func main() {
fm := flag.String("fm", "featurematrix.afm", "AFM formated feature matrix to use.")
rf := flag.String("rfpred", "rface.sf", "A predictor forest.")
outf := flag.String("leaves", "leaves.tsv", "a case by case sparse matrix of leaf co-occurrence in tsv format")
boutf := flag.String("branches", "", "a case by feature sparse matrix of leaf co-occurrence in tsv format")
soutf := flag.String("splits", "", "a file to write a json record of splite per feature")
var threads int
flag.IntVar(&threads, "threads", 1, "Parse seperate forests in n seperate threads.")
flag.Parse()
splits := make(map[string][]string)
//Parse Data
data, err := CloudForest.LoadAFM(*fm)
if err != nil {
log.Fatal(err)
}
log.Print("Data file ", len(data.Data), " by ", data.Data[0].Length())
counts := new(CloudForest.SparseCounter)
var caseFeatureCounts *CloudForest.SparseCounter
if *boutf != "" {
caseFeatureCounts = new(CloudForest.SparseCounter)
}
files := strings.Split(*rf, ",")
runtime.GOMAXPROCS(threads)
fileChan := make(chan string, 0)
doneChan := make(chan int, 0)
go func() {
for _, fn := range files {
fileChan <- fn
}
}()
for i := 0; i < threads; i++ {
go func() {
for {
fn := <-fileChan
forestfile, err := os.Open(fn) // For read access.
if err != nil {
log.Fatal(err)
}
defer forestfile.Close()
forestreader := CloudForest.NewForestReader(forestfile)
forest, err := forestreader.ReadForest()
if err != nil {
log.Fatal(err)
}
log.Print("Forest has ", len(forest.Trees), " trees ")
for i := 0; i < len(forest.Trees); i++ {
fmt.Print(".")
leaves := forest.Trees[i].GetLeaves(data, caseFeatureCounts)
for _, leaf := range leaves {
for j := 0; j < len(leaf.Cases); j++ {
for k := 0; k < len(leaf.Cases); k++ {
counts.Add(leaf.Cases[j], leaf.Cases[k], 1)
}
}
}
if *soutf != "" {
forest.Trees[i].Root.Climb(func(n *CloudForest.Node) {
if n.Splitter != nil {
name := n.Splitter.Feature
_, ok := splits[name]
if !ok {
splits[name] = make([]string, 0, 10)
}
split := ""
switch n.Splitter.Numerical {
case true:
split = fmt.Sprintf("%v", n.Splitter.Value)
case false:
keys := make([]string, 0, len(n.Splitter.Left))
for k := range n.Splitter.Left {
keys = append(keys, k)
}
split = strings.Join(keys, ",")
}
splits[name] = append(splits[name], split)
}
})
}
}
doneChan <- 1
}
}()
}
for i := 0; i < len(files); i++ {
<-doneChan
}
log.Print("Outputting Case Case Co-Occurrence Counts")
outfile, err := os.Create(*outf)
if err != nil {
log.Fatal(err)
}
defer outfile.Close()
counts.WriteTsv(outfile)
if *boutf != "" {
log.Print("Outputting Case Feature Co-Occurrence Counts")
boutfile, err := os.Create(*boutf)
if err != nil {
log.Fatal(err)
}
defer boutfile.Close()
caseFeatureCounts.WriteTsv(boutfile)
}
if *soutf != "" {
soutfile, err := os.Create(*soutf)
if err != nil {
log.Fatal(err)
}
defer soutfile.Close()
encoder := json.NewEncoder(soutfile)
encoder.Encode(splits)
}
}
func main() {
fm := flag.String("fm",
"featurematrix.afm", "AFM formated feature matrix containing data.")
rf := flag.String("rfpred",
"rface.sf", "A predictor forest.")
predfn := flag.String("preds",
"", "The name of a file to write the predictions into.")
votefn := flag.String("votes",
"", "The name of a file to write categorical vote totals to.")
var num bool
flag.BoolVar(&num, "mean", false, "Force numeric (mean) voting.")
var sum bool
flag.BoolVar(&sum, "sum", false, "Force numeric sum voting (for gradient boosting etc).")
var expit bool
flag.BoolVar(&expit, "expit", false, "Expit (inverst logit) transform data (for gradient boosting classification).")
var cat bool
flag.BoolVar(&cat, "mode", false, "Force categorical (mode) voting.")
flag.Parse()
//Parse Data
data, err := CloudForest.LoadAFM(*fm)
if err != nil {
log.Fatal(err)
}
forestfile, err := os.Open(*rf) // For read access.
if err != nil {
log.Fatal(err)
}
defer forestfile.Close()
forestreader := CloudForest.NewForestReader(forestfile)
forest, err := forestreader.ReadForest()
if err != nil {
log.Fatal(err)
}
var predfile *os.File
if *predfn != "" {
predfile, err = os.Create(*predfn)
if err != nil {
log.Fatal(err)
}
defer predfile.Close()
}
var bb CloudForest.VoteTallyer
switch {
case sum:
bb = CloudForest.NewSumBallotBox(data.Data[0].Length())
case !cat && (num || strings.HasPrefix(forest.Target, "N")):
bb = CloudForest.NewNumBallotBox(data.Data[0].Length())
default:
bb = CloudForest.NewCatBallotBox(data.Data[0].Length())
}
for _, tree := range forest.Trees {
tree.Vote(data, bb)
}
targeti, hasTarget := data.Map[forest.Target]
if hasTarget {
fmt.Printf("Target is %v in feature %v\n", forest.Target, targeti)
er := bb.TallyError(data.Data[targeti])
fmt.Printf("Error: %v\n", er)
}
if *predfn != "" {
fmt.Printf("Outputting label predicted actual tsv to %v\n", *predfn)
for i, l := range data.CaseLabels {
actual := "NA"
if hasTarget {
actual = data.Data[targeti].GetStr(i)
}
result := ""
if sum || forest.Intercept != 0.0 {
numresult := 0.0
if sum {
numresult = bb.(*CloudForest.SumBallotBox).TallyNum(i) + forest.Intercept
} else {
numresult = bb.(*CloudForest.NumBallotBox).TallyNum(i) + forest.Intercept
}
if expit {
numresult = CloudForest.Expit(numresult)
}
result = fmt.Sprintf("%v", numresult)
} else {
result = bb.Tally(i)
}
fmt.Fprintf(predfile, "%v\t%v\t%v\n", l, result, actual)
}
}
//Not thread safe code!
if *votefn != "" {
fmt.Printf("Outputting vote totals to %v\n", *votefn)
cbb := bb.(*CloudForest.CatBallotBox)
votefile, err := os.Create(*votefn)
if err != nil {
log.Fatal(err)
}
defer votefile.Close()
fmt.Fprintf(votefile, ".")
for _, lable := range cbb.CatMap.Back {
fmt.Fprintf(votefile, "\t%v", lable)
}
fmt.Fprintf(votefile, "\n")
for i, box := range cbb.Box {
fmt.Fprintf(votefile, "%v", data.CaseLabels[i])
for j, _ := range cbb.CatMap.Back {
total := 0.0
total = box.Map[j]
fmt.Fprintf(votefile, "\t%v", total)
}
fmt.Fprintf(votefile, "\n")
}
}
}
func main() {
fm := flag.String("fm", "featurematrix.afm", "AFM formated feature matrix to use.")
rf := flag.String("rfpred", "rface.sf", "A predictor forest.")
outf := flag.String("leaves", "leaves.tsv", "a case by case sparse matrix of leaf co-occurrence in tsv format")
boutf := flag.String("branches", "", "a case by feature sparse matrix of leaf co-occurrence in tsv format")
var threads int
flag.IntVar(&threads, "threads", 1, "Parse seperate forests in n seperate threads.")
flag.Parse()
//Parse Data
data, err := CloudForest.LoadAFM(*fm)
if err != nil {
log.Fatal(err)
}
log.Print("Data file ", len(data.Data), " by ", data.Data[0].Length())
counts := new(CloudForest.SparseCounter)
var caseFeatureCounts *CloudForest.SparseCounter
if *boutf != "" {
caseFeatureCounts = new(CloudForest.SparseCounter)
}
files := strings.Split(*rf, ",")
runtime.GOMAXPROCS(threads)
fileChan := make(chan string, 0)
doneChan := make(chan int, 0)
go func() {
for _, fn := range files {
fileChan <- fn
}
}()
for i := 0; i < threads; i++ {
go func() {
for {
fn := <-fileChan
forestfile, err := os.Open(fn) // For read access.
if err != nil {
log.Fatal(err)
}
defer forestfile.Close()
forestreader := CloudForest.NewForestReader(forestfile)
forest, err := forestreader.ReadForest()
if err != nil {
log.Fatal(err)
}
log.Print("Forest has ", len(forest.Trees), " trees ")
for i := 0; i < len(forest.Trees); i++ {
leaves := forest.Trees[i].GetLeaves(data, caseFeatureCounts)
for _, leaf := range leaves {
for j := 0; j < len(leaf.Cases); j++ {
for k := 0; k < len(leaf.Cases); k++ {
counts.Add(leaf.Cases[j], leaf.Cases[k], 1)
}
}
}
}
doneChan <- 1
}
}()
}
for i := 0; i < len(files); i++ {
<-doneChan
}
log.Print("Outputting Case Case Co-Occurrence Counts")
outfile, err := os.Create(*outf) // For read access.
if err != nil {
log.Fatal(err)
}
defer outfile.Close()
counts.WriteTsv(outfile)
if *boutf != "" {
log.Print("Outputting Case Feature Co-Occurrence Counts")
boutfile, err := os.Create(*boutf) // For read access.
if err != nil {
log.Fatal(err)
}
defer boutfile.Close()
caseFeatureCounts.WriteTsv(boutfile)
}
}
