const annotationMaxTileSpan = 100
type sliceNumpy struct {
- filter filter
- threads int
- chi2Cases []bool
- chi2PValue float64
- pcaComponents int
- minCoverage int
- includeVariant1 bool
- debugTag tagID
+ filter filter
+ threads int
+ chi2Cases []bool
+ chi2PValue float64
+ pvalueMinFrequency float64
+ maxFrequency float64
+ pcaComponents int
+ minCoverage int
+ minCoverageAll bool
+ includeVariant1 bool
+ debugTag tagID
cgnames []string
samples []sampleInfo
flags.IntVar(&cmd.pcaComponents, "pca-components", 4, "number of PCA components to compute / use in logistic regression")
maxPCATiles := flags.Int("max-pca-tiles", 0, "maximum tiles to use as PCA input (filter, then drop every 2nd colum pair until below max)")
debugTag := flags.Int("debug-tag", -1, "log debugging details about specified tag")
+ flags.BoolVar(&cmd.minCoverageAll, "min-coverage-all", false, "apply -min-coverage filter based on all samples, not just training set")
flags.IntVar(&cmd.threads, "threads", 16, "number of memory-hungry assembly threads, and number of VCPUs to request for arvados container")
flags.Float64Var(&cmd.chi2PValue, "chi2-p-value", 1, "do Χ² test (or logistic regression if -samples file has PCA components) and omit columns with p-value above this threshold")
+ flags.Float64Var(&cmd.pvalueMinFrequency, "pvalue-min-frequency", 0.01, "skip p-value calculation on tile variants below this frequency in the training set")
+ flags.Float64Var(&cmd.maxFrequency, "max-frequency", 1, "do not output variants above this frequency in the training set")
flags.BoolVar(&cmd.includeVariant1, "include-variant-1", false, "include most common variant when building one-hot matrix")
cmd.filter.Flags(flags)
err := flags.Parse(args)
"-chunked-onehot=" + fmt.Sprintf("%v", *onehotChunked),
"-samples=" + *samplesFilename,
"-case-control-only=" + fmt.Sprintf("%v", *caseControlOnly),
+ "-min-coverage-all=" + fmt.Sprintf("%v", cmd.minCoverageAll),
"-pca=" + fmt.Sprintf("%v", *onlyPCA),
"-pca-components=" + fmt.Sprintf("%d", cmd.pcaComponents),
"-max-pca-tiles=" + fmt.Sprintf("%d", *maxPCATiles),
"-chi2-p-value=" + fmt.Sprintf("%f", cmd.chi2PValue),
+ "-pvalue-min-frequency=" + fmt.Sprintf("%f", cmd.pvalueMinFrequency),
+ "-max-frequency=" + fmt.Sprintf("%f", cmd.maxFrequency),
"-include-variant-1=" + fmt.Sprintf("%v", cmd.includeVariant1),
"-debug-tag=" + fmt.Sprintf("%d", cmd.debugTag),
}
if err != nil {
return err
}
- if len(cmd.samples[0].pcaComponents) > 0 {
- cmd.pvalue = glmPvalueFunc(cmd.samples, cmd.pcaComponents)
- // Unfortunately, statsmodel/glm lib logs
- // stuff to os.Stdout when it panics on an
- // unsolvable problem. We recover() from the
- // panic in glm.go, but we also need to
- // commandeer os.Stdout to avoid producing
- // large quantities of logs.
- stdoutWas := os.Stdout
- defer func() { os.Stdout = stdoutWas }()
- os.Stdout, err = os.Open(os.DevNull)
- if err != nil {
- return err
- }
- }
} else if *caseControlOnly {
return fmt.Errorf("-case-control-only does not make sense without -samples")
}
}
}
}
- if cmd.filter.MinCoverage == 1 {
- // In the generic formula below, floating point
- // arithmetic can effectively push the coverage
- // threshold above 1.0, which is impossible/useless.
- // 1.0 needs to mean exactly 100% coverage.
+
+ if cmd.minCoverageAll {
cmd.minCoverage = len(cmd.cgnames)
} else {
- cmd.minCoverage = int(math.Ceil(cmd.filter.MinCoverage * float64(len(cmd.cgnames))))
+ cmd.minCoverage = cmd.trainingSetSize
+ }
+ if cmd.filter.MinCoverage < 1 {
+ cmd.minCoverage = int(math.Ceil(cmd.filter.MinCoverage * float64(cmd.minCoverage)))
+ }
+
+ if len(cmd.samples[0].pcaComponents) > 0 {
+ cmd.pvalue = glmPvalueFunc(cmd.samples, cmd.pcaComponents)
+ // Unfortunately, statsmodel/glm lib logs stuff to
+ // os.Stdout when it panics on an unsolvable
+ // problem. We recover() from the panic in glm.go, but
+ // we also need to commandeer os.Stdout to avoid
+ // producing large quantities of logs.
+ stdoutWas := os.Stdout
+ defer func() { os.Stdout = stdoutWas }()
+ os.Stdout, err = os.Open(os.DevNull)
+ if err != nil {
+ return err
+ }
}
// cgnamemap[name]==true for samples that we are including in
cgnamemap[name] = true
}
- {
- samplesOutFilename := *outputDir + "/samples.csv"
- log.Infof("writing sample metadata to %s", samplesOutFilename)
- var f *os.File
- f, err = os.Create(samplesOutFilename)
- if err != nil {
- return err
- }
- defer f.Close()
- for i, si := range cmd.samples {
- var cc, tv string
- if si.isCase {
- cc = "1"
- } else if si.isControl {
- cc = "0"
- }
- if si.isTraining {
- tv = "1"
- } else {
- tv = "0"
- }
- _, err = fmt.Fprintf(f, "%d,%s,%s,%s\n", i, si.id, cc, tv)
- if err != nil {
- err = fmt.Errorf("write %s: %w", samplesOutFilename, err)
- return err
- }
- }
- err = f.Close()
- if err != nil {
- err = fmt.Errorf("close %s: %w", samplesOutFilename, err)
- return err
- }
- log.Print("done")
+ err = writeSampleInfo(cmd.samples, *outputDir)
+ if err != nil {
+ return err
}
log.Info("indexing reference tiles")
return err
}
foundthistag := false
- taglib.FindAll(tiledata[:len(tiledata)-1], func(tagid tagID, offset, _ int) {
+ taglib.FindAll(bufio.NewReader(bytes.NewReader(tiledata[:len(tiledata)-1])), nil, func(tagid tagID, offset, _ int) {
if !foundthistag && tagid == libref.Tag {
foundthistag = true
return
if err == errSkip {
return nil
} else if err != nil {
- return fmt.Errorf("%04d: DecodeLibrary(%s): err", infileIdx, infile)
+ return fmt.Errorf("%04d: DecodeLibrary(%s): %w", infileIdx, infile, err)
}
tagstart := cgs[cmd.cgnames[0]].StartTag
tagend := cgs[cmd.cgnames[0]].EndTag
count[blake2b.Sum256(rt.tiledata)] = 0
}
- for cgname, cg := range cgs {
+ for cgidx, cgname := range cmd.cgnames {
+ if !cmd.minCoverageAll && !cmd.samples[cgidx].isTraining {
+ continue
+ }
+ cg := cgs[cgname]
idx := int(tag-tagstart) * 2
for allele := 0; allele < 2; allele++ {
v := cg.Variants[idx+allele]
if cmd.filter.MaxTag >= 0 && tag > tagID(cmd.filter.MaxTag) {
break
}
- if rt := reftile[tag]; rt == nil || rt.excluded {
+ if rt := reftile[tag]; mask != nil && (rt == nil || rt.excluded) {
continue
}
if v == 0 {
}
log.Print("done")
- samplesOutFilename := *outputDir + "/samples.csv"
- log.Infof("writing sample metadata to %s", samplesOutFilename)
- var f *os.File
- f, err = os.Create(samplesOutFilename)
- if err != nil {
- return err
- }
- defer f.Close()
- pcaLabels := ""
- for i := 0; i < outcols; i++ {
- pcaLabels += fmt.Sprintf(",PCA%d", i)
- }
- _, err = fmt.Fprintf(f, "Index,SampleID,CaseControl,TrainingValidation%s\n", pcaLabels)
- if err != nil {
- return err
- }
- for i, si := range cmd.samples {
- var cc, tv string
- if si.isCase {
- cc = "1"
- } else if si.isControl {
- cc = "0"
- }
- if si.isTraining {
- tv = "1"
- } else if si.isValidation {
- tv = "0"
- }
- var pcavals string
+ log.Print("copying pca components to sampleInfo")
+ for i := range cmd.samples {
+ cmd.samples[i].pcaComponents = make([]float64, outcols)
for c := 0; c < outcols; c++ {
- pcavals += fmt.Sprintf(",%f", pca.At(i, c))
- }
- _, err = fmt.Fprintf(f, "%d,%s,%s,%s%s\n", i, si.id, cc, tv, pcavals)
- if err != nil {
- err = fmt.Errorf("write %s: %w", samplesOutFilename, err)
- return err
+ cmd.samples[i].pcaComponents[c] = pca.At(i, c)
}
}
- err = f.Close()
+ log.Print("done")
+
+ err = writeSampleInfo(cmd.samples, *outputDir)
if err != nil {
- err = fmt.Errorf("close %s: %w", samplesOutFilename, err)
return err
}
- log.Print("done")
}
}
if !*mergeOutput && !*onehotChunked && !*onehotSingle && !*onlyPCA {
isCase: split[2] == "1",
isControl: split[2] == "0",
isTraining: split[3] == "1",
- isValidation: split[3] == "0",
+ isValidation: split[3] == "0" && len(split[2]) > 0, // fix errant 0s in input
pcaComponents: pcaComponents,
})
}
return si, nil
}
+func writeSampleInfo(samples []sampleInfo, outputDir string) error {
+ fnm := outputDir + "/samples.csv"
+ log.Infof("writing sample metadata to %s", fnm)
+ f, err := os.Create(fnm)
+ if err != nil {
+ return err
+ }
+ defer f.Close()
+ pcaLabels := ""
+ if len(samples) > 0 {
+ for i := range samples[0].pcaComponents {
+ pcaLabels += fmt.Sprintf(",PCA%d", i)
+ }
+ }
+ _, err = fmt.Fprintf(f, "Index,SampleID,CaseControl,TrainingValidation%s\n", pcaLabels)
+ if err != nil {
+ return err
+ }
+ for i, si := range samples {
+ var cc, tv string
+ if si.isCase {
+ cc = "1"
+ } else if si.isControl {
+ cc = "0"
+ }
+ if si.isTraining {
+ tv = "1"
+ } else if si.isValidation {
+ tv = "0"
+ }
+ var pcavals string
+ for _, pcaval := range si.pcaComponents {
+ pcavals += fmt.Sprintf(",%f", pcaval)
+ }
+ _, err = fmt.Fprintf(f, "%d,%s,%s,%s%s\n", i, si.id, cc, tv, pcavals)
+ if err != nil {
+ return fmt.Errorf("write %s: %w", fnm, err)
+ }
+ }
+ err = f.Close()
+ if err != nil {
+ return fmt.Errorf("close %s: %w", fnm, err)
+ }
+ log.Print("done")
+ return nil
+}
+
func (cmd *sliceNumpy) filterHGVScolpair(colpair [2][]int8) bool {
if cmd.chi2PValue >= 1 {
return true
variant tileVariantID
hom bool
pvalue float64
+ maf float64
}
const onehotXrefSize = unsafe.Sizeof(onehotXref{})
}
tagoffset := tag - chunkstarttag
coverage := 0
- for _, cg := range cgs {
+ for cgidx, cgname := range cmd.cgnames {
+ if !cmd.minCoverageAll && !cmd.samples[cgidx].isTraining {
+ continue
+ }
+ cg := cgs[cgname]
alleles := 0
for _, v := range cg.Variants[tagoffset*2 : tagoffset*2+2] {
if v > 0 && int(v) < len(seq[tag]) && len(seq[tag][v].Sequence) > 0 {
}
var onehot [][]int8
var xref []onehotXref
+ var maf float64
for col := 2; col < len(obs); col++ {
// col 0,1 correspond to tile variant 0, i.e.,
// no-call; col 2,3 correspond to the most common
if col < 4 && !cmd.includeVariant1 {
continue
}
+ if col&1 == 0 {
+ maf = homhet2maf(obs[col : col+2])
+ if maf < cmd.pvalueMinFrequency {
+ // Skip both columns (hom and het) if
+ // allele frequency is below threshold
+ col++
+ continue
+ }
+ if maf > cmd.maxFrequency {
+ // Skip both columns if allele
+ // frequency is above threshold
+ col++
+ continue
+ }
+ }
atomic.AddInt64(&cmd.pvalueCallCount, 1)
p := cmd.pvalue(obs[col])
if cmd.chi2PValue < 1 && !(p < cmd.chi2PValue) {
variant: tileVariantID(col >> 1),
hom: col&1 == 0,
pvalue: p,
+ maf: maf,
})
}
return onehot, xref
}
+func homhet2maf(onehot [][]bool) float64 {
+ if len(onehot[0]) == 0 {
+ return 0
+ }
+ n := 0
+ for i := range onehot[0] {
+ if onehot[0][i] {
+ // hom
+ n += 2
+ } else if onehot[1][i] {
+ // het
+ n += 1
+ }
+ }
+ return float64(n) / float64(len(onehot[0])*2)
+}
+
// convert a []onehotXref with length N to a numpy-style []int32
// matrix with N columns, one row per field of onehotXref struct.
//
// P-value row contains 1000000x actual p-value.
func onehotXref2int32(xrefs []onehotXref) []int32 {
xcols := len(xrefs)
- xdata := make([]int32, 5*xcols)
+ xdata := make([]int32, 6*xcols)
for i, xref := range xrefs {
xdata[i] = int32(xref.tag)
xdata[xcols+i] = int32(xref.variant)
}
xdata[xcols*3+i] = int32(xref.pvalue * 1000000)
xdata[xcols*4+i] = int32(-math.Log10(xref.pvalue) * 1000000)
+ xdata[xcols*5+i] = int32(xref.maf * 1000000)
}
return xdata
}