// Copyright 2013 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 MOJO_SYSTEM_MESSAGE_IN_TRANSIT_H_ #define MOJO_SYSTEM_MESSAGE_IN_TRANSIT_H_ #include #include #include #include "base/macros.h" #include "base/memory/aligned_memory.h" #include "base/memory/scoped_ptr.h" #include "mojo/system/dispatcher.h" #include "mojo/system/system_impl_export.h" namespace mojo { namespace system { class Channel; class TransportData; // This class is used to represent data in transit. It is thread-unsafe. // // |MessageInTransit| buffers: // // A |MessageInTransit| can be serialized by writing the main buffer and then, // if it has one, the transport data buffer. Both buffers are // |kMessageAlignment|-byte aligned and a multiple of |kMessageAlignment| bytes // in size. // // The main buffer consists of the header (of type |Header|, which is an // internal detail of this class) followed immediately by the message data // (accessed by |bytes()| and of size |num_bytes()|, and also // |kMessageAlignment|-byte aligned), and then any padding needed to make the // main buffer a multiple of |kMessageAlignment| bytes in size. // // See |TransportData| for a description of the (serialized) transport data // buffer. class MOJO_SYSTEM_IMPL_EXPORT MessageInTransit { public: typedef uint16_t Type; // Messages that are forwarded to |MessagePipeEndpoint|s. static const Type kTypeMessagePipeEndpoint = 0; // Messages that are forwarded to |MessagePipe|s. static const Type kTypeMessagePipe = 1; // Messages that are consumed by the channel. static const Type kTypeChannel = 2; typedef uint16_t Subtype; // Subtypes for type |kTypeMessagePipeEndpoint|: static const Subtype kSubtypeMessagePipeEndpointData = 0; // Subtypes for type |kTypeMessagePipe|: // Nothing currently. // Subtypes for type |kTypeChannel|: static const Subtype kSubtypeChannelRunMessagePipeEndpoint = 0; static const Subtype kSubtypeChannelRemoveMessagePipeEndpoint = 1; static const Subtype kSubtypeChannelRemoveMessagePipeEndpointAck = 2; typedef uint32_t EndpointId; // Never a valid endpoint ID. static const EndpointId kInvalidEndpointId = 0; // Messages (the header and data) must always be aligned to a multiple of this // quantity (which must be a power of 2). static const size_t kMessageAlignment = 8; // Forward-declare |Header| so that |View| can use it: private: struct Header; public: // This represents a view of serialized message data in a raw buffer. class MOJO_SYSTEM_IMPL_EXPORT View { public: // Constructs a view from the given buffer of the given size. (The size must // be as provided by |MessageInTransit::GetNextMessageSize()|.) The buffer // must remain alive/unmodified through the lifetime of this object. // |buffer| should be |kMessageAlignment|-byte aligned. View(size_t message_size, const void* buffer); // Checks that the given |View| appears to be for a valid message, within // predetermined limits (e.g., |num_bytes()| and |main_buffer_size()|, that // |transport_data_buffer()|/|transport_data_buffer_size()| is for valid // transport data -- see |TransportData::ValidateBuffer()|). // // It returns true (and leaves |error_message| alone) if this object appears // to be a valid message (according to the above) and false, pointing // |*error_message| to a suitable error message, if not. bool IsValid(const char** error_message) const; // API parallel to that for |MessageInTransit| itself (mostly getters for // header data). const void* main_buffer() const { return buffer_; } size_t main_buffer_size() const { return RoundUpMessageAlignment(sizeof(Header) + header()->num_bytes); } const void* transport_data_buffer() const { return (total_size() > main_buffer_size()) ? static_cast(buffer_) + main_buffer_size() : NULL; } size_t transport_data_buffer_size() const { return total_size() - main_buffer_size(); } size_t total_size() const { return header()->total_size; } uint32_t num_bytes() const { return header()->num_bytes; } const void* bytes() const { return static_cast(buffer_) + sizeof(Header); } Type type() const { return header()->type; } Subtype subtype() const { return header()->subtype; } EndpointId source_id() const { return header()->source_id; } EndpointId destination_id() const { return header()->destination_id; } private: const Header* header() const { return static_cast(buffer_); } const void* const buffer_; // Though this struct is trivial, disallow copy and assign, since it doesn't // own its data. (If you're copying/assigning this, you're probably doing // something wrong.) DISALLOW_COPY_AND_ASSIGN(View); }; // |bytes| is optional; if null, the message data will be zero-initialized. MessageInTransit(Type type, Subtype subtype, uint32_t num_bytes, const void* bytes); // Constructs a |MessageInTransit| from a |View|. explicit MessageInTransit(const View& message_view); ~MessageInTransit(); // Gets the size of the next message from |buffer|, which has |buffer_size| // bytes currently available, returning true and setting |*next_message_size| // on success. |buffer| should be aligned on a |kMessageAlignment| boundary // (and on success, |*next_message_size| will be a multiple of // |kMessageAlignment|). // TODO(vtl): In |RawChannelPosix|, the alignment requirements are currently // satisified on a faith-based basis. static bool GetNextMessageSize(const void* buffer, size_t buffer_size, size_t* next_message_size); // Makes this message "own" the given set of dispatchers. The dispatchers must // not be referenced from anywhere else (in particular, not from the handle // table), i.e., each dispatcher must have a reference count of 1. This // message must not already have dispatchers. void SetDispatchers(scoped_ptr dispatchers); // Serializes any dispatchers to the secondary buffer. This message must not // already have a secondary buffer (so this must only be called once). The // caller must ensure (e.g., by holding on to a reference) that |channel| // stays alive through the call. void SerializeAndCloseDispatchers(Channel* channel); // Gets the main buffer and its size (in number of bytes), respectively. const void* main_buffer() const { return main_buffer_.get(); } size_t main_buffer_size() const { return main_buffer_size_; } // Gets the transport data buffer (if any). const TransportData* transport_data() const { return transport_data_.get(); } // Gets the total size of the message (see comment in |Header|, below). size_t total_size() const { return header()->total_size; } // Gets the size of the message data. uint32_t num_bytes() const { return header()->num_bytes; } // Gets the message data (of size |num_bytes()| bytes). const void* bytes() const { return main_buffer_.get() + sizeof(Header); } void* bytes() { return main_buffer_.get() + sizeof(Header); } Type type() const { return header()->type; } Subtype subtype() const { return header()->subtype; } EndpointId source_id() const { return header()->source_id; } EndpointId destination_id() const { return header()->destination_id; } void set_source_id(EndpointId source_id) { header()->source_id = source_id; } void set_destination_id(EndpointId destination_id) { header()->destination_id = destination_id; } // Gets the dispatchers attached to this message; this may return null if // there are none. Note that the caller may mutate the set of dispatchers // (e.g., take ownership of all the dispatchers, leaving the vector empty). DispatcherVector* dispatchers() { return dispatchers_.get(); } // Returns true if this message has dispatchers attached. bool has_dispatchers() const { return dispatchers_ && !dispatchers_->empty(); } // Rounds |n| up to a multiple of |kMessageAlignment|. static inline size_t RoundUpMessageAlignment(size_t n) { return (n + kMessageAlignment - 1) & ~(kMessageAlignment - 1); } private: // To allow us to make compile-assertions about |Header| in the .cc file. struct PrivateStructForCompileAsserts; // Header for the data (main buffer). Must be a multiple of // |kMessageAlignment| bytes in size. Must be POD. struct Header { // Total size of the message, including the header, the message data // ("bytes") including padding (to make it a multiple of |kMessageAlignment| // bytes), and serialized handle information. Note that this may not be the // correct value if dispatchers are attached but // |SerializeAndCloseDispatchers()| has not been called. uint32_t total_size; Type type; // 2 bytes. Subtype subtype; // 2 bytes. EndpointId source_id; // 4 bytes. EndpointId destination_id; // 4 bytes. // Size of actual message data. uint32_t num_bytes; uint32_t unused; }; const Header* header() const { return reinterpret_cast(main_buffer_.get()); } Header* header() { return reinterpret_cast(main_buffer_.get()); } void UpdateTotalSize(); const size_t main_buffer_size_; const scoped_ptr main_buffer_; // Never null. scoped_ptr transport_data_; // May be null. // Any dispatchers that may be attached to this message. These dispatchers // should be "owned" by this message, i.e., have a ref count of exactly 1. (We // allow a dispatcher entry to be null, in case it couldn't be duplicated for // some reason.) scoped_ptr dispatchers_; DISALLOW_COPY_AND_ASSIGN(MessageInTransit); }; } // namespace system } // namespace mojo #endif // MOJO_SYSTEM_MESSAGE_IN_TRANSIT_H_