//===- SystemUtils.h - Utilities to do low-level system stuff --*- C++ -*--===// // // This file contains functions used to do a variety of low-level, often // system-specific, tasks. // //===----------------------------------------------------------------------===// #include "Support/SystemUtils.h" #include #include #include #include #include "Config/sys/types.h" #include "Config/sys/stat.h" #include "Config/fcntl.h" #include "Config/sys/wait.h" #include "Config/unistd.h" #include "Config/errno.h" /// isExecutableFile - This function returns true if the filename specified /// exists and is executable. /// bool isExecutableFile(const std::string &ExeFileName) { struct stat Buf; if (stat(ExeFileName.c_str(), &Buf)) return false; // Must not be executable! if (!(Buf.st_mode & S_IFREG)) return false; // Not a regular file? if (Buf.st_uid == getuid()) // Owner of file? return Buf.st_mode & S_IXUSR; else if (Buf.st_gid == getgid()) // In group of file? return Buf.st_mode & S_IXGRP; else // Unrelated to file? return Buf.st_mode & S_IXOTH; } /// FindExecutable - Find a named executable, giving the argv[0] of program /// being executed. This allows us to find another LLVM tool if it is built /// into the same directory, but that directory is neither the current /// directory, nor in the PATH. If the executable cannot be found, return an /// empty string. /// std::string FindExecutable(const std::string &ExeName, const std::string &ProgramPath) { // First check the directory that bugpoint is in. We can do this if // BugPointPath contains at least one / character, indicating that it is a // relative path to bugpoint itself. // std::string Result = ProgramPath; while (!Result.empty() && Result[Result.size()-1] != '/') Result.erase(Result.size()-1, 1); if (!Result.empty()) { Result += ExeName; if (isExecutableFile(Result)) return Result; // Found it? } // Okay, if the path to the program didn't tell us anything, try using the // PATH environment variable. const char *PathStr = getenv("PATH"); if (PathStr == 0) return ""; // Now we have a colon separated list of directories to search... try them... unsigned PathLen = strlen(PathStr); while (PathLen) { // Find the first colon... const char *Colon = std::find(PathStr, PathStr+PathLen, ':'); // Check to see if this first directory contains the executable... std::string FilePath = std::string(PathStr, Colon) + '/' + ExeName; if (isExecutableFile(FilePath)) return FilePath; // Found the executable! // Nope it wasn't in this directory, check the next range! PathLen -= Colon-PathStr; PathStr = Colon; while (*PathStr == ':') { // Advance past colons PathStr++; PathLen--; } } // If we fell out, we ran out of directories in PATH to search, return failure return ""; } static void RedirectFD(const std::string &File, int FD) { if (File.empty()) return; // Noop // Open the file int InFD = open(File.c_str(), FD == 0 ? O_RDONLY : O_WRONLY|O_CREAT, 0666); if (InFD == -1) { std::cerr << "Error opening file '" << File << "' for " << (FD == 0 ? "input" : "output") << "!\n"; exit(1); } dup2(InFD, FD); // Install it as the requested FD close(InFD); // Close the original FD } /// RunProgramWithTimeout - This function executes the specified program, with /// the specified null-terminated argument array, with the stdin/out/err fd's /// redirected, with a timeout specified on the command line. This terminates /// the calling program if there is an error executing the specified program. /// It returns the return value of the program, or -1 if a timeout is detected. /// int RunProgramWithTimeout(const std::string &ProgramPath, const char **Args, const std::string &StdInFile, const std::string &StdOutFile, const std::string &StdErrFile) { // FIXME: install sigalarm handler here for timeout... int Child = fork(); switch (Child) { case -1: std::cerr << "ERROR forking!\n"; exit(1); case 0: // Child RedirectFD(StdInFile, 0); // Redirect file descriptors... RedirectFD(StdOutFile, 1); RedirectFD(StdErrFile, 2); execv(ProgramPath.c_str(), (char *const *)Args); std::cerr << "Error executing program: '" << ProgramPath; for (; *Args; ++Args) std::cerr << " " << *Args; std::cerr << "'\n"; exit(1); default: break; } // Make sure all output has been written while waiting std::cout << std::flush; int Status; if (wait(&Status) != Child) { if (errno == EINTR) { static bool FirstTimeout = true; if (FirstTimeout) { std::cout << "*** Program execution timed out! This mechanism is designed to handle\n" " programs stuck in infinite loops gracefully. The -timeout option\n" " can be used to change the timeout threshold or disable it completely\n" " (with -timeout=0). This message is only displayed once.\n"; FirstTimeout = false; } return -1; // Timeout detected } std::cerr << "Error waiting for child process!\n"; exit(1); } return Status; } // // Function: ExecWait () // // Description: // This function executes a program with the specified arguments and // environment. It then waits for the progarm to termiante and then returns // to the caller. // // Inputs: // argv - The arguments to the program as an array of C strings. The first // argument should be the name of the program to execute, and the // last argument should be a pointer to NULL. // // envp - The environment passes to the program as an array of C strings in // the form of "name=value" pairs. The last element should be a // pointer to NULL. // // Outputs: // None. // // Return value: // 0 - No errors. // 1 - The program could not be executed. // 1 - The program returned a non-zero exit status. // 1 - The program terminated abnormally. // // Notes: // The program will inherit the stdin, stdout, and stderr file descriptors // as well as other various configuration settings (umask). // // This function should not print anything to stdout/stderr on its own. It is // a generic library function. The caller or executed program should report // errors in the way it sees fit. // // This function does not use $PATH to find programs. // int ExecWait (const char * const old_argv[], const char * const old_envp[]) { // Child process ID register int child; // Status from child process when it exits int status; // // Create local versions of the parameters that can be passed into execve() // without creating const problems. // char ** const argv = (char ** const) old_argv; char ** const envp = (char ** const) old_envp; // // Create a child process. // switch (child=fork()) { // // An error occured: Return to the caller. // case -1: return 1; break; // // Child process: Execute the program. // case 0: execve (argv[0], argv, envp); // // If the execve() failed, we should exit and let the parent pick up // our non-zero exit status. // exit (1); break; // // Parent process: Break out of the switch to do our processing. // default: break; } // // Parent process: Wait for the child process to termiante. // if ((wait (&status)) == -1) { return 1; } // // If the program exited normally with a zero exit status, return success! // if (WIFEXITED (status) && (WEXITSTATUS(status) == 0)) { return 0; } // // Otherwise, return failure. // return 1; }