/* * Copyright (C) 2016 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "fd_utils.h" #include #include #include #include #include #include #include #include #include #include #include #include // Static whitelist of open paths that the zygote is allowed to keep open. static const char* kPathWhitelist[] = { "/apex/com.android.conscrypt/javalib/conscrypt.jar", "/apex/com.android.media/javalib/updatable-media.jar", "/dev/null", "/dev/socket/zygote", "/dev/socket/zygote_secondary", "/dev/socket/usap_pool_primary", "/dev/socket/usap_pool_secondary", "/dev/socket/webview_zygote", "/dev/socket/heapprofd", "/sys/kernel/debug/tracing/trace_marker", "/system/framework/framework-res.apk", "/dev/urandom", "/dev/ion", "/dev/dri/renderD129", // Fixes b/31172436 }; static const char kFdPath[] = "/proc/self/fd"; // static FileDescriptorWhitelist* FileDescriptorWhitelist::Get() { if (instance_ == nullptr) { instance_ = new FileDescriptorWhitelist(); } return instance_; } bool FileDescriptorWhitelist::IsAllowed(const std::string& path) const { // Check the static whitelist path. for (const auto& whitelist_path : kPathWhitelist) { if (path == whitelist_path) return true; } // Check any paths added to the dynamic whitelist. for (const auto& whitelist_path : whitelist_) { if (path == whitelist_path) return true; } // Framework jars are allowed. static const char* kFrameworksPrefix = "/system/framework/"; static const char* kJarSuffix = ".jar"; if (android::base::StartsWith(path, kFrameworksPrefix) && android::base::EndsWith(path, kJarSuffix)) { return true; } // Jars from the runtime apex are allowed. static const char* kRuntimeApexPrefix = "/apex/com.android.runtime/javalib/"; if (android::base::StartsWith(path, kRuntimeApexPrefix) && android::base::EndsWith(path, kJarSuffix)) { return true; } // Whitelist files needed for Runtime Resource Overlay, like these: // /system/vendor/overlay/framework-res.apk // /system/vendor/overlay-subdir/pg/framework-res.apk // /vendor/overlay/framework-res.apk // /vendor/overlay/PG/android-framework-runtime-resource-overlay.apk // /data/resource-cache/system@vendor@overlay@framework-res.apk@idmap // /data/resource-cache/system@vendor@overlay-subdir@pg@framework-res.apk@idmap // See AssetManager.cpp for more details on overlay-subdir. static const char* kOverlayDir = "/system/vendor/overlay/"; static const char* kVendorOverlayDir = "/vendor/overlay"; static const char* kVendorOverlaySubdir = "/system/vendor/overlay-subdir/"; static const char* kSystemProductOverlayDir = "/system/product/overlay/"; static const char* kProductOverlayDir = "/product/overlay"; static const char* kSystemProductServicesOverlayDir = "/system/product_services/overlay/"; static const char* kProductServicesOverlayDir = "/product_services/overlay"; static const char* kSystemOdmOverlayDir = "/system/odm/overlay"; static const char* kOdmOverlayDir = "/odm/overlay"; static const char* kSystemOemOverlayDir = "/system/oem/overlay"; static const char* kOemOverlayDir = "/oem/overlay"; static const char* kApkSuffix = ".apk"; if ((android::base::StartsWith(path, kOverlayDir) || android::base::StartsWith(path, kVendorOverlaySubdir) || android::base::StartsWith(path, kVendorOverlayDir) || android::base::StartsWith(path, kSystemProductOverlayDir) || android::base::StartsWith(path, kProductOverlayDir) || android::base::StartsWith(path, kSystemProductServicesOverlayDir) || android::base::StartsWith(path, kProductServicesOverlayDir) || android::base::StartsWith(path, kSystemOdmOverlayDir) || android::base::StartsWith(path, kOdmOverlayDir) || android::base::StartsWith(path, kSystemOemOverlayDir) || android::base::StartsWith(path, kOemOverlayDir)) && android::base::EndsWith(path, kApkSuffix) && path.find("/../") == std::string::npos) { return true; } static const char* kOverlayIdmapPrefix = "/data/resource-cache/"; static const char* kOverlayIdmapSuffix = ".apk@idmap"; if (android::base::StartsWith(path, kOverlayIdmapPrefix) && android::base::EndsWith(path, kOverlayIdmapSuffix) && path.find("/../") == std::string::npos) { return true; } // All regular files that are placed under this path are whitelisted automatically. static const char* kZygoteWhitelistPath = "/vendor/zygote_whitelist/"; if (android::base::StartsWith(path, kZygoteWhitelistPath) && path.find("/../") == std::string::npos) { return true; } return false; } FileDescriptorWhitelist::FileDescriptorWhitelist() : whitelist_() { } FileDescriptorWhitelist* FileDescriptorWhitelist::instance_ = nullptr; // Keeps track of all relevant information (flags, offset etc.) of an // open zygote file descriptor. class FileDescriptorInfo { public: // Create a FileDescriptorInfo for a given file descriptor. static FileDescriptorInfo* CreateFromFd(int fd, fail_fn_t fail_fn); // Checks whether the file descriptor associated with this object // refers to the same description. bool RefersToSameFile() const; void ReopenOrDetach(fail_fn_t fail_fn) const; const int fd; const struct stat stat; const std::string file_path; const int open_flags; const int fd_flags; const int fs_flags; const off_t offset; const bool is_sock; private: explicit FileDescriptorInfo(int fd); FileDescriptorInfo(struct stat stat, const std::string& file_path, int fd, int open_flags, int fd_flags, int fs_flags, off_t offset); // Returns the locally-bound name of the socket |fd|. Returns true // iff. all of the following hold : // // - the socket's sa_family is AF_UNIX. // - the length of the path is greater than zero (i.e, not an unnamed socket). // - the first byte of the path isn't zero (i.e, not a socket with an abstract // address). static bool GetSocketName(const int fd, std::string* result); void DetachSocket(fail_fn_t fail_fn) const; DISALLOW_COPY_AND_ASSIGN(FileDescriptorInfo); }; // static FileDescriptorInfo* FileDescriptorInfo::CreateFromFd(int fd, fail_fn_t fail_fn) { struct stat f_stat; // This should never happen; the zygote should always have the right set // of permissions required to stat all its open files. if (TEMP_FAILURE_RETRY(fstat(fd, &f_stat)) == -1) { fail_fn(android::base::StringPrintf("Unable to stat %d", fd)); } const FileDescriptorWhitelist* whitelist = FileDescriptorWhitelist::Get(); if (S_ISSOCK(f_stat.st_mode)) { std::string socket_name; if (!GetSocketName(fd, &socket_name)) { fail_fn("Unable to get socket name"); } if (!whitelist->IsAllowed(socket_name)) { fail_fn(android::base::StringPrintf("Socket name not whitelisted : %s (fd=%d)", socket_name.c_str(), fd)); } return new FileDescriptorInfo(fd); } // We only handle whitelisted regular files and character devices. Whitelisted // character devices must provide a guarantee of sensible behaviour when // reopened. // // S_ISDIR : Not supported. (We could if we wanted to, but it's unused). // S_ISLINK : Not supported. // S_ISBLK : Not supported. // S_ISFIFO : Not supported. Note that the Zygote and USAPs use pipes to // communicate with the child processes across forks but those should have been // added to the redirection exemption list. if (!S_ISCHR(f_stat.st_mode) && !S_ISREG(f_stat.st_mode)) { std::string mode = "Unknown"; if (S_ISDIR(f_stat.st_mode)) { mode = "DIR"; } else if (S_ISLNK(f_stat.st_mode)) { mode = "LINK"; } else if (S_ISBLK(f_stat.st_mode)) { mode = "BLOCK"; } else if (S_ISFIFO(f_stat.st_mode)) { mode = "FIFO"; } fail_fn(android::base::StringPrintf("Unsupported st_mode for FD %d: %s", fd, mode.c_str())); } std::string file_path; const std::string fd_path = android::base::StringPrintf("/proc/self/fd/%d", fd); if (!android::base::Readlink(fd_path, &file_path)) { fail_fn(android::base::StringPrintf("Could not read fd link %s: %s", fd_path.c_str(), strerror(errno))); } if (!whitelist->IsAllowed(file_path)) { fail_fn(std::string("Not whitelisted : ").append(file_path)); } // File descriptor flags : currently on FD_CLOEXEC. We can set these // using F_SETFD - we're single threaded at this point of execution so // there won't be any races. const int fd_flags = TEMP_FAILURE_RETRY(fcntl(fd, F_GETFD)); if (fd_flags == -1) { fail_fn(android::base::StringPrintf("Failed fcntl(%d, F_GETFD) (%s): %s", fd, file_path.c_str(), strerror(errno))); } // File status flags : // - File access mode : (O_RDONLY, O_WRONLY...) we'll pass these through // to the open() call. // // - File creation flags : (O_CREAT, O_EXCL...) - there's not much we can // do about these, since the file has already been created. We shall ignore // them here. // // - Other flags : We'll have to set these via F_SETFL. On linux, F_SETFL // can only set O_APPEND, O_ASYNC, O_DIRECT, O_NOATIME, and O_NONBLOCK. // In particular, it can't set O_SYNC and O_DSYNC. We'll have to test for // their presence and pass them in to open(). int fs_flags = TEMP_FAILURE_RETRY(fcntl(fd, F_GETFL)); if (fs_flags == -1) { fail_fn(android::base::StringPrintf("Failed fcntl(%d, F_GETFL) (%s): %s", fd, file_path.c_str(), strerror(errno))); } // File offset : Ignore the offset for non seekable files. const off_t offset = TEMP_FAILURE_RETRY(lseek64(fd, 0, SEEK_CUR)); // We pass the flags that open accepts to open, and use F_SETFL for // the rest of them. static const int kOpenFlags = (O_RDONLY | O_WRONLY | O_RDWR | O_DSYNC | O_SYNC); int open_flags = fs_flags & (kOpenFlags); fs_flags = fs_flags & (~(kOpenFlags)); return new FileDescriptorInfo(f_stat, file_path, fd, open_flags, fd_flags, fs_flags, offset); } bool FileDescriptorInfo::RefersToSameFile() const { struct stat f_stat; if (TEMP_FAILURE_RETRY(fstat(fd, &f_stat)) == -1) { PLOG(ERROR) << "Unable to restat fd " << fd; return false; } return f_stat.st_ino == stat.st_ino && f_stat.st_dev == stat.st_dev; } void FileDescriptorInfo::ReopenOrDetach(fail_fn_t fail_fn) const { if (is_sock) { return DetachSocket(fail_fn); } // NOTE: This might happen if the file was unlinked after being opened. // It's a common pattern in the case of temporary files and the like but // we should not allow such usage from the zygote. const int new_fd = TEMP_FAILURE_RETRY(open(file_path.c_str(), open_flags)); if (new_fd == -1) { fail_fn(android::base::StringPrintf("Failed open(%s, %i): %s", file_path.c_str(), open_flags, strerror(errno))); } if (TEMP_FAILURE_RETRY(fcntl(new_fd, F_SETFD, fd_flags)) == -1) { close(new_fd); fail_fn(android::base::StringPrintf("Failed fcntl(%d, F_SETFD, %d) (%s): %s", new_fd, fd_flags, file_path.c_str(), strerror(errno))); } if (TEMP_FAILURE_RETRY(fcntl(new_fd, F_SETFL, fs_flags)) == -1) { close(new_fd); fail_fn(android::base::StringPrintf("Failed fcntl(%d, F_SETFL, %d) (%s): %s", new_fd, fs_flags, file_path.c_str(), strerror(errno))); } if (offset != -1 && TEMP_FAILURE_RETRY(lseek64(new_fd, offset, SEEK_SET)) == -1) { close(new_fd); fail_fn(android::base::StringPrintf("Failed lseek64(%d, SEEK_SET) (%s): %s", new_fd, file_path.c_str(), strerror(errno))); } int dup_flags = (fd_flags & FD_CLOEXEC) ? O_CLOEXEC : 0; if (TEMP_FAILURE_RETRY(dup3(new_fd, fd, dup_flags)) == -1) { close(new_fd); fail_fn(android::base::StringPrintf("Failed dup3(%d, %d, %d) (%s): %s", fd, new_fd, dup_flags, file_path.c_str(), strerror(errno))); } close(new_fd); } FileDescriptorInfo::FileDescriptorInfo(int fd) : fd(fd), stat(), open_flags(0), fd_flags(0), fs_flags(0), offset(0), is_sock(true) { } FileDescriptorInfo::FileDescriptorInfo(struct stat stat, const std::string& file_path, int fd, int open_flags, int fd_flags, int fs_flags, off_t offset) : fd(fd), stat(stat), file_path(file_path), open_flags(open_flags), fd_flags(fd_flags), fs_flags(fs_flags), offset(offset), is_sock(false) { } bool FileDescriptorInfo::GetSocketName(const int fd, std::string* result) { sockaddr_storage ss; sockaddr* addr = reinterpret_cast(&ss); socklen_t addr_len = sizeof(ss); if (TEMP_FAILURE_RETRY(getsockname(fd, addr, &addr_len)) == -1) { PLOG(ERROR) << "Failed getsockname(" << fd << ")"; return false; } if (addr->sa_family != AF_UNIX) { LOG(ERROR) << "Unsupported socket (fd=" << fd << ") with family " << addr->sa_family; return false; } const sockaddr_un* unix_addr = reinterpret_cast(&ss); size_t path_len = addr_len - offsetof(struct sockaddr_un, sun_path); // This is an unnamed local socket, we do not accept it. if (path_len == 0) { LOG(ERROR) << "Unsupported AF_UNIX socket (fd=" << fd << ") with empty path."; return false; } // This is a local socket with an abstract address. Remove the leading NUL byte and // add a human-readable "ABSTRACT/" prefix. if (unix_addr->sun_path[0] == '\0') { *result = "ABSTRACT/"; result->append(&unix_addr->sun_path[1], path_len - 1); return true; } // If we're here, sun_path must refer to a null terminated filesystem // pathname (man 7 unix). Remove the terminator before assigning it to an // std::string. if (unix_addr->sun_path[path_len - 1] == '\0') { --path_len; } result->assign(unix_addr->sun_path, path_len); return true; } void FileDescriptorInfo::DetachSocket(fail_fn_t fail_fn) const { const int dev_null_fd = open("/dev/null", O_RDWR | O_CLOEXEC); if (dev_null_fd < 0) { fail_fn(std::string("Failed to open /dev/null: ").append(strerror(errno))); } if (dup3(dev_null_fd, fd, O_CLOEXEC) == -1) { fail_fn(android::base::StringPrintf("Failed dup3 on socket descriptor %d: %s", fd, strerror(errno))); } if (close(dev_null_fd) == -1) { fail_fn(android::base::StringPrintf("Failed close(%d): %s", dev_null_fd, strerror(errno))); } } // static FileDescriptorTable* FileDescriptorTable::Create(const std::vector& fds_to_ignore, fail_fn_t fail_fn) { DIR* proc_fd_dir = opendir(kFdPath); if (proc_fd_dir == nullptr) { fail_fn(std::string("Unable to open directory ").append(kFdPath)); } int dir_fd = dirfd(proc_fd_dir); dirent* dir_entry; std::unordered_map open_fd_map; while ((dir_entry = readdir(proc_fd_dir)) != nullptr) { const int fd = ParseFd(dir_entry, dir_fd); if (fd == -1) { continue; } if (std::find(fds_to_ignore.begin(), fds_to_ignore.end(), fd) != fds_to_ignore.end()) { continue; } open_fd_map[fd] = FileDescriptorInfo::CreateFromFd(fd, fail_fn); } if (closedir(proc_fd_dir) == -1) { fail_fn("Unable to close directory"); } return new FileDescriptorTable(open_fd_map); } void FileDescriptorTable::Restat(const std::vector& fds_to_ignore, fail_fn_t fail_fn) { std::set open_fds; // First get the list of open descriptors. DIR* proc_fd_dir = opendir(kFdPath); if (proc_fd_dir == nullptr) { fail_fn(android::base::StringPrintf("Unable to open directory %s: %s", kFdPath, strerror(errno))); } int dir_fd = dirfd(proc_fd_dir); dirent* dir_entry; while ((dir_entry = readdir(proc_fd_dir)) != nullptr) { const int fd = ParseFd(dir_entry, dir_fd); if (fd == -1) { continue; } if (std::find(fds_to_ignore.begin(), fds_to_ignore.end(), fd) != fds_to_ignore.end()) { continue; } open_fds.insert(fd); } if (closedir(proc_fd_dir) == -1) { fail_fn(android::base::StringPrintf("Unable to close directory: %s", strerror(errno))); } RestatInternal(open_fds, fail_fn); } // Reopens all file descriptors that are contained in the table. void FileDescriptorTable::ReopenOrDetach(fail_fn_t fail_fn) { std::unordered_map::const_iterator it; for (it = open_fd_map_.begin(); it != open_fd_map_.end(); ++it) { const FileDescriptorInfo* info = it->second; if (info == nullptr) { return; } else { info->ReopenOrDetach(fail_fn); } } } FileDescriptorTable::FileDescriptorTable( const std::unordered_map& map) : open_fd_map_(map) { } void FileDescriptorTable::RestatInternal(std::set& open_fds, fail_fn_t fail_fn) { // Iterate through the list of file descriptors we've already recorded // and check whether : // // (a) they continue to be open. // (b) they refer to the same file. // // We'll only store the last error message. std::unordered_map::iterator it = open_fd_map_.begin(); while (it != open_fd_map_.end()) { std::set::const_iterator element = open_fds.find(it->first); if (element == open_fds.end()) { // The entry from the file descriptor table is no longer in the list // of open files. We warn about this condition and remove it from // the list of FDs under consideration. // // TODO(narayan): This will be an error in a future android release. // error = true; // ALOGW("Zygote closed file descriptor %d.", it->first); it = open_fd_map_.erase(it); } else { // The entry from the file descriptor table is still open. Restat // it and check whether it refers to the same file. if (!it->second->RefersToSameFile()) { // The file descriptor refers to a different description. We must // update our entry in the table. delete it->second; it->second = FileDescriptorInfo::CreateFromFd(*element, fail_fn); } else { // It's the same file. Nothing to do here. Move on to the next open // FD. } ++it; // Finally, remove the FD from the set of open_fds. We do this last because // |element| will not remain valid after a call to erase. open_fds.erase(element); } } if (open_fds.size() > 0) { // The zygote has opened new file descriptors since our last inspection. // We warn about this condition and add them to our table. // // TODO(narayan): This will be an error in a future android release. // error = true; // ALOGW("Zygote opened %zd new file descriptor(s).", open_fds.size()); // TODO(narayan): This code will be removed in a future android release. std::set::const_iterator it; for (it = open_fds.begin(); it != open_fds.end(); ++it) { const int fd = (*it); open_fd_map_[fd] = FileDescriptorInfo::CreateFromFd(fd, fail_fn); } } } // static int FileDescriptorTable::ParseFd(dirent* dir_entry, int dir_fd) { char* end; const int fd = strtol(dir_entry->d_name, &end, 10); if ((*end) != '\0') { return -1; } // Don't bother with the standard input/output/error, they're handled // specially post-fork anyway. if (fd <= STDERR_FILENO || fd == dir_fd) { return -1; } return fd; }