243 lines
7.3 KiB
Plaintext
243 lines
7.3 KiB
Plaintext
//TODO: multimodal, add interface, test somehow, track performance, refactor sampleSet, refactor ASTEvaluator.res.
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type t = GenericDist_Types.genericDist
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type error = GenericDist_Types.error
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type toPointSetFn = t => result<PointSetTypes.pointSetDist, error>
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type toSampleSetFn = t => result<array<float>, error>
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type scaleMultiplyFn = (t, float) => result<t, error>
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type pointwiseAddFn = (t, t) => result<t, error>
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let sampleN = (n, t: t) =>
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switch t {
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| #PointSet(r) => Ok(PointSetDist.sampleNRendered(n, r))
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| #Symbolic(r) => Ok(SymbolicDist.T.sampleN(n, r))
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| #SampleSet(_) => Error(GenericDist_Types.NotYetImplemented)
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}
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let fromFloat = (f: float) => #Symbolic(SymbolicDist.Float.make(f))
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let toString = (t: t) =>
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switch t {
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| #PointSet(_) => "Point Set Distribution"
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| #Symbolic(r) => SymbolicDist.T.toString(r)
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| #SampleSet(_) => "Sample Set Distribution"
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}
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let normalize = (t: t) =>
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switch t {
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| #PointSet(r) => #PointSet(PointSetDist.T.normalize(r))
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| #Symbolic(_) => t
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| #SampleSet(_) => t
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}
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let operationToFloat = (toPointSet: toPointSetFn, fnName, t) => {
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let symbolicSolution = switch t {
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| #Symbolic(r) =>
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switch SymbolicDist.T.operate(fnName, r) {
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| Ok(f) => Some(f)
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| _ => None
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}
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| _ => None
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}
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switch symbolicSolution {
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| Some(r) => Ok(r)
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| None => toPointSet(t) |> E.R.fmap(PointSetDist.operate(fnName))
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}
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}
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//TODO: Refactor this bit.
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let defaultSamplingInputs: SamplingInputs.samplingInputs = {
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sampleCount: 10000,
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outputXYPoints: 10000,
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pointSetDistLength: 1000,
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kernelWidth: None,
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}
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let toPointSet = (xyPointLength, t: t): result<PointSetTypes.pointSetDist, error> => {
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switch t {
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| #PointSet(pointSet) => Ok(pointSet)
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| #Symbolic(r) => Ok(SymbolicDist.T.toPointSetDist(xyPointLength, r))
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| #SampleSet(r) => {
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let response = SampleSet.toPointSetDist(
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~samples=r,
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~samplingInputs=defaultSamplingInputs,
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(),
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).pointSetDist
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switch response {
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| Some(r) => Ok(r)
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| None => Error(Other("Converting sampleSet to pointSet failed"))
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}
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}
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}
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}
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module Truncate = {
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let trySymbolicSimplification = (leftCutoff, rightCutoff, t): option<t> =>
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switch (leftCutoff, rightCutoff, t) {
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| (None, None, _) => None
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| (lc, rc, #Symbolic(#Uniform(u))) if lc < rc =>
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Some(#Symbolic(#Uniform(SymbolicDist.Uniform.truncate(lc, rc, u))))
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| _ => None
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}
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let run = (
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toPointSet: toPointSetFn,
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leftCutoff: option<float>,
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rightCutoff: option<float>,
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t: t,
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): result<t, error> => {
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let doesNotNeedCutoff = E.O.isNone(leftCutoff) && E.O.isNone(rightCutoff)
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if doesNotNeedCutoff {
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Ok(t)
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} else {
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switch trySymbolicSimplification(leftCutoff, rightCutoff, t) {
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| Some(r) => Ok(r)
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| None =>
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toPointSet(t) |> E.R.fmap(t =>
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#PointSet(PointSetDist.T.truncate(leftCutoff, rightCutoff, t))
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)
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}
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}
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}
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}
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let truncate = Truncate.run
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/* Given two random variables A and B, this returns the distribution
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of a new variable that is the result of the operation on A and B.
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For instance, normal(0, 1) + normal(1, 1) -> normal(1, 2).
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In general, this is implemented via convolution. */
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module AlgebraicCombination = {
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let tryAnalyticalSimplification = (
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operation: GenericDist_Types.Operation.arithmeticOperation,
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t1: t,
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t2: t,
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): option<result<SymbolicDistTypes.symbolicDist, string>> =>
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switch (operation, t1, t2) {
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| (operation, #Symbolic(d1), #Symbolic(d2)) =>
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switch SymbolicDist.T.tryAnalyticalSimplification(d1, d2, operation) {
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| #AnalyticalSolution(symbolicDist) => Some(Ok(symbolicDist))
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| #Error(er) => Some(Error(er))
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| #NoSolution => None
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}
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| _ => None
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}
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let runConvolution = (
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toPointSet: toPointSetFn,
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operation: GenericDist_Types.Operation.arithmeticOperation,
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t1: t,
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t2: t,
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) =>
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E.R.merge(toPointSet(t1), toPointSet(t2)) |> E.R.fmap(((a, b)) =>
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PointSetDist.combineAlgebraically(operation, a, b)
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)
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let runMonteCarlo = (
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toSampleSet: toSampleSetFn,
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operation: GenericDist_Types.Operation.arithmeticOperation,
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t1: t,
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t2: t,
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) => {
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let operation = Operation.Algebraic.toFn(operation)
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E.R.merge(toSampleSet(t1), toSampleSet(t2)) |> E.R.fmap(((a, b)) => {
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Belt.Array.zip(a, b) |> E.A.fmap(((a, b)) => operation(a, b))
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})
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}
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//I'm (Ozzie) really just guessing here, very little idea what's best
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let expectedConvolutionCost: t => int = x =>
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switch x {
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| #Symbolic(#Float(_)) => 1
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| #Symbolic(_) => 1000
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| #PointSet(Discrete(m)) => m.xyShape |> XYShape.T.length
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| #PointSet(Mixed(_)) => 1000
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| #PointSet(Continuous(_)) => 1000
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| _ => 1000
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}
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let chooseConvolutionOrMonteCarlo = (t2: t, t1: t) =>
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expectedConvolutionCost(t1) * expectedConvolutionCost(t2) > 10000
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? #CalculateWithMonteCarlo
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: #CalculateWithConvolution
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let run = (
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toPointSet: toPointSetFn,
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toSampleSet: toSampleSetFn,
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algebraicOp,
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t1: t,
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t2: t,
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): result<t, error> => {
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switch tryAnalyticalSimplification(algebraicOp, t1, t2) {
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| Some(Ok(symbolicDist)) => Ok(#Symbolic(symbolicDist))
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| Some(Error(e)) => Error(Other(e))
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| None =>
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switch chooseConvolutionOrMonteCarlo(t1, t2) {
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| #CalculateWithMonteCarlo =>
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runMonteCarlo(toSampleSet, algebraicOp, t1, t2) |> E.R.fmap(r => #SampleSet(r))
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| #CalculateWithConvolution =>
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runConvolution(toPointSet, algebraicOp, t1, t2) |> E.R.fmap(r => #PointSet(r))
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}
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}
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}
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}
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let algebraicCombination = AlgebraicCombination.run
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//TODO: Add faster pointwiseCombine fn
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let pointwiseCombination = (toPointSet: toPointSetFn, operation, t2: t, t1: t): result<
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t,
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error,
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> => {
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E.R.merge(toPointSet(t1), toPointSet(t2))
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|> E.R.fmap(((t1, t2)) =>
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PointSetDist.combinePointwise(GenericDist_Types.Operation.arithmeticToFn(operation), t1, t2)
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)
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|> E.R.fmap(r => #PointSet(r))
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}
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let pointwiseCombinationFloat = (
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toPointSet: toPointSetFn,
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operation: GenericDist_Types.Operation.arithmeticOperation,
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f: float,
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t: t,
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): result<t, error> => {
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switch operation {
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| #Add | #Subtract => Error(GenericDist_Types.DistributionVerticalShiftIsInvalid)
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| (#Multiply | #Divide | #Exponentiate | #Log) as operation =>
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toPointSet(t) |> E.R.fmap(t => {
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//TODO: Move to PointSet codebase
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let fn = (secondary, main) => Operation.Scale.toFn(operation, main, secondary)
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let integralSumCacheFn = Operation.Scale.toIntegralSumCacheFn(operation)
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let integralCacheFn = Operation.Scale.toIntegralCacheFn(operation)
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PointSetDist.T.mapY(
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~integralSumCacheFn=integralSumCacheFn(f),
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~integralCacheFn=integralCacheFn(f),
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~fn=fn(f),
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t,
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)
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})
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} |> E.R.fmap(r => #PointSet(r))
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}
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let mixture = (
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scaleMultiply: scaleMultiplyFn,
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pointwiseAdd: pointwiseAddFn,
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values: array<(t, float)>,
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) => {
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if E.A.length(values) == 0 {
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Error(GenericDist_Types.Other("mixture must have at least 1 element"))
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} else {
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let properlyWeightedValues =
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values |> E.A.fmap(((dist, weight)) => scaleMultiply(dist, weight)) |> E.A.R.firstErrorOrOpen
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properlyWeightedValues |> E.R.bind(_, values => {
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values
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|> Js.Array.sliceFrom(1)
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|> E.A.fold_left(
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(acc, x) => E.R.bind(acc, acc => pointwiseAdd(acc, x)),
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Ok(E.A.unsafe_get(values, 0)),
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)
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})
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}
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}
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