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350 lines
12 KiB
350 lines
12 KiB
// Copyright 2016 Google LLC
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//
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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 bundler supports bundling (batching) of items. Bundling amortizes an
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// action with fixed costs over multiple items. For example, if an API provides
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// an RPC that accepts a list of items as input, but clients would prefer
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// adding items one at a time, then a Bundler can accept individual items from
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// the client and bundle many of them into a single RPC.
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//
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// This package is experimental and subject to change without notice.
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package bundler
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import (
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"context"
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"errors"
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"math"
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"reflect"
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"sync"
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"time"
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"golang.org/x/sync/semaphore"
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)
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const (
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DefaultDelayThreshold = time.Second
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DefaultBundleCountThreshold = 10
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DefaultBundleByteThreshold = 1e6 // 1M
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DefaultBufferedByteLimit = 1e9 // 1G
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)
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var (
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// ErrOverflow indicates that Bundler's stored bytes exceeds its BufferedByteLimit.
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ErrOverflow = errors.New("bundler reached buffered byte limit")
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// ErrOversizedItem indicates that an item's size exceeds the maximum bundle size.
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ErrOversizedItem = errors.New("item size exceeds bundle byte limit")
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)
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// A Bundler collects items added to it into a bundle until the bundle
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// exceeds a given size, then calls a user-provided function to handle the bundle.
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type Bundler struct {
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// Starting from the time that the first message is added to a bundle, once
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// this delay has passed, handle the bundle. The default is DefaultDelayThreshold.
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DelayThreshold time.Duration
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// Once a bundle has this many items, handle the bundle. Since only one
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// item at a time is added to a bundle, no bundle will exceed this
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// threshold, so it also serves as a limit. The default is
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// DefaultBundleCountThreshold.
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BundleCountThreshold int
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// Once the number of bytes in current bundle reaches this threshold, handle
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// the bundle. The default is DefaultBundleByteThreshold. This triggers handling,
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// but does not cap the total size of a bundle.
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BundleByteThreshold int
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// The maximum size of a bundle, in bytes. Zero means unlimited.
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BundleByteLimit int
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// The maximum number of bytes that the Bundler will keep in memory before
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// returning ErrOverflow. The default is DefaultBufferedByteLimit.
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BufferedByteLimit int
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// The maximum number of handler invocations that can be running at once.
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// The default is 1.
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HandlerLimit int
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handler func(interface{}) // called to handle a bundle
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itemSliceZero reflect.Value // nil (zero value) for slice of items
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flushTimer *time.Timer // implements DelayThreshold
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mu sync.Mutex
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sem *semaphore.Weighted // enforces BufferedByteLimit
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semOnce sync.Once
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curBundle bundle // incoming items added to this bundle
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// Each bundle is assigned a unique ticket that determines the order in which the
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// handler is called. The ticket is assigned with mu locked, but waiting for tickets
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// to be handled is done via mu2 and cond, below.
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nextTicket uint64 // next ticket to be assigned
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mu2 sync.Mutex
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cond *sync.Cond
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nextHandled uint64 // next ticket to be handled
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// In this implementation, active uses space proportional to HandlerLimit, and
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// waitUntilAllHandled takes time proportional to HandlerLimit each time an acquire
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// or release occurs, so large values of HandlerLimit max may cause performance
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// issues.
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active map[uint64]bool // tickets of bundles actively being handled
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}
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type bundle struct {
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items reflect.Value // slice of item type
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size int // size in bytes of all items
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}
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// NewBundler creates a new Bundler.
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//
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// itemExample is a value of the type that will be bundled. For example, if you
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// want to create bundles of *Entry, you could pass &Entry{} for itemExample.
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//
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// handler is a function that will be called on each bundle. If itemExample is
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// of type T, the argument to handler is of type []T. handler is always called
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// sequentially for each bundle, and never in parallel.
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//
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// Configure the Bundler by setting its thresholds and limits before calling
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// any of its methods.
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func NewBundler(itemExample interface{}, handler func(interface{})) *Bundler {
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b := &Bundler{
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DelayThreshold: DefaultDelayThreshold,
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BundleCountThreshold: DefaultBundleCountThreshold,
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BundleByteThreshold: DefaultBundleByteThreshold,
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BufferedByteLimit: DefaultBufferedByteLimit,
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HandlerLimit: 1,
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handler: handler,
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itemSliceZero: reflect.Zero(reflect.SliceOf(reflect.TypeOf(itemExample))),
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active: map[uint64]bool{},
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}
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b.curBundle.items = b.itemSliceZero
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b.cond = sync.NewCond(&b.mu2)
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return b
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}
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func (b *Bundler) initSemaphores() {
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// Create the semaphores lazily, because the user may set limits
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// after NewBundler.
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b.semOnce.Do(func() {
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b.sem = semaphore.NewWeighted(int64(b.BufferedByteLimit))
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})
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}
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// Add adds item to the current bundle. It marks the bundle for handling and
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// starts a new one if any of the thresholds or limits are exceeded.
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//
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// If the item's size exceeds the maximum bundle size (Bundler.BundleByteLimit), then
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// the item can never be handled. Add returns ErrOversizedItem in this case.
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//
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// If adding the item would exceed the maximum memory allowed
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// (Bundler.BufferedByteLimit) or an AddWait call is blocked waiting for
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// memory, Add returns ErrOverflow.
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//
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// Add never blocks.
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func (b *Bundler) Add(item interface{}, size int) error {
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// If this item exceeds the maximum size of a bundle,
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// we can never send it.
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if b.BundleByteLimit > 0 && size > b.BundleByteLimit {
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return ErrOversizedItem
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}
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// If adding this item would exceed our allotted memory
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// footprint, we can't accept it.
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// (TryAcquire also returns false if anything is waiting on the semaphore,
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// so calls to Add and AddWait shouldn't be mixed.)
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b.initSemaphores()
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if !b.sem.TryAcquire(int64(size)) {
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return ErrOverflow
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}
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b.add(item, size)
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return nil
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}
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// add adds item to the current bundle. It marks the bundle for handling and
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// starts a new one if any of the thresholds or limits are exceeded.
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func (b *Bundler) add(item interface{}, size int) {
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b.mu.Lock()
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defer b.mu.Unlock()
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// If adding this item to the current bundle would cause it to exceed the
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// maximum bundle size, close the current bundle and start a new one.
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if b.BundleByteLimit > 0 && b.curBundle.size+size > b.BundleByteLimit {
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b.startFlushLocked()
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}
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// Add the item.
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b.curBundle.items = reflect.Append(b.curBundle.items, reflect.ValueOf(item))
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b.curBundle.size += size
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// Start a timer to flush the item if one isn't already running.
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// startFlushLocked clears the timer and closes the bundle at the same time,
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// so we only allocate a new timer for the first item in each bundle.
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// (We could try to call Reset on the timer instead, but that would add a lot
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// of complexity to the code just to save one small allocation.)
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if b.flushTimer == nil {
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b.flushTimer = time.AfterFunc(b.DelayThreshold, b.Flush)
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}
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// If the current bundle equals the count threshold, close it.
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if b.curBundle.items.Len() == b.BundleCountThreshold {
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b.startFlushLocked()
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}
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// If the current bundle equals or exceeds the byte threshold, close it.
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if b.curBundle.size >= b.BundleByteThreshold {
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b.startFlushLocked()
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}
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}
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// AddWait adds item to the current bundle. It marks the bundle for handling and
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// starts a new one if any of the thresholds or limits are exceeded.
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//
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// If the item's size exceeds the maximum bundle size (Bundler.BundleByteLimit), then
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// the item can never be handled. AddWait returns ErrOversizedItem in this case.
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//
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// If adding the item would exceed the maximum memory allowed (Bundler.BufferedByteLimit),
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// AddWait blocks until space is available or ctx is done.
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//
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// Calls to Add and AddWait should not be mixed on the same Bundler.
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func (b *Bundler) AddWait(ctx context.Context, item interface{}, size int) error {
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// If this item exceeds the maximum size of a bundle,
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// we can never send it.
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if b.BundleByteLimit > 0 && size > b.BundleByteLimit {
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return ErrOversizedItem
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}
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// If adding this item would exceed our allotted memory footprint, block
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// until space is available. The semaphore is FIFO, so there will be no
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// starvation.
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b.initSemaphores()
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if err := b.sem.Acquire(ctx, int64(size)); err != nil {
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return err
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}
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// Here, we've reserved space for item. Other goroutines can call AddWait
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// and even acquire space, but no one can take away our reservation
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// (assuming sem.Release is used correctly). So there is no race condition
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// resulting from locking the mutex after sem.Acquire returns.
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b.add(item, size)
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return nil
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}
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// Flush invokes the handler for all remaining items in the Bundler and waits
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// for it to return.
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func (b *Bundler) Flush() {
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b.mu.Lock()
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b.startFlushLocked()
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// Here, all bundles with tickets < b.nextTicket are
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// either finished or active. Those are the ones
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// we want to wait for.
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t := b.nextTicket
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b.mu.Unlock()
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b.initSemaphores()
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b.waitUntilAllHandled(t)
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}
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func (b *Bundler) startFlushLocked() {
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if b.flushTimer != nil {
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b.flushTimer.Stop()
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b.flushTimer = nil
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}
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if b.curBundle.items.Len() == 0 {
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return
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}
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// Here, both semaphores must have been initialized.
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bun := b.curBundle
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b.curBundle = bundle{items: b.itemSliceZero}
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ticket := b.nextTicket
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b.nextTicket++
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go func() {
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defer func() {
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b.sem.Release(int64(bun.size))
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b.release(ticket)
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}()
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b.acquire(ticket)
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b.handler(bun.items.Interface())
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}()
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}
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// acquire blocks until ticket is the next to be served, then returns. In order for N
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// acquire calls to return, the tickets must be in the range [0, N). A ticket must
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// not be presented to acquire more than once.
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func (b *Bundler) acquire(ticket uint64) {
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b.mu2.Lock()
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defer b.mu2.Unlock()
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if ticket < b.nextHandled {
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panic("bundler: acquire: arg too small")
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}
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for !(ticket == b.nextHandled && len(b.active) < b.HandlerLimit) {
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b.cond.Wait()
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}
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// Here,
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// ticket == b.nextHandled: the caller is the next one to be handled;
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// and len(b.active) < b.HandlerLimit: there is space available.
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b.active[ticket] = true
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b.nextHandled++
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// Broadcast, not Signal: although at most one acquire waiter can make progress,
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// there might be waiters in waitUntilAllHandled.
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b.cond.Broadcast()
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}
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// If a ticket is used for a call to acquire, it must later be passed to release. A
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// ticket must not be presented to release more than once.
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func (b *Bundler) release(ticket uint64) {
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b.mu2.Lock()
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defer b.mu2.Unlock()
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if !b.active[ticket] {
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panic("bundler: release: not an active ticket")
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}
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delete(b.active, ticket)
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b.cond.Broadcast()
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}
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// waitUntilAllHandled blocks until all tickets < n have called release, meaning
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// all bundles with tickets < n have been handled.
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func (b *Bundler) waitUntilAllHandled(n uint64) {
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// Proof of correctness of this function.
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// "N is acquired" means acquire(N) has returned.
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// "N is released" means release(N) has returned.
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// 1. If N is acquired, N-1 is acquired.
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// Follows from the loop test in acquire, and the fact
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// that nextHandled is incremented by 1.
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// 2. If nextHandled >= N, then N-1 is acquired.
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// Because we only increment nextHandled to N after N-1 is acquired.
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// 3. If nextHandled >= N, then all n < N is acquired.
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// Follows from #1 and #2.
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// 4. If N is acquired and N is not in active, then N is released.
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// Because we put N in active before acquire returns, and only
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// remove it when it is released.
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// Let min(active) be the smallest member of active, or infinity if active is empty.
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// 5. If nextHandled >= N and N <= min(active), then all n < N is released.
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// From nextHandled >= N and #3, all n < N is acquired.
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// N <= min(active) implies n < min(active) for all n < N. So all n < N is not in active.
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// So from #4, all n < N is released.
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// The loop test below is the antecedent of #5.
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b.mu2.Lock()
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defer b.mu2.Unlock()
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for !(b.nextHandled >= n && n <= min(b.active)) {
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b.cond.Wait()
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}
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}
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// min returns the minimum value of the set s, or the largest uint64 if
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// s is empty.
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func min(s map[uint64]bool) uint64 {
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var m uint64 = math.MaxUint64
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for n := range s {
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if n < m {
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m = n
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}
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}
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return m
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}
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