/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ // Copyright (c) 2006-2008 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #ifndef CHROME_COMMON_IPC_MESSAGE_H__ #define CHROME_COMMON_IPC_MESSAGE_H__ #include #include "base/basictypes.h" #include "base/pickle.h" #include "mojo/core/ports/user_message.h" #include "mojo/core/ports/port_ref.h" #include "mozilla/RefPtr.h" #include "mozilla/TimeStamp.h" #include "mozilla/UniquePtrExtensions.h" #include "mozilla/ipc/ScopedPort.h" #include "nsTArray.h" namespace mozilla { #ifdef FUZZING_SNAPSHOT namespace fuzzing { class IPCFuzzController; } #endif namespace ipc { class MiniTransceiver; } } // namespace mozilla namespace IPC { //------------------------------------------------------------------------------ // Generated by IPDL compiler const char* StringFromIPCMessageType(uint32_t aMessageType); class Channel; class Message; class MessageReader; class MessageWriter; struct LogData; class Message : public mojo::core::ports::UserMessage, public Pickle { public: static const TypeInfo kUserMessageTypeInfo; typedef uint32_t msgid_t; enum NestedLevel { NOT_NESTED = 1, NESTED_INSIDE_SYNC = 2, NESTED_INSIDE_CPOW = 3 }; enum PriorityValue { NORMAL_PRIORITY = 0, INPUT_PRIORITY = 1, VSYNC_PRIORITY = 2, MEDIUMHIGH_PRIORITY = 3, CONTROL_PRIORITY = 4, }; enum MessageCompression { COMPRESSION_NONE, COMPRESSION_ENABLED, COMPRESSION_ALL }; enum Sync { SYNC = 0, ASYNC = 1, }; enum Constructor { NOT_CONSTRUCTOR = 0, CONSTRUCTOR = 1, }; enum Reply { NOT_REPLY = 0, REPLY = 1, }; enum LazySend { EAGER_SEND = 0, LAZY_SEND = 1, }; // The hard limit of handles or file descriptors allowed in a single message. static constexpr size_t MAX_DESCRIPTORS_PER_MESSAGE = 32767; class HeaderFlags { friend class Message; #ifdef FUZZING_SNAPSHOT // IPCFuzzController calls various private API functions on the header. friend class mozilla::fuzzing::IPCFuzzController; #endif enum { NESTED_MASK = 0x0003, PRIO_MASK = 0x001C, SYNC_BIT = 0x0020, REPLY_BIT = 0x0040, REPLY_ERROR_BIT = 0x0080, LAZY_SEND_BIT = 0x0100, COMPRESS_BIT = 0x0200, COMPRESSALL_BIT = 0x0400, CONSTRUCTOR_BIT = 0x0800, RELAY_BIT = 0x1000, }; public: constexpr HeaderFlags() : mFlags(NOT_NESTED) {} explicit constexpr HeaderFlags(NestedLevel level) : mFlags(level) {} constexpr HeaderFlags(NestedLevel level, PriorityValue priority, MessageCompression compression, LazySend lazy_send, Constructor constructor, Sync sync, Reply reply) : mFlags(level | (priority << 2) | (compression == COMPRESSION_ENABLED ? COMPRESS_BIT : compression == COMPRESSION_ALL ? COMPRESSALL_BIT : 0) | (lazy_send == LAZY_SEND ? LAZY_SEND_BIT : 0) | (constructor == CONSTRUCTOR ? CONSTRUCTOR_BIT : 0) | (sync == SYNC ? SYNC_BIT : 0) | (reply == REPLY ? REPLY_BIT : 0)) {} NestedLevel Level() const { return static_cast(mFlags & NESTED_MASK); } PriorityValue Priority() const { return static_cast((mFlags & PRIO_MASK) >> 2); } MessageCompression Compression() const { return ((mFlags & COMPRESS_BIT) ? COMPRESSION_ENABLED : (mFlags & COMPRESSALL_BIT) ? COMPRESSION_ALL : COMPRESSION_NONE); } bool IsLazySend() const { return (mFlags & LAZY_SEND_BIT) != 0; } bool IsConstructor() const { return (mFlags & CONSTRUCTOR_BIT) != 0; } bool IsSync() const { return (mFlags & SYNC_BIT) != 0; } bool IsReply() const { return (mFlags & REPLY_BIT) != 0; } bool IsReplyError() const { return (mFlags & REPLY_ERROR_BIT) != 0; } bool IsRelay() const { return (mFlags & RELAY_BIT) != 0; } private: void SetConstructor() { mFlags |= CONSTRUCTOR_BIT; } void SetSync() { mFlags |= SYNC_BIT; } void SetReply() { mFlags |= REPLY_BIT; } void SetReplyError() { mFlags |= REPLY_ERROR_BIT; } void SetRelay(bool relay) { if (relay) { mFlags |= RELAY_BIT; } else { mFlags &= ~RELAY_BIT; } } uint32_t mFlags; }; virtual ~Message(); // Initialize a message with a user-defined type, priority value, and // destination WebView ID. Message(int32_t routing_id, msgid_t type, uint32_t segmentCapacity = 0, // 0 for the default capacity. HeaderFlags flags = HeaderFlags()); Message(const char* data, int data_len); Message(const Message&) = delete; Message(Message&&) = delete; Message& operator=(const Message&) = delete; Message& operator=(Message&&) = delete; // Helper method for the common case (default segmentCapacity, recording // the write latency of messages) of IPDL message creation. This helps // move the malloc and some of the parameter setting out of autogenerated // code. static mozilla::UniquePtr IPDLMessage(int32_t routing_id, msgid_t type, uint32_t segmentCapacity, HeaderFlags flags); // One-off constructors for special error-handling messages. static mozilla::UniquePtr ForSyncDispatchError(NestedLevel level); NestedLevel nested_level() const { return header()->flags.Level(); } PriorityValue priority() const { return header()->flags.Priority(); } bool is_constructor() const { return header()->flags.IsConstructor(); } // True if this is a synchronous message. bool is_sync() const { return header()->flags.IsSync(); } MessageCompression compress_type() const { return header()->flags.Compression(); } bool is_lazy_send() const { return header()->flags.IsLazySend(); } bool is_reply() const { return header()->flags.IsReply(); } bool is_reply_error() const { return header()->flags.IsReplyError(); } msgid_t type() const { return header()->type; } int32_t routing_id() const { return header()->routing; } void set_routing_id(int32_t new_id) { header()->routing = new_id; } int32_t transaction_id() const { return header()->txid; } void set_transaction_id(int32_t txid) { header()->txid = txid; } int32_t seqno() const { return header()->seqno; } void set_seqno(int32_t aSeqno) { header()->seqno = aSeqno; } const char* name() const { return StringFromIPCMessageType(type()); } uint32_t num_handles() const; bool is_relay() const { return header()->flags.IsRelay(); } void set_relay(bool new_relay) { header()->flags.SetRelay(new_relay); } template static bool Dispatch(const Message* msg, T* obj, void (T::*func)()) { (obj->*func)(); return true; } template static bool Dispatch(const Message* msg, T* obj, void (T::*func)() const) { (obj->*func)(); return true; } template static bool Dispatch(const Message* msg, T* obj, void (T::*func)(const Message&)) { (obj->*func)(*msg); return true; } template static bool Dispatch(const Message* msg, T* obj, void (T::*func)(const Message&) const) { (obj->*func)(*msg); return true; } // We should not be sending messages that are smaller than our header size. void AssertAsLargeAsHeader() const; // UserMessage implementation size_t GetSizeIfSerialized() const override { return size(); } bool WillBeRoutedExternally(mojo::core::ports::UserMessageEvent&) override; // Write the given footer bytes to the end of the current message. The // footer's `data_len` will be padded to a multiple of 4 bytes. void WriteFooter(const void* data, uint32_t data_len); // Read a footer written with `WriteFooter` from the end of the message, given // a buffer and the length of the footer. If `truncate` is true, the message // will be truncated, removing the footer. [[nodiscard]] bool ReadFooter(void* buffer, uint32_t buffer_len, bool truncate); uint32_t event_footer_size() const { return header()->event_footer_size; } void set_event_footer_size(uint32_t size) { header()->event_footer_size = size; } static int HeaderSize() { return sizeof(Header); } // Figure out how big the message starting at range_start is. Returns 0 if // there's no enough data to determine (i.e., if [range_start, range_end) does // not contain enough of the message header to know the size). static uint32_t MessageSize(const char* range_start, const char* range_end) { return Pickle::MessageSize(HeaderSize(), range_start, range_end); } bool WriteFileHandle(mozilla::UniqueFileHandle handle); // WARNING: This method is marked as `const` so it can be called when // deserializing the message, but will mutate it, consuming the handle. bool ConsumeFileHandle(PickleIterator* iter, mozilla::UniqueFileHandle* handle) const; // Called when receiving an IPC message to attach file handles which were // received from IPC. Must only be called when there are no handles on this // IPC::Message. void SetAttachedFileHandles(nsTArray handles); #if defined(OS_MACOSX) || defined(OS_IOS) void set_fd_cookie(uint32_t cookie) { header()->cookie = cookie; } uint32_t fd_cookie() const { return header()->cookie; } #endif void WritePort(mozilla::ipc::ScopedPort port); // This method consumes the port from the message, preventing the message's // destructor from destroying the port and meaning that future attempts to // read this port will instead produce an invalid port. // // WARNING: This method is marked as `const` so it can be called when // deserializing the message, but will mutate the message. bool ConsumePort(PickleIterator* iter, mozilla::ipc::ScopedPort* port) const; // Called when loading an IPC message to attach ports which were recieved form // IPC. Must only be called when there are no ports on this IPC::Message. void SetAttachedPorts(nsTArray ports); #if defined(OS_MACOSX) || defined(OS_IOS) bool WriteMachSendRight(mozilla::UniqueMachSendRight port); // WARNING: This method is marked as `const` so it can be called when // deserializing the message, but will mutate it, consuming the send rights. bool ConsumeMachSendRight(PickleIterator* iter, mozilla::UniqueMachSendRight* port) const; uint32_t num_send_rights() const; #endif uint32_t num_relayed_attachments() const { #if defined(OS_WIN) return num_handles(); #elif defined(OS_MACOSX) || defined(OS_IOS) return num_send_rights(); #else return 0; #endif } #ifdef FUZZING_SNAPSHOT bool IsFuzzMsg() { return isFuzzMsg; } void SetFuzzMsg() { isFuzzMsg = true; } #endif friend class Channel; friend class MessageReplyDeserializer; friend class SyncMessage; friend class mozilla::ipc::MiniTransceiver; #if !defined(OS_MACOSX) && !defined(OS_IOS) && !defined(FUZZING_SNAPSHOT) protected: #endif struct Header : Pickle::Header { int32_t routing; // ID of the view that this message is destined for msgid_t type; // specifies the user-defined message type HeaderFlags flags; // specifies control flags for the message uint32_t num_handles; // the number of handles included with this message #if defined(OS_MACOSX) || defined(OS_IOS) uint32_t cookie; // cookie to ACK that the descriptors have been read. uint32_t num_send_rights; // the number of mach send rights included with // this message #endif // For sync messages, a transaction ID for message ordering. int32_t txid; // Sequence number int32_t seqno; // Size of the message's event footer uint32_t event_footer_size; }; Header* header() { return headerT
(); } const Header* header() const { return headerT
(); } // The set of file handles which are attached to this message. // // Mutable, as this array can be mutated during `ReadHandle` when // deserializing a message. mutable nsTArray attached_handles_; // The set of mojo ports which are attached to this message. // // Mutable, as this array can be mutated during `ConsumePort` when // deserializing a message. mutable nsTArray attached_ports_; #if defined(OS_MACOSX) || defined(OS_IOS) // The set of mach send rights which are attached to this message. // // Mutable, as this array can be mutated during `ConsumeMachSendRight` when // deserializing a message. mutable nsTArray attached_send_rights_; #endif #ifdef FUZZING_SNAPSHOT bool isFuzzMsg = false; #endif }; //------------------------------------------------------------------------------ } // namespace IPC enum SpecialRoutingIDs { // indicates that we don't have a routing ID yet. MSG_ROUTING_NONE = kint32min, // indicates a general message not sent to a particular tab. MSG_ROUTING_CONTROL = kint32max }; #define IPC_REPLY_ID 0xFFF0 // Special message id for replies #define IPC_LOGGING_ID 0xFFF1 // Special message id for logging #endif // CHROME_COMMON_IPC_MESSAGE_H__