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645 lines
28 KiB
Go

package xlsx
import (
"errors"
"fmt"
"math"
"strconv"
"strings"
)
// Do not edit these attributes once this struct is created. This struct should only be created by
// parseFullNumberFormatString() from a number format string. If the format for a cell needs to change, change
// the number format string and getNumberFormat() will invalidate the old struct and re-parse the string.
type parsedNumberFormat struct {
numFmt string
isTimeFormat bool
negativeFormatExpectsPositive bool
positiveFormat *formatOptions
negativeFormat *formatOptions
zeroFormat *formatOptions
textFormat *formatOptions
parseEncounteredError *error
}
type formatOptions struct {
isTimeFormat bool
showPercent bool
fullFormatString string
reducedFormatString string
prefix string
suffix string
}
// FormatValue returns a value, and possibly an error condition
// from a Cell. If it is possible to apply a format to the cell
// value, it will do so, if not then an error will be returned, along
// with the raw value of the Cell.
//
// This is the documentation of the "General" Format in the Office Open XML spec:
//
// Numbers
// The application shall attempt to display the full number up to 11 digits (inc. decimal point). If the number is too
// large*, the application shall attempt to show exponential format. If the number has too many significant digits, the
// display shall be truncated. The optimal method of display is based on the available cell width. If the number cannot
// be displayed using any of these formats in the available width, the application shall show "#" across the width of
// the cell.
//
// Conditions for switching to exponential format:
// 1. The cell value shall have at least five digits for xE-xx
// 2. If the exponent is bigger than the size allowed, a floating point number cannot fit, so try exponential notation.
// 3. Similarly, for negative exponents, check if there is space for even one (non-zero) digit in floating point format**.
// 4. Finally, if there isn't room for all of the significant digits in floating point format (for a negative exponent),
// exponential format shall display more digits if the exponent is less than -3. (The 3 is because E-xx takes 4
// characters, and the leading 0 in floating point takes only 1 character. Thus, for an exponent less than -3, there is
// more than 3 additional leading 0's, more than enough to compensate for the size of the E-xx.)
//
// Floating point rule:
// For general formatting in cells, max overall length for cell display is 11, not including negative sign, but includes
// leading zeros and decimal separator.***
//
// Added Notes:
// * "If the number is too large" can also mean "if the number has more than 11 digits", so greater than or equal to
// 1e11 and less than 1e-9.
// ** Means that you should switch to scientific if there would be 9 zeros after the decimal (the decimal and first zero
// count against the 11 character limit), so less than 1e9.
// *** The way this is written, you can get numbers that are more than 11 characters because the golang Float fmt
// does not support adjusting the precision while not padding with zeros, while also not switching to scientific
// notation too early.
func (fullFormat *parsedNumberFormat) FormatValue(cell *Cell) (string, error) {
switch cell.cellType {
case CellTypeError:
// The error type is what XLSX uses in error cases such as when formulas are invalid.
// There will be text in the cell's value that can be shown, something ugly like #NAME? or #######
return cell.Value, nil
case CellTypeBool:
if cell.Value == "0" {
return "FALSE", nil
} else if cell.Value == "1" {
return "TRUE", nil
} else {
return cell.Value, errors.New("invalid value in bool cell")
}
case CellTypeString:
fallthrough
case CellTypeInline:
fallthrough
case CellTypeStringFormula:
textFormat := cell.parsedNumFmt.textFormat
// This switch statement is only for String formats
switch textFormat.reducedFormatString {
case builtInNumFmt[builtInNumFmtIndex_GENERAL]: // General is literally "general"
return cell.Value, nil
case builtInNumFmt[builtInNumFmtIndex_STRING]: // String is "@"
return textFormat.prefix + cell.Value + textFormat.suffix, nil
case "":
// If cell is not "General" and there is not an "@" symbol in the format, then the cell's value is not
// used when determining what to display. It would be completely legal to have a format of "Error"
// for strings, and all values that are not numbers would show up as "Error". In that case, this code would
// have a prefix of "Error" and a reduced format string of "" (empty string).
return textFormat.prefix + textFormat.suffix, nil
default:
return cell.Value, errors.New("invalid or unsupported format, unsupported string format")
}
case CellTypeDate:
// These are dates that are stored in date format instead of being stored as numbers with a format to turn them
// into a date string.
return cell.Value, nil
case CellTypeNumeric:
return fullFormat.formatNumericCell(cell)
default:
return cell.Value, errors.New("unknown cell type")
}
}
func (fullFormat *parsedNumberFormat) formatNumericCell(cell *Cell) (string, error) {
rawValue := strings.TrimSpace(cell.Value)
// If there wasn't a value in the cell, it shouldn't have been marked as Numeric.
// It's better to support this case though.
if rawValue == "" {
return "", nil
}
if fullFormat.isTimeFormat {
return fullFormat.parseTime(rawValue, cell.date1904)
}
var numberFormat *formatOptions
floatVal, floatErr := strconv.ParseFloat(rawValue, 64)
if floatErr != nil {
return rawValue, floatErr
}
// Choose the correct format. There can be different formats for positive, negative, and zero numbers.
// Excel only uses the zero format if the value is literally zero, even if the number is so small that it shows
// up as "0" when the positive format is used.
if floatVal > 0 {
numberFormat = fullFormat.positiveFormat
} else if floatVal < 0 {
// If format string specified a different format for negative numbers, then the number should be made positive
// before getting formatted. The format string itself will contain formatting that denotes a negative number and
// this formatting will end up in the prefix or suffix. Commonly if there is a negative format specified, the
// number will get surrounded by parenthesis instead of showing it with a minus sign.
if fullFormat.negativeFormatExpectsPositive {
floatVal = math.Abs(floatVal)
}
numberFormat = fullFormat.negativeFormat
} else {
numberFormat = fullFormat.zeroFormat
}
// When showPercent is true, multiply the number by 100.
// The percent sign will be in the prefix or suffix already, so it does not need to be added in this function.
// The number format itself will be the same as any other number format once the value is multiplied by 100.
if numberFormat.showPercent {
floatVal = 100 * floatVal
}
// Only the most common format strings are supported here.
// Eventually this switch needs to be replaced with a more general solution.
// Some of these "supported" formats should have thousand separators, but don't get them since Go fmt
// doesn't have a way to request thousands separators.
// The only things that should be supported here are in the array formattingCharacters,
// everything else has been stripped out before and will be placed in the prefix or suffix.
// The formatting characters can have non-formatting characters mixed in with them and those should be maintained.
// However, at this time we fail to parse those formatting codes and they get replaced with "General"
var formattedNum string
switch numberFormat.reducedFormatString {
case builtInNumFmt[builtInNumFmtIndex_GENERAL]: // General is literally "general"
// prefix, showPercent, and suffix cannot apply to the general format
// The logic for showing numbers when the format is "general" is much more complicated than the rest of these.
generalFormatted, err := generalNumericScientific(cell.Value, true)
if err != nil {
return rawValue, nil
}
return generalFormatted, nil
case builtInNumFmt[builtInNumFmtIndex_STRING]: // String is "@"
formattedNum = cell.Value
case builtInNumFmt[builtInNumFmtIndex_INT], "#,##0": // Int is "0"
// Previously this case would cast to int and print with %d, but that will not round the value correctly.
formattedNum = fmt.Sprintf("%.0f", floatVal)
case "0.0", "#,##0.0":
formattedNum = fmt.Sprintf("%.1f", floatVal)
case builtInNumFmt[builtInNumFmtIndex_FLOAT], "#,##0.00": // Float is "0.00"
formattedNum = fmt.Sprintf("%.2f", floatVal)
case "0.000", "#,##0.000":
formattedNum = fmt.Sprintf("%.3f", floatVal)
case "0.0000", "#,##0.0000":
formattedNum = fmt.Sprintf("%.4f", floatVal)
case "0.00e+00", "##0.0e+0":
formattedNum = fmt.Sprintf("%e", floatVal)
case "":
// Do nothing.
default:
return rawValue, nil
}
return numberFormat.prefix + formattedNum + numberFormat.suffix, nil
}
func generalNumericScientific(value string, allowScientific bool) (string, error) {
if strings.TrimSpace(value) == "" {
return "", nil
}
f, err := strconv.ParseFloat(value, 64)
if err != nil {
return value, err
}
if allowScientific {
absF := math.Abs(f)
// When using General format, numbers that are less than 1e-9 (0.000000001) and greater than or equal to
// 1e11 (100,000,000,000) should be shown in scientific notation.
// Numbers less than the number after zero, are assumed to be zero.
if (absF >= math.SmallestNonzeroFloat64 && absF < minNonScientificNumber) || absF >= maxNonScientificNumber {
return strconv.FormatFloat(f, 'E', -1, 64), nil
}
}
// This format (fmt="f", prec=-1) will prevent padding with zeros and will never switch to scientific notation.
// However, it will show more than 11 characters for very precise numbers, and this cannot be changed.
// You could also use fmt="g", prec=11, which doesn't pad with zeros and allows the correct precision,
// but it will use scientific notation on numbers less than 1e-4. That value is hardcoded in Go and cannot be
// configured or disabled.
return strconv.FormatFloat(f, 'f', -1, 64), nil
}
// Format strings are a little strange to compare because empty string needs to be taken as general, and general needs
// to be compared case insensitively.
func compareFormatString(fmt1, fmt2 string) bool {
if fmt1 == fmt2 {
return true
}
if fmt1 == "" || strings.EqualFold(fmt1, "general") {
fmt1 = "general"
}
if fmt2 == "" || strings.EqualFold(fmt2, "general") {
fmt2 = "general"
}
return fmt1 == fmt2
}
func parseFullNumberFormatString(numFmt string) *parsedNumberFormat {
parsedNumFmt := &parsedNumberFormat{
numFmt: numFmt,
}
if isTimeFormat(numFmt) {
// Time formats cannot have multiple groups separated by semicolons, there is only one format.
// Strings are unaffected by the time format.
parsedNumFmt.isTimeFormat = true
parsedNumFmt.textFormat, _ = parseNumberFormatSection("general")
return parsedNumFmt
}
var fmtOptions []*formatOptions
formats, err := splitFormatOnSemicolon(numFmt)
if err == nil {
for _, formatSection := range formats {
parsedFormat, err := parseNumberFormatSection(formatSection)
if err != nil {
// If an invalid number section is found, fall back to general
parsedFormat = fallbackErrorFormat
parsedNumFmt.parseEncounteredError = &err
}
fmtOptions = append(fmtOptions, parsedFormat)
}
} else {
fmtOptions = append(fmtOptions, fallbackErrorFormat)
parsedNumFmt.parseEncounteredError = &err
}
if len(fmtOptions) > 4 {
fmtOptions = []*formatOptions{fallbackErrorFormat}
err = errors.New("invalid number format, too many format sections")
parsedNumFmt.parseEncounteredError = &err
}
if len(fmtOptions) == 1 {
// If there is only one option, it is used for all
parsedNumFmt.positiveFormat = fmtOptions[0]
parsedNumFmt.negativeFormat = fmtOptions[0]
parsedNumFmt.zeroFormat = fmtOptions[0]
if strings.Contains(fmtOptions[0].fullFormatString, "@") {
parsedNumFmt.textFormat = fmtOptions[0]
} else {
parsedNumFmt.textFormat, _ = parseNumberFormatSection("general")
}
} else if len(fmtOptions) == 2 {
// If there are two formats, the first is used for positive and zeros, the second gets used as a negative format,
// and strings are not formatted.
// When negative numbers now have their own format, they should become positive before having the format applied.
// The format will contain a negative sign if it is desired, but they may be colored red or wrapped in
// parenthesis instead.
parsedNumFmt.negativeFormatExpectsPositive = true
parsedNumFmt.positiveFormat = fmtOptions[0]
parsedNumFmt.negativeFormat = fmtOptions[1]
parsedNumFmt.zeroFormat = fmtOptions[0]
parsedNumFmt.textFormat, _ = parseNumberFormatSection("general")
} else if len(fmtOptions) == 3 {
// If there are three formats, the first is used for positive, the second gets used as a negative format,
// the third is for negative, and strings are not formatted.
parsedNumFmt.negativeFormatExpectsPositive = true
parsedNumFmt.positiveFormat = fmtOptions[0]
parsedNumFmt.negativeFormat = fmtOptions[1]
parsedNumFmt.zeroFormat = fmtOptions[2]
parsedNumFmt.textFormat, _ = parseNumberFormatSection("general")
} else {
// With four options, the first is positive, the second is negative, the third is zero, and the fourth is strings
// Negative numbers should be still become positive before having the negative formatting applied.
parsedNumFmt.negativeFormatExpectsPositive = true
parsedNumFmt.positiveFormat = fmtOptions[0]
parsedNumFmt.negativeFormat = fmtOptions[1]
parsedNumFmt.zeroFormat = fmtOptions[2]
parsedNumFmt.textFormat = fmtOptions[3]
}
return parsedNumFmt
}
// splitFormatOnSemicolon will split the format string into the format sections
// This logic to split the different formats on semicolon is fully correct, and will skip all literal semicolons,
// and will catch all breaking semicolons.
func splitFormatOnSemicolon(format string) ([]string, error) {
var formats []string
prevIndex := 0
for i := 0; i < len(format); i++ {
if format[i] == ';' {
formats = append(formats, format[prevIndex:i])
prevIndex = i + 1
} else if format[i] == '\\' {
i++
} else if format[i] == '"' {
endQuoteIndex := strings.Index(format[i+1:], "\"")
if endQuoteIndex == -1 {
// This is an invalid format string, fall back to general
return nil, errors.New("invalid format string, unmatched double quote")
}
i += endQuoteIndex + 1
}
}
return append(formats, format[prevIndex:]), nil
}
var fallbackErrorFormat = &formatOptions{
fullFormatString: "general",
reducedFormatString: "general",
}
// parseNumberFormatSection takes in individual format and parses out most of the options.
// Some options are parsed, removed from the string, and set as settings on formatOptions.
// There remainder of the format string is put in the reducedFormatString attribute, and supported values for these
// are handled in a switch in the Cell.FormattedValue() function.
// Ideally more and more of the format string would be parsed out here into settings until there is no remainder string
// at all.
// Features that this supports:
// - Time formats are detected, and marked in the options. Time format strings are handled when doing the formatting.
// The logic to detect time formats is currently not correct, and can catch formats that are not time formats as well
// as miss formats that are time formats.
// - Color formats are detected and removed.
// - Currency annotations are handled properly.
// - Literal strings wrapped in quotes are handled and put into prefix or suffix.
// - Numbers that should be percent are detected and marked in the options.
// - Conditionals are detected and removed, but they are not obeyed. The conditional groups will be used just like the
// positive;negative;zero;string format groups. Here is an example of a conditional format: "[Red][<=100];[Blue][>100]"
// Decoding the actual number formatting portion is out of scope, that is placed into reducedFormatString and is used
// when formatting the string. The string there will be reduced to only the things in the formattingCharacters array.
// Everything not in that array has been parsed out and put into formatOptions.
func parseNumberFormatSection(fullFormat string) (*formatOptions, error) {
reducedFormat := strings.TrimSpace(fullFormat)
// general is the only format that does not use the normal format symbols notations
if compareFormatString(reducedFormat, "general") {
return &formatOptions{
fullFormatString: "general",
reducedFormatString: "general",
}, nil
}
prefix, reducedFormat, showPercent1, err := parseLiterals(reducedFormat)
if err != nil {
return nil, err
}
reducedFormat, suffixFormat := splitFormatAndSuffixFormat(reducedFormat)
suffix, remaining, showPercent2, err := parseLiterals(suffixFormat)
if err != nil {
return nil, err
}
if len(remaining) > 0 {
// This paradigm of codes consisting of literals, number formats, then more literals is not always correct, they can
// actually be intertwined. Though 99% of the time number formats will not do this.
// Excel uses this format string for Social Security Numbers: 000\-00\-0000
// and this for US phone numbers: [<=9999999]###\-####;\(###\)\ ###\-####
return nil, errors.New("invalid or unsupported format string")
}
return &formatOptions{
fullFormatString: fullFormat,
isTimeFormat: false,
reducedFormatString: reducedFormat,
prefix: prefix,
suffix: suffix,
showPercent: showPercent1 || showPercent2,
}, nil
}
// formattingCharacters will be left in the reducedNumberFormat
// It is important that these be looked for in order so that the slash cases are handled correctly.
// / (slash) is a fraction format if preceded by 0, #, or ?, otherwise it is not a formatting character
// E- E+ e- e+ are scientific notation, but E, e, -, + are not formatting characters independently
// \ (back slash) makes the next character a literal (not formatting)
// " Anything in double quotes is not a formatting character
// _ (underscore) skips the width of the next character, so the next character cannot be formatting
var formattingCharacters = []string{"0/", "#/", "?/", "E-", "E+", "e-", "e+", "0", "#", "?", ".", ",", "@", "*"}
// The following are also time format characters, but since this is only used for detecting, not decoding, they are
// redundant here: ee, gg, ggg, rr, ss, mm, hh, yyyy, dd, ddd, dddd, mm, mmm, mmmm, mmmmm, ss.0000, ss.000, ss.00, ss.0
// The .00 type format is very tricky, because it only counts if it comes after ss or s or [ss] or [s]
// .00 is actually a valid number format by itself.
var timeFormatCharacters = []string{"m", "d", "yy", "h", "m", "AM/PM", "A/P", "am/pm", "a/p", "r", "g", "e", "b1", "b2", "[hh]", "[h]", "[mm]", "[m]",
"s.0000", "s.000", "s.00", "s.0", "s", "[ss].0000", "[ss].000", "[ss].00", "[ss].0", "[ss]", "[s].0000", "[s].000", "[s].00", "[s].0", "[s]"}
func splitFormatAndSuffixFormat(format string) (string, string) {
var i int
for ; i < len(format); i++ {
curReducedFormat := format[i:]
var found bool
for _, special := range formattingCharacters {
if strings.HasPrefix(curReducedFormat, special) {
// Skip ahead if the special character was longer than length 1
i += len(special) - 1
found = true
break
}
}
if !found {
break
}
}
suffixFormat := format[i:]
format = format[:i]
return format, suffixFormat
}
func parseLiterals(format string) (string, string, bool, error) {
var prefix string
showPercent := false
for i := 0; i < len(format); i++ {
curReducedFormat := format[i:]
switch curReducedFormat[0] {
case '\\':
// If there is a slash, skip the next character, and add it to the prefix
if len(curReducedFormat) > 1 {
i++
prefix += curReducedFormat[1:2]
}
case '_':
// If there is an underscore, skip the next character, but don't add it to the prefix
if len(curReducedFormat) > 1 {
i++
}
case '*':
// Asterisks are used to repeat the next character to fill the full cell width.
// There isn't really a cell size in this context, so this will be ignored.
case '"':
// If there is a quote skip to the next quote, and add the quoted characters to the prefix
endQuoteIndex := strings.Index(curReducedFormat[1:], "\"")
if endQuoteIndex == -1 {
return "", "", false, errors.New("invalid formatting code, unmatched double quote")
}
prefix = prefix + curReducedFormat[1:endQuoteIndex+1]
i += endQuoteIndex + 1
case '%':
showPercent = true
prefix += "%"
case '[':
// Brackets can be currency annotations (e.g. [$$-409])
// color formats (e.g. [color1] through [color56], as well as [red] etc.)
// conditionals (e.g. [>100], the valid conditionals are =, >, <, >=, <=, <>)
bracketIndex := strings.Index(curReducedFormat, "]")
if bracketIndex == -1 {
return "", "", false, errors.New("invalid formatting code, invalid brackets")
}
// Currencies in Excel are annotated with this format: [$<Currency String>-<Language Info>]
// Currency String is something like $, ¥, €, or £
// Language Info is three hexadecimal characters
if len(curReducedFormat) > 2 && curReducedFormat[1] == '$' {
dashIndex := strings.Index(curReducedFormat, "-")
if dashIndex != -1 && dashIndex < bracketIndex {
// Get the currency symbol, and skip to the end of the currency format
prefix += curReducedFormat[2:dashIndex]
} else {
return "", "", false, errors.New("invalid formatting code, invalid currency annotation")
}
}
i += bracketIndex
case '$', '-', '+', '/', '(', ')', ':', '!', '^', '&', '\'', '~', '{', '}', '<', '>', '=', ' ':
// These symbols are allowed to be used as literal without escaping
prefix += curReducedFormat[0:1]
default:
for _, special := range formattingCharacters {
if strings.HasPrefix(curReducedFormat, special) {
// This means we found the start of the actual number formatting portion, and should return.
return prefix, format[i:], showPercent, nil
}
}
// Symbols that don't have meaning and aren't in the exempt literal characters and are not escaped.
return "", "", false, errors.New("invalid formatting code: unsupported or unescaped characters")
}
}
return prefix, "", showPercent, nil
}
// parseTime returns a string parsed using time.Time
func (fullFormat *parsedNumberFormat) parseTime(value string, date1904 bool) (string, error) {
f, err := strconv.ParseFloat(value, 64)
if err != nil {
return value, err
}
val := TimeFromExcelTime(f, date1904)
format := fullFormat.numFmt
// Replace Excel placeholders with Go time placeholders.
// For example, replace yyyy with 2006. These are in a specific order,
// due to the fact that m is used in month, minute, and am/pm. It would
// be easier to fix that with regular expressions, but if it's possible
// to keep this simple it would be easier to maintain.
// Full-length month and days (e.g. March, Tuesday) have letters in them that would be replaced
// by other characters below (such as the 'h' in March, or the 'd' in Tuesday) below.
// First we convert them to arbitrary characters unused in Excel Date formats, and then at the end,
// turn them to what they should actually be.
// Based off: http://www.ozgrid.com/Excel/CustomFormats.htm
replacements := []struct{ xltime, gotime string }{
{"yyyy", "2006"},
{"yy", "06"},
{"mmmm", "%%%%"},
{"dddd", "&&&&"},
{"dd", "02"},
{"d", "2"},
{"mmm", "Jan"},
{"mmss", "0405"},
{"ss", "05"},
{"mm:", "04:"},
{":mm", ":04"},
{"mm", "01"},
{"am/pm", "pm"},
{"m/", "1/"},
{"%%%%", "January"},
{"&&&&", "Monday"},
}
// It is the presence of the "am/pm" indicator that determins
// if this is a 12 hour or 24 hours time format, not the
// number of 'h' characters.
if is12HourTime(format) {
format = strings.Replace(format, "hh", "03", 1)
format = strings.Replace(format, "h", "3", 1)
} else {
format = strings.Replace(format, "hh", "15", 1)
format = strings.Replace(format, "h", "15", 1)
}
for _, repl := range replacements {
format = strings.Replace(format, repl.xltime, repl.gotime, 1)
}
// If the hour is optional, strip it out, along with the
// possible dangling colon that would remain.
if val.Hour() < 1 {
format = strings.Replace(format, "]:", "]", 1)
format = strings.Replace(format, "[03]", "", 1)
format = strings.Replace(format, "[3]", "", 1)
format = strings.Replace(format, "[15]", "", 1)
} else {
format = strings.Replace(format, "[3]", "3", 1)
format = strings.Replace(format, "[15]", "15", 1)
}
return val.Format(format), nil
}
// isTimeFormat checks whether an Excel format string represents a time.Time.
// This function is now correct, but it can detect time format strings that cannot be correctly handled by parseTime()
func isTimeFormat(format string) bool {
var foundTimeFormatCharacters bool
for i := 0; i < len(format); i++ {
curReducedFormat := format[i:]
switch curReducedFormat[0] {
case '\\', '_':
// If there is a slash, skip the next character, and add it to the prefix
// If there is an underscore, skip the next character, but don't add it to the prefix
if len(curReducedFormat) > 1 {
i++
}
case '*':
// Asterisks are used to repeat the next character to fill the full cell width.
// There isn't really a cell size in this context, so this will be ignored.
case '"':
// If there is a quote skip to the next quote, and add the quoted characters to the prefix
endQuoteIndex := strings.Index(curReducedFormat[1:], "\"")
if endQuoteIndex == -1 {
// This is not any type of valid format.
return false
}
i += endQuoteIndex + 1
case '$', '-', '+', '/', '(', ')', ':', '!', '^', '&', '\'', '~', '{', '}', '<', '>', '=', ' ':
// These symbols are allowed to be used as literal without escaping
case ',':
// This is not documented in the XLSX spec as far as I can tell, but Excel and Numbers will include
// commas in number formats without escaping them, so this should be supported.
default:
foundInThisLoop := false
for _, special := range timeFormatCharacters {
if strings.HasPrefix(curReducedFormat, special) {
foundTimeFormatCharacters = true
foundInThisLoop = true
i += len(special) - 1
break
}
}
if foundInThisLoop {
continue
}
if curReducedFormat[0] == '[' {
// For number formats, this code would happen above in a case '[': section.
// However, for time formats it must happen after looking for occurrences in timeFormatCharacters
// because there are a few time formats that can be wrapped in brackets.
// Brackets can be currency annotations (e.g. [$$-409])
// color formats (e.g. [color1] through [color56], as well as [red] etc.)
// conditionals (e.g. [>100], the valid conditionals are =, >, <, >=, <=, <>)
bracketIndex := strings.Index(curReducedFormat, "]")
if bracketIndex == -1 {
// This is not any type of valid format.
return false
}
i += bracketIndex
continue
}
// Symbols that don't have meaning, aren't in the exempt literal characters, and aren't escaped are invalid.
// The string could still be a valid number format string.
return false
}
}
// If the string doesn't have any time formatting characters, it could technically be a time format, but it
// would be a pretty weak time format. A valid time format with no time formatting symbols will also be a number
// format with no number formatting symbols, which is essentially a constant string that does not depend on the
// cell's value in anyway. The downstream logic will do the right thing in that case if this returns false.
return foundTimeFormatCharacters
}
// is12HourTime checks whether an Excel time format string is a 12
// hours form.
func is12HourTime(format string) bool {
return strings.Contains(format, "am/pm") || strings.Contains(format, "AM/PM") || strings.Contains(format, "a/p") || strings.Contains(format, "A/P")
}