mirror of
https://github.com/ClusterCockpit/cc-metric-store.git
synced 2024-11-15 07:27:25 +01:00
234 lines
5.1 KiB
Go
234 lines
5.1 KiB
Go
package memorystore
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import (
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"errors"
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"sync"
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"github.com/ClusterCockpit/cc-metric-store/internal/util"
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)
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// Default buffer capacity.
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// `buffer.data` will only ever grow up to it's capacity and a new link
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// in the buffer chain will be created if needed so that no copying
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// of data or reallocation needs to happen on writes.
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const (
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BUFFER_CAP int = 512
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)
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// So that we can reuse allocations
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var bufferPool sync.Pool = sync.Pool{
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New: func() interface{} {
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return &buffer{
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data: make([]util.Float, 0, BUFFER_CAP),
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}
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},
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}
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var (
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ErrNoData error = errors.New("no data for this metric/level")
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ErrDataDoesNotAlign error = errors.New("data from lower granularities does not align")
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)
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// Each metric on each level has it's own buffer.
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// This is where the actual values go.
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// If `cap(data)` is reached, a new buffer is created and
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// becomes the new head of a buffer list.
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type buffer struct {
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prev *buffer
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next *buffer
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data []util.Float
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frequency int64
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start int64
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archived bool
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closed bool
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}
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func newBuffer(ts, freq int64) *buffer {
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b := bufferPool.Get().(*buffer)
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b.frequency = freq
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b.start = ts - (freq / 2)
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b.prev = nil
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b.next = nil
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b.archived = false
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b.closed = false
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b.data = b.data[:0]
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return b
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}
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// If a new buffer was created, the new head is returnd.
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// Otherwise, the existing buffer is returnd.
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// Normaly, only "newer" data should be written, but if the value would
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// end up in the same buffer anyways it is allowed.
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func (b *buffer) write(ts int64, value util.Float) (*buffer, error) {
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if ts < b.start {
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return nil, errors.New("cannot write value to buffer from past")
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}
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// idx := int((ts - b.start + (b.frequency / 3)) / b.frequency)
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idx := int((ts - b.start) / b.frequency)
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if idx >= cap(b.data) {
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newbuf := newBuffer(ts, b.frequency)
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newbuf.prev = b
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b.next = newbuf
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b.close()
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b = newbuf
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idx = 0
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}
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// Overwriting value or writing value from past
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if idx < len(b.data) {
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b.data[idx] = value
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return b, nil
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}
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// Fill up unwritten slots with NaN
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for i := len(b.data); i < idx; i++ {
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b.data = append(b.data, util.NaN)
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}
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b.data = append(b.data, value)
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return b, nil
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}
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func (b *buffer) end() int64 {
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return b.firstWrite() + int64(len(b.data))*b.frequency
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}
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func (b *buffer) firstWrite() int64 {
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return b.start + (b.frequency / 2)
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}
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func (b *buffer) close() {}
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/*
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func (b *buffer) close() {
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if b.closed {
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return
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}
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b.closed = true
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n, sum, min, max := 0, 0., math.MaxFloat64, -math.MaxFloat64
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for _, x := range b.data {
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if x.IsNaN() {
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continue
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}
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n += 1
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f := float64(x)
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sum += f
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min = math.Min(min, f)
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max = math.Max(max, f)
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}
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b.statisticts.samples = n
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if n > 0 {
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b.statisticts.avg = Float(sum / float64(n))
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b.statisticts.min = Float(min)
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b.statisticts.max = Float(max)
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} else {
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b.statisticts.avg = NaN
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b.statisticts.min = NaN
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b.statisticts.max = NaN
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}
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}
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*/
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// func interpolate(idx int, data []Float) Float {
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// if idx == 0 || idx+1 == len(data) {
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// return NaN
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// }
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// return (data[idx-1] + data[idx+1]) / 2.0
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// }
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// Return all known values from `from` to `to`. Gaps of information are represented as NaN.
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// Simple linear interpolation is done between the two neighboring cells if possible.
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// If values at the start or end are missing, instead of NaN values, the second and thrid
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// return values contain the actual `from`/`to`.
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// This function goes back the buffer chain if `from` is older than the currents buffer start.
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// The loaded values are added to `data` and `data` is returned, possibly with a shorter length.
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// If `data` is not long enough to hold all values, this function will panic!
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func (b *buffer) read(from, to int64, data []util.Float) ([]util.Float, int64, int64, error) {
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if from < b.firstWrite() {
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if b.prev != nil {
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return b.prev.read(from, to, data)
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}
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from = b.firstWrite()
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}
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i := 0
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t := from
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for ; t < to; t += b.frequency {
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idx := int((t - b.start) / b.frequency)
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if idx >= cap(b.data) {
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if b.next == nil {
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break
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}
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b = b.next
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idx = 0
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}
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if idx >= len(b.data) {
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if b.next == nil || to <= b.next.start {
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break
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}
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data[i] += util.NaN
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} else if t < b.start {
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data[i] += util.NaN
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// } else if b.data[idx].IsNaN() {
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// data[i] += interpolate(idx, b.data)
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} else {
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data[i] += b.data[idx]
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}
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i++
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}
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return data[:i], from, t, nil
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}
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// Returns true if this buffer needs to be freed.
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func (b *buffer) free(t int64) (delme bool, n int) {
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if b.prev != nil {
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delme, m := b.prev.free(t)
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n += m
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if delme {
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b.prev.next = nil
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if cap(b.prev.data) == BUFFER_CAP {
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bufferPool.Put(b.prev)
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}
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b.prev = nil
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}
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}
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end := b.end()
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if end < t {
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return true, n + 1
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}
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return false, n
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}
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// Call `callback` on every buffer that contains data in the range from `from` to `to`.
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func (b *buffer) iterFromTo(from, to int64, callback func(b *buffer) error) error {
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if b == nil {
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return nil
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}
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if err := b.prev.iterFromTo(from, to, callback); err != nil {
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return err
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}
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if from <= b.end() && b.start <= to {
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return callback(b)
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}
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return nil
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}
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func (b *buffer) count() int64 {
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res := int64(len(b.data))
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if b.prev != nil {
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res += b.prev.count()
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}
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return res
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}
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