mirror of
https://github.com/prometheus/prometheus.git
synced 2024-12-29 07:29:42 -08:00
f2b48b8c4a
This is mainly a small performance improvement, since we skip past the last extracted time immediately if it was also the last sample in the chunk, instead of trying to extract non-existent values before the chunk end again and again and only gradually approaching the end of the chunk.
700 lines
18 KiB
Go
700 lines
18 KiB
Go
// Copyright 2013 Prometheus Team
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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package metric
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import (
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"fmt"
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"github.com/prometheus/prometheus/model"
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"math"
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"sort"
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"time"
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)
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// Encapsulates a primitive query operation.
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type op interface {
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// The time at which this operation starts.
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StartsAt() time.Time
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// Extract samples from stream of values and advance operation time.
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ExtractSamples(in model.Values) (out model.Values)
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// Get current operation time or nil if no subsequent work associated with
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// this operator remains.
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CurrentTime() *time.Time
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// GreedierThan indicates whether this present operation should take
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// precedence over the other operation due to greediness.
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//
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// A critical assumption is that this operator and the other occur at the
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// same time: this.StartsAt().Equal(op.StartsAt()).
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GreedierThan(op) bool
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}
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// Provides a sortable collection of operations.
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type ops []op
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func (o ops) Len() int {
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return len(o)
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}
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// startsAtSort implements the sorting protocol and allows operator to be sorted
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// in chronological order by when they start.
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type startsAtSort struct {
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ops
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}
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func (s startsAtSort) Less(i, j int) bool {
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return s.ops[i].StartsAt().Before(s.ops[j].StartsAt())
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}
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func (o ops) Swap(i, j int) {
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o[i], o[j] = o[j], o[i]
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}
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// Encapsulates getting values at or adjacent to a specific time.
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type getValuesAtTimeOp struct {
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time time.Time
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consumed bool
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}
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func (o getValuesAtTimeOp) String() string {
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return fmt.Sprintf("getValuesAtTimeOp at %s", o.time)
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}
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func (g getValuesAtTimeOp) StartsAt() time.Time {
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return g.time
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}
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func (g *getValuesAtTimeOp) ExtractSamples(in model.Values) (out model.Values) {
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if len(in) == 0 {
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return
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}
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out = extractValuesAroundTime(g.time, in)
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g.consumed = true
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return
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}
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func (g getValuesAtTimeOp) GreedierThan(op op) (superior bool) {
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switch op.(type) {
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case *getValuesAtTimeOp:
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superior = true
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case durationOperator:
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superior = false
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default:
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panic("unknown operation")
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}
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return
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}
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// extractValuesAroundTime searches for the provided time in the list of
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// available samples and emits a slice containing the data points that
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// are adjacent to it.
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//
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// An assumption of this is that the provided samples are already sorted!
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func extractValuesAroundTime(t time.Time, in model.Values) (out model.Values) {
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i := sort.Search(len(in), func(i int) bool {
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return !in[i].Timestamp.Before(t)
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})
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if i == len(in) {
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// Target time is past the end, return only the last sample.
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out = in[len(in)-1:]
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} else {
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if in[i].Timestamp.Equal(t) && len(in) > i+1 {
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// We hit exactly the current sample time. Very unlikely in practice.
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// Return only the current sample.
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out = in[i : i+1]
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} else {
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if i == 0 {
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// We hit before the first sample time. Return only the first sample.
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out = in[0:1]
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} else {
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// We hit between two samples. Return both surrounding samples.
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out = in[i-1 : i+1]
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}
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}
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}
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return
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}
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func (g getValuesAtTimeOp) CurrentTime() (currentTime *time.Time) {
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if !g.consumed {
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currentTime = &g.time
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}
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return
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}
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// Encapsulates getting values at a given interval over a duration.
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type getValuesAtIntervalOp struct {
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from time.Time
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through time.Time
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interval time.Duration
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}
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func (o getValuesAtIntervalOp) String() string {
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return fmt.Sprintf("getValuesAtIntervalOp from %s each %s through %s", o.from, o.interval, o.through)
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}
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func (g getValuesAtIntervalOp) StartsAt() time.Time {
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return g.from
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}
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func (g getValuesAtIntervalOp) Through() time.Time {
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return g.through
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}
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func (g *getValuesAtIntervalOp) ExtractSamples(in model.Values) (out model.Values) {
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if len(in) == 0 {
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return
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}
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lastChunkTime := in[len(in)-1].Timestamp
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for len(in) > 0 {
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out = append(out, extractValuesAroundTime(g.from, in)...)
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lastExtractedTime := out[len(out)-1].Timestamp
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in = in.TruncateBefore(lastExtractedTime.Add(1))
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g.from = g.from.Add(g.interval)
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for !g.from.After(lastExtractedTime) {
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g.from = g.from.Add(g.interval)
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}
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if lastExtractedTime.Equal(lastChunkTime) {
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break
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}
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if g.from.After(g.through) {
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break
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}
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}
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return
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}
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func (g getValuesAtIntervalOp) CurrentTime() (currentTime *time.Time) {
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if g.from.After(g.through) {
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return
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}
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return &g.from
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}
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func (g getValuesAtIntervalOp) GreedierThan(op op) (superior bool) {
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switch o := op.(type) {
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case *getValuesAtTimeOp:
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superior = true
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case durationOperator:
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superior = g.Through().After(o.Through())
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default:
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panic("unknown operation")
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}
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return
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}
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type getValuesAlongRangeOp struct {
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from time.Time
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through time.Time
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}
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func (o getValuesAlongRangeOp) String() string {
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return fmt.Sprintf("getValuesAlongRangeOp from %s through %s", o.from, o.through)
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}
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func (g getValuesAlongRangeOp) StartsAt() time.Time {
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return g.from
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}
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func (g getValuesAlongRangeOp) Through() time.Time {
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return g.through
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}
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func (g *getValuesAlongRangeOp) ExtractSamples(in model.Values) (out model.Values) {
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if len(in) == 0 {
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return
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}
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// Find the first sample where time >= g.from.
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firstIdx := sort.Search(len(in), func(i int) bool {
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return !in[i].Timestamp.Before(g.from)
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})
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if firstIdx == len(in) {
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// No samples at or after operator start time. This can only happen if we
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// try applying the operator to a time after the last recorded sample. In
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// this case, we're finished.
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g.from = g.through.Add(1)
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return
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}
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// Find the first sample where time > g.through.
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lastIdx := sort.Search(len(in), func(i int) bool {
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return in[i].Timestamp.After(g.through)
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})
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if lastIdx == firstIdx {
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g.from = g.through.Add(1)
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return
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}
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lastSampleTime := in[lastIdx-1].Timestamp
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// Sample times are stored with a maximum time resolution of one second, so
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// we have to add exactly that to target the next chunk on the next op
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// iteration.
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g.from = lastSampleTime.Add(time.Second)
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return in[firstIdx:lastIdx]
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}
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func (g getValuesAlongRangeOp) CurrentTime() (currentTime *time.Time) {
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if g.from.After(g.through) {
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return
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}
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return &g.from
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}
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func (g getValuesAlongRangeOp) GreedierThan(op op) (superior bool) {
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switch o := op.(type) {
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case *getValuesAtTimeOp:
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superior = true
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case durationOperator:
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superior = g.Through().After(o.Through())
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default:
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panic("unknown operation")
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}
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return
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}
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// Provides a collection of getMetricRangeOperation.
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type getMetricRangeOperations []*getValuesAlongRangeOp
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func (s getMetricRangeOperations) Len() int {
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return len(s)
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}
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func (s getMetricRangeOperations) Swap(i, j int) {
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s[i], s[j] = s[j], s[i]
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}
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// Sorts getMetricRangeOperation according to duration in descending order.
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type rangeDurationSorter struct {
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getMetricRangeOperations
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}
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func (s rangeDurationSorter) Less(i, j int) bool {
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l := s.getMetricRangeOperations[i]
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r := s.getMetricRangeOperations[j]
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return !l.through.Before(r.through)
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}
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// Encapsulates a general operation that occurs over a duration.
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type durationOperator interface {
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op
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Through() time.Time
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}
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// greedinessSort sorts the operations in descending order by level of
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// greediness.
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type greedinessSort struct {
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ops
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}
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func (g greedinessSort) Less(i, j int) bool {
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return g.ops[i].GreedierThan(g.ops[j])
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}
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// Contains getValuesAtIntervalOp operations.
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type getValuesAtIntervalOps []*getValuesAtIntervalOp
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func (s getValuesAtIntervalOps) Len() int {
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return len(s)
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}
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func (s getValuesAtIntervalOps) Swap(i, j int) {
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s[i], s[j] = s[j], s[i]
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}
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// Sorts durationOperator by the operation's duration in descending order.
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type intervalDurationSorter struct {
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getValuesAtIntervalOps
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}
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func (s intervalDurationSorter) Less(i, j int) bool {
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l := s.getValuesAtIntervalOps[i]
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r := s.getValuesAtIntervalOps[j]
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return !l.through.Before(r.through)
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}
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// Sorts getValuesAtIntervalOp operations in ascending order by their
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// frequency.
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type frequencySorter struct {
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getValuesAtIntervalOps
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}
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func (s frequencySorter) Less(i, j int) bool {
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l := s.getValuesAtIntervalOps[i]
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r := s.getValuesAtIntervalOps[j]
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return l.interval < r.interval
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}
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// Selects and returns all operations that are getValuesAtIntervalOp operations
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// in a map whereby the operation interval is the key and the value are the
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// operations sorted by respective level of greediness.
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func collectIntervals(o ops) (intervals map[time.Duration]ops) {
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intervals = make(map[time.Duration]ops)
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for _, operation := range o {
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switch t := operation.(type) {
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case *getValuesAtIntervalOp:
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operations, _ := intervals[t.interval]
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operations = append(operations, t)
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intervals[t.interval] = operations
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}
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}
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return
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}
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// Selects and returns all operations that are getValuesAlongRangeOp operations.
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func collectRanges(ops ops) (ranges ops) {
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for _, operation := range ops {
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switch t := operation.(type) {
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case *getValuesAlongRangeOp:
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ranges = append(ranges, t)
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}
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}
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return
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}
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// optimizeForward iteratively scans operations and peeks ahead to subsequent
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// ones to find candidates that can either be removed or truncated through
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// simplification. For instance, if a range query happens to overlap a get-a-
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// value-at-a-certain-point-request, the range query should flatten and subsume
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// the other.
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func optimizeForward(pending ops) (out ops) {
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if len(pending) == 0 {
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return
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}
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var (
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head op = pending[0]
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tail ops
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)
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pending = pending[1:]
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switch t := head.(type) {
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case *getValuesAtTimeOp:
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out = ops{head}
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case *getValuesAtIntervalOp:
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// If the last value was a scan at a given frequency along an interval,
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// several optimizations may exist.
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for _, peekOperation := range pending {
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if peekOperation.StartsAt().After(t.Through()) {
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break
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}
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// If the type is not a range request, we can't do anything.
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switch next := peekOperation.(type) {
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case *getValuesAlongRangeOp:
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if !next.GreedierThan(t) {
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var (
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before = getValuesAtIntervalOp(*t)
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after = getValuesAtIntervalOp(*t)
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)
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before.through = next.from
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// Truncate the get value at interval request if a range request cuts
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// it off somewhere.
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var (
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from = next.from
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)
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for !from.After(next.through) {
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from = from.Add(t.interval)
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}
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after.from = from
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pending = append(ops{&before, &after}, pending...)
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sort.Sort(startsAtSort{pending})
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return optimizeForward(pending)
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}
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}
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}
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case *getValuesAlongRangeOp:
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for _, peekOperation := range pending {
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if peekOperation.StartsAt().After(t.Through()) {
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break
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}
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switch next := peekOperation.(type) {
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// All values at a specific time may be elided into the range query.
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case *getValuesAtTimeOp:
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pending = pending[1:]
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continue
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case *getValuesAlongRangeOp:
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// Range queries should be concatenated if they overlap.
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if next.GreedierThan(t) {
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next.from = t.from
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return optimizeForward(pending)
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} else {
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pending = pending[1:]
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}
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case *getValuesAtIntervalOp:
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pending = pending[1:]
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if next.GreedierThan(t) {
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var (
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nextStart = next.from
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)
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for !nextStart.After(next.through) {
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nextStart = nextStart.Add(next.interval)
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}
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next.from = nextStart
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tail = append(ops{next}, pending...)
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}
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default:
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panic("unknown operation type")
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}
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}
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default:
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panic("unknown operation type")
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}
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// Strictly needed?
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sort.Sort(startsAtSort{pending})
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tail = optimizeForward(pending)
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return append(ops{head}, tail...)
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}
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// selectQueriesForTime chooses all subsequent operations from the slice that
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// have the same start time as the provided time and emits them.
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func selectQueriesForTime(time time.Time, queries ops) (out ops) {
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if len(queries) == 0 {
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return
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}
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if !queries[0].StartsAt().Equal(time) {
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return
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}
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out = append(out, queries[0])
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tail := selectQueriesForTime(time, queries[1:])
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return append(out, tail...)
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}
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// selectGreediestRange scans through the various getValuesAlongRangeOp
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// operations and emits the one that is the greediest.
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func selectGreediestRange(in ops) (o durationOperator) {
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if len(in) == 0 {
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return
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}
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sort.Sort(greedinessSort{in})
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o = in[0].(*getValuesAlongRangeOp)
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return
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}
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// selectGreediestIntervals scans through the various getValuesAtIntervalOp
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// operations and emits a map of the greediest operation keyed by its start
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// time.
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func selectGreediestIntervals(in map[time.Duration]ops) (out map[time.Duration]durationOperator) {
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if len(in) == 0 {
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return
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}
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out = make(map[time.Duration]durationOperator)
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for i, ops := range in {
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sort.Sort(greedinessSort{ops})
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out[i] = ops[0].(*getValuesAtIntervalOp)
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}
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return
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}
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// rewriteForGreediestRange rewrites the current pending operation such that the
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// greediest range operation takes precedence over all other operators in this
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// time group.
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//
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// Between two range operations O1 and O2, they both start at the same time;
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// however, O2 extends for a longer duration than O1. Thusly, O1 should be
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// deleted with O2.
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//
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// O1------>|
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// T1 T4
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//
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// O2------------>|
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// T1 T7
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//
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// Thusly O1 can be squashed into O2 without having side-effects.
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func rewriteForGreediestRange(greediestRange durationOperator) ops {
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return ops{greediestRange}
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}
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// rewriteForGreediestInterval rewrites teh current pending interval operations
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// such that the interval operation with the smallest collection period is
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// invoked first, for it will skip around the soonest of any of the remaining
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// other operators.
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//
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// Between two interval operations O1 and O2, they both start at the same time;
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// however, O2's period is shorter than O1, meaning it will sample far more
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// frequently from the underlying time series. Thusly, O2 should start before
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// O1.
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//
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// O1---->|---->|
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// T1 T5
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//
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// O2->|->|->|->|
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// T1 T5
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//
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// The rewriter presently does not scan and compact for common divisors in the
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// periods, though this may be nice to have. For instance, if O1 has a period
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// of 2 and O2 has a period of 4, O2 would be dropped for O1 would implicitly
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|
// cover its period.
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func rewriteForGreediestInterval(greediestIntervals map[time.Duration]durationOperator) ops {
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|
var (
|
|
memo getValuesAtIntervalOps
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|
out ops
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|
)
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|
|
|
for _, o := range greediestIntervals {
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|
memo = append(memo, o.(*getValuesAtIntervalOp))
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|
}
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|
|
|
sort.Sort(frequencySorter{memo})
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|
|
|
for _, o := range memo {
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|
out = append(out, o)
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|
}
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|
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|
return out
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|
}
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|
|
|
// rewriteForRangeAndInterval examines the existence of a range operation and a
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|
// set of interval operations that start at the same time and deletes all
|
|
// interval operations that start and finish before the range operation
|
|
// completes and rewrites all interval operations that continue longer than
|
|
// the range operation to start at the next best increment after the range.
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|
//
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|
// Assume that we have a range operator O1 and two interval operations O2 and
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|
// O3. O2 and O3 have the same period (i.e., sampling interval), but O2
|
|
// terminates before O1 and O3 continue beyond O1.
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|
//
|
|
// O1------------>|
|
|
// T1------------T7
|
|
//
|
|
// O2-->|-->|-->|
|
|
// T1----------T6
|
|
//
|
|
// O3-->|-->|-->|-->|-->|
|
|
// T1------------------T10
|
|
//
|
|
// This scenario will be rewritten such that O2 is deleted and O3 is truncated
|
|
// from T1 through T7, and O3's new starting time is at T7 and runs through T10:
|
|
//
|
|
// O1------------>|
|
|
// T1------------T7
|
|
//
|
|
// O2>|-->|
|
|
// T7---T10
|
|
//
|
|
// All rewritten interval operators will respect their original start time
|
|
// multipliers.
|
|
func rewriteForRangeAndInterval(greediestRange durationOperator, greediestIntervals map[time.Duration]durationOperator) (out ops) {
|
|
out = append(out, greediestRange)
|
|
for _, op := range greediestIntervals {
|
|
if !op.GreedierThan(greediestRange) {
|
|
continue
|
|
}
|
|
|
|
// The range operation does not exceed interval. Leave a snippet of
|
|
// interval.
|
|
var (
|
|
truncated = op.(*getValuesAtIntervalOp)
|
|
newIntervalOperation getValuesAtIntervalOp
|
|
// Refactor
|
|
remainingSlice = greediestRange.Through().Sub(greediestRange.StartsAt()) / time.Second
|
|
nextIntervalPoint = time.Duration(math.Ceil(float64(remainingSlice)/float64(truncated.interval)) * float64(truncated.interval/time.Second))
|
|
nextStart = greediestRange.Through().Add(nextIntervalPoint)
|
|
)
|
|
|
|
newIntervalOperation.from = nextStart
|
|
newIntervalOperation.interval = truncated.interval
|
|
newIntervalOperation.through = truncated.Through()
|
|
// Added back to the pending because additional curation could be
|
|
// necessary.
|
|
out = append(out, &newIntervalOperation)
|
|
}
|
|
|
|
return
|
|
}
|
|
|
|
// Flattens queries that occur at the same time according to duration and level
|
|
// of greed. Consult the various rewriter functions for their respective modes
|
|
// of operation.
|
|
func optimizeTimeGroup(group ops) (out ops) {
|
|
var (
|
|
greediestRange = selectGreediestRange(collectRanges(group))
|
|
greediestIntervals = selectGreediestIntervals(collectIntervals(group))
|
|
containsRange = greediestRange != nil
|
|
containsInterval = len(greediestIntervals) > 0
|
|
)
|
|
|
|
switch {
|
|
case containsRange && !containsInterval:
|
|
out = rewriteForGreediestRange(greediestRange)
|
|
case !containsRange && containsInterval:
|
|
out = rewriteForGreediestInterval(greediestIntervals)
|
|
case containsRange && containsInterval:
|
|
out = rewriteForRangeAndInterval(greediestRange, greediestIntervals)
|
|
default:
|
|
// Operation is OK as-is.
|
|
out = append(out, group[0])
|
|
}
|
|
return
|
|
}
|
|
|
|
// Flattens all groups of time according to greed.
|
|
func optimizeTimeGroups(pending ops) (out ops) {
|
|
if len(pending) == 0 {
|
|
return
|
|
}
|
|
|
|
sort.Sort(startsAtSort{pending})
|
|
|
|
var (
|
|
nextOperation = pending[0]
|
|
groupedQueries = selectQueriesForTime(nextOperation.StartsAt(), pending)
|
|
)
|
|
|
|
out = optimizeTimeGroup(groupedQueries)
|
|
pending = pending[len(groupedQueries):]
|
|
|
|
tail := optimizeTimeGroups(pending)
|
|
|
|
return append(out, tail...)
|
|
}
|
|
|
|
func optimize(pending ops) (out ops) {
|
|
return optimizeForward(optimizeTimeGroups(pending))
|
|
}
|