// ***************************************************************************** // * This file is part of the FreeFileSync project. It is distributed under * // * GNU General Public License: http://www.gnu.org/licenses/gpl-3.0 * // * Copyright (C) Zenju (zenju AT freefilesync DOT org) - All Rights Reserved * // ***************************************************************************** #include "format_unit.h" //#include //swprintf #include #include #include "basic_math.h" #include "i18n.h" #include "time.h" #include "globals.h" #include //thousands separator #include "utf.h" // using namespace zen; std::wstring zen::formatTwoDigitPrecision(double value) { //print two digits: 0,1 | 1,1 | 11 if (numeric::abs(value) < 9.95) //9.99 must not be formatted as "10.0" return printNumber(L"%.1f", value); return numberTo(numeric::round(value)); } std::wstring zen::formatThreeDigitPrecision(double value) { //print three digits: 0,01 | 0,11 | 1,11 | 11,1 | 111 if (numeric::abs(value) < 9.995) //9.999 must not be formatted as "10.00" return printNumber(L"%.2f", value); if (numeric::abs(value) < 99.95) //99.99 must not be formatted as "100.0" return printNumber(L"%.1f", value); return numberTo(numeric::round(value)); } std::wstring zen::filesizeToShortString(int64_t size) { //if (size < 0) return _("Error"); -> really? if (numeric::abs(size) <= 999) return _P("1 byte", "%x bytes", static_cast(size)); double sizeInUnit = static_cast(size); auto formatUnit = [&](const std::wstring& unitTxt) { return replaceCpy(unitTxt, L"%x", formatThreeDigitPrecision(sizeInUnit)); }; sizeInUnit /= 1024; if (numeric::abs(sizeInUnit) < 999.5) return formatUnit(_("%x KB")); sizeInUnit /= 1024; if (numeric::abs(sizeInUnit) < 999.5) return formatUnit(_("%x MB")); sizeInUnit /= 1024; if (numeric::abs(sizeInUnit) < 999.5) return formatUnit(_("%x GB")); sizeInUnit /= 1024; if (numeric::abs(sizeInUnit) < 999.5) return formatUnit(_("%x TB")); sizeInUnit /= 1024; return formatUnit(_("%x PB")); } namespace { enum UnitRemTime { URT_SEC, URT_MIN, URT_HOUR, URT_DAY }; std::wstring formatUnitTime(int val, UnitRemTime unit) { switch (unit) { case URT_SEC: return _P("1 sec", "%x sec", val); case URT_MIN: return _P("1 min", "%x min", val); case URT_HOUR: return _P("1 hour", "%x hours", val); case URT_DAY: return _P("1 day", "%x days", val); } assert(false); return _("Error"); } template std::wstring roundToBlock(double timeInHigh, UnitRemTime unitHigh, const int (&stepsHigh)[M], int unitLowPerHigh, UnitRemTime unitLow, const int (&stepsLow)[N]) { assert(unitLowPerHigh > 0); const double granularity = 0.1; const double timeInLow = timeInHigh * unitLowPerHigh; const int blockSizeLow = granularity * timeInHigh < 1 ? numeric::nearMatch(granularity * timeInLow, std::begin(stepsLow), std::end(stepsLow)): numeric::nearMatch(granularity * timeInHigh, std::begin(stepsHigh), std::end(stepsHigh)) * unitLowPerHigh; const int roundedtimeInLow = numeric::round(timeInLow / blockSizeLow) * blockSizeLow; std::wstring output = formatUnitTime(roundedtimeInLow / unitLowPerHigh, unitHigh); if (unitLowPerHigh > blockSizeLow) output += L" " + formatUnitTime(roundedtimeInLow % unitLowPerHigh, unitLow); return output; }; } std::wstring zen::remainingTimeToString(double timeInSec) { const int steps10[] = { 1, 2, 5, 10 }; const int steps24[] = { 1, 2, 3, 4, 6, 8, 12, 24 }; const int steps60[] = { 1, 2, 5, 10, 15, 20, 30, 60 }; //determine preferred unit double timeInUnit = timeInSec; if (timeInUnit <= 60) return roundToBlock(timeInUnit, URT_SEC, steps60, 1, URT_SEC, steps60); timeInUnit /= 60; if (timeInUnit <= 60) return roundToBlock(timeInUnit, URT_MIN, steps60, 60, URT_SEC, steps60); timeInUnit /= 60; if (timeInUnit <= 24) return roundToBlock(timeInUnit, URT_HOUR, steps24, 60, URT_MIN, steps60); timeInUnit /= 24; return roundToBlock(timeInUnit, URT_DAY, steps10, 24, URT_HOUR, steps24); //note: for 10% granularity steps10 yields a valid blocksize only up to timeInUnit == 100! //for larger time sizes this results in a finer granularity than expected: 10 days -> should not be a problem considering "usual" remaining time for synchronization } //std::wstring zen::fractionToString1Dec(double fraction) //{ // return printNumber(L"%.1f", fraction * 100.0) + L'%'; //no need to internationalize fraction!? //} std::wstring zen::fractionToString(double fraction) { return printNumber(L"%.2f", fraction * 100.0) + L'%'; //no need to internationalize fraction!? } std::wstring zen::ffs_Impl::includeNumberSeparator(const std::wstring& number) { //we have to include thousands separator ourselves; this doesn't work for all countries (e.g india), but is better than nothing //::setlocale (LC_ALL, ""); -> implicitly called by wxLocale const lconv* localInfo = ::localeconv(); //always bound according to doc const std::wstring& thousandSep = utfTo(localInfo->thousands_sep); // THOUSANDS_SEPARATOR = std::use_facet>(std::locale("")).thousands_sep(); - why not working? // DECIMAL_POINT = std::use_facet>(std::locale("")).decimal_point(); std::wstring output(number); size_t i = output.size(); for (;;) { if (i <= 3) break; i -= 3; if (!isDigit(output[i - 1])) //stop on +, - signs break; output.insert(i, thousandSep); } return output; } std::wstring zen::utcToLocalTimeString(int64_t utcTime) { auto errorMsg = [&] { return _("Error") + L" (time_t: " + numberTo(utcTime) + L")"; }; TimeComp loc = getLocalTime(utcTime); std::wstring dateString = formatTime(L"%x %X", loc); return !dateString.empty() ? dateString : errorMsg(); }