// Copyright (c) 2008 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. #include "base/process_util.h" #include #include #include #include #include #include #include #include "base/file_util.h" #include "base/logging.h" #include "base/string_tokenizer.h" #include "base/string_util.h" namespace { enum ParsingState { KEY_NAME, KEY_VALUE }; } // namespace namespace base { bool LaunchApp(const std::vector& argv, const file_handle_mapping_vector& fds_to_remap, bool wait, ProcessHandle* process_handle) { bool retval = true; char* argv_copy[argv.size() + 1]; for (size_t i = 0; i < argv.size(); i++) { argv_copy[i] = new char[argv[i].size() + 1]; strcpy(argv_copy[i], argv[i].c_str()); } argv_copy[argv.size()] = NULL; // Make sure we don't leak any FDs to the child process by marking all FDs // as close-on-exec. SetAllFDsToCloseOnExec(); int pid = fork(); if (pid == 0) { for (file_handle_mapping_vector::const_iterator it = fds_to_remap.begin(); it != fds_to_remap.end(); ++it) { int src_fd = it->first; int dest_fd = it->second; if (src_fd == dest_fd) { int flags = fcntl(src_fd, F_GETFD); if (flags != -1) { fcntl(src_fd, F_SETFD, flags & ~FD_CLOEXEC); } } else { dup2(src_fd, dest_fd); } } execvp(argv_copy[0], argv_copy); } else if (pid < 0) { retval = false; } else { if (wait) waitpid(pid, 0, 0); if (process_handle) *process_handle = pid; } for (size_t i = 0; i < argv.size(); i++) delete[] argv_copy[i]; return retval; } bool LaunchApp(const CommandLine& cl, bool wait, bool start_hidden, ProcessHandle* process_handle) { file_handle_mapping_vector no_files; return LaunchApp(cl.argv(), no_files, wait, process_handle); } NamedProcessIterator::NamedProcessIterator(const std::wstring& executable_name, const ProcessFilter* filter) : executable_name_(executable_name), filter_(filter) { procfs_dir_ = opendir("/proc"); } NamedProcessIterator::~NamedProcessIterator() { if (procfs_dir_) { closedir(procfs_dir_); procfs_dir_ = NULL; } } const ProcessEntry* NamedProcessIterator::NextProcessEntry() { bool result = false; do { result = CheckForNextProcess(); } while (result && !IncludeEntry()); if (result) return &entry_; return NULL; } bool NamedProcessIterator::CheckForNextProcess() { // TODO(port): skip processes owned by different UID dirent* slot = 0; const char* openparen; const char* closeparen; // Arbitrarily guess that there will never be more than 200 non-process // files in /proc. Hardy has 53. int skipped = 0; const int kSkipLimit = 200; while (skipped < kSkipLimit) { slot = readdir(procfs_dir_); // all done looking through /proc? if (!slot) return false; // If not a process, keep looking for one. bool notprocess = false; int i; for (i = 0; i < NAME_MAX && slot->d_name[i]; ++i) { if (!isdigit(slot->d_name[i])) { notprocess = true; break; } } if (i == NAME_MAX || notprocess) { skipped++; continue; } // Read the process's status. char buf[NAME_MAX + 12]; sprintf(buf, "/proc/%s/stat", slot->d_name); FILE *fp = fopen(buf, "r"); if (!fp) return false; const char* result = fgets(buf, sizeof(buf), fp); fclose(fp); if (!result) return false; // Parse the status. It is formatted like this: // %d (%s) %c %d ... // pid (name) runstate ppid // To avoid being fooled by names containing a closing paren, scan // backwards. openparen = strchr(buf, '('); closeparen = strrchr(buf, ')'); if (!openparen || !closeparen) return false; char runstate = closeparen[2]; // Is the process in 'Zombie' state, i.e. dead but waiting to be reaped? // Allowed values: D R S T Z if (runstate != 'Z') break; // Nope, it's a zombie; somebody isn't cleaning up after their children. // (e.g. WaitForProcessesToExit doesn't clean up after dead children yet.) // There could be a lot of zombies, can't really decrement i here. } if (skipped >= kSkipLimit) { NOTREACHED(); return false; } entry_.pid = atoi(slot->d_name); entry_.ppid = atoi(closeparen + 3); // TODO(port): read pid's commandline's $0, like killall does. Using the // short name between openparen and closeparen won't work for long names! int len = closeparen - openparen - 1; if (len > NAME_MAX) len = NAME_MAX; memcpy(entry_.szExeFile, openparen + 1, len); entry_.szExeFile[len] = 0; return true; } bool NamedProcessIterator::IncludeEntry() { // TODO(port): make this also work for non-ASCII filenames if (WideToASCII(executable_name_) != entry_.szExeFile) return false; if (!filter_) return true; return filter_->Includes(entry_.pid, entry_.ppid); } // To have /proc/self/io file you must enable CONFIG_TASK_IO_ACCOUNTING // in your kernel configuration. bool ProcessMetrics::GetIOCounters(IoCounters* io_counters) const { std::string proc_io_contents; if (!file_util::ReadFileToString(L"/proc/self/io", &proc_io_contents)) return false; (*io_counters).OtherOperationCount = 0; (*io_counters).OtherTransferCount = 0; StringTokenizer tokenizer(proc_io_contents, ": \n"); ParsingState state = KEY_NAME; std::string last_key_name; while (tokenizer.GetNext()) { switch (state) { case KEY_NAME: last_key_name = tokenizer.token(); state = KEY_VALUE; break; case KEY_VALUE: DCHECK(!last_key_name.empty()); if (last_key_name == "syscr") { (*io_counters).ReadOperationCount = StringToInt64(tokenizer.token()); } else if (last_key_name == "syscw") { (*io_counters).WriteOperationCount = StringToInt64(tokenizer.token()); } else if (last_key_name == "rchar") { (*io_counters).ReadTransferCount = StringToInt64(tokenizer.token()); } else if (last_key_name == "wchar") { (*io_counters).WriteTransferCount = StringToInt64(tokenizer.token()); } state = KEY_NAME; break; } } return true; } } // namespace base