content/public/common/zygote_fork_delegate_linux.h - chromium/src - Git at Google

 // Copyright (c) 2012 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 CONTENT_PUBLIC_COMMON_ZYGOTE_FORK_DELEGATE_LINUX_H_
 #define CONTENT_PUBLIC_COMMON_ZYGOTE_FORK_DELEGATE_LINUX_H_

 #include <unistd.h>

 #include <string>
 #include <vector>

 // TODO(jln) base::TerminationStatus should be forward declared when switching
 // to C++11.
 #include "base/process/kill.h"

 namespace content {

 // The ZygoteForkDelegate allows the Chrome Linux zygote to delegate
 // fork operations to another class that knows how to do some
 // specialized version of fork.
 class ZygoteForkDelegate {
  public:
   // A ZygoteForkDelegate is created during Chrome linux zygote
   // initialization, and provides "fork()" functionality as an
   // alternative to forking the zygote.  A new delegate is passed in
   // as an argument to ZygoteMain().
   virtual ~ZygoteForkDelegate() {}

   // Initialization happens in the zygote after it has been
   // started by ZygoteMain.
   // If |enable_layer1_sandbox| is true, the delegate must enable a
   // layer-1 sandbox such as the setuid sandbox.
   virtual void Init(int sandboxdesc, bool enable_layer1_sandbox) = 0;

   // After Init, supply a UMA_HISTOGRAM_ENUMERATION the delegate would like
   // reported to the browser process.  (Note: Because these reports are
   // piggy-backed onto fork responses that don't otherwise contain UMA reports,
   // this method may not be called until much later.)
   virtual void InitialUMA(std::string* uma_name,
                           int* uma_sample,
                           int* uma_boundary_value) = 0;

   // Returns 'true' if the delegate would like to handle a given fork
   // request.  Otherwise returns false.  Optionally, fills in uma_name et al
   // with a report the helper wants to make via UMA_HISTOGRAM_ENUMERATION.
   virtual bool CanHelp(const std::string& process_type, std::string* uma_name,
                        int* uma_sample, int* uma_boundary_value) = 0;

   // Indexes of FDs in the vector passed to Fork().
   enum {
     // Used to pass in the descriptor for talking to the Browser.
     // Because the children use ChannelMojo, this is actually the Mojo fd.
     kBrowserFDIndex,
     // The PID oracle is used in the protocol for discovering the
     // child process's real PID from within the SUID sandbox.
     // The child process is required to write to the socket after
     // successfully forking.
     kPIDOracleFDIndex,
     kNumPassedFDs  // Number of FDs in the vector passed to Fork().
   };

   // Delegate forks, returning a -1 on failure. Outside the
   // suid sandbox, Fork() returns the Linux process ID.
   // This method is not aware of any potential pid namespaces, so it'll
   // return a raw pid just like fork() would.
   // Delegate is responsible for communicating the channel ID to the
   // newly created child process.
   virtual pid_t Fork(const std::string& process_type,
                      const std::vector<int>& fds,
                      const std::string& channel_id) = 0;

   // The fork delegate must also assume the role of waiting for its children
   // since the caller will not be their parents and cannot do it. |pid| here
   // should be a pid that has been returned by the Fork() method. i.e. This
   // method is completely unaware of eventual PID namespaces due to sandboxing.
   // |known_dead| indicates that the process is already dead and that a
   // blocking wait() should be performed. In this case, GetTerminationStatus()
   // will send a SIGKILL to the target process first.
   virtual bool GetTerminationStatus(pid_t pid, bool known_dead,
                                     base::TerminationStatus* status,
                                     int* exit_code) = 0;
 };

 }  // namespace content

 #endif  // CONTENT_PUBLIC_COMMON_ZYGOTE_FORK_DELEGATE_LINUX_H_
	// Copyright (c) 2012 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 CONTENT_PUBLIC_COMMON_ZYGOTE_FORK_DELEGATE_LINUX_H_
	#define CONTENT_PUBLIC_COMMON_ZYGOTE_FORK_DELEGATE_LINUX_H_

	#include <unistd.h>

	#include <string>
	#include <vector>

	// TODO(jln) base::TerminationStatus should be forward declared when switching
	// to C++11.
	#include "base/process/kill.h"

	namespace content {

	// The ZygoteForkDelegate allows the Chrome Linux zygote to delegate
	// fork operations to another class that knows how to do some
	// specialized version of fork.
	class ZygoteForkDelegate {
	public:
	// A ZygoteForkDelegate is created during Chrome linux zygote
	// initialization, and provides "fork()" functionality as an
	// alternative to forking the zygote. A new delegate is passed in
	// as an argument to ZygoteMain().
	virtual ~ZygoteForkDelegate() {}

	// Initialization happens in the zygote after it has been
	// started by ZygoteMain.
	// If \|enable_layer1_sandbox\| is true, the delegate must enable a
	// layer-1 sandbox such as the setuid sandbox.
	virtual void Init(int sandboxdesc, bool enable_layer1_sandbox) = 0;

	// After Init, supply a UMA_HISTOGRAM_ENUMERATION the delegate would like
	// reported to the browser process. (Note: Because these reports are
	// piggy-backed onto fork responses that don't otherwise contain UMA reports,
	// this method may not be called until much later.)
	virtual void InitialUMA(std::string* uma_name,
	int* uma_sample,
	int* uma_boundary_value) = 0;

	// Returns 'true' if the delegate would like to handle a given fork
	// request. Otherwise returns false. Optionally, fills in uma_name et al
	// with a report the helper wants to make via UMA_HISTOGRAM_ENUMERATION.
	virtual bool CanHelp(const std::string& process_type, std::string* uma_name,
	int* uma_sample, int* uma_boundary_value) = 0;

	// Indexes of FDs in the vector passed to Fork().
	enum {
	// Used to pass in the descriptor for talking to the Browser.
	// Because the children use ChannelMojo, this is actually the Mojo fd.
	kBrowserFDIndex,
	// The PID oracle is used in the protocol for discovering the
	// child process's real PID from within the SUID sandbox.
	// The child process is required to write to the socket after
	// successfully forking.
	kPIDOracleFDIndex,
	kNumPassedFDs // Number of FDs in the vector passed to Fork().
	};

	// Delegate forks, returning a -1 on failure. Outside the
	// suid sandbox, Fork() returns the Linux process ID.
	// This method is not aware of any potential pid namespaces, so it'll
	// return a raw pid just like fork() would.
	// Delegate is responsible for communicating the channel ID to the
	// newly created child process.
	virtual pid_t Fork(const std::string& process_type,
	const std::vector<int>& fds,
	const std::string& channel_id) = 0;

	// The fork delegate must also assume the role of waiting for its children
	// since the caller will not be their parents and cannot do it. \|pid\| here
	// should be a pid that has been returned by the Fork() method. i.e. This
	// method is completely unaware of eventual PID namespaces due to sandboxing.
	// \|known_dead\| indicates that the process is already dead and that a
	// blocking wait() should be performed. In this case, GetTerminationStatus()
	// will send a SIGKILL to the target process first.
	virtual bool GetTerminationStatus(pid_t pid, bool known_dead,
	base::TerminationStatus* status,
	int* exit_code) = 0;
	};

	} // namespace content

	#endif // CONTENT_PUBLIC_COMMON_ZYGOTE_FORK_DELEGATE_LINUX_H_