package storage import "math" // BufferedSeriesIterator wraps an iterator with a look-back buffer. type BufferedSeriesIterator struct { it SeriesIterator buf *sampleRing lastTime int64 } // NewBuffer returns a new iterator that buffers the values within the time range // of the current element and the duration of delta before. func NewBuffer(it SeriesIterator, delta int64) *BufferedSeriesIterator { return &BufferedSeriesIterator{ it: it, buf: newSampleRing(delta, 16), lastTime: math.MinInt64, } } // PeekBack returns the previous element of the iterator. If there is none buffered, // ok is false. func (b *BufferedSeriesIterator) PeekBack() (t int64, v float64, ok bool) { return b.buf.last() } // Buffer returns an iterator over the buffered data. func (b *BufferedSeriesIterator) Buffer() SeriesIterator { return b.buf.iterator() } // Seek advances the iterator to the element at time t or greater. func (b *BufferedSeriesIterator) Seek(t int64) bool { t0 := t - b.buf.delta // If the delta would cause us to seek backwards, preserve the buffer // and just continue regular advancment while filling the buffer on the way. if t0 > b.lastTime { b.buf.reset() ok := b.it.Seek(t0) if !ok { return false } b.lastTime, _ = b.Values() } if b.lastTime >= t { return true } for b.Next() { if b.lastTime >= t { return true } } return false } // Next advances the iterator to the next element. func (b *BufferedSeriesIterator) Next() bool { // Add current element to buffer before advancing. b.buf.add(b.it.Values()) ok := b.it.Next() if ok { b.lastTime, _ = b.Values() } return ok } // Values returns the current element of the iterator. func (b *BufferedSeriesIterator) Values() (int64, float64) { return b.it.Values() } // Err returns the last encountered error. func (b *BufferedSeriesIterator) Err() error { return b.it.Err() } type sample struct { t int64 v float64 } type sampleRing struct { delta int64 buf []sample // lookback buffer i int // position of most recent element in ring buffer f int // position of first element in ring buffer l int // number of elements in buffer } func newSampleRing(delta int64, sz int) *sampleRing { r := &sampleRing{delta: delta, buf: make([]sample, sz)} r.reset() return r } func (r *sampleRing) reset() { r.l = 0 r.i = -1 r.f = 0 } func (r *sampleRing) iterator() SeriesIterator { return &sampleRingIterator{r: r, i: -1} } type sampleRingIterator struct { r *sampleRing i int } func (it *sampleRingIterator) Next() bool { it.i++ return it.i < it.r.l } func (it *sampleRingIterator) Seek(int64) bool { return false } func (it *sampleRingIterator) Err() error { return nil } func (it *sampleRingIterator) Values() (int64, float64) { return it.r.at(it.i) } func (r *sampleRing) at(i int) (int64, float64) { j := (r.f + i) % len(r.buf) s := r.buf[j] return s.t, s.v } // add adds a sample to the ring buffer and frees all samples that fall // out of the delta range. func (r *sampleRing) add(t int64, v float64) { l := len(r.buf) // Grow the ring buffer if it fits no more elements. if l == r.l { buf := make([]sample, 2*l) copy(buf[l+r.f:], r.buf[r.f:]) copy(buf, r.buf[:r.f]) r.buf = buf r.i = r.f r.f += l } else { r.i++ if r.i >= l { r.i -= l } } r.buf[r.i] = sample{t: t, v: v} r.l++ // Free head of the buffer of samples that just fell out of the range. for r.buf[r.f].t < t-r.delta { r.f++ if r.f >= l { r.f -= l } r.l-- } } // last returns the most recent element added to the ring. func (r *sampleRing) last() (int64, float64, bool) { if r.l == 0 { return 0, 0, false } s := r.buf[r.i] return s.t, s.v, true } func (r *sampleRing) samples() []sample { res := make([]sample, r.l) var k = r.f + r.l var j int if k > len(r.buf) { k = len(r.buf) j = r.l - k + r.f } n := copy(res, r.buf[r.f:k]) copy(res[n:], r.buf[:j]) return res }