package xlsx import ( "fmt" "math" "strconv" "time" ) const ( maxNonScientificNumber = 1e11 minNonScientificNumber = 1e-9 ) // CellType is an int type for storing metadata about the data type in the cell. type CellType int // These are the cell types from the ST_CellType spec const ( CellTypeString CellType = iota // CellTypeStringFormula is a specific format for formulas that return string values. Formulas that return numbers // and booleans are stored as those types. CellTypeStringFormula CellTypeNumeric CellTypeBool // CellTypeInline is not respected on save, all inline string cells will be saved as SharedStrings // when saving to an XLSX file. This the same behavior as that found in Excel. CellTypeInline CellTypeError // d (Date): Cell contains a date in the ISO 8601 format. // That is the only mention of this format in the XLSX spec. // Date seems to be unused by the current version of Excel, it stores dates as Numeric cells with a date format string. // For now these cells will have their value output directly. It is unclear if the value is supposed to be parsed // into a number and then formatted using the formatting or not. CellTypeDate ) func (ct CellType) Ptr() *CellType { return &ct } // Cell is a high level structure intended to provide user access to // the contents of Cell within an xlsx.Row. type Cell struct { Row *Row Value string formula string style *Style NumFmt string parsedNumFmt *parsedNumberFormat date1904 bool Hidden bool HMerge int VMerge int cellType CellType } // CellInterface defines the public API of the Cell. type CellInterface interface { String() string FormattedValue() string } // NewCell creates a cell and adds it to a row. func NewCell(r *Row) *Cell { return &Cell{Row: r, NumFmt: "general"} } // Merge with other cells, horizontally and/or vertically. func (c *Cell) Merge(hcells, vcells int) { c.HMerge = hcells c.VMerge = vcells } // Type returns the CellType of a cell. See CellType constants for more details. func (c *Cell) Type() CellType { return c.cellType } // SetString sets the value of a cell to a string. func (c *Cell) SetString(s string) { c.Value = s c.formula = "" c.cellType = CellTypeString } // String returns the value of a Cell as a string. If you'd like to // see errors returned from formatting then please use // Cell.FormattedValue() instead. func (c *Cell) String() string { // To preserve the String() interface we'll throw away errors. // Not that using FormattedValue is therefore strongly // preferred. value, _ := c.FormattedValue() return value } // SetFloat sets the value of a cell to a float. func (c *Cell) SetFloat(n float64) { c.SetValue(n) } //GetTime returns the value of a Cell as a time.Time func (c *Cell) GetTime(date1904 bool) (t time.Time, err error) { f, err := c.Float() if err != nil { return t, err } return TimeFromExcelTime(f, date1904), nil } /* The following are samples of format samples. * "0.00e+00" * "0", "#,##0" * "0.00", "#,##0.00", "@" * "#,##0 ;(#,##0)", "#,##0 ;[red](#,##0)" * "#,##0.00;(#,##0.00)", "#,##0.00;[red](#,##0.00)" * "0%", "0.00%" * "0.00e+00", "##0.0e+0" */ // SetFloatWithFormat sets the value of a cell to a float and applies // formatting to the cell. func (c *Cell) SetFloatWithFormat(n float64, format string) { c.SetValue(n) c.NumFmt = format c.formula = "" } var timeLocationUTC, _ = time.LoadLocation("UTC") func TimeToUTCTime(t time.Time) time.Time { return time.Date(t.Year(), t.Month(), t.Day(), t.Hour(), t.Minute(), t.Second(), t.Nanosecond(), timeLocationUTC) } func TimeToExcelTime(t time.Time) float64 { return float64(t.UnixNano())/8.64e13 + 25569.0 } // DateTimeOptions are additional options for exporting times type DateTimeOptions struct { // Location allows calculating times in other timezones/locations Location *time.Location // ExcelTimeFormat is the string you want excel to use to format the datetime ExcelTimeFormat string } var ( DefaultDateFormat = builtInNumFmt[14] DefaultDateTimeFormat = builtInNumFmt[22] DefaultDateOptions = DateTimeOptions{ Location: timeLocationUTC, ExcelTimeFormat: DefaultDateFormat, } DefaultDateTimeOptions = DateTimeOptions{ Location: timeLocationUTC, ExcelTimeFormat: DefaultDateTimeFormat, } ) // SetDate sets the value of a cell to a float. func (c *Cell) SetDate(t time.Time) { c.SetDateWithOptions(t, DefaultDateOptions) } func (c *Cell) SetDateTime(t time.Time) { c.SetDateWithOptions(t, DefaultDateTimeOptions) } // SetDateWithOptions allows for more granular control when exporting dates and times func (c *Cell) SetDateWithOptions(t time.Time, options DateTimeOptions) { _, offset := t.In(options.Location).Zone() t = time.Unix(t.Unix()+int64(offset), 0) c.SetDateTimeWithFormat(TimeToExcelTime(t.In(timeLocationUTC)), options.ExcelTimeFormat) } func (c *Cell) SetDateTimeWithFormat(n float64, format string) { c.Value = strconv.FormatFloat(n, 'f', -1, 64) c.NumFmt = format c.formula = "" c.cellType = CellTypeNumeric } // Float returns the value of cell as a number. func (c *Cell) Float() (float64, error) { f, err := strconv.ParseFloat(c.Value, 64) if err != nil { return math.NaN(), err } return f, nil } // SetInt64 sets a cell's value to a 64-bit integer. func (c *Cell) SetInt64(n int64) { c.SetValue(n) } // Int64 returns the value of cell as 64-bit integer. func (c *Cell) Int64() (int64, error) { f, err := strconv.ParseInt(c.Value, 10, 64) if err != nil { return -1, err } return f, nil } // GeneralNumeric returns the value of the cell as a string. It is formatted very closely to the the XLSX spec for how // to display values when the storage type is Number and the format type is General. It is not 100% identical to the // spec but is as close as you can get using the built in Go formatting tools. func (c *Cell) GeneralNumeric() (string, error) { return generalNumericScientific(c.Value, true) } // GeneralNumericWithoutScientific returns numbers that are always formatted as numbers, but it does not follow // the rules for when XLSX should switch to scientific notation, since sometimes scientific notation is not desired, // even if that is how the document is supposed to be formatted. func (c *Cell) GeneralNumericWithoutScientific() (string, error) { return generalNumericScientific(c.Value, false) } // SetInt sets a cell's value to an integer. func (c *Cell) SetInt(n int) { c.SetValue(n) } // SetInt sets a cell's value to an integer. func (c *Cell) SetValue(n interface{}) { switch t := n.(type) { case time.Time: c.SetDateTime(t) return case int, int8, int16, int32, int64: c.setNumeric(fmt.Sprintf("%d", n)) case float64: // When formatting floats, do not use fmt.Sprintf("%v", n), this will cause numbers below 1e-4 to be printed in // scientific notation. Scientific notation is not a valid way to store numbers in XML. // Also not not use fmt.Sprintf("%f", n), this will cause numbers to be stored as X.XXXXXX. Which means that // numbers will lose precision and numbers with fewer significant digits such as 0 will be stored as 0.000000 // which causes tests to fail. c.setNumeric(strconv.FormatFloat(t, 'f', -1, 64)) case float32: c.setNumeric(strconv.FormatFloat(float64(t), 'f', -1, 32)) case string: c.SetString(t) case []byte: c.SetString(string(t)) case nil: c.SetString("") default: c.SetString(fmt.Sprintf("%v", n)) } } // setNumeric sets a cell's value to a number func (c *Cell) setNumeric(s string) { c.Value = s c.NumFmt = builtInNumFmt[builtInNumFmtIndex_GENERAL] c.formula = "" c.cellType = CellTypeNumeric } // Int returns the value of cell as integer. // Has max 53 bits of precision // See: float64(int64(math.MaxInt)) func (c *Cell) Int() (int, error) { f, err := strconv.ParseFloat(c.Value, 64) if err != nil { return -1, err } return int(f), nil } // SetBool sets a cell's value to a boolean. func (c *Cell) SetBool(b bool) { if b { c.Value = "1" } else { c.Value = "0" } c.cellType = CellTypeBool } // Bool returns a boolean from a cell's value. // TODO: Determine if the current return value is // appropriate for types other than CellTypeBool. func (c *Cell) Bool() bool { // If bool, just return the value. if c.cellType == CellTypeBool { return c.Value == "1" } // If numeric, base it on a non-zero. if c.cellType == CellTypeNumeric { return c.Value != "0" } // Return whether there's an empty string. return c.Value != "" } // SetFormula sets the format string for a cell. func (c *Cell) SetFormula(formula string) { c.formula = formula c.cellType = CellTypeNumeric } func (c *Cell) SetStringFormula(formula string) { c.formula = formula c.cellType = CellTypeStringFormula } // Formula returns the formula string for the cell. func (c *Cell) Formula() string { return c.formula } // GetStyle returns the Style associated with a Cell func (c *Cell) GetStyle() *Style { if c.style == nil { c.style = NewStyle() } return c.style } // SetStyle sets the style of a cell. func (c *Cell) SetStyle(style *Style) { c.style = style } // GetNumberFormat returns the number format string for a cell. func (c *Cell) GetNumberFormat() string { return c.NumFmt } func (c *Cell) formatToFloat(format string) (string, error) { f, err := strconv.ParseFloat(c.Value, 64) if err != nil { return c.Value, err } return fmt.Sprintf(format, f), nil } func (c *Cell) formatToInt(format string) (string, error) { f, err := strconv.ParseFloat(c.Value, 64) if err != nil { return c.Value, err } return fmt.Sprintf(format, int(f)), nil } // getNumberFormat will update the parsedNumFmt struct if it has become out of date, since a cell's NumFmt string is a // public field that could be edited by clients. func (c *Cell) getNumberFormat() *parsedNumberFormat { if c.parsedNumFmt == nil || c.parsedNumFmt.numFmt != c.NumFmt { c.parsedNumFmt = parseFullNumberFormatString(c.NumFmt) } return c.parsedNumFmt } // FormattedValue 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. func (c *Cell) FormattedValue() (string, error) { fullFormat := c.getNumberFormat() returnVal, err := fullFormat.FormatValue(c) if fullFormat.parseEncounteredError != nil { return returnVal, *fullFormat.parseEncounteredError } return returnVal, err }