src/d8-posix.cc - platform/external/v8 - Git at Google

 // Copyright 2009 the V8 project authors. All rights reserved.
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are
 // met:
 //
 //     * Redistributions of source code must retain the above copyright
 //       notice, this list of conditions and the following disclaimer.
 //     * Redistributions in binary form must reproduce the above
 //       copyright notice, this list of conditions and the following
 //       disclaimer in the documentation and/or other materials provided
 //       with the distribution.
 //     * Neither the name of Google Inc. nor the names of its
 //       contributors may be used to endorse or promote products derived
 //       from this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.


 #include <stdlib.h>
 #include <errno.h>
 #include <sys/types.h>
 #include <sys/stat.h>
 #include <sys/time.h>
 #include <time.h>
 #include <unistd.h>
 #include <fcntl.h>
 #include <sys/wait.h>
 #include <signal.h>


 #include "d8.h"
 #include "d8-debug.h"
 #include "debug.h"


 namespace v8 {


 // If the buffer ends in the middle of a UTF-8 sequence then we return
 // the length of the string up to but not including the incomplete UTF-8
 // sequence.  If the buffer ends with a valid UTF-8 sequence then we
 // return the whole buffer.
 static int LengthWithoutIncompleteUtf8(char* buffer, int len) {
   int answer = len;
   // 1-byte encoding.
   static const int kUtf8SingleByteMask = 0x80;
   static const int kUtf8SingleByteValue = 0x00;
   // 2-byte encoding.
   static const int kUtf8TwoByteMask = 0xe0;
   static const int kUtf8TwoByteValue = 0xc0;
   // 3-byte encoding.
   static const int kUtf8ThreeByteMask = 0xf0;
   static const int kUtf8ThreeByteValue = 0xe0;
   // 4-byte encoding.
   static const int kUtf8FourByteMask = 0xf8;
   static const int kUtf8FourByteValue = 0xf0;
   // Subsequent bytes of a multi-byte encoding.
   static const int kMultiByteMask = 0xc0;
   static const int kMultiByteValue = 0x80;
   int multi_byte_bytes_seen = 0;
   while (answer > 0) {
     int c = buffer[answer - 1];
     // Ends in valid single-byte sequence?
     if ((c & kUtf8SingleByteMask) == kUtf8SingleByteValue) return answer;
     // Ends in one or more subsequent bytes of a multi-byte value?
     if ((c & kMultiByteMask) == kMultiByteValue) {
       multi_byte_bytes_seen++;
       answer--;
     } else {
       if ((c & kUtf8TwoByteMask) == kUtf8TwoByteValue) {
         if (multi_byte_bytes_seen >= 1) {
           return answer + 2;
         }
         return answer - 1;
       } else if ((c & kUtf8ThreeByteMask) == kUtf8ThreeByteValue) {
         if (multi_byte_bytes_seen >= 2) {
           return answer + 3;
         }
         return answer - 1;
       } else if ((c & kUtf8FourByteMask) == kUtf8FourByteValue) {
         if (multi_byte_bytes_seen >= 3) {
           return answer + 4;
         }
         return answer - 1;
       } else {
         return answer;  // Malformed UTF-8.
       }
     }
   }
   return 0;
 }


 // Suspends the thread until there is data available from the child process.
 // Returns false on timeout, true on data ready.
 static bool WaitOnFD(int fd,
                      int read_timeout,
                      int total_timeout,
                      struct timeval& start_time) {
   fd_set readfds, writefds, exceptfds;
   struct timeval timeout;
   int gone = 0;
   if (total_timeout != -1) {
     struct timeval time_now;
     gettimeofday(&time_now, NULL);
     int seconds = time_now.tv_sec - start_time.tv_sec;
     gone = seconds * 1000 + (time_now.tv_usec - start_time.tv_usec) / 1000;
     if (gone >= total_timeout) return false;
   }
   FD_ZERO(&readfds);
   FD_ZERO(&writefds);
   FD_ZERO(&exceptfds);
   FD_SET(fd, &readfds);
   FD_SET(fd, &exceptfds);
   if (read_timeout == -1 ||
       (total_timeout != -1 && total_timeout - gone < read_timeout)) {
     read_timeout = total_timeout - gone;
   }
   timeout.tv_usec = (read_timeout % 1000) * 1000;
   timeout.tv_sec = read_timeout / 1000;
   int number_of_fds_ready = select(fd + 1,
                                    &readfds,
                                    &writefds,
                                    &exceptfds,
                                    read_timeout != -1 ? &timeout : NULL);
   return number_of_fds_ready == 1;
 }


 // Checks whether we ran out of time on the timeout.  Returns true if we ran out
 // of time, false if we still have time.
 static bool TimeIsOut(const struct timeval& start_time, const int& total_time) {
   if (total_time == -1) return false;
   struct timeval time_now;
   gettimeofday(&time_now, NULL);
   // Careful about overflow.
   int seconds = time_now.tv_sec - start_time.tv_sec;
   if (seconds > 100) {
     if (seconds * 1000 > total_time) return true;
     return false;
   }
   int useconds = time_now.tv_usec - start_time.tv_usec;
   if (seconds * 1000000 + useconds > total_time * 1000) {
     return true;
   }
   return false;
 }


 // A utility class that does a non-hanging waitpid on the child process if we
 // bail out of the System() function early.  If you don't ever do a waitpid on
 // a subprocess then it turns into one of those annoying 'zombie processes'.
 class ZombieProtector {
  public:
   explicit ZombieProtector(int pid): pid_(pid) { }
   ~ZombieProtector() { if (pid_ != 0) waitpid(pid_, NULL, 0); }
   void ChildIsDeadNow() { pid_ = 0; }
  private:
   int pid_;
 };


 // A utility class that closes a file descriptor when it goes out of scope.
 class OpenFDCloser {
  public:
   explicit OpenFDCloser(int fd): fd_(fd) { }
   ~OpenFDCloser() { close(fd_); }
  private:
   int fd_;
 };


 // A utility class that takes the array of command arguments and puts then in an
 // array of new[]ed UTF-8 C strings.  Deallocates them again when it goes out of
 // scope.
 class ExecArgs {
  public:
   ExecArgs() {
     exec_args_[0] = NULL;
   }
   bool Init(Handle<Value> arg0, Handle<Array> command_args) {
     String::Utf8Value prog(arg0);
     if (*prog == NULL) {
       const char* message =
           "os.system(): String conversion of program name failed";
       ThrowException(String::New(message));
       return false;
     }
     int len = prog.length() + 3;
     char* c_arg = new char[len];
     snprintf(c_arg, len, "%s", *prog);
     exec_args_[0] = c_arg;
     int i = 1;
     for (unsigned j = 0; j < command_args->Length(); i++, j++) {
       Handle<Value> arg(command_args->Get(Integer::New(j)));
       String::Utf8Value utf8_arg(arg);
       if (*utf8_arg == NULL) {
         exec_args_[i] = NULL;  // Consistent state for destructor.
         const char* message =
             "os.system(): String conversion of argument failed.";
         ThrowException(String::New(message));
         return false;
       }
       int len = utf8_arg.length() + 1;
       char* c_arg = new char[len];
       snprintf(c_arg, len, "%s", *utf8_arg);
       exec_args_[i] = c_arg;
     }
     exec_args_[i] = NULL;
     return true;
   }
   ~ExecArgs() {
     for (unsigned i = 0; i < kMaxArgs; i++) {
       if (exec_args_[i] == NULL) {
         return;
       }
       delete [] exec_args_[i];
       exec_args_[i] = 0;
     }
   }
   static const unsigned kMaxArgs = 1000;
   char** arg_array() { return exec_args_; }
   char* arg0() { return exec_args_[0]; }
  private:
   char* exec_args_[kMaxArgs + 1];
 };


 // Gets the optional timeouts from the arguments to the system() call.
 static bool GetTimeouts(const Arguments& args,
                         int* read_timeout,
                         int* total_timeout) {
   if (args.Length() > 3) {
     if (args[3]->IsNumber()) {
       *total_timeout = args[3]->Int32Value();
     } else {
       ThrowException(String::New("system: Argument 4 must be a number"));
       return false;
     }
   }
   if (args.Length() > 2) {
     if (args[2]->IsNumber()) {
       *read_timeout = args[2]->Int32Value();
     } else {
       ThrowException(String::New("system: Argument 3 must be a number"));
       return false;
     }
   }
   return true;
 }


 static const int kReadFD = 0;
 static const int kWriteFD = 1;


 // This is run in the child process after fork() but before exec().  It normally
 // ends with the child process being replaced with the desired child program.
 // It only returns if an error occurred.
 static void ExecSubprocess(int* exec_error_fds,
                            int* stdout_fds,
                            ExecArgs& exec_args) {
   close(exec_error_fds[kReadFD]);  // Don't need this in the child.
   close(stdout_fds[kReadFD]);      // Don't need this in the child.
   close(1);                        // Close stdout.
   dup2(stdout_fds[kWriteFD], 1);   // Dup pipe fd to stdout.
   close(stdout_fds[kWriteFD]);     // Don't need the original fd now.
   fcntl(exec_error_fds[kWriteFD], F_SETFD, FD_CLOEXEC);
   execvp(exec_args.arg0(), exec_args.arg_array());
   // Only get here if the exec failed.  Write errno to the parent to tell
   // them it went wrong.  If it went well the pipe is closed.
   int err = errno;
   int bytes_written;
   do {
     bytes_written = write(exec_error_fds[kWriteFD], &err, sizeof(err));
   } while (bytes_written == -1 && errno == EINTR);
   // Return (and exit child process).
 }


 // Runs in the parent process.  Checks that the child was able to exec (closing
 // the file desriptor), or reports an error if it failed.
 static bool ChildLaunchedOK(int* exec_error_fds) {
   int bytes_read;
   int err;
   do {
     bytes_read = read(exec_error_fds[kReadFD], &err, sizeof(err));
   } while (bytes_read == -1 && errno == EINTR);
   if (bytes_read != 0) {
     ThrowException(String::New(strerror(err)));
     return false;
   }
   return true;
 }


 // Accumulates the output from the child in a string handle.  Returns true if it
 // succeeded or false if an exception was thrown.
 static Handle<Value> GetStdout(int child_fd,
                                struct timeval& start_time,
                                int read_timeout,
                                int total_timeout) {
   Handle<String> accumulator = String::Empty();
   const char* source = "(function(a, b) { return a + b; })";
   Handle<Value> cons_as_obj(Script::Compile(String::New(source))->Run());
   Handle<Function> cons_function(Function::Cast(*cons_as_obj));
   Handle<Value> cons_args[2];

   int fullness = 0;
   static const int kStdoutReadBufferSize = 4096;
   char buffer[kStdoutReadBufferSize];

   if (fcntl(child_fd, F_SETFL, O_NONBLOCK) != 0) {
     return ThrowException(String::New(strerror(errno)));
   }

   int bytes_read;
   do {
     bytes_read = read(child_fd,
                       buffer + fullness,
                       kStdoutReadBufferSize - fullness);
     if (bytes_read == -1) {
       if (errno == EAGAIN) {
         if (!WaitOnFD(child_fd,
                       read_timeout,
                       total_timeout,
                       start_time) ||
             (TimeIsOut(start_time, total_timeout))) {
           return ThrowException(String::New("Timed out waiting for output"));
         }
         continue;
       } else if (errno == EINTR) {
         continue;
       } else {
         break;
       }
     }
     if (bytes_read + fullness > 0) {
       int length = bytes_read == 0 ?
                    bytes_read + fullness :
                    LengthWithoutIncompleteUtf8(buffer, bytes_read + fullness);
       Handle<String> addition = String::New(buffer, length);
       cons_args[0] = accumulator;
       cons_args[1] = addition;
       accumulator = Handle<String>::Cast(cons_function->Call(
           Shell::utility_context()->Global(),
           2,
           cons_args));
       fullness = bytes_read + fullness - length;
       memcpy(buffer, buffer + length, fullness);
     }
   } while (bytes_read != 0);
   return accumulator;
 }


 // Modern Linux has the waitid call, which is like waitpid, but more useful
 // if you want a timeout.  If we don't have waitid we can't limit the time
 // waiting for the process to exit without losing the information about
 // whether it exited normally.  In the common case this doesn't matter because
 // we don't get here before the child has closed stdout and most programs don't
 // do that before they exit.
 //
 // We're disabling usage of waitid in Mac OS X because it doens't work for us:
 // a parent process hangs on waiting while a child process is already a zombie.
 // See http://code.google.com/p/v8/issues/detail?id=401.
 #if defined(WNOWAIT) && !defined(ANDROID) && !defined(__APPLE__)
 #if !defined(__FreeBSD__)
 #define HAS_WAITID 1
 #endif
 #endif


 // Get exit status of child.
 static bool WaitForChild(int pid,
                          ZombieProtector& child_waiter,
                          struct timeval& start_time,
                          int read_timeout,
                          int total_timeout) {
 #ifdef HAS_WAITID

   siginfo_t child_info;
   child_info.si_pid = 0;
   int useconds = 1;
   // Wait for child to exit.
   while (child_info.si_pid == 0) {
     waitid(P_PID, pid, &child_info, WEXITED | WNOHANG | WNOWAIT);
     usleep(useconds);
     if (useconds < 1000000) useconds <<= 1;
     if ((read_timeout != -1 && useconds / 1000 > read_timeout) ||
         (TimeIsOut(start_time, total_timeout))) {
       ThrowException(String::New("Timed out waiting for process to terminate"));
       kill(pid, SIGINT);
       return false;
     }
   }
   if (child_info.si_code == CLD_KILLED) {
     char message[999];
     snprintf(message,
              sizeof(message),
              "Child killed by signal %d",
              child_info.si_status);
     ThrowException(String::New(message));
     return false;
   }
   if (child_info.si_code == CLD_EXITED && child_info.si_status != 0) {
     char message[999];
     snprintf(message,
              sizeof(message),
              "Child exited with status %d",
              child_info.si_status);
     ThrowException(String::New(message));
     return false;
   }

 #else  // No waitid call.

   int child_status;
   waitpid(pid, &child_status, 0);  // We hang here if the child doesn't exit.
   child_waiter.ChildIsDeadNow();
   if (WIFSIGNALED(child_status)) {
     char message[999];
     snprintf(message,
              sizeof(message),
              "Child killed by signal %d",
              WTERMSIG(child_status));
     ThrowException(String::New(message));
     return false;
   }
   if (WEXITSTATUS(child_status) != 0) {
     char message[999];
     int exit_status = WEXITSTATUS(child_status);
     snprintf(message,
              sizeof(message),
              "Child exited with status %d",
              exit_status);
     ThrowException(String::New(message));
     return false;
   }

 #endif  // No waitid call.

   return true;
 }


 // Implementation of the system() function (see d8.h for details).
 Handle<Value> Shell::System(const Arguments& args) {
   HandleScope scope;
   int read_timeout = -1;
   int total_timeout = -1;
   if (!GetTimeouts(args, &read_timeout, &total_timeout)) return v8::Undefined();
   Handle<Array> command_args;
   if (args.Length() > 1) {
     if (!args[1]->IsArray()) {
       return ThrowException(String::New("system: Argument 2 must be an array"));
     }
     command_args = Handle<Array>::Cast(args[1]);
   } else {
     command_args = Array::New(0);
   }
   if (command_args->Length() > ExecArgs::kMaxArgs) {
     return ThrowException(String::New("Too many arguments to system()"));
   }
   if (args.Length() < 1) {
     return ThrowException(String::New("Too few arguments to system()"));
   }

   struct timeval start_time;
   gettimeofday(&start_time, NULL);

   ExecArgs exec_args;
   if (!exec_args.Init(args[0], command_args)) {
     return v8::Undefined();
   }
   int exec_error_fds[2];
   int stdout_fds[2];

   if (pipe(exec_error_fds) != 0) {
     return ThrowException(String::New("pipe syscall failed."));
   }
   if (pipe(stdout_fds) != 0) {
     return ThrowException(String::New("pipe syscall failed."));
   }

   pid_t pid = fork();
   if (pid == 0) {  // Child process.
     ExecSubprocess(exec_error_fds, stdout_fds, exec_args);
     exit(1);
   }

   // Parent process.  Ensure that we clean up if we exit this function early.
   ZombieProtector child_waiter(pid);
   close(exec_error_fds[kWriteFD]);
   close(stdout_fds[kWriteFD]);
   OpenFDCloser error_read_closer(exec_error_fds[kReadFD]);
   OpenFDCloser stdout_read_closer(stdout_fds[kReadFD]);

   if (!ChildLaunchedOK(exec_error_fds)) return v8::Undefined();

   Handle<Value> accumulator = GetStdout(stdout_fds[kReadFD],
                                         start_time,
                                         read_timeout,
                                         total_timeout);
   if (accumulator->IsUndefined()) {
     kill(pid, SIGINT);  // On timeout, kill the subprocess.
     return accumulator;
   }

   if (!WaitForChild(pid,
                     child_waiter,
                     start_time,
                     read_timeout,
                     total_timeout)) {
     return v8::Undefined();
   }

   return scope.Close(accumulator);
 }


 Handle<Value> Shell::ChangeDirectory(const Arguments& args) {
   if (args.Length() != 1) {
     const char* message = "chdir() takes one argument";
     return ThrowException(String::New(message));
   }
   String::Utf8Value directory(args[0]);
   if (*directory == NULL) {
     const char* message = "os.chdir(): String conversion of argument failed.";
     return ThrowException(String::New(message));
   }
   if (chdir(*directory) != 0) {
     return ThrowException(String::New(strerror(errno)));
   }
   return v8::Undefined();
 }


 Handle<Value> Shell::SetUMask(const Arguments& args) {
   if (args.Length() != 1) {
     const char* message = "umask() takes one argument";
     return ThrowException(String::New(message));
   }
   if (args[0]->IsNumber()) {
     mode_t mask = args[0]->Int32Value();
     int previous = umask(mask);
     return Number::New(previous);
   } else {
     const char* message = "umask() argument must be numeric";
     return ThrowException(String::New(message));
   }
 }


 static bool CheckItsADirectory(char* directory) {
   struct stat stat_buf;
   int stat_result = stat(directory, &stat_buf);
   if (stat_result != 0) {
     ThrowException(String::New(strerror(errno)));
     return false;
   }
   if ((stat_buf.st_mode & S_IFDIR) != 0) return true;
   ThrowException(String::New(strerror(EEXIST)));
   return false;
 }


 // Returns true for success.  Creates intermediate directories as needed.  No
 // error if the directory exists already.
 static bool mkdirp(char* directory, mode_t mask) {
   int result = mkdir(directory, mask);
   if (result == 0) return true;
   if (errno == EEXIST) {
     return CheckItsADirectory(directory);
   } else if (errno == ENOENT) {  // Intermediate path element is missing.
     char* last_slash = strrchr(directory, '/');
     if (last_slash == NULL) {
       ThrowException(String::New(strerror(errno)));
       return false;
     }
     *last_slash = 0;
     if (!mkdirp(directory, mask)) return false;
     *last_slash = '/';
     result = mkdir(directory, mask);
     if (result == 0) return true;
     if (errno == EEXIST) {
       return CheckItsADirectory(directory);
     }
     ThrowException(String::New(strerror(errno)));
     return false;
   } else {
     ThrowException(String::New(strerror(errno)));
     return false;
   }
 }


 Handle<Value> Shell::MakeDirectory(const Arguments& args) {
   mode_t mask = 0777;
   if (args.Length() == 2) {
     if (args[1]->IsNumber()) {
       mask = args[1]->Int32Value();
     } else {
       const char* message = "mkdirp() second argument must be numeric";
       return ThrowException(String::New(message));
     }
   } else if (args.Length() != 1) {
     const char* message = "mkdirp() takes one or two arguments";
     return ThrowException(String::New(message));
   }
   String::Utf8Value directory(args[0]);
   if (*directory == NULL) {
     const char* message = "os.mkdirp(): String conversion of argument failed.";
     return ThrowException(String::New(message));
   }
   mkdirp(*directory, mask);
   return v8::Undefined();
 }


 Handle<Value> Shell::RemoveDirectory(const Arguments& args) {
   if (args.Length() != 1) {
     const char* message = "rmdir() takes one or two arguments";
     return ThrowException(String::New(message));
   }
   String::Utf8Value directory(args[0]);
   if (*directory == NULL) {
     const char* message = "os.rmdir(): String conversion of argument failed.";
     return ThrowException(String::New(message));
   }
   rmdir(*directory);
   return v8::Undefined();
 }


 Handle<Value> Shell::SetEnvironment(const Arguments& args) {
   if (args.Length() != 2) {
     const char* message = "setenv() takes two arguments";
     return ThrowException(String::New(message));
   }
   String::Utf8Value var(args[0]);
   String::Utf8Value value(args[1]);
   if (*var == NULL) {
     const char* message =
         "os.setenv(): String conversion of variable name failed.";
     return ThrowException(String::New(message));
   }
   if (*value == NULL) {
     const char* message =
         "os.setenv(): String conversion of variable contents failed.";
     return ThrowException(String::New(message));
   }
   setenv(*var, *value, 1);
   return v8::Undefined();
 }


 Handle<Value> Shell::UnsetEnvironment(const Arguments& args) {
   if (args.Length() != 1) {
     const char* message = "unsetenv() takes one argument";
     return ThrowException(String::New(message));
   }
   String::Utf8Value var(args[0]);
   if (*var == NULL) {
     const char* message =
         "os.setenv(): String conversion of variable name failed.";
     return ThrowException(String::New(message));
   }
   unsetenv(*var);
   return v8::Undefined();
 }


 void Shell::AddOSMethods(Handle<ObjectTemplate> os_templ) {
   os_templ->Set(String::New("system"), FunctionTemplate::New(System));
   os_templ->Set(String::New("chdir"), FunctionTemplate::New(ChangeDirectory));
   os_templ->Set(String::New("setenv"), FunctionTemplate::New(SetEnvironment));
   os_templ->Set(String::New("unsetenv"),
                 FunctionTemplate::New(UnsetEnvironment));
   os_templ->Set(String::New("umask"), FunctionTemplate::New(SetUMask));
   os_templ->Set(String::New("mkdirp"), FunctionTemplate::New(MakeDirectory));
   os_templ->Set(String::New("rmdir"), FunctionTemplate::New(RemoveDirectory));
 }

 }  // namespace v8
	// Copyright 2009 the V8 project authors. All rights reserved.
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are
	// met:
	//
	// * Redistributions of source code must retain the above copyright
	// notice, this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above
	// copyright notice, this list of conditions and the following
	// disclaimer in the documentation and/or other materials provided
	// with the distribution.
	// * Neither the name of Google Inc. nor the names of its
	// contributors may be used to endorse or promote products derived
	// from this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.


	#include <stdlib.h>
	#include <errno.h>
	#include <sys/types.h>
	#include <sys/stat.h>
	#include <sys/time.h>
	#include <time.h>
	#include <unistd.h>
	#include <fcntl.h>
	#include <sys/wait.h>
	#include <signal.h>


	#include "d8.h"
	#include "d8-debug.h"
	#include "debug.h"


	namespace v8 {


	// If the buffer ends in the middle of a UTF-8 sequence then we return
	// the length of the string up to but not including the incomplete UTF-8
	// sequence. If the buffer ends with a valid UTF-8 sequence then we
	// return the whole buffer.
	static int LengthWithoutIncompleteUtf8(char* buffer, int len) {
	int answer = len;
	// 1-byte encoding.
	static const int kUtf8SingleByteMask = 0x80;
	static const int kUtf8SingleByteValue = 0x00;
	// 2-byte encoding.
	static const int kUtf8TwoByteMask = 0xe0;
	static const int kUtf8TwoByteValue = 0xc0;
	// 3-byte encoding.
	static const int kUtf8ThreeByteMask = 0xf0;
	static const int kUtf8ThreeByteValue = 0xe0;
	// 4-byte encoding.
	static const int kUtf8FourByteMask = 0xf8;
	static const int kUtf8FourByteValue = 0xf0;
	// Subsequent bytes of a multi-byte encoding.
	static const int kMultiByteMask = 0xc0;
	static const int kMultiByteValue = 0x80;
	int multi_byte_bytes_seen = 0;
	while (answer > 0) {
	int c = buffer[answer - 1];
	// Ends in valid single-byte sequence?
	if ((c & kUtf8SingleByteMask) == kUtf8SingleByteValue) return answer;
	// Ends in one or more subsequent bytes of a multi-byte value?
	if ((c & kMultiByteMask) == kMultiByteValue) {
	multi_byte_bytes_seen++;
	answer--;
	} else {
	if ((c & kUtf8TwoByteMask) == kUtf8TwoByteValue) {
	if (multi_byte_bytes_seen >= 1) {
	return answer + 2;
	}
	return answer - 1;
	} else if ((c & kUtf8ThreeByteMask) == kUtf8ThreeByteValue) {
	if (multi_byte_bytes_seen >= 2) {
	return answer + 3;
	}
	return answer - 1;
	} else if ((c & kUtf8FourByteMask) == kUtf8FourByteValue) {
	if (multi_byte_bytes_seen >= 3) {
	return answer + 4;
	}
	return answer - 1;
	} else {
	return answer; // Malformed UTF-8.
	}
	}
	}
	return 0;
	}


	// Suspends the thread until there is data available from the child process.
	// Returns false on timeout, true on data ready.
	static bool WaitOnFD(int fd,
	int read_timeout,
	int total_timeout,
	struct timeval& start_time) {
	fd_set readfds, writefds, exceptfds;
	struct timeval timeout;
	int gone = 0;
	if (total_timeout != -1) {
	struct timeval time_now;
	gettimeofday(&time_now, NULL);
	int seconds = time_now.tv_sec - start_time.tv_sec;
	gone = seconds * 1000 + (time_now.tv_usec - start_time.tv_usec) / 1000;
	if (gone >= total_timeout) return false;
	}
	FD_ZERO(&readfds);
	FD_ZERO(&writefds);
	FD_ZERO(&exceptfds);
	FD_SET(fd, &readfds);
	FD_SET(fd, &exceptfds);
	if (read_timeout == -1 \|\|
	(total_timeout != -1 && total_timeout - gone < read_timeout)) {
	read_timeout = total_timeout - gone;
	}
	timeout.tv_usec = (read_timeout % 1000) * 1000;
	timeout.tv_sec = read_timeout / 1000;
	int number_of_fds_ready = select(fd + 1,
	&readfds,
	&writefds,
	&exceptfds,
	read_timeout != -1 ? &timeout : NULL);
	return number_of_fds_ready == 1;
	}


	// Checks whether we ran out of time on the timeout. Returns true if we ran out
	// of time, false if we still have time.
	static bool TimeIsOut(const struct timeval& start_time, const int& total_time) {
	if (total_time == -1) return false;
	struct timeval time_now;
	gettimeofday(&time_now, NULL);
	// Careful about overflow.
	int seconds = time_now.tv_sec - start_time.tv_sec;
	if (seconds > 100) {
	if (seconds * 1000 > total_time) return true;
	return false;
	}
	int useconds = time_now.tv_usec - start_time.tv_usec;
	if (seconds * 1000000 + useconds > total_time * 1000) {
	return true;
	}
	return false;
	}


	// A utility class that does a non-hanging waitpid on the child process if we
	// bail out of the System() function early. If you don't ever do a waitpid on
	// a subprocess then it turns into one of those annoying 'zombie processes'.
	class ZombieProtector {
	public:
	explicit ZombieProtector(int pid): pid_(pid) { }
	~ZombieProtector() { if (pid_ != 0) waitpid(pid_, NULL, 0); }
	void ChildIsDeadNow() { pid_ = 0; }
	private:
	int pid_;
	};


	// A utility class that closes a file descriptor when it goes out of scope.
	class OpenFDCloser {
	public:
	explicit OpenFDCloser(int fd): fd_(fd) { }
	~OpenFDCloser() { close(fd_); }
	private:
	int fd_;
	};


	// A utility class that takes the array of command arguments and puts then in an
	// array of new[]ed UTF-8 C strings. Deallocates them again when it goes out of
	// scope.
	class ExecArgs {
	public:
	ExecArgs() {
	exec_args_[0] = NULL;
	}
	bool Init(Handle<Value> arg0, Handle<Array> command_args) {
	String::Utf8Value prog(arg0);
	if (*prog == NULL) {
	const char* message =
	"os.system(): String conversion of program name failed";
	ThrowException(String::New(message));
	return false;
	}
	int len = prog.length() + 3;
	char* c_arg = new char[len];
	snprintf(c_arg, len, "%s", *prog);
	exec_args_[0] = c_arg;
	int i = 1;
	for (unsigned j = 0; j < command_args->Length(); i++, j++) {
	Handle<Value> arg(command_args->Get(Integer::New(j)));
	String::Utf8Value utf8_arg(arg);
	if (*utf8_arg == NULL) {
	exec_args_[i] = NULL; // Consistent state for destructor.
	const char* message =
	"os.system(): String conversion of argument failed.";
	ThrowException(String::New(message));
	return false;
	}
	int len = utf8_arg.length() + 1;
	char* c_arg = new char[len];
	snprintf(c_arg, len, "%s", *utf8_arg);
	exec_args_[i] = c_arg;
	}
	exec_args_[i] = NULL;
	return true;
	}
	~ExecArgs() {
	for (unsigned i = 0; i < kMaxArgs; i++) {
	if (exec_args_[i] == NULL) {
	return;
	}
	delete [] exec_args_[i];
	exec_args_[i] = 0;
	}
	}
	static const unsigned kMaxArgs = 1000;
	char** arg_array() { return exec_args_; }
	char* arg0() { return exec_args_[0]; }
	private:
	char* exec_args_[kMaxArgs + 1];
	};


	// Gets the optional timeouts from the arguments to the system() call.
	static bool GetTimeouts(const Arguments& args,
	int* read_timeout,
	int* total_timeout) {
	if (args.Length() > 3) {
	if (args[3]->IsNumber()) {
	*total_timeout = args[3]->Int32Value();
	} else {
	ThrowException(String::New("system: Argument 4 must be a number"));
	return false;
	}
	}
	if (args.Length() > 2) {
	if (args[2]->IsNumber()) {
	*read_timeout = args[2]->Int32Value();
	} else {
	ThrowException(String::New("system: Argument 3 must be a number"));
	return false;
	}
	}
	return true;
	}


	static const int kReadFD = 0;
	static const int kWriteFD = 1;


	// This is run in the child process after fork() but before exec(). It normally
	// ends with the child process being replaced with the desired child program.
	// It only returns if an error occurred.
	static void ExecSubprocess(int* exec_error_fds,
	int* stdout_fds,
	ExecArgs& exec_args) {
	close(exec_error_fds[kReadFD]); // Don't need this in the child.
	close(stdout_fds[kReadFD]); // Don't need this in the child.
	close(1); // Close stdout.
	dup2(stdout_fds[kWriteFD], 1); // Dup pipe fd to stdout.
	close(stdout_fds[kWriteFD]); // Don't need the original fd now.
	fcntl(exec_error_fds[kWriteFD], F_SETFD, FD_CLOEXEC);
	execvp(exec_args.arg0(), exec_args.arg_array());
	// Only get here if the exec failed. Write errno to the parent to tell
	// them it went wrong. If it went well the pipe is closed.
	int err = errno;
	int bytes_written;
	do {
	bytes_written = write(exec_error_fds[kWriteFD], &err, sizeof(err));
	} while (bytes_written == -1 && errno == EINTR);
	// Return (and exit child process).
	}


	// Runs in the parent process. Checks that the child was able to exec (closing
	// the file desriptor), or reports an error if it failed.
	static bool ChildLaunchedOK(int* exec_error_fds) {
	int bytes_read;
	int err;
	do {
	bytes_read = read(exec_error_fds[kReadFD], &err, sizeof(err));
	} while (bytes_read == -1 && errno == EINTR);
	if (bytes_read != 0) {
	ThrowException(String::New(strerror(err)));
	return false;
	}
	return true;
	}


	// Accumulates the output from the child in a string handle. Returns true if it
	// succeeded or false if an exception was thrown.
	static Handle<Value> GetStdout(int child_fd,
	struct timeval& start_time,
	int read_timeout,
	int total_timeout) {
	Handle<String> accumulator = String::Empty();
	const char* source = "(function(a, b) { return a + b; })";
	Handle<Value> cons_as_obj(Script::Compile(String::New(source))->Run());
	Handle<Function> cons_function(Function::Cast(*cons_as_obj));
	Handle<Value> cons_args[2];

	int fullness = 0;
	static const int kStdoutReadBufferSize = 4096;
	char buffer[kStdoutReadBufferSize];

	if (fcntl(child_fd, F_SETFL, O_NONBLOCK) != 0) {
	return ThrowException(String::New(strerror(errno)));
	}

	int bytes_read;
	do {
	bytes_read = read(child_fd,
	buffer + fullness,
	kStdoutReadBufferSize - fullness);
	if (bytes_read == -1) {
	if (errno == EAGAIN) {
	if (!WaitOnFD(child_fd,
	read_timeout,
	total_timeout,
	start_time) \|\|
	(TimeIsOut(start_time, total_timeout))) {
	return ThrowException(String::New("Timed out waiting for output"));
	}
	continue;
	} else if (errno == EINTR) {
	continue;
	} else {
	break;
	}
	}
	if (bytes_read + fullness > 0) {
	int length = bytes_read == 0 ?
	bytes_read + fullness :
	LengthWithoutIncompleteUtf8(buffer, bytes_read + fullness);
	Handle<String> addition = String::New(buffer, length);
	cons_args[0] = accumulator;
	cons_args[1] = addition;
	accumulator = Handle<String>::Cast(cons_function->Call(
	Shell::utility_context()->Global(),
	2,
	cons_args));
	fullness = bytes_read + fullness - length;
	memcpy(buffer, buffer + length, fullness);
	}
	} while (bytes_read != 0);
	return accumulator;
	}


	// Modern Linux has the waitid call, which is like waitpid, but more useful
	// if you want a timeout. If we don't have waitid we can't limit the time
	// waiting for the process to exit without losing the information about
	// whether it exited normally. In the common case this doesn't matter because
	// we don't get here before the child has closed stdout and most programs don't
	// do that before they exit.
	//
	// We're disabling usage of waitid in Mac OS X because it doens't work for us:
	// a parent process hangs on waiting while a child process is already a zombie.
	// See http://code.google.com/p/v8/issues/detail?id=401.
	#if defined(WNOWAIT) && !defined(ANDROID) && !defined(__APPLE__)
	#if !defined(__FreeBSD__)
	#define HAS_WAITID 1
	#endif
	#endif


	// Get exit status of child.
	static bool WaitForChild(int pid,
	ZombieProtector& child_waiter,
	struct timeval& start_time,
	int read_timeout,
	int total_timeout) {
	#ifdef HAS_WAITID

	siginfo_t child_info;
	child_info.si_pid = 0;
	int useconds = 1;
	// Wait for child to exit.
	while (child_info.si_pid == 0) {
	waitid(P_PID, pid, &child_info, WEXITED \| WNOHANG \| WNOWAIT);
	usleep(useconds);
	if (useconds < 1000000) useconds <<= 1;
	if ((read_timeout != -1 && useconds / 1000 > read_timeout) \|\|
	(TimeIsOut(start_time, total_timeout))) {
	ThrowException(String::New("Timed out waiting for process to terminate"));
	kill(pid, SIGINT);
	return false;
	}
	}
	if (child_info.si_code == CLD_KILLED) {
	char message[999];
	snprintf(message,
	sizeof(message),
	"Child killed by signal %d",
	child_info.si_status);
	ThrowException(String::New(message));
	return false;
	}
	if (child_info.si_code == CLD_EXITED && child_info.si_status != 0) {
	char message[999];
	snprintf(message,
	sizeof(message),
	"Child exited with status %d",
	child_info.si_status);
	ThrowException(String::New(message));
	return false;
	}

	#else // No waitid call.

	int child_status;
	waitpid(pid, &child_status, 0); // We hang here if the child doesn't exit.
	child_waiter.ChildIsDeadNow();
	if (WIFSIGNALED(child_status)) {
	char message[999];
	snprintf(message,
	sizeof(message),
	"Child killed by signal %d",
	WTERMSIG(child_status));
	ThrowException(String::New(message));
	return false;
	}
	if (WEXITSTATUS(child_status) != 0) {
	char message[999];
	int exit_status = WEXITSTATUS(child_status);
	snprintf(message,
	sizeof(message),
	"Child exited with status %d",
	exit_status);
	ThrowException(String::New(message));
	return false;
	}

	#endif // No waitid call.

	return true;
	}


	// Implementation of the system() function (see d8.h for details).
	Handle<Value> Shell::System(const Arguments& args) {
	HandleScope scope;
	int read_timeout = -1;
	int total_timeout = -1;
	if (!GetTimeouts(args, &read_timeout, &total_timeout)) return v8::Undefined();
	Handle<Array> command_args;
	if (args.Length() > 1) {
	if (!args[1]->IsArray()) {
	return ThrowException(String::New("system: Argument 2 must be an array"));
	}
	command_args = Handle<Array>::Cast(args[1]);
	} else {
	command_args = Array::New(0);
	}
	if (command_args->Length() > ExecArgs::kMaxArgs) {
	return ThrowException(String::New("Too many arguments to system()"));
	}
	if (args.Length() < 1) {
	return ThrowException(String::New("Too few arguments to system()"));
	}

	struct timeval start_time;
	gettimeofday(&start_time, NULL);

	ExecArgs exec_args;
	if (!exec_args.Init(args[0], command_args)) {
	return v8::Undefined();
	}
	int exec_error_fds[2];
	int stdout_fds[2];

	if (pipe(exec_error_fds) != 0) {
	return ThrowException(String::New("pipe syscall failed."));
	}
	if (pipe(stdout_fds) != 0) {
	return ThrowException(String::New("pipe syscall failed."));
	}

	pid_t pid = fork();
	if (pid == 0) { // Child process.
	ExecSubprocess(exec_error_fds, stdout_fds, exec_args);
	exit(1);
	}

	// Parent process. Ensure that we clean up if we exit this function early.
	ZombieProtector child_waiter(pid);
	close(exec_error_fds[kWriteFD]);
	close(stdout_fds[kWriteFD]);
	OpenFDCloser error_read_closer(exec_error_fds[kReadFD]);
	OpenFDCloser stdout_read_closer(stdout_fds[kReadFD]);

	if (!ChildLaunchedOK(exec_error_fds)) return v8::Undefined();

	Handle<Value> accumulator = GetStdout(stdout_fds[kReadFD],
	start_time,
	read_timeout,
	total_timeout);
	if (accumulator->IsUndefined()) {
	kill(pid, SIGINT); // On timeout, kill the subprocess.
	return accumulator;
	}

	if (!WaitForChild(pid,
	child_waiter,
	start_time,
	read_timeout,
	total_timeout)) {
	return v8::Undefined();
	}

	return scope.Close(accumulator);
	}


	Handle<Value> Shell::ChangeDirectory(const Arguments& args) {
	if (args.Length() != 1) {
	const char* message = "chdir() takes one argument";
	return ThrowException(String::New(message));
	}
	String::Utf8Value directory(args[0]);
	if (*directory == NULL) {
	const char* message = "os.chdir(): String conversion of argument failed.";
	return ThrowException(String::New(message));
	}
	if (chdir(*directory) != 0) {
	return ThrowException(String::New(strerror(errno)));
	}
	return v8::Undefined();
	}


	Handle<Value> Shell::SetUMask(const Arguments& args) {
	if (args.Length() != 1) {
	const char* message = "umask() takes one argument";
	return ThrowException(String::New(message));
	}
	if (args[0]->IsNumber()) {
	mode_t mask = args[0]->Int32Value();
	int previous = umask(mask);
	return Number::New(previous);
	} else {
	const char* message = "umask() argument must be numeric";
	return ThrowException(String::New(message));
	}
	}


	static bool CheckItsADirectory(char* directory) {
	struct stat stat_buf;
	int stat_result = stat(directory, &stat_buf);
	if (stat_result != 0) {
	ThrowException(String::New(strerror(errno)));
	return false;
	}
	if ((stat_buf.st_mode & S_IFDIR) != 0) return true;
	ThrowException(String::New(strerror(EEXIST)));
	return false;
	}


	// Returns true for success. Creates intermediate directories as needed. No
	// error if the directory exists already.
	static bool mkdirp(char* directory, mode_t mask) {
	int result = mkdir(directory, mask);
	if (result == 0) return true;
	if (errno == EEXIST) {
	return CheckItsADirectory(directory);
	} else if (errno == ENOENT) { // Intermediate path element is missing.
	char* last_slash = strrchr(directory, '/');
	if (last_slash == NULL) {
	ThrowException(String::New(strerror(errno)));
	return false;
	}
	*last_slash = 0;
	if (!mkdirp(directory, mask)) return false;
	*last_slash = '/';
	result = mkdir(directory, mask);
	if (result == 0) return true;
	if (errno == EEXIST) {
	return CheckItsADirectory(directory);
	}
	ThrowException(String::New(strerror(errno)));
	return false;
	} else {
	ThrowException(String::New(strerror(errno)));
	return false;
	}
	}


	Handle<Value> Shell::MakeDirectory(const Arguments& args) {
	mode_t mask = 0777;
	if (args.Length() == 2) {
	if (args[1]->IsNumber()) {
	mask = args[1]->Int32Value();
	} else {
	const char* message = "mkdirp() second argument must be numeric";
	return ThrowException(String::New(message));
	}
	} else if (args.Length() != 1) {
	const char* message = "mkdirp() takes one or two arguments";
	return ThrowException(String::New(message));
	}
	String::Utf8Value directory(args[0]);
	if (*directory == NULL) {
	const char* message = "os.mkdirp(): String conversion of argument failed.";
	return ThrowException(String::New(message));
	}
	mkdirp(*directory, mask);
	return v8::Undefined();
	}


	Handle<Value> Shell::RemoveDirectory(const Arguments& args) {
	if (args.Length() != 1) {
	const char* message = "rmdir() takes one or two arguments";
	return ThrowException(String::New(message));
	}
	String::Utf8Value directory(args[0]);
	if (*directory == NULL) {
	const char* message = "os.rmdir(): String conversion of argument failed.";
	return ThrowException(String::New(message));
	}
	rmdir(*directory);
	return v8::Undefined();
	}


	Handle<Value> Shell::SetEnvironment(const Arguments& args) {
	if (args.Length() != 2) {
	const char* message = "setenv() takes two arguments";
	return ThrowException(String::New(message));
	}
	String::Utf8Value var(args[0]);
	String::Utf8Value value(args[1]);
	if (*var == NULL) {
	const char* message =
	"os.setenv(): String conversion of variable name failed.";
	return ThrowException(String::New(message));
	}
	if (*value == NULL) {
	const char* message =
	"os.setenv(): String conversion of variable contents failed.";
	return ThrowException(String::New(message));
	}
	setenv(var, value, 1);
	return v8::Undefined();
	}


	Handle<Value> Shell::UnsetEnvironment(const Arguments& args) {
	if (args.Length() != 1) {
	const char* message = "unsetenv() takes one argument";
	return ThrowException(String::New(message));
	}
	String::Utf8Value var(args[0]);
	if (*var == NULL) {
	const char* message =
	"os.setenv(): String conversion of variable name failed.";
	return ThrowException(String::New(message));
	}
	unsetenv(*var);
	return v8::Undefined();
	}


	void Shell::AddOSMethods(Handle<ObjectTemplate> os_templ) {
	os_templ->Set(String::New("system"), FunctionTemplate::New(System));
	os_templ->Set(String::New("chdir"), FunctionTemplate::New(ChangeDirectory));
	os_templ->Set(String::New("setenv"), FunctionTemplate::New(SetEnvironment));
	os_templ->Set(String::New("unsetenv"),
	FunctionTemplate::New(UnsetEnvironment));
	os_templ->Set(String::New("umask"), FunctionTemplate::New(SetUMask));
	os_templ->Set(String::New("mkdirp"), FunctionTemplate::New(MakeDirectory));
	os_templ->Set(String::New("rmdir"), FunctionTemplate::New(RemoveDirectory));
	}

	} // namespace v8