func (ntb *NumericToBinary) SetOutput() {
newAtts := make([]data.Attribute, 0)
newClassIndex := ntb.input.ClassIndex()
out := data.NewInstances()
vals := make([]string, 2)
// Compute new attributes
for j, att := range ntb.input.Attributes() {
if j == newClassIndex || att.Type() != data.NUMERIC {
newAtts = append(newAtts, att)
} else {
attributeName := att.Name() + "_binarize"
vals[0] = "0"
vals[1] = "1"
nAtt := data.NewAttribute()
nAtt.SetName(attributeName)
nAtt.SetType(data.NOMINAL)
nAtt.SetValues(vals)
nAtt.SetHasFixedBounds(true)
hash := make(map[string]int, 2)
hash[vals[0]] = 0
hash[vals[1]] = 1
nAtt.SetValuesIndexes(hash)
newAtts = append(newAtts, nAtt)
}
}
out.SetAttributes(newAtts)
out.SetDatasetName(ntb.input.DatasetName())
out.SetClassIndex(newClassIndex)
ntb.output = out
}
func (stwv *StringToWordVector) determineDictionary(inst *data.Instances) {
/* TODO: see if use a stopwords list*/
fmt.Println("Determing dictionary!")
classInd := inst.ClassIndex()
values := 1
if stwv.perClass && (classInd != -1) {
values = len(inst.Attributes()[classInd].Values())
}
dicA := make([]*omap.Map, values)
for i := 0; i < values; i++ {
dicA[i] = omap.NewStringKeyed()
}
// Tokenize all training text into an orderedMap of "words".
pruneRate := int64((stwv.perdiodicPruningRate / 100) * len(inst.Instances()))
for i, instance := range inst.Instances() {
vInd := int(0)
if stwv.perClass && (classInd != -1) {
vInd = int(instance.RealValues()[classInd])
}
//Iterate through all relevant string attributes of the current instance
hashtable := make(map[string]int, 0)
for j := 0; j < instance.NumAttributes(); j++ {
if !instance.IsMissingValue(j) && inst.Attributes()[j].IsString() {
// Iterate through tokens, perform stemming, and remove stopwords
// (if required)
//fmt.Println(instance.Values())
words := strings.Fields(instance.Values()[j])
for _, word := range words {
_, present := hashtable[word]
if !present {
hashtable[word] = 0
}
//fmt.Println(word)
if count, present := dicA[vInd].Find(word); !present {
dicA[vInd].Insert(word, Count{1, 0})
} else {
count, _ := count.(Count)
count.Count++
dicA[vInd].Insert(word, count)
}
//fmt.Println(dicA[vInd][word])
}
}
}
//updating the docCount for the words that have occurred in this
//instance(document).
enumeration := make([]string, 0, len(hashtable))
for word, _ := range hashtable { //only the words
enumeration = append(enumeration, word)
}
for _, word := range enumeration {
if count, present := dicA[vInd].Find(word); present {
count := count.(Count)
count.DocCount++
//delete(dicA[vInd], word)
dicA[vInd].Insert(word, count)
//fmt.Println(word, " ",dicA[vInd][word])
} else {
panic("Check the code, there must be a word in the dictionary")
}
fmt.Println(dicA[vInd].Find(word))
}
if pruneRate > 0 {
if int64(i)%pruneRate == 0 && i > 0 {
for z := 0; z < values; z++ {
d := make([]string, 1000)
dicA[z].Do(func(key, value interface{}) {
word, _ := key.(string)
count, _ := value.(Count)
if count.Count <= 1 {
d = append(d, word)
}
})
// for word, _ := range dicA[z] {
// count := dicA[z][word]
// if count.Count <= 1 {
// d = append(d, word)
// }
// }
for _, word := range d {
dicA[z].Delete(word)
//delete(dicA[z], word)
}
}
}
}
//fmt.Println("new instance-----------------------------------------------------------")
}
//fmt.Println(dicA)
// Figure out the minimum required word frequency
totalSize := int(0)
prune := make([]int, values)
for z := 0; z < values; z++ {
totalSize += dicA[z].Len()
array := make([]int, dicA[z].Len())
pos := int(0)
dicA[z].Do(func(key, value interface{}) {
//_, _ := key.(string)
count, _ := value.(Count)
array[pos] = count.Count
pos++
})
// for word, _ := range dicA[z] {
// count := dicA[z][word]
// array[pos] = count.Count
// pos++
// }
sort.Ints(array)
fmt.Println(array)
if len(array) < stwv.wordsToKeep {
// if there aren't enough words, set the threshold to
// minFreq
prune[z] = int(stwv.minTermFreq)
} else {
// otherwise set it to be at least minFreq
idx := len(array) - stwv.wordsToKeep
prune[z] = int(math.Max(float64(stwv.minTermFreq), float64(array[idx])))
}
//fmt.Println(prune[z])
}
// Convert the dictionary into an attribute index
// and create one attribute per word
attributes := make([]data.Attribute, 0, totalSize+len(inst.Attributes()))
fmt.Println(totalSize+len(inst.Attributes()), "len(attributes)")
// Add the non-converted attributes
classIndex := int(-1)
for i, attr := range stwv.inputFormat.Attributes() {
if !attr.IsString() {
if inst.ClassIndex() == i {
classIndex = len(attributes)
}
//fmt.Println(attr)
attributes = append(attributes, attr)
}
}
// Add the word vector attributes (eliminating duplicates
// that occur in multiple classes)
newDic := omap.NewStringKeyed()
index := len(attributes)
for z := 0; z < values; z++ {
dicA[z].Do(func(key, value interface{}) {
word, _ := key.(string)
count, _ := value.(Count)
if count.Count >= prune[z] {
if _, present := newDic.Find(word); !present {
newDic.Insert(word, int(index))
index++
att := data.NewAttribute()
att.SetName(word)
att.SetType(data.NUMERIC)
attributes = append(attributes, att)
//fmt.Println(index)
}
}
})
// for word, _ := range dicA[z] {
// count := dicA[z][word]
// //fmt.Println(count.Count, prune[z])
// if count.Count >= prune[z] {
// if _, present := newDic[word]; !present {
// newDic[word] = float64(index)
// index++
// att := data.NewAttribute()
// att.SetName(word)
// att.SetType(data.STRING)
// attributes = append(attributes, att)
// fmt.Println(index)
// }
// }
// }
}
//fmt.Println(newDic)
// Compute document frequencies
stwv.docsCounts = make([]int, len(attributes))
//idx := 0
newDic.Do(func(key, value interface{}) {
word, _ := key.(string)
idx, _ := value.(int)
docsCount := 0
for j := 0; j < values; j++ {
if count, present := dicA[j].Find(word); present {
count := count.(Count)
//fmt.Println(count.DocCount, "doccount newdic")
docsCount += count.DocCount
}
}
stwv.docsCounts[idx] = docsCount
})
// for word, idx := range newDic {
// docsCount := 0
// for j := 0; j < values; j++ {
// if count, present := dicA[j][word]; present {
// docsCount += count.DocCount
// }
// }
// stwv.docsCounts[int(idx)] = docsCount
// //idx++
// }
fmt.Println("doc: ", stwv.docsCounts)
stwv.dictionary = newDic
////fmt.Println("numInst", len(inst.Instances()))
stwv.numInstances = len(inst.Instances())
stwv.outputFormat = data.NewInstances()
stwv.outputFormat.SetAttributes(attributes)
stwv.outputFormat.SetClassIndex(classIndex)
}