Adding instrumentation to locate the source of jankiness.
[chromium-blink-merge.git] / ipc / ipc_channel.h
blobf6bd5044c14af5150e12a9a964a382d7d630c4cc
1 // Copyright (c) 2012 The Chromium Authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
5 #ifndef IPC_IPC_CHANNEL_H_
6 #define IPC_IPC_CHANNEL_H_
8 #include <string>
10 #if defined(OS_POSIX)
11 #include <sys/types.h>
12 #endif
14 #include "base/compiler_specific.h"
15 #include "base/process/process.h"
16 #include "ipc/ipc_channel_handle.h"
17 #include "ipc/ipc_message.h"
18 #include "ipc/ipc_sender.h"
20 namespace IPC {
22 class Listener;
24 //------------------------------------------------------------------------------
25 // See
26 // http://www.chromium.org/developers/design-documents/inter-process-communication
27 // for overview of IPC in Chromium.
29 // Channels are implemented using named pipes on Windows, and
30 // socket pairs (or in some special cases unix domain sockets) on POSIX.
31 // On Windows we access pipes in various processes by name.
32 // On POSIX we pass file descriptors to child processes and assign names to them
33 // in a lookup table.
34 // In general on POSIX we do not use unix domain sockets due to security
35 // concerns and the fact that they can leave garbage around the file system
36 // (MacOS does not support abstract named unix domain sockets).
37 // You can use unix domain sockets if you like on POSIX by constructing the
38 // the channel with the mode set to one of the NAMED modes. NAMED modes are
39 // currently used by automation and service processes.
41 class IPC_EXPORT Channel : public Sender {
42 // Security tests need access to the pipe handle.
43 friend class ChannelTest;
45 public:
46 // Flags to test modes
47 enum ModeFlags {
48 MODE_NO_FLAG = 0x0,
49 MODE_SERVER_FLAG = 0x1,
50 MODE_CLIENT_FLAG = 0x2,
51 MODE_NAMED_FLAG = 0x4,
52 #if defined(OS_POSIX)
53 MODE_OPEN_ACCESS_FLAG = 0x8, // Don't restrict access based on client UID.
54 #endif
57 // Some Standard Modes
58 // TODO(morrita): These are under deprecation work. You should use Create*()
59 // functions instead.
60 enum Mode {
61 MODE_NONE = MODE_NO_FLAG,
62 MODE_SERVER = MODE_SERVER_FLAG,
63 MODE_CLIENT = MODE_CLIENT_FLAG,
64 MODE_NAMED_SERVER = MODE_SERVER_FLAG | MODE_NAMED_FLAG,
65 MODE_NAMED_CLIENT = MODE_CLIENT_FLAG | MODE_NAMED_FLAG,
66 #if defined(OS_POSIX)
67 MODE_OPEN_NAMED_SERVER = MODE_OPEN_ACCESS_FLAG | MODE_SERVER_FLAG |
68 MODE_NAMED_FLAG
69 #endif
72 // Messages internal to the IPC implementation are defined here.
73 // Uses Maximum value of message type (uint16), to avoid conflicting
74 // with normal message types, which are enumeration constants starting from 0.
75 enum {
76 // The Hello message is sent by the peer when the channel is connected.
77 // The message contains just the process id (pid).
78 // The message has a special routing_id (MSG_ROUTING_NONE)
79 // and type (HELLO_MESSAGE_TYPE).
80 HELLO_MESSAGE_TYPE = kuint16max,
81 // The CLOSE_FD_MESSAGE_TYPE is used in the IPC class to
82 // work around a bug in sendmsg() on Mac. When an FD is sent
83 // over the socket, a CLOSE_FD_MESSAGE is sent with hops = 2.
84 // The client will return the message with hops = 1, *after* it
85 // has received the message that contains the FD. When we
86 // receive it again on the sender side, we close the FD.
87 CLOSE_FD_MESSAGE_TYPE = HELLO_MESSAGE_TYPE - 1
90 // The maximum message size in bytes. Attempting to receive a message of this
91 // size or bigger results in a channel error.
92 static const size_t kMaximumMessageSize = 128 * 1024 * 1024;
94 // Amount of data to read at once from the pipe.
95 static const size_t kReadBufferSize = 4 * 1024;
97 // Initialize a Channel.
99 // |channel_handle| identifies the communication Channel. For POSIX, if
100 // the file descriptor in the channel handle is != -1, the channel takes
101 // ownership of the file descriptor and will close it appropriately, otherwise
102 // it will create a new descriptor internally.
103 // |listener| receives a callback on the current thread for each newly
104 // received message.
106 // There are four type of modes how channels operate:
108 // - Server and named server: In these modes, the Channel is
109 // responsible for settingb up the IPC object
110 // - An "open" named server: It accepts connections from ANY client.
111 // The caller must then implement their own access-control based on the
112 // client process' user Id.
113 // - Client and named client: In these mode, the Channel merely
114 // connects to the already established IPC object.
116 // Each mode has its own Create*() API to create the Channel object.
118 // TODO(morrita): Replace CreateByModeForProxy() with one of above Create*().
120 static scoped_ptr<Channel> Create(
121 const IPC::ChannelHandle &channel_handle, Mode mode, Listener* listener);
123 static scoped_ptr<Channel> CreateClient(
124 const IPC::ChannelHandle &channel_handle, Listener* listener);
126 // Channels on Windows are named by default and accessible from other
127 // processes. On POSIX channels are anonymous by default and not accessible
128 // from other processes. Named channels work via named unix domain sockets.
129 // On Windows MODE_NAMED_SERVER is equivalent to MODE_SERVER and
130 // MODE_NAMED_CLIENT is equivalent to MODE_CLIENT.
131 static scoped_ptr<Channel> CreateNamedServer(
132 const IPC::ChannelHandle &channel_handle, Listener* listener);
133 static scoped_ptr<Channel> CreateNamedClient(
134 const IPC::ChannelHandle &channel_handle, Listener* listener);
135 #if defined(OS_POSIX)
136 // An "open" named server accepts connections from ANY client.
137 // The caller must then implement their own access-control based on the
138 // client process' user Id.
139 static scoped_ptr<Channel> CreateOpenNamedServer(
140 const IPC::ChannelHandle &channel_handle, Listener* listener);
141 #endif
142 static scoped_ptr<Channel> CreateServer(
143 const IPC::ChannelHandle &channel_handle, Listener* listener);
146 virtual ~Channel();
148 // Connect the pipe. On the server side, this will initiate
149 // waiting for connections. On the client, it attempts to
150 // connect to a pre-existing pipe. Note, calling Connect()
151 // will not block the calling thread and may complete
152 // asynchronously.
153 virtual bool Connect() WARN_UNUSED_RESULT = 0;
155 // Close this Channel explicitly. May be called multiple times.
156 // On POSIX calling close on an IPC channel that listens for connections will
157 // cause it to close any accepted connections, and it will stop listening for
158 // new connections. If you just want to close the currently accepted
159 // connection and listen for new ones, use ResetToAcceptingConnectionState.
160 virtual void Close() = 0;
162 // Get the process ID for the connected peer.
164 // Returns base::kNullProcessId if the peer is not connected yet. Watch out
165 // for race conditions. You can easily get a channel to another process, but
166 // if your process has not yet processed the "hello" message from the remote
167 // side, this will fail. You should either make sure calling this is either
168 // in response to a message from the remote side (which guarantees that it's
169 // been connected), or you wait for the "connected" notification on the
170 // listener.
171 virtual base::ProcessId GetPeerPID() const = 0;
173 // Get its own process id. This value is told to the peer.
174 virtual base::ProcessId GetSelfPID() const = 0;
176 // Send a message over the Channel to the listener on the other end.
178 // |message| must be allocated using operator new. This object will be
179 // deleted once the contents of the Message have been sent.
180 virtual bool Send(Message* message) = 0;
182 #if defined(OS_POSIX) && !defined(OS_NACL)
183 // On POSIX an IPC::Channel wraps a socketpair(), this method returns the
184 // FD # for the client end of the socket.
185 // This method may only be called on the server side of a channel.
186 // This method can be called on any thread.
187 virtual int GetClientFileDescriptor() const = 0;
189 // Same as GetClientFileDescriptor, but transfers the ownership of the
190 // file descriptor to the caller.
191 // This method can be called on any thread.
192 virtual int TakeClientFileDescriptor() = 0;
193 #endif // defined(OS_POSIX) && !defined(OS_NACL)
195 // Returns true if a named server channel is initialized on the given channel
196 // ID. Even if true, the server may have already accepted a connection.
197 static bool IsNamedServerInitialized(const std::string& channel_id);
199 #if !defined(OS_NACL)
200 // Generates a channel ID that's non-predictable and unique.
201 static std::string GenerateUniqueRandomChannelID();
203 // Generates a channel ID that, if passed to the client as a shared secret,
204 // will validate that the client's authenticity. On platforms that do not
205 // require additional this is simply calls GenerateUniqueRandomChannelID().
206 // For portability the prefix should not include the \ character.
207 static std::string GenerateVerifiedChannelID(const std::string& prefix);
208 #endif
210 #if defined(OS_LINUX)
211 // Sandboxed processes live in a PID namespace, so when sending the IPC hello
212 // message from client to server we need to send the PID from the global
213 // PID namespace.
214 static void SetGlobalPid(int pid);
215 #endif
217 #if defined(OS_ANDROID)
218 // Most tests are single process and work the same on all platforms. However
219 // in some cases we want to test multi-process, and Android differs in that it
220 // can't 'exec' after forking. This callback resets any data in the forked
221 // process such that it acts similar to if it was exec'd, for tests.
222 static void NotifyProcessForkedForTesting();
223 #endif
227 #if defined(OS_POSIX)
228 // SocketPair() creates a pair of socket FDs suitable for using with
229 // IPC::Channel.
230 IPC_EXPORT bool SocketPair(int* fd1, int* fd2);
231 #endif
233 } // namespace IPC
235 #endif // IPC_IPC_CHANNEL_H_