src/parsec/disk-image/parsec/parsec-benchmark/pkgs/tools/cmake/src/Source/cmWin32ProcessExecution.h - public/gem5-resources - Git at Google

 /*=========================================================================

   Program:   CMake - Cross-Platform Makefile Generator
   Module:    $RCSfile: cmWin32ProcessExecution.h,v $
   Language:  C++
   Date:      $Date: 2012/03/29 17:21:08 $
   Version:   $Revision: 1.1.1.1 $

   Copyright (c) 2002 Kitware, Inc., Insight Consortium.  All rights reserved.
   See Copyright.txt or http://www.cmake.org/HTML/Copyright.html for details.

      This software is distributed WITHOUT ANY WARRANTY; without even
      the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
      PURPOSE.  See the above copyright notices for more information.

 =========================================================================*/
 #ifndef cmWin32ProcessExecution_h
 #define cmWin32ProcessExecution_h

 #include "cmStandardIncludes.h"
 #include "windows.h"

 class cmMakefile;

 /** \class cmWin32ProcessExecution
  * \brief A process executor for windows
  *
  * cmWin32ProcessExecution is a class that provides a "clean" way of
  * executing processes on Windows. It is modified code from Python 2.1
  * distribution.
  *
  * Portable 'popen' replacement for Win32.
  *
  * Written by Bill Tutt <billtut@microsoft.com>.  Minor tweaks and 2.0
  * integration by Fredrik Lundh <fredrik@pythonware.com> Return code
  * handling by David Bolen <db3l@fitlinxx.com>.
  *
  * Modified for CMake.
  *
  * For more information, please check Microsoft Knowledge Base
  * Articles Q190351 and Q150956.
  */
 class cmWin32ProcessExecution
 {
 public:
   cmWin32ProcessExecution()
     {
     this->HideWindows = false;
     this->SetConsoleSpawn("w9xpopen.exe");
     this->Initialize();
     }
   ~cmWin32ProcessExecution();
   ///! If true windows will be created hidden.
   void SetHideWindows(bool v) { this->HideWindows = v;  }

   /**
    * Initialize the process execution datastructure. Do not call while
    * running the process.
    */
   void Initialize()
     {
     this->ProcessHandle = 0;
     this->ExitValue    = -1;
     // Comment this out. Maybe we will need it in the future.
     // file IO access to the process might be cool.
     //this->StdIn  =  0;
     //this->StdOut =  0;
     //this->StdErr =  0;
     this->pStdIn  =  -1;
     this->pStdOut =  -1;
     this->pStdErr =  -1;
     }

   /**
    * Start the process in the directory path. Make sure that the
    * executable is either in the path or specify the full path. The
    * argument verbose specifies wether or not to display output while
    * it is being generated.
    */
   bool StartProcess(const char*, const char* path, bool verbose);

   /**
    * Wait for the process to finish. If timeout is specified, it will
    * break the process after timeout expires. (Timeout code is not yet
    * implemented.
    */
   bool Wait(int timeout);

   /**
    * Get the output of the process (mixed stdout and stderr) as
    * std::string.
    */
   const std::string GetOutput() const { return this->Output; }

   /**
    * Get the return value of the process. If the process is still
    * running, the return value is -1.
    */
   int GetExitValue() const { return this->ExitValue; }

   /**
    * On Windows 9x there is a bug in the process execution code which
    * may result in blocking. That is why this workaround is
    * used. Specify the console spawn, which should run the
    * Windows9xHack code.
    */
   void SetConsoleSpawn(const char* prog) { this->ConsoleSpawn = prog; }
   static int Windows9xHack(const char* command);

   /** Code from a Borland web site with the following explaination :
    * In this article, I will explain how to spawn a console
    * application and redirect its standard input/output using
    * anonymous pipes. An anonymous pipe is a pipe that goes only in
    * one direction (read pipe, write pipe, etc.). Maybe you are
    * asking, "why would I ever need to do this sort of thing?" One
    * example would be a Windows telnet server, where you spawn a shell
    * and listen on a port and send and receive data between the shell
    * and the socket client. (Windows does not really have a built-in
    * remote shell). First, we should talk about pipes. A pipe in
    * Windows is simply a method of communication, often between
    * process. The SDK defines a pipe as "a communication conduit with
    * two ends; a process with a handle to one end can communicate with
    * a process having a handle to the other end." In our case, we are
    * using "anonymous" pipes, one-way pipes that "transfer data
    * between a parent process and a child process or between two child
    * processes of the same parent process." It's easiest to imagine a
    * pipe as its namesake. An actual pipe running between processes
    * that can carry data. We are using anonymous pipes because the
    * console app we are spawning is a child process. We use the
    * CreatePipe function which will create an anonymous pipe and
    * return a read handle and a write handle. We will create two
    * pipes, on for stdin and one for stdout. We will then monitor the
    * read end of the stdout pipe to check for display on our child
    * process. Every time there is something availabe for reading, we
    * will display it in our app. Consequently, we check for input in
    * our app and send it off to the write end of the stdin pipe.
    */
   static bool BorlandRunCommand(const char* command,
                                 const char* dir,
                                 std::string& output, int& retVal,
                                 bool verbose,
                                 int timeout, bool hideWindows);

 private:
   bool CloseHandles();
   bool PrivateOpen(const char*, const char*, int, int);
   bool PrivateClose(int timeout);

   HANDLE ProcessHandle;
   HANDLE hChildStdinRd;
   HANDLE hChildStdinWr;
   HANDLE hChildStdoutRd;
   HANDLE hChildStdoutWr;
   HANDLE hChildStderrRd;
   HANDLE hChildStderrWr;
   HANDLE hChildStdinWrDup;
   HANDLE hChildStdoutRdDup;
   HANDLE hChildStderrRdDup;


   int pStdIn;
   int pStdOut;
   int pStdErr;

   int ExitValue;

   std::string Output;
   std::string ConsoleSpawn;
   bool Verbose;
   bool HideWindows;
 };


 #endif
	/*=========================================================================

	Program: CMake - Cross-Platform Makefile Generator
	Module: $RCSfile: cmWin32ProcessExecution.h,v $
	Language: C++
	Date: $Date: 2012/03/29 17:21:08 $
	Version: $Revision: 1.1.1.1 $

	Copyright (c) 2002 Kitware, Inc., Insight Consortium. All rights reserved.
	See Copyright.txt or http://www.cmake.org/HTML/Copyright.html for details.

	This software is distributed WITHOUT ANY WARRANTY; without even
	the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
	PURPOSE. See the above copyright notices for more information.

	=========================================================================*/
	#ifndef cmWin32ProcessExecution_h
	#define cmWin32ProcessExecution_h

	#include "cmStandardIncludes.h"
	#include "windows.h"

	class cmMakefile;

	/** \class cmWin32ProcessExecution
	* \brief A process executor for windows
	*
	* cmWin32ProcessExecution is a class that provides a "clean" way of
	* executing processes on Windows. It is modified code from Python 2.1
	* distribution.
	*
	* Portable 'popen' replacement for Win32.
	*
	* Written by Bill Tutt <billtut@microsoft.com>. Minor tweaks and 2.0
	* integration by Fredrik Lundh <fredrik@pythonware.com> Return code
	* handling by David Bolen <db3l@fitlinxx.com>.
	*
	* Modified for CMake.
	*
	* For more information, please check Microsoft Knowledge Base
	* Articles Q190351 and Q150956.
	*/
	class cmWin32ProcessExecution
	{
	public:
	cmWin32ProcessExecution()
	{
	this->HideWindows = false;
	this->SetConsoleSpawn("w9xpopen.exe");
	this->Initialize();
	}
	~cmWin32ProcessExecution();
	///! If true windows will be created hidden.
	void SetHideWindows(bool v) { this->HideWindows = v; }

	/**
	* Initialize the process execution datastructure. Do not call while
	* running the process.
	*/
	void Initialize()
	{
	this->ProcessHandle = 0;
	this->ExitValue = -1;
	// Comment this out. Maybe we will need it in the future.
	// file IO access to the process might be cool.
	//this->StdIn = 0;
	//this->StdOut = 0;
	//this->StdErr = 0;
	this->pStdIn = -1;
	this->pStdOut = -1;
	this->pStdErr = -1;
	}

	/**
	* Start the process in the directory path. Make sure that the
	* executable is either in the path or specify the full path. The
	* argument verbose specifies wether or not to display output while
	* it is being generated.
	*/
	bool StartProcess(const char, const char path, bool verbose);

	/**
	* Wait for the process to finish. If timeout is specified, it will
	* break the process after timeout expires. (Timeout code is not yet
	* implemented.
	*/
	bool Wait(int timeout);

	/**
	* Get the output of the process (mixed stdout and stderr) as
	* std::string.
	*/
	const std::string GetOutput() const { return this->Output; }

	/**
	* Get the return value of the process. If the process is still
	* running, the return value is -1.
	*/
	int GetExitValue() const { return this->ExitValue; }

	/**
	* On Windows 9x there is a bug in the process execution code which
	* may result in blocking. That is why this workaround is
	* used. Specify the console spawn, which should run the
	* Windows9xHack code.
	*/
	void SetConsoleSpawn(const char* prog) { this->ConsoleSpawn = prog; }
	static int Windows9xHack(const char* command);

	/** Code from a Borland web site with the following explaination :
	* In this article, I will explain how to spawn a console
	* application and redirect its standard input/output using
	* anonymous pipes. An anonymous pipe is a pipe that goes only in
	* one direction (read pipe, write pipe, etc.). Maybe you are
	* asking, "why would I ever need to do this sort of thing?" One
	* example would be a Windows telnet server, where you spawn a shell
	* and listen on a port and send and receive data between the shell
	* and the socket client. (Windows does not really have a built-in
	* remote shell). First, we should talk about pipes. A pipe in
	* Windows is simply a method of communication, often between
	* process. The SDK defines a pipe as "a communication conduit with
	* two ends; a process with a handle to one end can communicate with
	* a process having a handle to the other end." In our case, we are
	* using "anonymous" pipes, one-way pipes that "transfer data
	* between a parent process and a child process or between two child
	* processes of the same parent process." It's easiest to imagine a
	* pipe as its namesake. An actual pipe running between processes
	* that can carry data. We are using anonymous pipes because the
	* console app we are spawning is a child process. We use the
	* CreatePipe function which will create an anonymous pipe and
	* return a read handle and a write handle. We will create two
	* pipes, on for stdin and one for stdout. We will then monitor the
	* read end of the stdout pipe to check for display on our child
	* process. Every time there is something availabe for reading, we
	* will display it in our app. Consequently, we check for input in
	* our app and send it off to the write end of the stdin pipe.
	*/
	static bool BorlandRunCommand(const char* command,
	const char* dir,
	std::string& output, int& retVal,
	bool verbose,
	int timeout, bool hideWindows);

	private:
	bool CloseHandles();
	bool PrivateOpen(const char, const char, int, int);
	bool PrivateClose(int timeout);

	HANDLE ProcessHandle;
	HANDLE hChildStdinRd;
	HANDLE hChildStdinWr;
	HANDLE hChildStdoutRd;
	HANDLE hChildStdoutWr;
	HANDLE hChildStderrRd;
	HANDLE hChildStderrWr;
	HANDLE hChildStdinWrDup;
	HANDLE hChildStdoutRdDup;
	HANDLE hChildStderrRdDup;


	int pStdIn;
	int pStdOut;
	int pStdErr;

	int ExitValue;

	std::string Output;
	std::string ConsoleSpawn;
	bool Verbose;
	bool HideWindows;
	};


	#endif