// Copyright 2016 - 2021 The excelize Authors. All rights reserved. Use of // this source code is governed by a BSD-style license that can be found in // the LICENSE file. // // Package excelize providing a set of functions that allow you to write to // and read from XLSX / XLSM / XLTM files. Supports reading and writing // spreadsheet documents generated by Microsoft Excelâ„¢ 2007 and later. Supports // complex components by high compatibility, and provided streaming API for // generating or reading data from a worksheet with huge amounts of data. This // library needs Go version 1.15 or later. package excelize import ( "math" "time" ) const ( dayNanoseconds = 24 * time.Hour maxDuration = 290 * 364 * dayNanoseconds ) var ( excelMinTime1900 = time.Date(1899, time.December, 31, 0, 0, 0, 0, time.UTC) excelBuggyPeriodStart = time.Date(1900, time.March, 1, 0, 0, 0, 0, time.UTC).Add(-time.Nanosecond) ) // timeToExcelTime provides a function to convert time to Excel time. func timeToExcelTime(t time.Time) (float64, error) { // TODO in future this should probably also handle date1904 and like TimeFromExcelTime if t.Before(excelMinTime1900) { return 0.0, nil } tt := t diff := t.Sub(excelMinTime1900) result := float64(0) for diff >= maxDuration { result += float64(maxDuration / dayNanoseconds) tt = tt.Add(-maxDuration) diff = tt.Sub(excelMinTime1900) } rem := diff % dayNanoseconds result += float64(diff-rem)/float64(dayNanoseconds) + float64(rem)/float64(dayNanoseconds) // Excel dates after 28th February 1900 are actually one day out. // Excel behaves as though the date 29th February 1900 existed, which it didn't. // Microsoft intentionally included this bug in Excel so that it would remain compatible with the spreadsheet // program that had the majority market share at the time; Lotus 1-2-3. // https://www.myonlinetraininghub.com/excel-date-and-time if t.After(excelBuggyPeriodStart) { result += 1.0 } return result, nil } // shiftJulianToNoon provides a function to process julian date to noon. func shiftJulianToNoon(julianDays, julianFraction float64) (float64, float64) { switch { case -0.5 < julianFraction && julianFraction < 0.5: julianFraction += 0.5 case julianFraction >= 0.5: julianDays++ julianFraction -= 0.5 case julianFraction <= -0.5: julianDays-- julianFraction += 1.5 } return julianDays, julianFraction } // fractionOfADay provides a function to return the integer values for hour, // minutes, seconds and nanoseconds that comprised a given fraction of a day. // values would round to 1 us. func fractionOfADay(fraction float64) (hours, minutes, seconds, nanoseconds int) { const ( c1us = 1e3 c1s = 1e9 c1day = 24 * 60 * 60 * c1s ) frac := int64(c1day*fraction + c1us/2) nanoseconds = int((frac%c1s)/c1us) * c1us frac /= c1s seconds = int(frac % 60) frac /= 60 minutes = int(frac % 60) hours = int(frac / 60) return } // julianDateToGregorianTime provides a function to convert julian date to // gregorian time. func julianDateToGregorianTime(part1, part2 float64) time.Time { part1I, part1F := math.Modf(part1) part2I, part2F := math.Modf(part2) julianDays := part1I + part2I julianFraction := part1F + part2F julianDays, julianFraction = shiftJulianToNoon(julianDays, julianFraction) day, month, year := doTheFliegelAndVanFlandernAlgorithm(int(julianDays)) hours, minutes, seconds, nanoseconds := fractionOfADay(julianFraction) return time.Date(year, time.Month(month), day, hours, minutes, seconds, nanoseconds, time.UTC) } // doTheFliegelAndVanFlandernAlgorithm; By this point generations of // programmers have repeated the algorithm sent to the editor of // "Communications of the ACM" in 1968 (published in CACM, volume 11, number // 10, October 1968, p.657). None of those programmers seems to have found it // necessary to explain the constants or variable names set out by Henry F. // Fliegel and Thomas C. Van Flandern. Maybe one day I'll buy that jounal and // expand an explanation here - that day is not today. func doTheFliegelAndVanFlandernAlgorithm(jd int) (day, month, year int) { l := jd + 68569 n := (4 * l) / 146097 l = l - (146097*n+3)/4 i := (4000 * (l + 1)) / 1461001 l = l - (1461*i)/4 + 31 j := (80 * l) / 2447 d := l - (2447*j)/80 l = j / 11 m := j + 2 - (12 * l) y := 100*(n-49) + i + l return d, m, y } // timeFromExcelTime provides a function to convert an excelTime // representation (stored as a floating point number) to a time.Time. func timeFromExcelTime(excelTime float64, date1904 bool) time.Time { const MDD int64 = 106750 // Max time.Duration Days, aprox. 290 years var date time.Time var intPart = int64(excelTime) // Excel uses Julian dates prior to March 1st 1900, and Gregorian // thereafter. if intPart <= 61 { const OFFSET1900 = 15018.0 const OFFSET1904 = 16480.0 const MJD0 float64 = 2400000.5 var date time.Time if date1904 { date = julianDateToGregorianTime(MJD0, excelTime+OFFSET1904) } else { date = julianDateToGregorianTime(MJD0, excelTime+OFFSET1900) } return date } var floatPart = excelTime - float64(intPart) var dayNanoSeconds float64 = 24 * 60 * 60 * 1000 * 1000 * 1000 if date1904 { date = time.Date(1904, 1, 1, 0, 0, 0, 0, time.UTC) } else { date = time.Date(1899, 12, 30, 0, 0, 0, 0, time.UTC) } // Duration is limited to aprox. 290 years for intPart > MDD { durationDays := time.Duration(MDD) * time.Hour * 24 date = date.Add(durationDays) intPart = intPart - MDD } durationDays := time.Duration(intPart) * time.Hour * 24 durationPart := time.Duration(dayNanoSeconds * floatPart) return date.Add(durationDays).Add(durationPart) } // ExcelDateToTime converts a float-based excel date representation to a time.Time. func ExcelDateToTime(excelDate float64, use1904Format bool) (time.Time, error) { if excelDate < 0 { return time.Time{}, newInvalidExcelDateError(excelDate) } return timeFromExcelTime(excelDate, use1904Format), nil }