Coverage Report

Created: 2026-07-16 07:12

next uncovered line (L), next uncovered region (R), next uncovered branch (B)
/src/PcapPlusPlus/Packet++/header/Layer.h
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#pragma once
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#include <stdint.h>
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#include <stdio.h>
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#include "ProtocolType.h"
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#include <ostream>
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#include <string>
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#include <stdexcept>
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#include <utility>
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/// @file
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/// @namespace pcpp
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/// @brief The main namespace for the PcapPlusPlus lib
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namespace pcpp
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{
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  /// @class IDataContainer
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  /// An interface (virtual abstract class) that indicates an object that holds a pointer to a buffer data. The Layer
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  /// class is an example of such object, hence it inherits this interface
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  class IDataContainer
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  {
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  public:
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    /// Get a pointer to the data
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    /// @param[in] offset Get a pointer in a certain offset. Default is 0 - get a pointer to start of data
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    /// @return A pointer to the data
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    virtual uint8_t* getDataPtr(size_t offset = 0) const = 0;
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    virtual ~IDataContainer() = default;
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  };
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  class Packet;
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  namespace internal
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  {
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    /// @brief Holds information about a Layer's data and object ownership.
37
    struct LayerAllocationInfo
38
    {
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      /// @brief Pointer to the Packet this layer is attached to (if any).
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      ///
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      /// If the layer is attached to a Packet, the layer's memory span (data) is considered managed by the
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      /// Packet. The Packet is responsible for keeping the layer's memory span valid and updating it should it
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      /// become necessary as long as the layer is attached to it.
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      ///
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      /// In an event the Packet is destroyed, all of its attached layers's memory views are considered invalid.
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      /// Accessing layer data after the Packet is destroyed results in undefined behavior.
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      ///
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      /// If nullptr, the layer is not attached to any Packet and is considered unmanaged.
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      /// It also means the layer's memory span is considered owned by the layer itself and will be freed when
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      /// the layer is destroyed.
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      Packet* attachedPacket = nullptr;
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      /// @brief Controls if the layer object is considered owned by the attached Packet
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      ///
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      /// If 'true', the Layer object is considered owned by the attached Packet and will be freed by it on Packet
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      /// destruction.
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      ///
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      /// If 'false', the Layer object is considered unmanaged and the user is responsible for freeing it.
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      /// This is commonly the case for layers created on the stack and attached to a Packet.
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      bool ownedByPacket = false;
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      /// @brief Sets the state of attachment to a specified Packet
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      /// @param packet Pointer to the Packet this layer is attached to (or nullptr if not attached to any Packet)
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      /// @param managed True if the layer object's lifetime is to be managed by the Packet, false otherwise
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      /// @param force If true, bypasses the check for existing attachment. Default is false.
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      /// @throws std::runtime_error if the layer is already attached to a Packet and 'force' is false
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      void attachPacket(Packet* packet, bool managed, bool force = false)
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0
      {
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0
        if (!force && attachedPacket != nullptr)
70
0
        {
71
0
          throw std::runtime_error("Layer is already attached to a Packet");
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0
        }
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0
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0
        attachedPacket = packet;
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0
        ownedByPacket = managed;
76
0
      }
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      /// @brief Clears the attachment to any Packet, resetting to unmanaged state.
79
      void detach()
80
0
      {
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0
        attachedPacket = nullptr;
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0
        ownedByPacket = false;
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0
      }
84
    };
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  }  // namespace internal
86
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  /// @class Layer
88
  /// Layer is the base class for all protocol layers. Each protocol supported in PcapPlusPlus has a class that
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  /// inherits Layer.
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  /// The protocol layer class expose all properties and methods relevant for viewing and editing protocol fields.
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  /// For example: a pointer to a structured header (e.g tcphdr, iphdr, etc.), protocol header size, payload size,
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  /// compute fields that can be automatically computed, print protocol data to string, etc.
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  /// Each protocol instance is obviously part of a protocol stack (which construct a packet). This protocol stack is
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  /// represented in PcapPlusPlus in a linked list, and each layer is an element in this list. That's why each layer
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  /// has properties to the next and previous layer in the protocol stack. The Layer class, as a base class, is
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  /// abstract and the user can't create an instance of it (it has a private constructor). Each layer holds a pointer
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  /// to the relevant place in the packet. The layer sees all the data from this pointer forward until the end of the
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  /// packet. Here is an example packet showing this concept:
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  ///
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  /// @code{.unparsed}
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  /// ====================================================
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  /// |Eth       |IPv4       |TCP       |Packet          |
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  /// |Header    |Header     |Header    |Payload         |
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  /// ====================================================
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  ///
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  /// |--------------------------------------------------|
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  /// EthLayer data
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  ///            |---------------------------------------|
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  ///            IPv4Layer data
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  ///                        |---------------------------|
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  ///                        TcpLayer data
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  ///                                   |----------------|
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  ///                                   PayloadLayer data
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  /// @endcode
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  class Layer : public IDataContainer
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  {
117
    friend class Packet;
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  public:
120
    /// A destructor for this class. Frees the data if it was allocated by the layer constructor (see
121
    /// isAllocatedToPacket() for more info)
122
    ~Layer() override;
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    /// @return A pointer to the next layer in the protocol stack or nullptr if the layer is the last one
125
    Layer* getNextLayer() const
126
0
    {
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0
      return m_NextLayer;
128
0
    }
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    /// @return A pointer to the previous layer in the protocol stack or nullptr if the layer is the first one
131
    Layer* getPrevLayer() const
132
0
    {
133
0
      return m_PrevLayer;
134
0
    }
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    /// @return The protocol enum
137
    ProtocolType getProtocol() const
138
0
    {
139
0
      return m_Protocol;
140
0
    }
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    /// Check if the layer's protocol matches a protocol family
143
    /// @param protocolTypeFamily The protocol family to check
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    /// @return True if the layer's protocol matches the protocol family, false otherwise
145
    bool isMemberOfProtocolFamily(ProtocolTypeFamily protocolTypeFamily) const;
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    /// @return A pointer to the layer raw data. In most cases it'll be a pointer to the first byte of the header
148
    uint8_t* getData() const
149
0
    {
150
0
      return m_Data;
151
0
    }
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    /// @return The length in bytes of the data from the first byte of the header until the end of the packet
154
    size_t getDataLen() const
155
0
    {
156
0
      return m_DataLen;
157
0
    }
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    /// @return A pointer for the layer payload, meaning the first byte after the header
160
    uint8_t* getLayerPayload() const
161
0
    {
162
0
      return m_Data + getHeaderLen();
163
0
    }
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    /// @return The size in bytes of the payload
166
    size_t getLayerPayloadSize() const
167
0
    {
168
0
      return m_DataLen - getHeaderLen();
169
0
    }
170
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    /// Raw data in layers can come from one of sources:
172
    /// 1. from an existing packet - this is the case when parsing packets received from files or the network. In
173
    /// this case the data was already allocated by someone else, and layer only holds the pointer to the relevant
174
    /// place inside this data
175
    /// 2. when creating packets, data is allocated when layer is created. In this case the layer is responsible for
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    /// freeing it as well
177
    ///
178
    /// @return Returns true if the data was allocated by an external source (a packet) or false if it was allocated
179
    /// by the layer itself
180
    bool isAllocatedToPacket() const
181
0
    {
182
0
      return m_AllocationInfo.attachedPacket != nullptr;
183
0
    }
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185
    /// @brief Copy the raw data of this layer to another array
186
    ///
187
    /// @warning The method does not perform any bounds checking on the destination array. The caller MUST ensure
188
    /// that the destination array has enough space to hold the getDataLen() bytes.
189
    ///
190
    /// @warning Prefer the overload of copyData() that accepts a destination size to ensure safe copying of data.
191
    ///
192
    /// @param[out] toArr The destination byte array
193
    void copyData(uint8_t* toArr) const;
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    /// @brief Copy the raw data of this layer to another array, with a specified maximum size.
196
    ///
197
    /// The method copies up to 'destSize' bytes of the layer's raw data into the provided destination array.
198
    /// If the layer's data length is greater than 'destSize', only the first 'destSize' bytes will be copied.
199
    ///
200
    /// To ensure sufficient space is available in the destination array, use getDataLen() to determine the actual
201
    /// length of the layer's data before calling this method.
202
    ///
203
    /// @param[out] dest The destination byte array
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    /// @param[in] destSize The maximum number of bytes to copy
205
    /// @return The number of bytes copied to the destination array.
206
    size_t copyData(uint8_t* dest, size_t destSize) const;
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208
    // implement abstract methods
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210
    uint8_t* getDataPtr(size_t offset = 0) const override
211
0
    {
212
0
      return static_cast<uint8_t*>(m_Data + offset);
213
0
    }
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    // abstract methods
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    /// Each layer is responsible for parsing the next layer
218
    virtual void parseNextLayer() = 0;
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220
    /// @return The header length in bytes
221
    virtual size_t getHeaderLen() const = 0;
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223
    /// Each layer can compute field values automatically using this method. This is an abstract method
224
    virtual void computeCalculateFields() = 0;
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226
    /// @return A string representation of the layer most important data (should look like the layer description in
227
    /// Wireshark)
228
    virtual std::string toString() const = 0;
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    /// @return The OSI Model layer this protocol belongs to
231
    virtual OsiModelLayer getOsiModelLayer() const = 0;
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233
  protected:
234
    uint8_t* m_Data;
235
    size_t m_DataLen;
236
    ProtocolType m_Protocol;
237
    Layer* m_NextLayer;
238
    Layer* m_PrevLayer;
239
240
  private:
241
    internal::LayerAllocationInfo m_AllocationInfo;
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243
  protected:
244
    Layer() : m_Data(nullptr), m_DataLen(0), m_Protocol(UnknownProtocol), m_NextLayer(nullptr), m_PrevLayer(nullptr)
245
0
    {}
246
247
    Layer(uint8_t* data, size_t dataLen, Layer* prevLayer, Packet* packet, ProtocolType protocol = UnknownProtocol)
248
        : m_Data(data), m_DataLen(dataLen), m_Protocol(protocol), m_NextLayer(nullptr), m_PrevLayer(prevLayer),
249
          m_AllocationInfo{ packet, false }
250
0
    {}
251
252
    // Copy c'tor
253
    Layer(const Layer& other);
254
    Layer& operator=(const Layer& other);
255
256
    /// @brief Get a pointer to the Packet this layer is attached to (if any).
257
    /// @return A pointer to the Packet this layer is attached to, or nullptr if the layer is not attached.
258
    Packet* getAttachedPacket()
259
0
    {
260
0
      return m_AllocationInfo.attachedPacket;
261
0
    }
262
263
    /// @brief Get a pointer to the Packet this layer is attached to (if any).
264
    /// @return A const pointer to the Packet this layer is attached to, or nullptr if the layer is not attached.
265
    Packet const* getAttachedPacket() const
266
0
    {
267
0
      return m_AllocationInfo.attachedPacket;
268
0
    }
269
270
    void setNextLayer(Layer* nextLayer)
271
0
    {
272
0
      m_NextLayer = nextLayer;
273
0
    }
274
    void setPrevLayer(Layer* prevLayer)
275
0
    {
276
0
      m_PrevLayer = prevLayer;
277
0
    }
278
279
    // ------ Memory Control Methods -----
280
    // Used by derived classes to request buffer size changes.
281
282
    /// @brief Requests the layer to allocate a new data buffer of the specified length.
283
    ///
284
    /// If the layer is not attached to a Packet, it will allocate a new buffer of the specified length.
285
    /// If the layer is attached to a Packet, it will throw a std::logic_error, as that case is not yet supported.
286
    ///
287
    /// The primary use case for this method is initial allocation of the data buffer in derived classes.
288
    ///
289
    /// @param[in] dataLen The length of the new data buffer.
290
    /// @param[in] zeroInit If true, the new buffer will be zero-initialized.
291
    /// @throws std::runtime_error if the layer already has allocated data.
292
    /// @throws std::logic_error if the layer is attached to a Packet (not yet supported).
293
    void allocData(size_t dataLen, bool zeroInit = true);
294
295
    virtual bool extendLayer(int offsetInLayer, size_t numOfBytesToExtend);
296
    virtual bool shortenLayer(int offsetInLayer, size_t numOfBytesToShorten);
297
298
    bool hasNextLayer() const
299
0
    {
300
0
      return m_NextLayer != nullptr;
301
0
    }
302
303
    /// @brief Construct the next layer in the protocol stack. No validation is performed on the data.
304
    ///
305
    /// This overload infers the Packet from the current layer.
306
    ///
307
    /// @tparam T The type of the layer to construct
308
    /// @tparam Args The types of the arguments to pass to the layer constructor
309
    /// @param data The data to construct the layer from
310
    /// @param dataLen The length of the data
311
    /// @param extraArgs Extra arguments to be forwarded to the layer constructor
312
    /// @return The constructed layer
313
    template <typename T, typename... Args>
314
    Layer* constructNextLayer(uint8_t* data, size_t dataLen, Args&&... extraArgs)
315
    {
316
      return constructNextLayer<T>(data, dataLen, getAttachedPacket(), std::forward<Args>(extraArgs)...);
317
    }
318
319
    /// Construct the next layer in the protocol stack. No validation is performed on the data.
320
    /// @tparam T The type of the layer to construct
321
    /// @tparam Args The types of the arguments to pass to the layer constructor
322
    /// @param[in] data The data to construct the layer from
323
    /// @param[in] dataLen The length of the data
324
    /// @param[in] packet The packet the layer belongs to
325
    /// @param[in] extraArgs Extra arguments to be forwarded to the layer constructor
326
    /// @return The constructed layer
327
    template <typename T, typename... Args>
328
    Layer* constructNextLayer(uint8_t* data, size_t dataLen, Packet* packet, Args&&... extraArgs)
329
    {
330
      if (hasNextLayer())
331
      {
332
        throw std::runtime_error("Next layer already exists");
333
      }
334
335
      Layer* newLayer = new T(data, dataLen, this, packet, std::forward<Args>(extraArgs)...);
336
      setNextLayer(newLayer);
337
      return newLayer;
338
    }
339
340
    /// @brief Construct the next layer in the protocol stack using a factory functor.
341
    ///
342
    /// No validation is performed on the data, outside of what the factory functor may perform.
343
    /// If the factory returns a nullptr, no next layer is set.
344
    ///
345
    /// The factory functor is expected to have the following signature:
346
    /// Layer* factoryFn(uint8_t* data, size_t dataLen, Layer* prevLayer, Packet* packet, ...);
347
    ///
348
    /// This overload infers the Packet from the current layer.
349
    ///
350
    /// @tparam TFactory The factory functor type.
351
    /// @tparam ...Args Parameter pack for extra arguments to pass to the factory functor.
352
    /// @param[in] factoryFn The factory functor to create the layer.
353
    /// @param[in] data The data to construct the layer from
354
    /// @param[in] dataLen The length of the data
355
    /// @param[in] extraArgs Extra arguments to be forwarded to the factory.
356
    /// @return The return value of the factory functor.
357
    template <typename TFactory, typename... Args>
358
    Layer* constructNextLayerFromFactory(TFactory factoryFn, uint8_t* data, size_t dataLen, Args&&... extraArgs)
359
    {
360
      return constructNextLayerFromFactory<TFactory>(factoryFn, data, dataLen, getAttachedPacket(),
361
                                                     std::forward<Args>(extraArgs)...);
362
    }
363
364
    /// @brief Construct the next layer in the protocol stack using a factory functor.
365
    ///
366
    /// No validation is performed on the data, outside of what the factory functor may perform.
367
    /// If the factory returns a nullptr, no next layer is set.
368
    ///
369
    /// The factory functor is expected to have the following signature:
370
    /// Layer* factoryFn(uint8_t* data, size_t dataLen, Layer* prevLayer, Packet* packet, ...);
371
    ///
372
    /// @tparam TFactory The factory functor type.
373
    /// @tparam ...Args Parameter pack for extra arguments to pass to the factory functor.
374
    /// @param[in] factoryFn The factory functor to create the layer.
375
    /// @param[in] data The data to construct the layer from
376
    /// @param[in] dataLen The length of the data
377
    /// @param[in] packet The packet the layer belongs to
378
    /// @param[in] extraArgs Extra arguments to be forwarded to the factory.
379
    /// @return The return value of the factory functor.
380
    template <typename TFactory, typename... Args>
381
    Layer* constructNextLayerFromFactory(TFactory factoryFn, uint8_t* data, size_t dataLen, Packet* packet,
382
                                         Args&&... extraArgs)
383
    {
384
      if (hasNextLayer())
385
      {
386
        throw std::runtime_error("Next layer already exists");
387
      }
388
389
      // cppcheck-suppress redundantInitialization
390
      Layer* newLayer = factoryFn(data, dataLen, this, packet, std::forward<Args>(extraArgs)...);
391
      setNextLayer(newLayer);
392
      return newLayer;
393
    }
394
395
    /// Try to construct the next layer in the protocol stack.
396
    ///
397
    /// This overload infers the Packet from the current layer.
398
    ///
399
    /// The method checks if the data is valid for the layer type T before constructing it by calling
400
    /// T::isDataValid(data, dataLen). If the data is invalid, no layer is constructed and a nullptr is returned.
401
    ///
402
    /// @tparam T The type of the layer to construct
403
    /// @tparam Args The types of the extra arguments to pass to the layer constructor
404
    /// @param[in] data The data to construct the layer from
405
    /// @param[in] dataLen The length of the data
406
    /// @param[in] extraArgs Extra arguments to be forwarded to the layer constructor
407
    /// @return The constructed layer or nullptr if the data is invalid
408
    template <typename T, typename... Args>
409
    Layer* tryConstructNextLayer(uint8_t* data, size_t dataLen, Args&&... extraArgs)
410
    {
411
      return tryConstructNextLayer<T>(data, dataLen, getAttachedPacket(), std::forward<Args>(extraArgs)...);
412
    }
413
414
    /// Try to construct the next layer in the protocol stack.
415
    ///
416
    /// The method checks if the data is valid for the layer type T before constructing it by calling
417
    /// T::isDataValid(data, dataLen). If the data is invalid, no layer is constructed and a nullptr is returned.
418
    ///
419
    /// @tparam T The type of the layer to construct
420
    /// @tparam Args The types of the extra arguments to pass to the layer constructor
421
    /// @param[in] data The data to construct the layer from
422
    /// @param[in] dataLen The length of the data
423
    /// @param[in] packet The packet the layer belongs to
424
    /// @param[in] extraArgs Extra arguments to be forwarded to the layer constructor
425
    /// @return The constructed layer or nullptr if the data is invalid
426
    template <typename T, typename... Args>
427
    Layer* tryConstructNextLayer(uint8_t* data, size_t dataLen, Packet* packet, Args&&... extraArgs)
428
    {
429
      if (T::isDataValid(data, dataLen))
430
      {
431
        return constructNextLayer<T>(data, dataLen, packet, std::forward<Args>(extraArgs)...);
432
      }
433
      return nullptr;
434
    }
435
436
    /// @brief Try to construct the next layer in the protocol stack with a fallback option.
437
    ///
438
    /// This overload infers the Packet from the current layer.
439
    ///
440
    /// The method checks if the data is valid for the layer type T before constructing it by calling
441
    /// T::isDataValid(data, dataLen). If the data is invalid, it constructs the layer of type TFallback.
442
    ///
443
    /// @tparam T The type of the layer to construct
444
    /// @tparam TFallback The fallback layer type to construct if T fails
445
    /// @tparam Args The types of the extra arguments to pass to the layer constructor of T
446
    /// @param[in] data The data to construct the layer from
447
    /// @param[in] dataLen The length of the data
448
    /// @param[in] extraArgs Extra arguments to be forwarded to the layer constructor of T
449
    /// @return The constructed layer of type T or TFallback
450
    /// @remarks The parameters extraArgs are forwarded to the factory function, but not to the TFallback
451
    /// constructor.
452
    template <typename T, typename TFallback, typename... Args>
453
    Layer* tryConstructNextLayerWithFallback(uint8_t* data, size_t dataLen, Args&&... extraArgs)
454
    {
455
      return tryConstructNextLayerWithFallback<T, TFallback>(data, dataLen, getAttachedPacket(),
456
                                                             std::forward<Args>(extraArgs)...);
457
    }
458
459
    /// Try to construct the next layer in the protocol stack with a fallback option.
460
    ///
461
    /// The method checks if the data is valid for the layer type T before constructing it by calling
462
    /// T::isDataValid(data, dataLen). If the data is invalid, it constructs the layer of type TFallback.
463
    ///
464
    /// @tparam T The type of the layer to construct
465
    /// @tparam TFallback The fallback layer type to construct if T fails
466
    /// @tparam Args The types of the extra arguments to pass to the layer constructor of T
467
    /// @param[in] data The data to construct the layer from
468
    /// @param[in] dataLen The length of the data
469
    /// @param[in] packet The packet the layer belongs to
470
    /// @param[in] extraArgs Extra arguments to be forwarded to the layer constructor of T
471
    /// @return The constructed layer of type T or TFallback
472
    /// @remarks The parameters extraArgs are forwarded to the factory function, but not to the TFallback
473
    /// constructor.
474
    template <typename T, typename TFallback, typename... Args>
475
    Layer* tryConstructNextLayerWithFallback(uint8_t* data, size_t dataLen, Packet* packet, Args&&... extraArgs)
476
    {
477
      if (tryConstructNextLayer<T>(data, dataLen, packet, std::forward<Args>(extraArgs)...))
478
      {
479
        return m_NextLayer;
480
      }
481
482
      return constructNextLayer<TFallback>(data, dataLen, packet);
483
    }
484
485
    /// @brief Try to construct the next layer in the protocol stack using a factory functor with a fallback option.
486
    ///
487
    /// The method will attempt to construct the next layer using the provided factory function.
488
    /// If the factory function returns nullptr, indicating failure to create the layer, the method will then
489
    /// construct a layer of type TFallback.
490
    ///
491
    /// The factory functor is expected to have the following signature:
492
    /// Layer* factoryFn(uint8_t* data, size_t dataLen, Layer* prevLayer, Packet* packet, ...);
493
    ///
494
    /// This overload infers the Packet from the current layer.
495
    ///
496
    /// @tparam TFallback The fallback layer type to construct if the factory fails.
497
    /// @tparam TFactory The factory functor type.
498
    /// @tparam ...Args Parameter pack for extra arguments to pass to the factory functor.
499
    /// @param[in] factoryFn The factory functor to create the layer.
500
    /// @param[in] data The data to construct the layer from
501
    /// @param[in] dataLen The length of the data
502
    /// @param[in] extraArgs Extra arguments to be forwarded to the factory.
503
    /// @return The return value of the factory functor.
504
    /// @remarks The parameters extraArgs are forwarded to the factory function, but not to the TFallback
505
    /// constructor.
506
    template <typename TFallback, typename TFactory, typename... Args>
507
    Layer* tryConstructNextLayerFromFactoryWithFallback(TFactory factoryFn, uint8_t* data, size_t dataLen,
508
                                                        Args&&... extraArgs)
509
    {
510
      // Note that the fallback is first to allow template argument deduction of the factory type.
511
      return tryConstructNextLayerFromFactoryWithFallback<TFallback, TFactory>(
512
          factoryFn, data, dataLen, getAttachedPacket(), std::forward<Args>(extraArgs)...);
513
    }
514
515
    /// @brief Try to construct the next layer in the protocol stack using a factory functor with a fallback option.
516
    ///
517
    /// The method will attempt to construct the next layer using the provided factory function.
518
    /// If the factory function returns nullptr, indicating failure to create the layer, the method will then
519
    /// construct a layer of type TFallback.
520
    ///
521
    /// The factory functor is expected to have the following signature:
522
    /// Layer* factoryFn(uint8_t* data, size_t dataLen, Layer* prevLayer, Packet* packet, ...);
523
    ///
524
    /// @tparam TFallback The fallback layer type to construct if the factory fails.
525
    /// @tparam TFactory The factory functor type.
526
    /// @tparam ...Args Parameter pack for extra arguments to pass to the factory functor.
527
    /// @param[in] factoryFn The factory functor to create the layer.
528
    /// @param[in] data The data to construct the layer from
529
    /// @param[in] dataLen The length of the data
530
    /// @param[in] packet The packet the layer belongs to
531
    /// @param[in] extraArgs Extra arguments to be forwarded to the factory.
532
    /// @return The return value of the factory functor.
533
    /// @remarks The parameters extraArgs are forwarded to the factory function, but not to the TFallback
534
    /// constructor.
535
    template <typename TFallback, typename TFactory, typename... Args>
536
    Layer* tryConstructNextLayerFromFactoryWithFallback(TFactory factoryFn, uint8_t* data, size_t dataLen,
537
                                                        Packet* packet, Args&&... extraArgs)
538
    {
539
      auto nextLayer = constructNextLayerFromFactory<TFactory>(factoryFn, data, dataLen, packet,
540
                                                               std::forward<Args>(extraArgs)...);
541
      if (nextLayer != nullptr)
542
      {
543
        return nextLayer;
544
      }
545
546
      // factory failed, construct fallback layer
547
      return constructNextLayer<TFallback>(data, dataLen, packet);
548
    }
549
550
    /// @brief Check if the data is large enough to reinterpret as a type
551
    ///
552
    /// The data must be non-null and at least as large as the type
553
    ///
554
    /// @tparam T The type to reinterpret as
555
    /// @param data The data to check
556
    /// @param dataLen The length of the data
557
    /// @return True if the data is large enough to reinterpret as T, false otherwise
558
    template <typename T> static bool canReinterpretAs(const uint8_t* data, size_t dataLen)
559
0
    {
560
0
      return data != nullptr && dataLen >= sizeof(T);
561
0
    }
Unexecuted instantiation: bool pcpp::Layer::canReinterpretAs<pcpp::arphdr>(unsigned char const*, unsigned long)
Unexecuted instantiation: bool pcpp::Layer::canReinterpretAs<pcpp::iphdr>(unsigned char const*, unsigned long)
562
  };
563
564
  inline std::ostream& operator<<(std::ostream& os, const pcpp::Layer& layer)
565
0
  {
566
0
    os << layer.toString();
567
0
    return os;
568
0
  }
569
}  // namespace pcpp