func (self *Strategy) consume(state *algorithm.State) {
ni, no := self.ni, self.no
np := uint(len(self.priority))
na := uint(len(self.accuracy))
nn := uint(len(state.Counts))
self.priority = append(self.priority, make([]float64, nn)...)
priority := self.priority[np:]
self.accuracy = append(self.accuracy, make([]float64, nn*no)...)
accuracy := self.accuracy[na:]
levels := internal.Levelize(state.Lndices, ni)
for i, o := uint(0), uint(0); i < nn; i++ {
count := state.Counts[i]
if levels[i] < uint64(self.lmin) {
priority[i] = internal.Infinity
internal.Set(accuracy[i*no:(i+1)*no], internal.Infinity)
} else if levels[i] < uint64(self.lmax) {
priority[i] = internal.Average(state.Scores[o:(o + count)])
self.threshold.Compress(accuracy[i*no:(i+1)*no],
state.Surpluses[o*no:(o+count)*no])
}
o += count
}
self.threshold.Update(state.Values)
}
func filter(indices []uint64, scores []float64, lmin, lmax uint, εs float64, ni uint) []uint64 {
nn := uint(len(scores))
levels := internal.Levelize(indices, ni)
na, ne := uint(0), nn
for i, j := uint(0), uint(0); i < nn; i++ {
if levels[i] >= uint64(lmin) && (scores[i] <= εs || levels[i] >= uint64(lmax)) {
j++
continue
}
if j > na {
copy(indices[na*ni:], indices[j*ni:ne*ni])
ne -= j - na
j = na
}
na++
j++
}
return indices[:na*ni]
}
func (self *Strategy) consume(state *algorithm.State) {
ni, no := self.ni, self.no
np := uint(len(self.priority))
na := uint(len(self.accuracy))
ns := uint(len(self.scores))
nn := uint(len(state.Counts))
self.priority = append(self.priority, make([]float64, nn)...)
priority := self.priority[np:]
self.accuracy = append(self.accuracy, make([]float64, nn*no)...)
accuracy := self.accuracy[na:]
self.scopes = append(self.scopes, make([][]uint, nn)...)
scopes := self.scopes[np:]
self.scores = append(self.scores, make([]float64, len(state.Scores))...)
scores := self.scores[ns:]
groups := state.Data.([][]uint64)
levels := internal.Levelize(state.Lndices, ni)
for i, o := uint(0), uint(0); i < nn; i++ {
count := state.Counts[i]
if levels[i] < uint64(self.lmin) {
internal.Set(accuracy[i*no:(i+1)*no], internal.Infinity)
internal.Set(scores[o:(o+count)], internal.Infinity)
} else if levels[i] < uint64(self.lmax) {
self.threshold.Compress(accuracy[i*no:(i+1)*no],
state.Surpluses[o*no:(o+count)*no])
copy(scores[o:(o+count)], state.Scores[o:(o+count)])
}
for j := uint(0); j < count; j++ {
index := state.Indices[(o+j)*ni : (o+j+1)*ni]
self.indexer[self.hash.Key(index)] = ns + o + j
}
o += count
}
for i := uint(0); i < nn; i++ {
count := uint(len(groups[i])) / ni
scope := make([]uint, count)
for j := uint(0); j < count; j++ {
index := groups[i][j*ni : (j+1)*ni]
k, ok := self.indexer[self.hash.Key(index)]
if !ok {
panic("something went wrong")
}
scope[j] = k
}
scopes[i] = scope
if levels[i] < uint64(self.lmin) {
priority[i] = internal.Infinity
} else if levels[i] < uint64(self.lmax) {
for _, j := range scope {
priority[i] += self.scores[j]
}
priority[i] /= float64(count)
}
lndex := state.Lndices[i*ni : (i+1)*ni]
self.lndexer[self.hash.Key(lndex)] = np + i
}
self.threshold.Update(state.Values)
}
