // the issue. If this flag is set, panics are instead allowed to continue up |
| 624 | // the stack. |
| 625 | SkipDecodeRecovery bool |
| 626 | // DecodeStreamsAsDatagrams enables routing of application-level layers in the TCP |
| 627 | // decoder. If true, we should try to decode layers after TCP in single packets. |
| 628 | // This is disabled by default because the reassembly package drives the decoding |
| 629 | // of TCP payload data after reassembly. |
| 630 | DecodeStreamsAsDatagrams bool |
| 631 | } |
| 632 | |
| 633 | // Default decoding provides the safest (but slowest) method for decoding |
| 634 | // packets. It eagerly processes all layers (so it's concurrency-safe) and it |
| 635 | // copies its input buffer upon creation of the packet (so the packet remains |
| 636 | // valid if the underlying slice is modified. Both of these take time, |
| 637 | // though, so beware. If you can guarantee that the packet will only be used |
| 638 | // by one goroutine at a time, set Lazy decoding. If you can guarantee that |
| 639 | // the underlying slice won't change, set NoCopy decoding. |
| 640 | var Default = DecodeOptions{} |
| 641 | |
| 642 | // Lazy is a DecodeOptions with just Lazy set. |
| 643 | var Lazy = DecodeOptions{Lazy: true} |
| 644 | |
| 645 | // NoCopy is a DecodeOptions with just NoCopy set. |
| 646 | var NoCopy = DecodeOptions{NoCopy: true} |
| 647 | |
| 648 | // DecodeStreamsAsDatagrams is a DecodeOptions with just DecodeStreamsAsDatagrams set. |
| 649 | var DecodeStreamsAsDatagrams = DecodeOptions{DecodeStreamsAsDatagrams: true} |
| 650 | |
| 651 | // NewPacket creates a new Packet object from a set of bytes. The |
| 652 | // firstLayerDecoder tells it how to interpret the first layer from the bytes, |
| 653 | // future layers will be generated from that first layer automatically. |
| 654 | func NewPacket(data []byte, firstLayerDecoder Decoder, options DecodeOptions) Packet { |
| 655 | if !options.NoCopy { |
| 656 | dataCopy := make([]byte, len(data)) |
| 657 | copy(dataCopy, data) |
| 658 | data = dataCopy |
| 659 | } |
| 660 | if options.Lazy { |
| 661 | p := &lazyPacket{ |
| 662 | packet: packet{data: data, decodeOptions: options}, |
| 663 | next: firstLayerDecoder, |
| 664 | } |
| 665 | p.layers = p.initialLayers[:0] |
| 666 | // Crazy craziness: |
| 667 | // If the following return statemet is REMOVED, and Lazy is FALSE, then |
| 668 | // eager packet processing becomes 17% FASTER. No, there is no logical |
| 669 | // explanation for this. However, it's such a hacky micro-optimization that |
| 670 | // we really can't rely on it. It appears to have to do with the size the |
| 671 | // compiler guesses for this function's stack space, since one symptom is |
| 672 | // that with the return statement in place, we more than double calls to |
| 673 | // runtime.morestack/runtime.lessstack. We'll hope the compiler gets better |
| 674 | // over time and we get this optimization for free. Until then, we'll have |
| 675 | // to live with slower packet processing. |
| 676 | return p |
| 677 | } |
| 678 | p := &eagerPacket{ |
| 679 | packet: packet{data: data, decodeOptions: options}, |
| 680 | } |
| 681 | p.layers = p.initialLayers[:0] |
| 682 | p.initialDecode(firstLayerDecoder) |
| 683 | return p |
| 684 | } |
| 685 | |
| 686 | // PacketDataSource is an interface for some source of packet data. Users may |
| 687 | // create their own implementations, or use the existing implementations in |
| 688 | // gopacket/pcap (libpcap, allows reading from live interfaces or from |
| 689 | // pcap files) or gopacket/pfring (PF_RING, allows reading from live |
| 690 | // interfaces). |
| 691 | type PacketDataSource interface { |
| 692 | // ReadPacketData returns the next packet available from this data source. |
| 693 | // It returns: |
| 694 | // data: The bytes of an individual packet. |
| 695 | // ci: Metadata about the capture |
| 696 | // err: An error encountered while reading packet data. If err != nil, |
| 697 | // then data/ci will be ignored. |
| 698 | ReadPacketData() (data []byte, ci CaptureInfo, err error) |
| 699 | } |
| 700 | |
| 701 | // ConcatFinitePacketDataSources returns a PacketDataSource that wraps a set |
| 702 | // of internal PacketDataSources, each of which will stop with io.EOF after |
| 703 | // reading a finite number of packets. The returned PacketDataSource will |
| 704 | // return all packets from the first finite source, followed by all packets from |
| 705 | // the second, etc. Once all finite sources have returned io.EOF, the returned |
| 706 | // source will as well. |
| 707 | func ConcatFinitePacketDataSources(pds ...PacketDataSource) PacketDataSource { |
| 708 | c := concat(pds) |
| 709 | return &c |
| 710 | } |
| 711 | |
| 712 | type concat []PacketDataSource |
| 713 | |
| 714 | func (c *concat) ReadPacketData() (data []byte, ci CaptureInfo, err error) { |
| 715 | for len(*c) > 0 { |
| 716 | data, ci, err = (*c)[0].ReadPacketData() |
| 717 | if err == io.EOF { |
| 718 | *c = (*c)[1:] |
| 719 | continue |
| 720 | } |
| 721 | return |
| 722 | } |
| 723 | return nil, CaptureInfo{}, io.EOF |
| 724 | } |
| 725 | |
| 726 | // ZeroCopyPacketDataSource is an interface to pull packet data from sources |
| 727 | // that allow data to be returned without copying to a user-controlled buffer. |
| 728 | // It's very similar to PacketDataSource, except that the caller must be more |
| 729 | // careful in how the returned buffer is handled. |
| 730 | type ZeroCopyPacketDataSource interface { |
| 731 | // ZeroCopyReadPacketData returns the next packet available from this data source. |
| 732 | // It returns: |
| 733 | // data: The bytes of an individual packet. Unlike with |
| 734 | // PacketDataSource's ReadPacketData, the slice returned here points |
| 735 | // to a buffer owned by the data source. In particular, the bytes in |
| 736 | // this buffer may be changed by future calls to |
| 737 | // ZeroCopyReadPacketData. Do not use the returned buffer after |
| 738 | // subsequent ZeroCopyReadPacketData calls. |
| 739 | // ci: Metadata about the capture |
| 740 | // err: An error encountered while reading packet data. If err != nil, |
| 741 | // then data/ci will be ignored. |
| 742 | ZeroCopyReadPacketData() (data []byte, ci CaptureInfo, err error) |
| 743 | } |
| 744 | |
| 745 | // PacketSource reads in packets from a PacketDataSource, decodes them, and |
| 746 | // returns them. |
| 747 | // |
| 748 | // There are currently two different methods for reading packets in through |
| 749 | // a PacketSource: |
| 750 | // |
| 751 | // Reading With Packets Function |
| 752 | // |
| 753 | // This method is the most convenient and easiest to code, but lacks |
| 754 | // flexibility. Packets returns a 'chan Packet', then asynchronously writes |
| 755 | // packets into that channel. Packets uses a blocking channel, and closes |
| 756 | // it if an io.EOF is returned by the underlying PacketDataSource. All other |
| 757 | // PacketDataSource errors are ignored and discarded. |
| 758 | // for packet := range packetSource.Packets() { |
| 759 | // ... |
| 760 | // } |
| 761 | // |
| 762 | // Reading With NextPacket Function |
| 763 | // |
| 764 | // This method is the most flexible, and exposes errors that may be |
| 765 | // encountered by the underlying PacketDataSource. It's also the fastest |
| 766 | // in a tight loop, since it doesn't have the overhead of a channel |
| 767 | // read/write. However, it requires the user to handle errors, most |
| 768 | // importantly the io.EOF error in cases where packets are being read from |
| 769 | // a file. |
| 770 | // for { |
| 771 | // packet, err := packetSource.NextPacket() |
| 772 | // if err == io.EOF { |
| 773 | // break |
| 774 | // } else if err != nil { |
| 775 | // log.Println("Error:", err) |
| 776 | // continue |
| 777 | // } |
| 778 | // handlePacket(packet) // Do something with each packet. |
| 779 | // } |
| 780 | type PacketSource struct { |
| 781 | source PacketDataSource |
| 782 | decoder Decoder |
| 783 | // DecodeOptions is the set of options to use for decoding each piece |
| 784 | // of packet data. This can/should be changed by the user to reflect the |
| 785 | // way packets should be decoded. |
| 786 | DecodeOptions |
| 787 | c chan Packet |
| 788 | } |
| 789 | |
| 790 | // NewPacketSource creates a packet data source. |
| 791 | func NewPacketSource(source PacketDataSource, decoder Decoder) *PacketSource { |
| 792 | return &PacketSource{ |
| 793 | source: source, |
| 794 | decoder: decoder, |
| 795 | } |
| 796 | } |
| 797 | |
| 798 | // NextPacket returns the next decoded packet from the PacketSource. On error, |
| 799 | // it returns a nil packet and a non-nil error. |
| 800 | func (p *PacketSource) NextPacket() (Packet, error) { |
| 801 | data, ci, err := p.source.ReadPacketData() |
| 802 | if err != nil { |
| 803 | return nil, err |
| 804 | } |
| 805 | packet := NewPacket(data, p.decoder, p.DecodeOptions) |
| 806 | m := packet.Metadata() |
| 807 | m.CaptureInfo = ci |
| 808 | m.Truncated = m.Truncated || ci.CaptureLength < ci.Length |
| 809 | return packet, nil |
| 810 | } |
| 811 | |
| 812 | // packetsToChannel reads in all packets from the packet source and sends them |
| 813 | // to the given channel. This routine terminates when a non-temporary error |
| 814 | // is returned by NextPacket(). |
| 815 | func (p *PacketSource) packetsToChannel() { |
| 816 | defer close(p.c) |
| 817 | for { |
| 818 | packet, err := p.NextPacket() |
| 819 | if err == nil { |
| 820 | p.c <- packet |
| 821 | continue |
| 822 | } |
| 823 | |
| 824 | // Immediately retry for temporary network errors |
| 825 | if nerr, ok := err.(net.Error); ok && nerr.Temporary() { |
| 826 | continue |
| 827 | } |
| 828 | |
| 829 | // Immediately retry for EAGAIN |
| 830 | if err == syscall.EAGAIN { |
| 831 | continue |
| 832 | } |
| 833 | |
| 834 | // Immediately break for known unrecoverable errors |
| 835 | if err == io.EOF || err == io.ErrUnexpectedEOF || |
| 836 | err == io.ErrNoProgress || err == io.ErrClosedPipe || err == io.ErrShortBuffer || |
| 837 | err == syscall.EBADF || |
| 838 | strings.Contains(err.Error(), "use of closed file") { |
| 839 | break |
| 840 | } |
| 841 | |
| 842 | // Sleep briefly and try again |
| 843 | time.Sleep(time.Millisecond * time.Duration(5)) |
| 844 | } |
| 845 | } |
| 846 | |
| 847 | // Packets returns a channel of packets, allowing easy iterating over |
| 848 | // packets. Packets will be asynchronously read in from the underlying |
| 849 | // PacketDataSource and written to the returned channel. If the underlying |
| 850 | // PacketDataSource returns an io.EOF error, the channel will be closed. |
| 851 | // If any other error is encountered, it is ignored. |
| 852 | // |
| 853 | // for packet := range packetSource.Packets() { |
| 854 | // handlePacket(packet) // Do something with each packet. |
| 855 | // } |
| 856 | // |
| 857 | // If called more than once, returns the same channel. |
| 858 | func (p *PacketSource) Packets() chan Packet { |
| 859 | if p.c == nil { |
| 860 | p.c = make(chan Packet, 1000) |
| 861 | go p.packetsToChannel() |
| 862 | } |
| 863 | return p.c |
| 864 | } |