ref #65, new formula functions: SKEW.P and SLOPE, remove no-required format default

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xuri 2022-04-16 13:53:16 +08:00
parent 5a279321bb
commit 6fa950a4f8
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GPG Key ID: BA5E5BB1C948EDF7
6 changed files with 160 additions and 35 deletions

70
calc.go
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@ -640,7 +640,9 @@ type formulaFuncs struct {
// SIN
// SINH
// SKEW
// SKEW.P
// SLN
// SLOPE
// SMALL
// SQRT
// SQRTPI
@ -8860,14 +8862,20 @@ func (fn *formulaFuncs) min(mina bool, argsList *list.List) formulaArg {
return newNumberFormulaArg(min)
}
// pearsonProduct is an implementation of the formula functions PEARSON and
// RSQ.
// pearsonProduct is an implementation of the formula functions PEARSON, RSQ
// and SLOPE.
func (fn *formulaFuncs) pearsonProduct(name string, argsList *list.List) formulaArg {
if argsList.Len() != 2 {
return newErrorFormulaArg(formulaErrorVALUE, fmt.Sprintf("%s requires 2 arguments", name))
}
array1 := argsList.Front().Value.(formulaArg).ToList()
array2 := argsList.Back().Value.(formulaArg).ToList()
var array1, array2 []formulaArg
if name == "SLOPE" {
array1 = argsList.Back().Value.(formulaArg).ToList()
array2 = argsList.Front().Value.(formulaArg).ToList()
} else {
array1 = argsList.Front().Value.(formulaArg).ToList()
array2 = argsList.Back().Value.(formulaArg).ToList()
}
if len(array1) != len(array2) {
return newErrorFormulaArg(formulaErrorNA, formulaErrorNA)
}
@ -8898,8 +8906,11 @@ func (fn *formulaFuncs) pearsonProduct(name string, argsList *list.List) formula
if name == "RSQ" {
return newNumberFormulaArg(math.Pow(sum/math.Sqrt(deltaX*deltaY), 2))
}
if name == "PEARSON" {
return newNumberFormulaArg(sum / math.Sqrt(deltaX*deltaY))
}
return newNumberFormulaArg(sum / deltaX)
}
// PEARSON function calculates the Pearson Product-Moment Correlation
// Coefficient for two sets of values. The syntax of the function is:
@ -9268,16 +9279,19 @@ func (fn *formulaFuncs) RSQ(argsList *list.List) formulaArg {
return fn.pearsonProduct("RSQ", argsList)
}
// SKEW function calculates the skewness of the distribution of a supplied set
// of values. The syntax of the function is:
//
// SKEW(number1,[number2],...)
//
func (fn *formulaFuncs) SKEW(argsList *list.List) formulaArg {
// skew is an implementation of the formula functions SKEW and SKEW.P.
func (fn *formulaFuncs) skew(name string, argsList *list.List) formulaArg {
if argsList.Len() < 1 {
return newErrorFormulaArg(formulaErrorVALUE, "SKEW requires at least 1 argument")
return newErrorFormulaArg(formulaErrorVALUE, fmt.Sprintf("%s requires at least 1 argument", name))
}
mean := fn.AVERAGE(argsList)
var stdDev formulaArg
var count, summer float64
if name == "SKEW" {
stdDev = fn.STDEV(argsList)
} else {
stdDev = fn.STDEVP(argsList)
}
mean, stdDev, count, summer := fn.AVERAGE(argsList), fn.STDEV(argsList), 0.0, 0.0
for arg := argsList.Front(); arg != nil; arg = arg.Next() {
token := arg.Value.(formulaArg)
switch token.Type {
@ -9300,11 +9314,43 @@ func (fn *formulaFuncs) SKEW(argsList *list.List) formulaArg {
}
}
if count > 2 {
if name == "SKEW" {
return newNumberFormulaArg(summer * (count / ((count - 1) * (count - 2))))
}
return newNumberFormulaArg(summer / count)
}
return newErrorFormulaArg(formulaErrorDIV, formulaErrorDIV)
}
// SKEW function calculates the skewness of the distribution of a supplied set
// of values. The syntax of the function is:
//
// SKEW(number1,[number2],...)
//
func (fn *formulaFuncs) SKEW(argsList *list.List) formulaArg {
return fn.skew("SKEW", argsList)
}
// SKEWdotP function calculates the skewness of the distribution of a supplied
// set of values. The syntax of the function is:
//
// SKEW.P(number1,[number2],...)
//
func (fn *formulaFuncs) SKEWdotP(argsList *list.List) formulaArg {
return fn.skew("SKEW.P", argsList)
}
// SLOPE returns the slope of the linear regression line through data points in
// known_y's and known_x's. The slope is the vertical distance divided by the
// horizontal distance between any two points on the line, which is the rate
// of change along the regression line. The syntax of the function is:
//
// SLOPE(known_y's,known_x's)
//
func (fn *formulaFuncs) SLOPE(argsList *list.List) formulaArg {
return fn.pearsonProduct("SLOPE", argsList)
}
// SMALL function returns the k'th smallest value from an array of numeric
// values. The syntax of the function is:
//

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@ -1157,6 +1157,12 @@ func TestCalcCellValue(t *testing.T) {
"=SKEW(1,2,3,4,3)": "-0.404796008910937",
"=SKEW(A1:B2)": "0",
"=SKEW(A1:D3)": "0",
// SKEW.P
"=SKEW.P(1,2,3,4,3)": "-0.27154541788364",
"=SKEW.P(A1:B2)": "0",
"=SKEW.P(A1:D3)": "0",
// SLOPE
"=SLOPE(A1:A4,B1:B4)": "1",
// SMALL
"=SMALL(A1:A5,1)": "0",
"=SMALL(A1:B5,2)": "1",
@ -3063,6 +3069,14 @@ func TestCalcCellValue(t *testing.T) {
"=SKEW()": "SKEW requires at least 1 argument",
"=SKEW(\"\")": "strconv.ParseFloat: parsing \"\": invalid syntax",
"=SKEW(0)": "#DIV/0!",
// SKEW.P
"=SKEW.P()": "SKEW.P requires at least 1 argument",
"=SKEW.P(\"\")": "strconv.ParseFloat: parsing \"\": invalid syntax",
"=SKEW.P(0)": "#DIV/0!",
// SLOPE
"=SLOPE()": "SLOPE requires 2 arguments",
"=SLOPE(A1:A2,B1:B1)": "#N/A",
"=SLOPE(A4,A4)": "#DIV/0!",
// SMALL
"=SMALL()": "SMALL requires 2 arguments",
"=SMALL(A1:A5,0)": "k should be > 0",
@ -4968,6 +4982,89 @@ func TestCalcMODE(t *testing.T) {
}
}
func TestCalcPEARSON(t *testing.T) {
cellData := [][]interface{}{
{"x", "y"},
{1, 10.11},
{2, 22.9},
{2, 27.61},
{3, 27.61},
{4, 11.15},
{5, 31.08},
{6, 37.9},
{7, 33.49},
{8, 21.05},
{9, 27.01},
{10, 45.78},
{11, 31.32},
{12, 50.57},
{13, 45.48},
{14, 40.94},
{15, 53.76},
{16, 36.18},
{17, 49.77},
{18, 55.66},
{19, 63.83},
{20, 63.6},
}
f := prepareCalcData(cellData)
formulaList := map[string]string{
"=PEARSON(A2:A22,B2:B22)": "0.864129542184994",
}
for formula, expected := range formulaList {
assert.NoError(t, f.SetCellFormula("Sheet1", "C1", formula))
result, err := f.CalcCellValue("Sheet1", "C1")
assert.NoError(t, err, formula)
assert.Equal(t, expected, result, formula)
}
}
func TestCalcRSQ(t *testing.T) {
cellData := [][]interface{}{
{"known_y's", "known_x's"},
{2, 22.9},
{7, 33.49},
{8, 34.5},
{3, 27.61},
{4, 19.5},
{1, 10.11},
{6, 37.9},
{5, 31.08},
}
f := prepareCalcData(cellData)
formulaList := map[string]string{
"=RSQ(A2:A9,B2:B9)": "0.711666290486784",
}
for formula, expected := range formulaList {
assert.NoError(t, f.SetCellFormula("Sheet1", "C1", formula))
result, err := f.CalcCellValue("Sheet1", "C1")
assert.NoError(t, err, formula)
assert.Equal(t, expected, result, formula)
}
}
func TestCalcSLOP(t *testing.T) {
cellData := [][]interface{}{
{"known_x's", "known_y's"},
{1, 3},
{2, 7},
{3, 17},
{4, 20},
{5, 20},
{6, 27},
}
f := prepareCalcData(cellData)
formulaList := map[string]string{
"=SLOPE(A2:A7,B2:B7)": "0.200826446280992",
}
for formula, expected := range formulaList {
assert.NoError(t, f.SetCellFormula("Sheet1", "C1", formula))
result, err := f.CalcCellValue("Sheet1", "C1")
assert.NoError(t, err, formula)
assert.Equal(t, expected, result, formula)
}
}
func TestCalcSHEET(t *testing.T) {
f := NewFile()
f.NewSheet("Sheet2")

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@ -479,16 +479,11 @@ func parseFormatChartSet(formatSet string) (*formatChart, error) {
},
Format: formatPicture{
FPrintsWithSheet: true,
FLocksWithSheet: false,
NoChangeAspect: false,
OffsetX: 0,
OffsetY: 0,
XScale: 1.0,
YScale: 1.0,
},
Legend: formatChartLegend{
Position: "bottom",
ShowLegendKey: false,
},
Title: formatChartTitle{
Name: " ",

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@ -31,11 +31,6 @@ import (
func parseFormatPictureSet(formatSet string) (*formatPicture, error) {
format := formatPicture{
FPrintsWithSheet: true,
FLocksWithSheet: false,
NoChangeAspect: false,
Autofit: false,
OffsetX: 0,
OffsetY: 0,
XScale: 1.0,
YScale: 1.0,
}

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@ -25,15 +25,10 @@ func parseFormatShapeSet(formatSet string) (*formatShape, error) {
Height: 160,
Format: formatPicture{
FPrintsWithSheet: true,
FLocksWithSheet: false,
NoChangeAspect: false,
OffsetX: 0,
OffsetY: 0,
XScale: 1.0,
YScale: 1.0,
},
Line: formatLine{Width: 1},
Macro: "",
}
err := json.Unmarshal([]byte(formatSet), &format)
return &format, err

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@ -23,10 +23,7 @@ import (
// parseFormatTableSet provides a function to parse the format settings of the
// table with default value.
func parseFormatTableSet(formatSet string) (*formatTable, error) {
format := formatTable{
TableStyle: "",
ShowRowStripes: true,
}
format := formatTable{ShowRowStripes: true}
err := json.Unmarshal(parseFormatSet(formatSet), &format)
return &format, err
}