func (g *GaussNoiseLayer) ApplyR(v autofunc.RVector, in autofunc.RResult) autofunc.RResult {
if g.Training {
return autofunc.AddR(in, g.noiseR(len(in.Output())))
} else {
return in
}
}
func manualNetworkSeq(rv autofunc.RVector, f autofunc.RFunc, start *autofunc.Variable,
ins [][]*autofunc.Variable, stateSize int) (out, outR [][]linalg.Vector) {
out = make([][]linalg.Vector, len(ins))
outR = make([][]linalg.Vector, len(ins))
for seqIdx, inSeq := range ins {
var state autofunc.RResult = autofunc.NewRVariable(start, rv)
for _, in := range inSeq {
inR := rv[in]
packedIn := append(linalg.Vector{}, in.Output()...)
packedIn = append(packedIn, state.Output()...)
packedInR := append(linalg.Vector{}, inR...)
packedInR = append(packedInR, state.ROutput()...)
stepOut := f.ApplyR(rv, &autofunc.RVariable{
Variable: &autofunc.Variable{Vector: packedIn},
ROutputVec: packedInR,
})
outSize := len(stepOut.Output()) - stateSize
out[seqIdx] = append(out[seqIdx], stepOut.Output()[:outSize])
outR[seqIdx] = append(outR[seqIdx], stepOut.ROutput()[:outSize])
state = &autofunc.RVariable{
Variable: &autofunc.Variable{Vector: stepOut.Output()[outSize:]},
ROutputVec: stepOut.ROutput()[outSize:],
}
}
}
return
}
func (u *UnstackLayer) ApplyR(v autofunc.RVector, in autofunc.RResult) autofunc.RResult {
return &unstackLayerRResult{
OutputVector: u.unstack(in.Output()),
ROutputVector: u.unstack(in.ROutput()),
Input: in,
Layer: u,
}
}
func (b *BorderLayer) ApplyR(rv autofunc.RVector, in autofunc.RResult) autofunc.RResult {
return &borderRResult{
OutputVec: b.addBorder(in.Output()),
ROutputVec: b.addBorder(in.ROutput()),
Input: in,
Info: b,
}
}
func (d *DropoutLayer) ApplyR(v autofunc.RVector, in autofunc.RResult) autofunc.RResult {
if d.Training {
mask := d.dropoutMask(len(in.Output()))
maskVar := autofunc.NewRVariable(mask, v)
return autofunc.MulR(in, maskVar)
} else {
return autofunc.ScaleR(in, d.KeepProbability)
}
}
func (v *VecRescaleLayer) ApplyR(rv autofunc.RVector, in autofunc.RResult) autofunc.RResult {
zeroVec := make(linalg.Vector, len(in.Output()))
biases := &autofunc.RVariable{
Variable: &autofunc.Variable{Vector: v.Biases},
ROutputVec: zeroVec,
}
scales := &autofunc.RVariable{
Variable: &autofunc.Variable{Vector: v.Scales},
ROutputVec: zeroVec,
}
return autofunc.MulR(autofunc.AddR(in, biases), scales)
}
func (s *LogSoftmaxLayer) ApplyR(v autofunc.RVector, in autofunc.RResult) autofunc.RResult {
return autofunc.PoolR(in, func(in autofunc.RResult) autofunc.RResult {
// See comment in Apply() for details on how this works.
maxIdx := maxVecIdx(in.Output())
maxValue := autofunc.SliceR(in, maxIdx, maxIdx+1)
exponents := autofunc.AddFirstR(in, autofunc.ScaleR(maxValue, -1))
expSum := autofunc.SumAllR(autofunc.Exp{}.ApplyR(v, exponents))
expLog := autofunc.Log{}.ApplyR(v, expSum)
denomLog := autofunc.AddR(expLog, maxValue)
return autofunc.AddFirstR(in, autofunc.ScaleR(denomLog, -1))
})
}
func (_ ReLU) ApplyR(v autofunc.RVector, r autofunc.RResult) autofunc.RResult {
outVec := r.Output()
outVecR := r.ROutput()
vec := make(linalg.Vector, len(outVec))
vecR := make(linalg.Vector, len(outVec))
for i, x := range outVec {
if x > 0 {
vec[i] = x
vecR[i] = outVecR[i]
}
}
return &reLURResult{
OutputVec: vec,
ROutputVec: vecR,
Input: r,
}
}
func (l *lstmGate) BatchR(rv autofunc.RVector, in autofunc.RResult, n int) autofunc.RResult {
if l.Peephole == nil {
return l.Activation.ApplyR(rv, l.Dense.BatchR(rv, in, n))
}
return autofunc.PoolR(in, func(in autofunc.RResult) autofunc.RResult {
vecSize := len(in.Output()) / n
var weightedInputs []autofunc.RResult
var peepholed []autofunc.RResult
peephole := autofunc.NewRVariable(l.Peephole, rv)
for i := 0; i < n; i++ {
start := vecSize * i
weightedEnd := start + vecSize - len(l.Peephole.Vector)
weightedInputs = append(weightedInputs, autofunc.SliceR(in, start, weightedEnd))
peepholeMe := autofunc.SliceR(in, weightedEnd, (i+1)*vecSize)
peepholed = append(peepholed, autofunc.MulR(peephole, peepholeMe))
}
weighted := l.Dense.BatchR(rv, autofunc.ConcatR(weightedInputs...), n)
joinedPeep := autofunc.ConcatR(peepholed...)
return l.Activation.ApplyR(rv, autofunc.AddR(joinedPeep, weighted))
})
}
// BatchR is like Batch, but for RResults.
func (c *ConvLayer) BatchR(rv autofunc.RVector, in autofunc.RResult,
n int) autofunc.RResult {
if c.Filters == nil || c.Biases == nil || c.FilterVar == nil {
panic(uninitPanicMessage)
}
outSize := c.OutputWidth() * c.OutputHeight() * c.OutputDepth()
inSize := c.InputWidth * c.InputHeight * c.InputDepth
if len(in.Output()) != n*inSize {
panic("invalid input size")
}
res := &convLayerRResult{
OutputVec: make(linalg.Vector, outSize*n),
ROutputVec: make(linalg.Vector, outSize*n),
Input: in,
FiltersR: rv[c.FilterVar],
N: n,
Layer: c,
}
for i := 0; i < n; i++ {
subIn := in.Output()[i*inSize : (i+1)*inSize]
subOut := res.OutputVec[i*outSize : (i+1)*outSize]
c.convolve(subIn, c.outputToTensor(subOut))
subInR := in.ROutput()[i*inSize : (i+1)*inSize]
subOutR := res.ROutputVec[i*outSize : (i+1)*outSize]
c.convolveR(rv, subIn, subInR, c.outputToTensor(subOutR))
}
return res
}
// BatchR is like Batch, but for RResults.
func (m *MaxPoolingLayer) BatchR(rv autofunc.RVector, in autofunc.RResult,
n int) autofunc.RResult {
outSize := m.OutputWidth() * m.OutputHeight() * m.InputDepth
inSize := m.InputWidth * m.InputHeight * m.InputDepth
if len(in.Output()) != n*inSize {
panic("invalid input size")
}
res := &maxPoolingRResult{
OutputVec: make(linalg.Vector, outSize*n),
ROutputVec: make(linalg.Vector, outSize*n),
Input: in,
Layer: m,
}
for i := 0; i < n; i++ {
outTensor := m.outputTensor(res.OutputVec[i*outSize : (i+1)*outSize])
inTensor := m.inputTensor(in.Output()[i*inSize : (i+1)*inSize])
choices := m.evaluate(inTensor, outTensor)
res.Choices = append(res.Choices, choices)
outTensorR := m.outputTensor(res.ROutputVec[i*outSize : (i+1)*outSize])
inTensorR := m.inputTensor(in.ROutput()[i*inSize : (i+1)*inSize])
choices.ForwardPropagate(inTensorR, outTensorR)
}
return res
}