// This file Copyright © 2009-2022 Mnemosyne LLC. // It may be used under GPLv2 (SPDX: GPL-2.0-only), GPLv3 (SPDX: GPL-3.0-only), // or any future license endorsed by Mnemosyne LLC. // License text can be found in the licenses/ folder. #include // std::sort #include // std::array #include /* isdigit() */ #include #include // DBL_DIG #include #include // localeconv() #include // SIZE_MAX #include // getenv() #include /* strerror() */ #include // nanosleep() #include // std::back_inserter #include #include #include #include #ifdef _WIN32 #include /* Sleep(), GetEnvironmentVariable() */ #include /* CommandLineToArgv() */ #include /* WSAStartup() */ #endif #ifdef HAVE_ICONV #include #endif #define UTF_CPP_CPLUSPLUS 201703L #include #include #include #include "transmission.h" #include "error-types.h" #include "error.h" #include "log.h" #include "mime-types.h" #include "net.h" // ntohl() #include "platform-quota.h" /* tr_device_info_create(), tr_device_info_get_disk_space(), tr_device_info_free() */ #include "tr-assert.h" #include "utils.h" #include "variant.h" using namespace std::literals; time_t __tr_current_time = 0; /*** **** ***/ struct tm* tr_gmtime_r(time_t const* timep, struct tm* result) { #if defined(HAVE_GMTIME_R) return gmtime_r(timep, result); #elif defined(HAVE_GMTIME_S) return gmtime_s(result, timep) == 0 ? result : nullptr; #else struct tm* p = gmtime(timep); if (p != nullptr) { *result = *p; return result; } return nullptr; #endif } struct tm* tr_localtime_r(time_t const* timep, struct tm* result) { #if defined(HAVE_LOCALTIME_R) return localtime_r(timep, result); #elif defined(HAVE_LOCALTIME_S) return localtime_s(result, timep) == 0 ? result : nullptr; #else struct tm* p = localtime(timep); if (p != nullptr) { *result = *p; return result; } return nullptr; #endif } struct timeval tr_gettimeofday() { auto const d = std::chrono::system_clock::now().time_since_epoch(); auto const s = std::chrono::duration_cast(d); auto ret = timeval{}; ret.tv_sec = s.count(); ret.tv_usec = std::chrono::duration_cast(d - s).count(); return ret; } /*** **** ***/ void* tr_malloc(size_t size) { return size != 0 ? malloc(size) : nullptr; } void* tr_malloc0(size_t size) { return size != 0 ? calloc(1, size) : nullptr; } void* tr_realloc(void* p, size_t size) { void* result = size != 0 ? realloc(p, size) : nullptr; if (result == nullptr) { tr_free(p); } return result; } void tr_free(void* p) { if (p != nullptr) { free(p); } } void* tr_memdup(void const* src, size_t byteCount) { return memcpy(tr_malloc(byteCount), src, byteCount); } /*** **** ***/ char const* tr_strip_positional_args(char const* str) { static auto buf = std::array{}; char const* in = str; size_t pos = 0; for (; (str != nullptr) && (*str != 0) && pos + 1 < std::size(buf); ++str) { buf[pos++] = *str; if (*str == '%' && (isdigit(str[1]) != 0)) { char const* tmp = str + 1; while (isdigit(*tmp) != 0) { ++tmp; } if (*tmp == '$') { str = tmp[1] == '\'' ? tmp + 1 : tmp; } } if (*str == '%' && str[1] == '\'') { str = str + 1; } } buf[pos] = '\0'; return (in != nullptr) && (strcmp(buf.data(), in) == 0) ? in : buf.data(); } /** *** **/ void tr_timerAdd(struct event* timer, int seconds, int microseconds) { auto tv = timeval{}; tv.tv_sec = seconds; tv.tv_usec = microseconds; TR_ASSERT(tv.tv_sec >= 0); TR_ASSERT(tv.tv_usec >= 0); TR_ASSERT(tv.tv_usec < 1000000); evtimer_add(timer, &tv); } void tr_timerAddMsec(struct event* timer, int msec) { int const seconds = msec / 1000; int const usec = (msec % 1000) * 1000; tr_timerAdd(timer, seconds, usec); } /** *** **/ uint8_t* tr_loadFile(char const* path, size_t* size, tr_error** error) { char const* const err_fmt = _("Couldn't read \"%1$s\": %2$s"); /* try to stat the file */ auto info = tr_sys_path_info{}; tr_error* my_error = nullptr; if (!tr_sys_path_get_info(path, 0, &info, &my_error)) { tr_logAddDebug(err_fmt, path, my_error->message); tr_error_propagate(error, &my_error); return nullptr; } if (info.type != TR_SYS_PATH_IS_FILE) { tr_logAddError(err_fmt, path, _("Not a regular file")); tr_error_set(error, TR_ERROR_EISDIR, "Not a regular file"sv); return nullptr; } /* file size should be able to fit into size_t */ if constexpr (sizeof(info.size) > sizeof(*size)) { TR_ASSERT(info.size <= SIZE_MAX); } /* Load the torrent file into our buffer */ auto const fd = tr_sys_file_open(path, TR_SYS_FILE_READ | TR_SYS_FILE_SEQUENTIAL, 0, &my_error); if (fd == TR_BAD_SYS_FILE) { tr_logAddError(err_fmt, path, my_error->message); tr_error_propagate(error, &my_error); return nullptr; } auto* buf = static_cast(tr_malloc(info.size + 1)); if (!tr_sys_file_read(fd, buf, info.size, nullptr, &my_error)) { tr_logAddError(err_fmt, path, my_error->message); tr_sys_file_close(fd, nullptr); tr_free(buf); tr_error_propagate(error, &my_error); return nullptr; } tr_sys_file_close(fd, nullptr); buf[info.size] = '\0'; *size = info.size; return buf; } bool tr_loadFile(std::vector& setme, std::string const& path, tr_error** error) { char const* const err_fmt = _("Couldn't read \"%1$s\": %2$s"); auto const* const path_sz = path.c_str(); /* try to stat the file */ auto info = tr_sys_path_info{}; tr_error* my_error = nullptr; if (!tr_sys_path_get_info(path_sz, 0, &info, &my_error)) { tr_logAddDebug(err_fmt, path_sz, my_error->message); tr_error_propagate(error, &my_error); return false; } if (info.type != TR_SYS_PATH_IS_FILE) { tr_logAddError(err_fmt, path_sz, _("Not a regular file")); tr_error_set(error, TR_ERROR_EISDIR, "Not a regular file"sv); return false; } /* Load the torrent file into our buffer */ auto const fd = tr_sys_file_open(path_sz, TR_SYS_FILE_READ | TR_SYS_FILE_SEQUENTIAL, 0, &my_error); if (fd == TR_BAD_SYS_FILE) { tr_logAddError(err_fmt, path_sz, my_error->message); tr_error_propagate(error, &my_error); return false; } setme.resize(info.size); if (!tr_sys_file_read(fd, std::data(setme), info.size, nullptr, &my_error)) { tr_logAddError(err_fmt, path_sz, my_error->message); tr_sys_file_close(fd, nullptr); tr_error_propagate(error, &my_error); return false; } tr_sys_file_close(fd, nullptr); return true; } bool tr_saveFile(std::string const& filename, std::string_view contents, tr_error** error) { // follow symlinks to find the "real" file, to make sure the temporary // we build with tr_sys_file_open_temp() is created on the right partition if (char* const real_filename_c_str = tr_sys_path_resolve(filename.c_str(), nullptr); real_filename_c_str != nullptr) { auto const real_filename = std::string{ real_filename_c_str }; tr_free(real_filename_c_str); if (real_filename != filename) { return tr_saveFile(real_filename, contents, error); } } // Write it to a temp file first. // This is a safeguard against edge cases, e.g. disk full, crash while writing, etc. auto tmp = tr_strvJoin(filename, ".tmp.XXXXXX"sv); auto const fd = tr_sys_file_open_temp(std::data(tmp), error); if (fd == TR_BAD_SYS_FILE) { return false; } // Save the contents. This might take >1 pass. auto ok = bool{ true }; while (!std::empty(contents)) { auto n_written = uint64_t{}; if (!tr_sys_file_write(fd, std::data(contents), std::size(contents), &n_written, error)) { ok = false; break; } contents.remove_prefix(n_written); } // If we saved it to disk successfully, move it from '.tmp' to the correct filename if (!tr_sys_file_close(fd, error) || !ok || !tr_sys_path_rename(tmp.c_str(), filename.c_str(), error)) { return false; } tr_logAddInfo(_("Saved \"%s\""), filename.c_str()); return true; } tr_disk_space tr_dirSpace(std::string_view dir) { if (std::empty(dir)) { errno = EINVAL; return { -1, -1 }; } return tr_device_info_get_disk_space(tr_device_info_create(dir)); } /**** ***** ****/ std::string evbuffer_free_to_str(evbuffer* buf) { auto const n = evbuffer_get_length(buf); auto ret = std::string{}; ret.resize(n); evbuffer_copyout(buf, std::data(ret), n); evbuffer_free(buf); return ret; } static char* evbuffer_free_to_str(struct evbuffer* buf, size_t* result_len) { size_t const n = evbuffer_get_length(buf); auto* const ret = tr_new(char, n + 1); evbuffer_copyout(buf, ret, n); evbuffer_free(buf); ret[n] = '\0'; if (result_len != nullptr) { *result_len = n; } return ret; } char* tr_strvDup(std::string_view in) { auto const n = std::size(in); auto* const ret = tr_new(char, n + 1); std::copy(std::begin(in), std::end(in), ret); ret[n] = '\0'; return ret; } char* tr_strndup(void const* vin, size_t len) { auto const* const in = static_cast(vin); return in == nullptr ? nullptr : tr_strvDup({ in, len }); } char* tr_strdup(void const* in) { return in == nullptr ? nullptr : tr_strvDup(static_cast(in)); } extern "C" { int DoMatch(char const* text, char const* p); } /* User-level routine. returns whether or not 'text' and 'p' matched */ bool tr_wildmat(char const* text, char const* p) { return (p[0] == '*' && p[1] == '\0') || (DoMatch(text, p) != 0); } char* tr_strdup_printf(char const* fmt, ...) { evbuffer* const buf = evbuffer_new(); va_list ap; va_start(ap, fmt); evbuffer_add_vprintf(buf, fmt, ap); va_end(ap); return evbuffer_free_to_str(buf, nullptr); } char const* tr_strerror(int i) { char const* ret = strerror(i); if (ret == nullptr) { ret = "Unknown Error"; } return ret; } int tr_strcmp0(char const* str1, char const* str2) { if (str1 != nullptr && str2 != nullptr) { return strcmp(str1, str2); } if (str1 != nullptr) { return 1; } if (str2 != nullptr) { return -1; } return 0; } /**** ***** ****/ std::string_view tr_strvStrip(std::string_view str) { auto constexpr test = [](auto ch) { return isspace(ch); }; auto const it = std::find_if_not(std::begin(str), std::end(str), test); str.remove_prefix(std::distance(std::begin(str), it)); auto const rit = std::find_if_not(std::rbegin(str), std::rend(str), test); str.remove_suffix(std::distance(std::rbegin(str), rit)); return str; } bool tr_str_has_suffix(char const* str, char const* suffix) { if (str == nullptr) { return false; } if (suffix == nullptr) { return true; } auto const str_len = strlen(str); auto const suffix_len = strlen(suffix); if (str_len < suffix_len) { return false; } return evutil_ascii_strncasecmp(str + str_len - suffix_len, suffix, suffix_len) == 0; } /**** ***** ****/ uint64_t tr_time_msec() { auto const tv = tr_gettimeofday(); return uint64_t(tv.tv_sec) * 1000 + (tv.tv_usec / 1000); } void tr_wait_msec(long int msec) { #ifdef _WIN32 Sleep((DWORD)msec); #else struct timespec ts; ts.tv_sec = msec / 1000; ts.tv_nsec = (msec % 1000) * 1000000; nanosleep(&ts, nullptr); #endif } /*** **** ***/ int tr_snprintf(void* buf, size_t buflen, char const* fmt, ...) { va_list args; va_start(args, fmt); int len = evutil_vsnprintf(static_cast(buf), buflen, fmt, args); va_end(args); return len; } /* * Copy src to string dst of size siz. At most siz-1 characters * will be copied. Always NUL terminates (unless siz == 0). * Returns strlen (src); if retval >= siz, truncation occurred. */ size_t tr_strlcpy(void* vdst, void const* vsrc, size_t siz) { auto* dst = static_cast(vdst); auto const* const src = static_cast(vsrc); TR_ASSERT(dst != nullptr); TR_ASSERT(src != nullptr); #ifdef HAVE_STRLCPY return strlcpy(dst, src, siz); #else auto* d = dst; auto const* s = src; size_t n = siz; /* Copy as many bytes as will fit */ if (n != 0) { while (--n != 0) { if ((*d++ = *s++) == '\0') { break; } } } /* Not enough room in dst, add NUL and traverse rest of src */ if (n == 0) { if (siz != 0) { *d = '\0'; /* NUL-terminate dst */ } while (*s++ != '\0') { } } return s - (char const*)src - 1; /* count does not include NUL */ #endif } /*** **** ***/ double tr_getRatio(uint64_t numerator, uint64_t denominator) { if (denominator > 0) { return numerator / (double)denominator; } if (numerator > 0) { return TR_RATIO_INF; } return TR_RATIO_NA; } /*** **** ***/ void tr_removeElementFromArray(void* array, size_t index_to_remove, size_t sizeof_element, size_t nmemb) { auto* a = static_cast(array); memmove( a + sizeof_element * index_to_remove, a + sizeof_element * (index_to_remove + 1), sizeof_element * (--nmemb - index_to_remove)); } /*** **** ***/ bool tr_utf8_validate(std::string_view sv, char const** good_end) { auto const* begin = std::data(sv); auto const* const end = begin + std::size(sv); auto const* walk = begin; auto all_good = false; try { while (walk < end) { utf8::next(walk, end); } all_good = true; } catch (utf8::exception const&) { all_good = false; } if (good_end != nullptr) { *good_end = walk; } return all_good; } static char* strip_non_utf8(std::string_view sv) { auto* const ret = tr_new(char, std::size(sv) + 1); if (ret != nullptr) { auto const it = utf8::unchecked::replace_invalid(std::data(sv), std::data(sv) + std::size(sv), ret, '?'); *it = '\0'; } return ret; } static char* to_utf8(std::string_view sv) { #ifdef HAVE_ICONV size_t const buflen = std::size(sv) * 4 + 10; auto* const out = tr_new(char, buflen); auto constexpr Encodings = std::array{ "CURRENT", "ISO-8859-15" }; for (auto const* test_encoding : Encodings) { iconv_t cd = iconv_open("UTF-8", test_encoding); if (cd == (iconv_t)-1) // NOLINT(performance-no-int-to-ptr) { continue; } #ifdef ICONV_SECOND_ARGUMENT_IS_CONST auto const* inbuf = std::data(sv); #else auto* inbuf = const_cast(std::data(sv)); #endif char* outbuf = out; size_t inbytesleft = std::size(sv); size_t outbytesleft = buflen; auto const rv = iconv(cd, &inbuf, &inbytesleft, &outbuf, &outbytesleft); iconv_close(cd); if (rv != size_t(-1)) { char* const ret = tr_strndup(out, buflen - outbytesleft); tr_free(out); return ret; } } tr_free(out); #endif return strip_non_utf8(sv); } std::string& tr_strvUtf8Clean(std::string_view cleanme, std::string& setme) { if (tr_utf8_validate(cleanme, nullptr)) { setme = cleanme; } else { auto* const tmp = to_utf8(cleanme); setme.assign(tmp != nullptr ? tmp : ""); tr_free(tmp); } return setme; } #ifdef _WIN32 char* tr_win32_native_to_utf8(wchar_t const* text, int text_size) { return tr_win32_native_to_utf8_ex(text, text_size, 0, 0, nullptr); } char* tr_win32_native_to_utf8_ex( wchar_t const* text, int text_size, int extra_chars_before, int extra_chars_after, int* real_result_size) { char* ret = nullptr; int size; if (text_size == -1) { text_size = wcslen(text); } size = WideCharToMultiByte(CP_UTF8, 0, text, text_size, nullptr, 0, nullptr, nullptr); if (size == 0) { goto fail; } ret = tr_new(char, size + extra_chars_before + extra_chars_after + 1); size = WideCharToMultiByte(CP_UTF8, 0, text, text_size, ret + extra_chars_before, size, nullptr, nullptr); if (size == 0) { goto fail; } ret[size + extra_chars_before + extra_chars_after] = '\0'; if (real_result_size != nullptr) { *real_result_size = size; } return ret; fail: tr_free(ret); return nullptr; } wchar_t* tr_win32_utf8_to_native(char const* text, int text_size) { return tr_win32_utf8_to_native_ex(text, text_size, 0, 0, nullptr); } wchar_t* tr_win32_utf8_to_native_ex( char const* text, int text_size, int extra_chars_before, int extra_chars_after, int* real_result_size) { wchar_t* ret = nullptr; int size; if (text_size == -1) { text_size = strlen(text); } size = MultiByteToWideChar(CP_UTF8, 0, text, text_size, nullptr, 0); if (size == 0) { goto fail; } ret = tr_new(wchar_t, size + extra_chars_before + extra_chars_after + 1); size = MultiByteToWideChar(CP_UTF8, 0, text, text_size, ret + extra_chars_before, size); if (size == 0) { goto fail; } ret[size + extra_chars_before + extra_chars_after] = L'\0'; if (real_result_size != nullptr) { *real_result_size = size; } return ret; fail: tr_free(ret); return nullptr; } char* tr_win32_format_message(uint32_t code) { wchar_t* wide_text = nullptr; DWORD wide_size; char* text = nullptr; size_t text_size; wide_size = FormatMessageW( FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS, nullptr, code, 0, (LPWSTR)&wide_text, 0, nullptr); if (wide_size == 0) { return tr_strdup_printf("Unknown error (0x%08x)", code); } if (wide_size != 0 && wide_text != nullptr) { text = tr_win32_native_to_utf8(wide_text, wide_size); } LocalFree(wide_text); if (text != nullptr) { /* Most (all?) messages contain "\r\n" in the end, chop it */ text_size = strlen(text); while (text_size > 0 && isspace((uint8_t)text[text_size - 1])) { text[--text_size] = '\0'; } } return text; } void tr_win32_make_args_utf8(int* argc, char*** argv) { int my_argc; wchar_t** my_wide_argv; my_wide_argv = CommandLineToArgvW(GetCommandLineW(), &my_argc); if (my_wide_argv == nullptr) { return; } TR_ASSERT(*argc == my_argc); char** my_argv = tr_new(char*, my_argc + 1); int processed_argc = 0; for (int i = 0; i < my_argc; ++i, ++processed_argc) { my_argv[i] = tr_win32_native_to_utf8(my_wide_argv[i], -1); if (my_argv[i] == nullptr) { break; } } if (processed_argc < my_argc) { for (int i = 0; i < processed_argc; ++i) { tr_free(my_argv[i]); } tr_free(my_argv); } else { my_argv[my_argc] = nullptr; *argc = my_argc; *argv = my_argv; /* TODO: Add atexit handler to cleanup? */ } LocalFree(my_wide_argv); } int tr_main_win32(int argc, char** argv, int (*real_main)(int, char**)) { tr_win32_make_args_utf8(&argc, &argv); SetConsoleCP(CP_UTF8); SetConsoleOutputCP(CP_UTF8); return (*real_main)(argc, argv); } #endif /*** **** ***/ struct number_range { int low; int high; }; /** * This should be a single number (ex. "6") or a range (ex. "6-9"). * Anything else is an error and will return failure. */ static bool parseNumberSection(std::string_view str, number_range& range) { auto constexpr Delimiter = "-"sv; auto const first = tr_parseNum(str); if (!first) { return false; } range.low = range.high = *first; if (std::empty(str)) { return true; } if (!tr_strvStartsWith(str, Delimiter)) { return false; } str.remove_prefix(std::size(Delimiter)); auto const second = tr_parseNum(str); if (!second) { return false; } range.high = *second; return true; } /** * Given a string like "1-4" or "1-4,6,9,14-51", this allocates and returns an * array of setmeCount ints of all the values in the array. * For example, "5-8" will return [ 5, 6, 7, 8 ] and setmeCount will be 4. * It's the caller's responsibility to call tr_free () on the returned array. * If a fragment of the string can't be parsed, nullptr is returned. */ std::vector tr_parseNumberRange(std::string_view str) { auto values = std::set{}; auto token = std::string_view{}; auto range = number_range{}; while (tr_strvSep(&str, &token, ',') && parseNumberSection(token, range)) { for (auto i = range.low; i <= range.high; ++i) { values.insert(i); } } return { std::begin(values), std::end(values) }; } /*** **** ***/ double tr_truncd(double x, int precision) { char buf[128]; tr_snprintf(buf, sizeof(buf), "%.*f", TR_ARG_TUPLE(DBL_DIG, x)); if (auto* const pt = strstr(buf, localeconv()->decimal_point); pt != nullptr) { pt[precision != 0 ? precision + 1 : 0] = '\0'; } return atof(buf); } /* return a truncated double as a string */ static char* tr_strtruncd(char* buf, double x, int precision, size_t buflen) { tr_snprintf(buf, buflen, "%.*f", precision, tr_truncd(x, precision)); return buf; } std::string tr_strpercent(double x) { auto buf = std::array{}; if (x < 5.0) { tr_strtruncd(std::data(buf), x, 2, std::size(buf)); } else if (x < 100.0) { tr_strtruncd(std::data(buf), x, 1, std::size(buf)); } else { tr_strtruncd(std::data(buf), x, 0, std::size(buf)); } return std::data(buf); } std::string tr_strratio(double ratio, char const* infinity) { if ((int)ratio == TR_RATIO_NA) { return _("None"); } if ((int)ratio == TR_RATIO_INF) { auto buf = std::array{}; tr_strlcpy(std::data(buf), infinity, std::size(buf)); return std::data(buf); } return tr_strpercent(ratio); } /*** **** ***/ bool tr_moveFile(char const* oldpath, char const* newpath, tr_error** error) { tr_sys_path_info info; /* make sure the old file exists */ if (!tr_sys_path_get_info(oldpath, 0, &info, error)) { tr_error_prefix(error, "Unable to get information on old file: "); return false; } if (info.type != TR_SYS_PATH_IS_FILE) { tr_error_set(error, TR_ERROR_EINVAL, "Old path does not point to a file."sv); return false; } /* make sure the target directory exists */ { char* newdir = tr_sys_path_dirname(newpath, error); bool const i = newdir != nullptr && tr_sys_dir_create(newdir, TR_SYS_DIR_CREATE_PARENTS, 0777, error); tr_free(newdir); if (!i) { tr_error_prefix(error, "Unable to create directory for new file: "); return false; } } /* they might be on the same filesystem... */ if (tr_sys_path_rename(oldpath, newpath, nullptr)) { return true; } /* Otherwise, copy the file. */ if (!tr_sys_path_copy(oldpath, newpath, error)) { tr_error_prefix(error, "Unable to copy: "); return false; } { tr_error* my_error = nullptr; if (!tr_sys_path_remove(oldpath, &my_error)) { tr_logAddError("Unable to remove file at old path: %s", my_error->message); tr_error_free(my_error); } } return true; } /*** **** ***/ uint64_t tr_htonll(uint64_t x) { #ifdef HAVE_HTONLL return htonll(x); #else /* fallback code by bdonlan at http://stackoverflow.com/questions/809902/64-bit-ntohl-in-c/875505#875505 */ union { uint32_t lx[2]; uint64_t llx; } u; u.lx[0] = htonl(x >> 32); u.lx[1] = htonl(x & 0xFFFFFFFFULL); return u.llx; #endif } uint64_t tr_ntohll(uint64_t x) { #ifdef HAVE_NTOHLL return ntohll(x); #else /* fallback code by bdonlan at http://stackoverflow.com/questions/809902/64-bit-ntohl-in-c/875505#875505 */ union { uint32_t lx[2]; uint64_t llx; } u; u.llx = x; return ((uint64_t)ntohl(u.lx[0]) << 32) | (uint64_t)ntohl(u.lx[1]); #endif } /*** **** **** **** ***/ struct formatter_unit { std::array name; uint64_t value; }; using formatter_units = std::array; enum { TR_FMT_KB, TR_FMT_MB, TR_FMT_GB, TR_FMT_TB }; static void formatter_init( formatter_units& units, uint64_t kilo, char const* kb, char const* mb, char const* gb, char const* tb) { uint64_t value = kilo; tr_strlcpy(std::data(units[TR_FMT_KB].name), kb, std::size(units[TR_FMT_KB].name)); units[TR_FMT_KB].value = value; value *= kilo; tr_strlcpy(std::data(units[TR_FMT_MB].name), mb, std::size(units[TR_FMT_MB].name)); units[TR_FMT_MB].value = value; value *= kilo; tr_strlcpy(std::data(units[TR_FMT_GB].name), gb, std::size(units[TR_FMT_GB].name)); units[TR_FMT_GB].value = value; value *= kilo; tr_strlcpy(std::data(units[TR_FMT_TB].name), tb, std::size(units[TR_FMT_TB].name)); units[TR_FMT_TB].value = value; } static char* formatter_get_size_str(formatter_units const& u, char* buf, uint64_t bytes, size_t buflen) { formatter_unit const* unit = nullptr; if (bytes < u[1].value) { unit = std::data(u); } else if (bytes < u[2].value) { unit = &u[1]; } else if (bytes < u[3].value) { unit = &u[2]; } else { unit = &u[3]; } double value = double(bytes) / unit->value; auto const* const units = std::data(unit->name); auto precision = int{}; if (unit->value == 1) { precision = 0; } else if (value < 100) { precision = 2; } else { precision = 1; } tr_snprintf(buf, buflen, "%.*f %s", TR_ARG_TUPLE(precision, value), units); return buf; } static formatter_units size_units; void tr_formatter_size_init(uint64_t kilo, char const* kb, char const* mb, char const* gb, char const* tb) { formatter_init(size_units, kilo, kb, mb, gb, tb); } std::string tr_formatter_size_B(uint64_t bytes) { auto buf = std::array{}; return formatter_get_size_str(size_units, std::data(buf), bytes, std::size(buf)); } static formatter_units speed_units; size_t tr_speed_K = 0; void tr_formatter_speed_init(size_t kilo, char const* kb, char const* mb, char const* gb, char const* tb) { tr_speed_K = kilo; formatter_init(speed_units, kilo, kb, mb, gb, tb); } std::string tr_formatter_speed_KBps(double KBps) { auto buf = std::array{}; if (auto speed = KBps; speed <= 999.95) /* 0.0 KB to 999.9 KB */ { tr_snprintf(std::data(buf), std::size(buf), "%d %s", int(speed), std::data(speed_units[TR_FMT_KB].name)); } else { double const K = speed_units[TR_FMT_KB].value; speed /= K; if (speed <= 99.995) /* 0.98 MB to 99.99 MB */ { tr_snprintf(std::data(buf), std::size(buf), "%.2f %s", speed, std::data(speed_units[TR_FMT_MB].name)); } else if (speed <= 999.95) /* 100.0 MB to 999.9 MB */ { tr_snprintf(std::data(buf), std::size(buf), "%.1f %s", speed, std::data(speed_units[TR_FMT_MB].name)); } else { tr_snprintf(std::data(buf), std::size(buf), "%.1f %s", speed / K, std::data(speed_units[TR_FMT_GB].name)); } } return std::data(buf); } static formatter_units mem_units; size_t tr_mem_K = 0; void tr_formatter_mem_init(size_t kilo, char const* kb, char const* mb, char const* gb, char const* tb) { tr_mem_K = kilo; formatter_init(mem_units, kilo, kb, mb, gb, tb); } std::string tr_formatter_mem_B(size_t bytes_per_second) { auto buf = std::array{}; return formatter_get_size_str(mem_units, std::data(buf), bytes_per_second, std::size(buf)); } void tr_formatter_get_units(void* vdict) { auto* dict = static_cast(vdict); tr_variantDictReserve(dict, 6); tr_variantDictAddInt(dict, TR_KEY_memory_bytes, mem_units[TR_FMT_KB].value); tr_variant* l = tr_variantDictAddList(dict, TR_KEY_memory_units, std::size(mem_units)); for (auto const& unit : mem_units) { tr_variantListAddStr(l, std::data(unit.name)); } tr_variantDictAddInt(dict, TR_KEY_size_bytes, size_units[TR_FMT_KB].value); l = tr_variantDictAddList(dict, TR_KEY_size_units, std::size(size_units)); for (auto const& unit : size_units) { tr_variantListAddStr(l, std::data(unit.name)); } tr_variantDictAddInt(dict, TR_KEY_speed_bytes, speed_units[TR_FMT_KB].value); l = tr_variantDictAddList(dict, TR_KEY_speed_units, std::size(speed_units)); for (auto const& unit : speed_units) { tr_variantListAddStr(l, std::data(unit.name)); } } /*** **** ENVIRONMENT ***/ bool tr_env_key_exists(char const* key) { TR_ASSERT(key != nullptr); #ifdef _WIN32 return GetEnvironmentVariableA(key, nullptr, 0) != 0; #else return getenv(key) != nullptr; #endif } int tr_env_get_int(char const* key, int default_value) { TR_ASSERT(key != nullptr); #ifdef _WIN32 char value[16]; if (GetEnvironmentVariableA(key, value, TR_N_ELEMENTS(value)) > 1) { return atoi(value); } #else if (char const* value = getenv(key); !tr_str_is_empty(value)) { return atoi(value); } #endif return default_value; } char* tr_env_get_string(char const* key, char const* default_value) { TR_ASSERT(key != nullptr); #ifdef _WIN32 wchar_t* wide_key = tr_win32_utf8_to_native(key, -1); char* value = nullptr; if (wide_key != nullptr) { DWORD const size = GetEnvironmentVariableW(wide_key, nullptr, 0); if (size != 0) { wchar_t* const wide_value = tr_new(wchar_t, size); if (GetEnvironmentVariableW(wide_key, wide_value, size) == size - 1) { value = tr_win32_native_to_utf8(wide_value, size); } tr_free(wide_value); } tr_free(wide_key); } if (value == nullptr && default_value != nullptr) { value = tr_strdup(default_value); } return value; #else char const* value = getenv(key); if (value == nullptr) { value = default_value; } return value != nullptr ? tr_strvDup(value) : nullptr; #endif } /*** **** ***/ void tr_net_init() { static bool initialized = false; if (!initialized) { #ifdef _WIN32 WSADATA wsaData; WSAStartup(MAKEWORD(2, 2), &wsaData); #endif initialized = true; } } /// mime-type std::string_view tr_get_mime_type_for_filename(std::string_view filename) { auto constexpr compare = [](mime_type_suffix const& entry, auto const& suffix) { return entry.suffix < suffix; }; if (auto const pos = filename.rfind('.'); pos != std::string_view::npos) { auto const suffix_lc = tr_strlower(filename.substr(pos + 1)); auto const it = std::lower_bound(std::begin(mime_type_suffixes), std::end(mime_type_suffixes), suffix_lc, compare); if (it != std::end(mime_type_suffixes) && suffix_lc == it->suffix) { return it->mime_type; } } // https://developer.mozilla.org/en-US/docs/Web/HTTP/Basics_of_HTTP/MIME_types/Common_types // application/octet-stream is the default value. // An unknown file type should use this type. auto constexpr Fallback = "application/octet-stream"sv; return Fallback; }