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kratos/pkg/container/pool/slice.go

419 lines
9.2 KiB

package pool
import (
"context"
"io"
"sync"
"time"
)
var _ Pool = &Slice{}
// Slice .
type Slice struct {
// New is an application supplied function for creating and configuring a
// item.
//
// The item returned from new must not be in a special state
// (subscribed to pubsub channel, transaction started, ...).
New func(ctx context.Context) (io.Closer, error)
stop func() // stop cancels the item opener.
// mu protects fields defined below.
mu sync.Mutex
freeItem []*item
itemRequests map[uint64]chan item
nextRequest uint64 // Next key to use in itemRequests.
active int // number of opened and pending open items
// Used to signal the need for new items
// a goroutine running itemOpener() reads on this chan and
// maybeOpenNewItems sends on the chan (one send per needed item)
// It is closed during db.Close(). The close tells the itemOpener
// goroutine to exit.
openerCh chan struct{}
closed bool
cleanerCh chan struct{}
// Config pool configuration
conf *Config
}
// NewSlice creates a new pool.
func NewSlice(c *Config) *Slice {
// check Config
if c == nil || c.Active < c.Idle {
panic("config nil or Idle Must <= Active")
}
ctx, cancel := context.WithCancel(context.Background())
// new pool
p := &Slice{
conf: c,
stop: cancel,
itemRequests: make(map[uint64]chan item),
openerCh: make(chan struct{}, 1000000),
}
p.startCleanerLocked(time.Duration(c.IdleTimeout))
go p.itemOpener(ctx)
return p
}
// Reload reload config.
func (p *Slice) Reload(c *Config) error {
p.mu.Lock()
//p.startCleanerLocked(time.Duration(c.IdleTimeout))
p.setActive(c.Active)
p.setIdle(c.Idle)
p.conf = c
p.mu.Unlock()
return nil
}
// Get returns a newly-opened or cached *item.
func (p *Slice) Get(ctx context.Context) (io.Closer, error) {
p.mu.Lock()
if p.closed {
p.mu.Unlock()
return nil, ErrPoolClosed
}
idleTimeout := time.Duration(p.conf.IdleTimeout)
// Prefer a free item, if possible.
numFree := len(p.freeItem)
for numFree > 0 {
i := p.freeItem[0]
copy(p.freeItem, p.freeItem[1:])
p.freeItem = p.freeItem[:numFree-1]
p.mu.Unlock()
if i.expired(idleTimeout) {
i.close()
p.mu.Lock()
p.release()
} else {
return i.c, nil
}
numFree = len(p.freeItem)
}
// Out of free items or we were asked not to use one. If we're not
// allowed to open any more items, make a request and wait.
if p.conf.Active > 0 && p.active >= p.conf.Active {
// check WaitTimeout and return directly
if p.conf.WaitTimeout == 0 && !p.conf.Wait {
p.mu.Unlock()
return nil, ErrPoolExhausted
}
// Make the item channel. It's buffered so that the
// itemOpener doesn't block while waiting for the req to be read.
req := make(chan item, 1)
reqKey := p.nextRequestKeyLocked()
p.itemRequests[reqKey] = req
wt := p.conf.WaitTimeout
p.mu.Unlock()
// reset context timeout
if wt > 0 {
var cancel func()
_, ctx, cancel = wt.Shrink(ctx)
defer cancel()
}
// Timeout the item request with the context.
select {
case <-ctx.Done():
// Remove the item request and ensure no value has been sent
// on it after removing.
p.mu.Lock()
delete(p.itemRequests, reqKey)
p.mu.Unlock()
return nil, ctx.Err()
case ret, ok := <-req:
if !ok {
return nil, ErrPoolClosed
}
if ret.expired(idleTimeout) {
ret.close()
p.mu.Lock()
p.release()
} else {
return ret.c, nil
}
}
}
p.active++ // optimistically
p.mu.Unlock()
c, err := p.New(ctx)
if err != nil {
p.mu.Lock()
p.release()
p.mu.Unlock()
return nil, err
}
return c, nil
}
// Put adds a item to the p's free pool.
// err is optionally the last error that occurred on this item.
func (p *Slice) Put(ctx context.Context, c io.Closer, forceClose bool) error {
p.mu.Lock()
defer p.mu.Unlock()
if forceClose {
p.release()
return c.Close()
}
added := p.putItemLocked(c)
if !added {
p.active--
return c.Close()
}
return nil
}
// Satisfy a item or put the item in the idle pool and return true
// or return false.
// putItemLocked will satisfy a item if there is one, or it will
// return the *item to the freeItem list if err == nil and the idle
// item limit will not be exceeded.
// If err != nil, the value of i is ignored.
// If err == nil, then i must not equal nil.
// If a item was fulfilled or the *item was placed in the
// freeItem list, then true is returned, otherwise false is returned.
func (p *Slice) putItemLocked(c io.Closer) bool {
if p.closed {
return false
}
if p.conf.Active > 0 && p.active > p.conf.Active {
return false
}
i := item{
c: c,
createdAt: nowFunc(),
}
if l := len(p.itemRequests); l > 0 {
var req chan item
var reqKey uint64
for reqKey, req = range p.itemRequests {
break
}
delete(p.itemRequests, reqKey) // Remove from pending requests.
req <- i
return true
} else if !p.closed && p.maxIdleItemsLocked() > len(p.freeItem) {
p.freeItem = append(p.freeItem, &i)
return true
}
return false
}
// Runs in a separate goroutine, opens new item when requested.
func (p *Slice) itemOpener(ctx context.Context) {
for {
select {
case <-ctx.Done():
return
case <-p.openerCh:
p.openNewItem(ctx)
}
}
}
func (p *Slice) maybeOpenNewItems() {
numRequests := len(p.itemRequests)
if p.conf.Active > 0 {
numCanOpen := p.conf.Active - p.active
if numRequests > numCanOpen {
numRequests = numCanOpen
}
}
for numRequests > 0 {
p.active++ // optimistically
numRequests--
if p.closed {
return
}
p.openerCh <- struct{}{}
}
}
// openNewItem one new item
func (p *Slice) openNewItem(ctx context.Context) {
// maybeOpenNewConnctions has already executed p.active++ before it sent
// on p.openerCh. This function must execute p.active-- if the
// item fails or is closed before returning.
c, err := p.New(ctx)
p.mu.Lock()
defer p.mu.Unlock()
if err != nil {
p.release()
return
}
if !p.putItemLocked(c) {
p.active--
c.Close()
}
}
// setIdle sets the maximum number of items in the idle
// item pool.
//
// If MaxOpenConns is greater than 0 but less than the new IdleConns
// then the new IdleConns will be reduced to match the MaxOpenConns limit
//
// If n <= 0, no idle items are retained.
func (p *Slice) setIdle(n int) {
if n > 0 {
p.conf.Idle = n
} else {
// No idle items.
p.conf.Idle = -1
}
// Make sure maxIdle doesn't exceed maxOpen
if p.conf.Active > 0 && p.maxIdleItemsLocked() > p.conf.Active {
p.conf.Idle = p.conf.Active
}
var closing []*item
idleCount := len(p.freeItem)
maxIdle := p.maxIdleItemsLocked()
if idleCount > maxIdle {
closing = p.freeItem[maxIdle:]
p.freeItem = p.freeItem[:maxIdle]
}
for _, c := range closing {
c.close()
}
}
// setActive sets the maximum number of open items to the database.
//
// If IdleConns is greater than 0 and the new MaxOpenConns is less than
// IdleConns, then IdleConns will be reduced to match the new
// MaxOpenConns limit
//
// If n <= 0, then there is no limit on the number of open items.
// The default is 0 (unlimited).
func (p *Slice) setActive(n int) {
p.conf.Active = n
if n < 0 {
p.conf.Active = 0
}
syncIdle := p.conf.Active > 0 && p.maxIdleItemsLocked() > p.conf.Active
if syncIdle {
p.setIdle(n)
}
}
// startCleanerLocked starts itemCleaner if needed.
func (p *Slice) startCleanerLocked(d time.Duration) {
if d <= 0 {
// if set 0, staleCleaner() will return directly
return
}
if d < time.Duration(p.conf.IdleTimeout) && p.cleanerCh != nil {
select {
case p.cleanerCh <- struct{}{}:
default:
}
}
// run only one, clean stale items.
if p.cleanerCh == nil {
p.cleanerCh = make(chan struct{}, 1)
go p.staleCleaner(time.Duration(p.conf.IdleTimeout))
}
}
func (p *Slice) staleCleaner(d time.Duration) {
const minInterval = 100 * time.Millisecond
if d < minInterval {
d = minInterval
}
t := time.NewTimer(d)
for {
select {
case <-t.C:
case <-p.cleanerCh: // maxLifetime was changed or db was closed.
}
p.mu.Lock()
d = time.Duration(p.conf.IdleTimeout)
if p.closed || d <= 0 {
p.mu.Unlock()
return
}
expiredSince := nowFunc().Add(-d)
var closing []*item
for i := 0; i < len(p.freeItem); i++ {
c := p.freeItem[i]
if c.createdAt.Before(expiredSince) {
closing = append(closing, c)
p.active--
last := len(p.freeItem) - 1
p.freeItem[i] = p.freeItem[last]
p.freeItem[last] = nil
p.freeItem = p.freeItem[:last]
i--
}
}
p.mu.Unlock()
for _, c := range closing {
c.close()
}
if d < minInterval {
d = minInterval
}
t.Reset(d)
}
}
// nextRequestKeyLocked returns the next item request key.
// It is assumed that nextRequest will not overflow.
func (p *Slice) nextRequestKeyLocked() uint64 {
next := p.nextRequest
p.nextRequest++
return next
}
const defaultIdleItems = 2
func (p *Slice) maxIdleItemsLocked() int {
n := p.conf.Idle
switch {
case n == 0:
return defaultIdleItems
case n < 0:
return 0
default:
return n
}
}
func (p *Slice) release() {
p.active--
p.maybeOpenNewItems()
}
// Close close pool.
func (p *Slice) Close() error {
p.mu.Lock()
if p.closed {
p.mu.Unlock()
return nil
}
if p.cleanerCh != nil {
close(p.cleanerCh)
}
var err error
for _, i := range p.freeItem {
i.close()
}
p.freeItem = nil
p.closed = true
for _, req := range p.itemRequests {
close(req)
}
p.mu.Unlock()
p.stop()
return err
}