peridot/vendor/github.com/vbauerster/mpb/v7/progress.go

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2022-07-07 20:11:50 +00:00
package mpb
import (
"bytes"
"container/heap"
"context"
"fmt"
"io"
"io/ioutil"
"log"
"math"
"os"
"sync"
"time"
"github.com/vbauerster/mpb/v7/cwriter"
"github.com/vbauerster/mpb/v7/decor"
)
const (
// default RefreshRate
prr = 120 * time.Millisecond
)
// Progress represents a container that renders one or more progress
// bars.
type Progress struct {
ctx context.Context
uwg *sync.WaitGroup
cwg *sync.WaitGroup
bwg *sync.WaitGroup
operateState chan func(*pState)
done chan struct{}
refreshCh chan time.Time
once sync.Once
dlogger *log.Logger
}
// pState holds bars in its priorityQueue. It gets passed to
// *Progress.serve(...) monitor goroutine.
type pState struct {
bHeap priorityQueue
heapUpdated bool
pMatrix map[int][]chan int
aMatrix map[int][]chan int
barShutdownQueue []*Bar
// following are provided/overrided by user
idCount int
reqWidth int
popCompleted bool
outputDiscarded bool
rr time.Duration
uwg *sync.WaitGroup
externalRefresh <-chan interface{}
renderDelay <-chan struct{}
shutdownNotifier chan struct{}
parkedBars map[*Bar]*Bar
output io.Writer
debugOut io.Writer
}
// New creates new Progress container instance. It's not possible to
// reuse instance after *Progress.Wait() method has been called.
func New(options ...ContainerOption) *Progress {
return NewWithContext(context.Background(), options...)
}
// NewWithContext creates new Progress container instance with provided
// context. It's not possible to reuse instance after *Progress.Wait()
// method has been called.
func NewWithContext(ctx context.Context, options ...ContainerOption) *Progress {
s := &pState{
bHeap: priorityQueue{},
rr: prr,
parkedBars: make(map[*Bar]*Bar),
output: os.Stdout,
debugOut: ioutil.Discard,
}
for _, opt := range options {
if opt != nil {
opt(s)
}
}
p := &Progress{
ctx: ctx,
uwg: s.uwg,
cwg: new(sync.WaitGroup),
bwg: new(sync.WaitGroup),
operateState: make(chan func(*pState)),
done: make(chan struct{}),
dlogger: log.New(s.debugOut, "[mpb] ", log.Lshortfile),
}
p.cwg.Add(1)
go p.serve(s, cwriter.New(s.output))
return p
}
// AddBar creates a bar with default bar filler. Different filler can
// be chosen and applied via `*Progress.Add(...) *Bar` method.
func (p *Progress) AddBar(total int64, options ...BarOption) *Bar {
return p.Add(total, NewBarFiller(BarStyle()), options...)
}
// AddSpinner creates a bar with default spinner filler. Different
// filler can be chosen and applied via `*Progress.Add(...) *Bar`
// method.
func (p *Progress) AddSpinner(total int64, options ...BarOption) *Bar {
return p.Add(total, NewBarFiller(SpinnerStyle()), options...)
}
// Add creates a bar which renders itself by provided filler.
// If `total <= 0` trigger complete event is disabled until reset with *bar.SetTotal(int64, bool).
// Panics if *Progress instance is done, i.e. called after *Progress.Wait().
func (p *Progress) Add(total int64, filler BarFiller, options ...BarOption) *Bar {
if filler == nil {
filler = BarFillerFunc(func(io.Writer, int, decor.Statistics) {})
}
p.bwg.Add(1)
result := make(chan *Bar)
select {
case p.operateState <- func(ps *pState) {
bs := ps.makeBarState(total, filler, options...)
bar := newBar(p, bs)
if bs.runningBar != nil {
bs.runningBar.noPop = true
ps.parkedBars[bs.runningBar] = bar
} else {
heap.Push(&ps.bHeap, bar)
ps.heapUpdated = true
}
ps.idCount++
result <- bar
}:
bar := <-result
bar.subscribeDecorators()
return bar
case <-p.done:
p.bwg.Done()
panic(fmt.Sprintf("%T instance can't be reused after it's done!", p))
}
}
func (p *Progress) dropBar(b *Bar) {
select {
case p.operateState <- func(s *pState) {
if b.index < 0 {
return
}
heap.Remove(&s.bHeap, b.index)
s.heapUpdated = true
}:
case <-p.done:
}
}
func (p *Progress) setBarPriority(b *Bar, priority int) {
select {
case p.operateState <- func(s *pState) {
if b.index < 0 {
return
}
b.priority = priority
heap.Fix(&s.bHeap, b.index)
}:
case <-p.done:
}
}
// UpdateBarPriority same as *Bar.SetPriority(int).
func (p *Progress) UpdateBarPriority(b *Bar, priority int) {
p.setBarPriority(b, priority)
}
// BarCount returns bars count.
func (p *Progress) BarCount() int {
result := make(chan int, 1)
select {
case p.operateState <- func(s *pState) { result <- s.bHeap.Len() }:
return <-result
case <-p.done:
return 0
}
}
// Wait waits for all bars to complete and finally shutdowns container.
// After this method has been called, there is no way to reuse *Progress
// instance.
func (p *Progress) Wait() {
if p.uwg != nil {
// wait for user wg
p.uwg.Wait()
}
// wait for bars to quit, if any
p.bwg.Wait()
p.once.Do(p.shutdown)
// wait for container to quit
p.cwg.Wait()
}
func (p *Progress) shutdown() {
close(p.done)
}
func (p *Progress) serve(s *pState, cw *cwriter.Writer) {
defer p.cwg.Done()
p.refreshCh = s.newTicker(p.done)
for {
select {
case op := <-p.operateState:
op(s)
case <-p.refreshCh:
if err := s.render(cw); err != nil {
p.dlogger.Println(err)
}
case <-s.shutdownNotifier:
if s.heapUpdated {
if err := s.render(cw); err != nil {
p.dlogger.Println(err)
}
}
return
}
}
}
func (s *pState) newTicker(done <-chan struct{}) chan time.Time {
ch := make(chan time.Time)
if s.shutdownNotifier == nil {
s.shutdownNotifier = make(chan struct{})
}
go func() {
if s.renderDelay != nil {
<-s.renderDelay
}
var internalRefresh <-chan time.Time
if !s.outputDiscarded {
if s.externalRefresh == nil {
ticker := time.NewTicker(s.rr)
defer ticker.Stop()
internalRefresh = ticker.C
}
} else {
s.externalRefresh = nil
}
for {
select {
case t := <-internalRefresh:
ch <- t
case x := <-s.externalRefresh:
if t, ok := x.(time.Time); ok {
ch <- t
} else {
ch <- time.Now()
}
case <-done:
close(s.shutdownNotifier)
return
}
}
}()
return ch
}
func (s *pState) render(cw *cwriter.Writer) error {
if s.heapUpdated {
s.updateSyncMatrix()
s.heapUpdated = false
}
syncWidth(s.pMatrix)
syncWidth(s.aMatrix)
tw, err := cw.GetWidth()
if err != nil {
tw = s.reqWidth
}
for i := 0; i < s.bHeap.Len(); i++ {
bar := s.bHeap[i]
go bar.render(tw)
}
return s.flush(cw)
}
func (s *pState) flush(cw *cwriter.Writer) error {
var lineCount int
bm := make(map[*Bar]struct{}, s.bHeap.Len())
for s.bHeap.Len() > 0 {
b := heap.Pop(&s.bHeap).(*Bar)
cw.ReadFrom(<-b.frameCh)
if b.toShutdown {
if b.recoveredPanic != nil {
s.barShutdownQueue = append(s.barShutdownQueue, b)
b.toShutdown = false
} else {
// shutdown at next flush
// this ensures no bar ends up with less than 100% rendered
defer func() {
s.barShutdownQueue = append(s.barShutdownQueue, b)
}()
}
}
lineCount += b.extendedLines + 1
bm[b] = struct{}{}
}
for _, b := range s.barShutdownQueue {
if parkedBar := s.parkedBars[b]; parkedBar != nil {
parkedBar.priority = b.priority
heap.Push(&s.bHeap, parkedBar)
delete(s.parkedBars, b)
b.toDrop = true
}
if s.popCompleted && !b.noPop {
lineCount -= b.extendedLines + 1
b.toDrop = true
}
if b.toDrop {
delete(bm, b)
s.heapUpdated = true
}
b.cancel()
}
s.barShutdownQueue = s.barShutdownQueue[0:0]
for b := range bm {
heap.Push(&s.bHeap, b)
}
return cw.Flush(lineCount)
}
func (s *pState) updateSyncMatrix() {
s.pMatrix = make(map[int][]chan int)
s.aMatrix = make(map[int][]chan int)
for i := 0; i < s.bHeap.Len(); i++ {
bar := s.bHeap[i]
table := bar.wSyncTable()
pRow, aRow := table[0], table[1]
for i, ch := range pRow {
s.pMatrix[i] = append(s.pMatrix[i], ch)
}
for i, ch := range aRow {
s.aMatrix[i] = append(s.aMatrix[i], ch)
}
}
}
func (s *pState) makeBarState(total int64, filler BarFiller, options ...BarOption) *bState {
bs := &bState{
id: s.idCount,
priority: s.idCount,
reqWidth: s.reqWidth,
total: total,
filler: filler,
extender: func(r io.Reader, _ int, _ decor.Statistics) (io.Reader, int) { return r, 0 },
debugOut: s.debugOut,
}
if total > 0 {
bs.triggerComplete = true
}
for _, opt := range options {
if opt != nil {
opt(bs)
}
}
if bs.middleware != nil {
bs.filler = bs.middleware(filler)
bs.middleware = nil
}
if s.popCompleted && !bs.noPop {
bs.priority = -(math.MaxInt32 - s.idCount)
}
bs.bufP = bytes.NewBuffer(make([]byte, 0, 128))
bs.bufB = bytes.NewBuffer(make([]byte, 0, 256))
bs.bufA = bytes.NewBuffer(make([]byte, 0, 128))
return bs
}
func syncWidth(matrix map[int][]chan int) {
for _, column := range matrix {
go maxWidthDistributor(column)
}
}
var maxWidthDistributor = func(column []chan int) {
var maxWidth int
for _, ch := range column {
if w := <-ch; w > maxWidth {
maxWidth = w
}
}
for _, ch := range column {
ch <- maxWidth
}
}