#include "config.h" #include "helpers.h" #include #include #include #include #include #include #include #include #include #include #include "almalloc.h" #include "alfstream.h" #include "alnumeric.h" #include "aloptional.h" #include "alspan.h" #include "alstring.h" #include "logging.h" #include "strutils.h" #include "vector.h" /* Mixing thread piority level */ int RTPrioLevel{1}; /* Allow reducing the process's RTTime limit for RTKit. */ bool AllowRTTimeLimit{true}; #ifdef _WIN32 #include const PathNamePair &GetProcBinary() { static al::optional procbin; if(procbin) return *procbin; #if WINAPI_FAMILY == WINAPI_FAMILY_DESKTOP_APP auto fullpath = al::vector(256); DWORD len{GetModuleFileNameW(nullptr, fullpath.data(), static_cast(fullpath.size()))}; while(len == fullpath.size()) { fullpath.resize(fullpath.size() << 1); len = GetModuleFileNameW(nullptr, fullpath.data(), static_cast(fullpath.size())); } if(len == 0) { ERR("Failed to get process name: error %lu\n", GetLastError()); procbin.emplace(); return *procbin; } fullpath.resize(len); if(fullpath.back() != 0) fullpath.push_back(0); std::replace(fullpath.begin(), fullpath.end(), '/', '\\'); auto sep = std::find(fullpath.rbegin()+1, fullpath.rend(), '\\'); if(sep != fullpath.rend()) { *sep = 0; procbin.emplace(wstr_to_utf8(fullpath.data()), wstr_to_utf8(al::to_address(sep.base()))); } else procbin.emplace(std::string{}, wstr_to_utf8(fullpath.data())); TRACE("Got binary: %s, %s\n", procbin->path.c_str(), procbin->fname.c_str()); #endif return *procbin; } namespace { void DirectorySearch(const char *path, const char *ext, al::vector *const results) { std::string pathstr{path}; pathstr += "\\*"; pathstr += ext; TRACE("Searching %s\n", pathstr.c_str()); #if WINAPI_FAMILY == WINAPI_FAMILY_DESKTOP_APP std::wstring wpath{utf8_to_wstr(pathstr.c_str())}; WIN32_FIND_DATAW fdata; HANDLE hdl{FindFirstFileW(wpath.c_str(), &fdata)}; if(hdl == INVALID_HANDLE_VALUE) return; const auto base = results->size(); do { results->emplace_back(); std::string &str = results->back(); str = path; str += '\\'; str += wstr_to_utf8(fdata.cFileName); } while(FindNextFileW(hdl, &fdata)); FindClose(hdl); const al::span newlist{results->data()+base, results->size()-base}; std::sort(newlist.begin(), newlist.end()); for(const auto &name : newlist) TRACE(" got %s\n", name.c_str()); # endif } } // namespace al::vector SearchDataFiles(const char *ext, const char *subdir) { auto is_slash = [](int c) noexcept -> int { return (c == '\\' || c == '/'); }; static std::mutex search_lock; std::lock_guard _{search_lock}; /* If the path is absolute, use it directly. */ al::vector results; if(isalpha(subdir[0]) && subdir[1] == ':' && is_slash(subdir[2])) { std::string path{subdir}; std::replace(path.begin(), path.end(), '/', '\\'); DirectorySearch(path.c_str(), ext, &results); return results; } if(subdir[0] == '\\' && subdir[1] == '\\' && subdir[2] == '?' && subdir[3] == '\\') { DirectorySearch(subdir, ext, &results); return results; } std::string path; /* Search the app-local directory. */ if(auto localpath = al::getenv(L"ALSOFT_LOCAL_PATH")) { path = wstr_to_utf8(localpath->c_str()); if(is_slash(path.back())) path.pop_back(); } #if WINAPI_FAMILY == WINAPI_FAMILY_DESKTOP_APP else if(WCHAR *cwdbuf{_wgetcwd(nullptr, 0)}) { path = wstr_to_utf8(cwdbuf); if(is_slash(path.back())) path.pop_back(); free(cwdbuf); } #endif else path = "."; std::replace(path.begin(), path.end(), '/', '\\'); DirectorySearch(path.c_str(), ext, &results); #if WINAPI_FAMILY == WINAPI_FAMILY_DESKTOP_APP /* Search the local and global data dirs. */ static const int ids[2]{ CSIDL_APPDATA, CSIDL_COMMON_APPDATA }; for(int id : ids) { WCHAR buffer[MAX_PATH]; if(SHGetSpecialFolderPathW(nullptr, buffer, id, FALSE) == FALSE) continue; path = wstr_to_utf8(buffer); if(!is_slash(path.back())) path += '\\'; path += subdir; std::replace(path.begin(), path.end(), '/', '\\'); DirectorySearch(path.c_str(), ext, &results); } #endif return results; } void SetRTPriority(void) { #if WINAPI_FAMILY == WINAPI_FAMILY_DESKTOP_APP if(RTPrioLevel > 0) { if(!SetThreadPriority(GetCurrentThread(), THREAD_PRIORITY_TIME_CRITICAL)) ERR("Failed to set priority level for thread\n"); } #endif } #else #include #include #include #ifdef __FreeBSD__ #include #endif #ifdef __HAIKU__ #include #endif #ifdef HAVE_PROC_PIDPATH #include #endif #if defined(HAVE_PTHREAD_SETSCHEDPARAM) && !defined(__OpenBSD__) #include #include #endif #ifdef HAVE_RTKIT #include #include #include "dbus_wrap.h" #include "rtkit.h" #ifndef RLIMIT_RTTIME #define RLIMIT_RTTIME 15 #endif #endif const PathNamePair &GetProcBinary() { static al::optional procbin; if(procbin) return *procbin; al::vector pathname; #ifdef __FreeBSD__ size_t pathlen; int mib[4] = { CTL_KERN, KERN_PROC, KERN_PROC_PATHNAME, -1 }; if(sysctl(mib, 4, nullptr, &pathlen, nullptr, 0) == -1) WARN("Failed to sysctl kern.proc.pathname: %s\n", strerror(errno)); else { pathname.resize(pathlen + 1); sysctl(mib, 4, pathname.data(), &pathlen, nullptr, 0); pathname.resize(pathlen); } #endif #ifdef HAVE_PROC_PIDPATH if(pathname.empty()) { char procpath[PROC_PIDPATHINFO_MAXSIZE]{}; const pid_t pid{getpid()}; if(proc_pidpath(pid, procpath, sizeof(procpath)) < 1) ERR("proc_pidpath(%d, ...) failed: %s\n", pid, strerror(errno)); else pathname.insert(pathname.end(), procpath, procpath+strlen(procpath)); } #endif #ifdef __HAIKU__ if(pathname.empty()) { char procpath[PATH_MAX]; if(find_path(B_APP_IMAGE_SYMBOL, B_FIND_PATH_IMAGE_PATH, NULL, procpath, sizeof(procpath)) == B_OK) pathname.insert(pathname.end(), procpath, procpath+strlen(procpath)); } #endif #ifndef __SWITCH__ if(pathname.empty()) { static const char SelfLinkNames[][32]{ "/proc/self/exe", "/proc/self/file", "/proc/curproc/exe", "/proc/curproc/file" }; pathname.resize(256); const char *selfname{}; ssize_t len{}; for(const char *name : SelfLinkNames) { selfname = name; len = readlink(selfname, pathname.data(), pathname.size()); if(len >= 0 || errno != ENOENT) break; } while(len > 0 && static_cast(len) == pathname.size()) { pathname.resize(pathname.size() << 1); len = readlink(selfname, pathname.data(), pathname.size()); } if(len <= 0) { WARN("Failed to readlink %s: %s\n", selfname, strerror(errno)); len = 0; } pathname.resize(static_cast(len)); } #endif while(!pathname.empty() && pathname.back() == 0) pathname.pop_back(); auto sep = std::find(pathname.crbegin(), pathname.crend(), '/'); if(sep != pathname.crend()) procbin.emplace(std::string(pathname.cbegin(), sep.base()-1), std::string(sep.base(), pathname.cend())); else procbin.emplace(std::string{}, std::string(pathname.cbegin(), pathname.cend())); TRACE("Got binary: \"%s\", \"%s\"\n", procbin->path.c_str(), procbin->fname.c_str()); return *procbin; } namespace { void DirectorySearch(const char *path, const char *ext, al::vector *const results) { TRACE("Searching %s for *%s\n", path, ext); DIR *dir{opendir(path)}; if(!dir) return; const auto base = results->size(); const size_t extlen{strlen(ext)}; while(struct dirent *dirent{readdir(dir)}) { if(strcmp(dirent->d_name, ".") == 0 || strcmp(dirent->d_name, "..") == 0) continue; const size_t len{strlen(dirent->d_name)}; if(len <= extlen) continue; if(al::strcasecmp(dirent->d_name+len-extlen, ext) != 0) continue; results->emplace_back(); std::string &str = results->back(); str = path; if(str.back() != '/') str.push_back('/'); str += dirent->d_name; } closedir(dir); const al::span newlist{results->data()+base, results->size()-base}; std::sort(newlist.begin(), newlist.end()); for(const auto &name : newlist) TRACE(" got %s\n", name.c_str()); } } // namespace al::vector SearchDataFiles(const char *ext, const char *subdir) { static std::mutex search_lock; std::lock_guard _{search_lock}; al::vector results; if(subdir[0] == '/') { DirectorySearch(subdir, ext, &results); return results; } /* Search the app-local directory. */ if(auto localpath = al::getenv("ALSOFT_LOCAL_PATH")) DirectorySearch(localpath->c_str(), ext, &results); else { al::vector cwdbuf(256); while(!getcwd(cwdbuf.data(), cwdbuf.size())) { if(errno != ERANGE) { cwdbuf.clear(); break; } cwdbuf.resize(cwdbuf.size() << 1); } if(cwdbuf.empty()) DirectorySearch(".", ext, &results); else { DirectorySearch(cwdbuf.data(), ext, &results); cwdbuf.clear(); } } // Search local data dir if(auto datapath = al::getenv("XDG_DATA_HOME")) { std::string &path = *datapath; if(path.back() != '/') path += '/'; path += subdir; DirectorySearch(path.c_str(), ext, &results); } else if(auto homepath = al::getenv("HOME")) { std::string &path = *homepath; if(path.back() == '/') path.pop_back(); path += "/.local/share/"; path += subdir; DirectorySearch(path.c_str(), ext, &results); } // Search global data dirs std::string datadirs{al::getenv("XDG_DATA_DIRS").value_or("/usr/local/share/:/usr/share/")}; size_t curpos{0u}; while(curpos < datadirs.size()) { size_t nextpos{datadirs.find(':', curpos)}; std::string path{(nextpos != std::string::npos) ? datadirs.substr(curpos, nextpos++ - curpos) : datadirs.substr(curpos)}; curpos = nextpos; if(path.empty()) continue; if(path.back() != '/') path += '/'; path += subdir; DirectorySearch(path.c_str(), ext, &results); } #ifdef ALSOFT_INSTALL_DATADIR // Search the installation data directory { std::string path{ALSOFT_INSTALL_DATADIR}; if(!path.empty()) { if(path.back() != '/') path += '/'; path += subdir; DirectorySearch(path.c_str(), ext, &results); } } #endif return results; } namespace { bool SetRTPriorityPthread(int prio) { int err{ENOTSUP}; #if defined(HAVE_PTHREAD_SETSCHEDPARAM) && !defined(__OpenBSD__) /* Get the min and max priority for SCHED_RR. Limit the max priority to * half, for now, to ensure the thread can't take the highest priority and * go rogue. */ int rtmin{sched_get_priority_min(SCHED_RR)}; int rtmax{sched_get_priority_max(SCHED_RR)}; rtmax = (rtmax-rtmin)/2 + rtmin; struct sched_param param{}; param.sched_priority = clampi(prio, rtmin, rtmax); #ifdef SCHED_RESET_ON_FORK err = pthread_setschedparam(pthread_self(), SCHED_RR|SCHED_RESET_ON_FORK, ¶m); if(err == EINVAL) #endif err = pthread_setschedparam(pthread_self(), SCHED_RR, ¶m); if(err == 0) return true; #else std::ignore = prio; #endif WARN("pthread_setschedparam failed: %s (%d)\n", std::strerror(err), err); return false; } bool SetRTPriorityRTKit(int prio) { #ifdef HAVE_RTKIT if(!HasDBus()) { WARN("D-Bus not available\n"); return false; } dbus::Error error; dbus::ConnectionPtr conn{dbus_bus_get(DBUS_BUS_SYSTEM, &error.get())}; if(!conn) { WARN("D-Bus connection failed with %s: %s\n", error->name, error->message); return false; } /* Don't stupidly exit if the connection dies while doing this. */ dbus_connection_set_exit_on_disconnect(conn.get(), false); int nicemin{}; int err{rtkit_get_min_nice_level(conn.get(), &nicemin)}; if(err == -ENOENT) { err = std::abs(err); ERR("Could not query RTKit: %s (%d)\n", std::strerror(err), err); return false; } int rtmax{rtkit_get_max_realtime_priority(conn.get())}; TRACE("Maximum real-time priority: %d, minimum niceness: %d\n", rtmax, nicemin); auto limit_rttime = [](DBusConnection *c) -> int { using ulonglong = unsigned long long; long long maxrttime{rtkit_get_rttime_usec_max(c)}; if(maxrttime <= 0) return static_cast(std::abs(maxrttime)); const ulonglong umaxtime{static_cast(maxrttime)}; struct rlimit rlim{}; if(getrlimit(RLIMIT_RTTIME, &rlim) != 0) return errno; TRACE("RTTime max: %llu (hard: %llu, soft: %llu)\n", umaxtime, static_cast(rlim.rlim_max), static_cast(rlim.rlim_cur)); if(rlim.rlim_max > umaxtime) { rlim.rlim_max = static_cast(std::min(umaxtime, std::numeric_limits::max())); rlim.rlim_cur = std::min(rlim.rlim_cur, rlim.rlim_max); if(setrlimit(RLIMIT_RTTIME, &rlim) != 0) return errno; } return 0; }; if(rtmax > 0) { if(AllowRTTimeLimit) { err = limit_rttime(conn.get()); if(err != 0) WARN("Failed to set RLIMIT_RTTIME for RTKit: %s (%d)\n", std::strerror(err), err); } /* Limit the maximum real-time priority to half. */ rtmax = (rtmax+1)/2; prio = clampi(prio, 1, rtmax); TRACE("Making real-time with priority %d (max: %d)\n", prio, rtmax); err = rtkit_make_realtime(conn.get(), 0, prio); if(err == 0) return true; err = std::abs(err); WARN("Failed to set real-time priority: %s (%d)\n", std::strerror(err), err); } /* Don't try to set the niceness for non-Linux systems. Standard POSIX has * niceness as a per-process attribute, while the intent here is for the * audio processing thread only to get a priority boost. Currently only * Linux is known to have per-thread niceness. */ #ifdef __linux__ if(nicemin < 0) { TRACE("Making high priority with niceness %d\n", nicemin); err = rtkit_make_high_priority(conn.get(), 0, nicemin); if(err == 0) return true; err = std::abs(err); WARN("Failed to set high priority: %s (%d)\n", std::strerror(err), err); } #endif /* __linux__ */ #else std::ignore = prio; WARN("D-Bus not supported\n"); #endif return false; } } // namespace void SetRTPriority() { if(RTPrioLevel <= 0) return; if(SetRTPriorityPthread(RTPrioLevel)) return; if(SetRTPriorityRTKit(RTPrioLevel)) return; } #endif