package mpb import ( "bytes" "context" "io" "strings" "sync" "time" "github.com/acarl005/stripansi" "github.com/mattn/go-runewidth" "github.com/vbauerster/mpb/v8/decor" ) // Bar represents a progress bar. type Bar struct { index int // used by heap priority int // used by heap frameCh chan *renderFrame operateState chan func(*bState) done chan struct{} container *Progress bs *bState cancel func() } type syncTable [2][]chan int type extenderFunc func([]io.Reader, decor.Statistics) ([]io.Reader, error) // bState is actual bar's state. type bState struct { id int priority int reqWidth int shutdown int total int64 current int64 refill int64 trimSpace bool completed bool aborted bool triggerComplete bool rmOnComplete bool noPop bool autoRefresh bool aDecorators []decor.Decorator pDecorators []decor.Decorator averageDecorators []decor.AverageDecorator ewmaDecorators []decor.EwmaDecorator shutdownListeners []decor.ShutdownListener buffers [3]*bytes.Buffer filler BarFiller extender extenderFunc renderReq chan<- time.Time waitBar *Bar // key for (*pState).queueBars } type renderFrame struct { rows []io.Reader shutdown int rmOnComplete bool noPop bool err error } func newBar(ctx context.Context, container *Progress, bs *bState) *Bar { ctx, cancel := context.WithCancel(ctx) bar := &Bar{ priority: bs.priority, frameCh: make(chan *renderFrame, 1), operateState: make(chan func(*bState)), done: make(chan struct{}), container: container, cancel: cancel, } container.bwg.Add(1) go bar.serve(ctx, bs) return bar } // ProxyReader wraps io.Reader with metrics required for progress // tracking. If `r` is 'unknown total/size' reader it's mandatory // to call `(*Bar).SetTotal(-1, true)` after the wrapper returns // `io.EOF`. If bar is already completed or aborted, returns nil. // Panics if `r` is nil. func (b *Bar) ProxyReader(r io.Reader) io.ReadCloser { if r == nil { panic("expected non nil io.Reader") } result := make(chan bool) select { case b.operateState <- func(s *bState) { result <- len(s.ewmaDecorators) != 0 }: return newProxyReader(r, b, <-result) case <-b.done: return nil } } // ProxyWriter wraps io.Writer with metrics required for progress tracking. // If bar is already completed or aborted, returns nil. // Panics if `w` is nil. func (b *Bar) ProxyWriter(w io.Writer) io.WriteCloser { if w == nil { panic("expected non nil io.Writer") } result := make(chan bool) select { case b.operateState <- func(s *bState) { result <- len(s.ewmaDecorators) != 0 }: return newProxyWriter(w, b, <-result) case <-b.done: return nil } } // ID returs id of the bar. func (b *Bar) ID() int { result := make(chan int) select { case b.operateState <- func(s *bState) { result <- s.id }: return <-result case <-b.done: return b.bs.id } } // Current returns bar's current value, in other words sum of all increments. func (b *Bar) Current() int64 { result := make(chan int64) select { case b.operateState <- func(s *bState) { result <- s.current }: return <-result case <-b.done: return b.bs.current } } // SetRefill sets refill flag with specified amount. // The underlying BarFiller will change its visual representation, to // indicate refill event. Refill event may be referred to some retry // operation for example. func (b *Bar) SetRefill(amount int64) { select { case b.operateState <- func(s *bState) { if amount < s.current { s.refill = amount } else { s.refill = s.current } }: case <-b.done: } } // TraverseDecorators traverses all available decorators and calls cb func on each. func (b *Bar) TraverseDecorators(cb func(decor.Decorator)) { iter := make(chan decor.Decorator) select { case b.operateState <- func(s *bState) { for _, decorators := range [][]decor.Decorator{ s.pDecorators, s.aDecorators, } { for _, d := range decorators { iter <- d } } close(iter) }: for d := range iter { cb(unwrap(d)) } case <-b.done: } } // EnableTriggerComplete enables triggering complete event. It's effective // only for bars which were constructed with `total <= 0` and after total // has been set with `(*Bar).SetTotal(int64, false)`. If `curren >= total` // at the moment of call, complete event is triggered right away. func (b *Bar) EnableTriggerComplete() { select { case b.operateState <- func(s *bState) { if s.triggerComplete || s.total <= 0 { return } if s.current >= s.total { s.current = s.total s.completed = true b.triggerCompletion(s) } else { s.triggerComplete = true } }: case <-b.done: } } // SetTotal sets total to an arbitrary value. It's effective only for bar // which was constructed with `total <= 0`. Setting total to negative value // is equivalent to `(*Bar).SetTotal((*Bar).Current(), bool)` but faster. If // triggerCompletion is true, total value is set to current and complete // event is triggered right away. func (b *Bar) SetTotal(total int64, triggerCompletion bool) { select { case b.operateState <- func(s *bState) { if s.triggerComplete { return } if total < 0 { s.total = s.current } else { s.total = total } if triggerCompletion { s.current = s.total s.completed = true b.triggerCompletion(s) } }: case <-b.done: } } // SetCurrent sets progress' current to an arbitrary value. func (b *Bar) SetCurrent(current int64) { if current < 0 { return } select { case b.operateState <- func(s *bState) { s.current = current if s.triggerComplete && s.current >= s.total { s.current = s.total s.completed = true b.triggerCompletion(s) } }: case <-b.done: } } // EwmaSetCurrent sets progress' current to an arbitrary value and updates // EWMA based decorators by dur of a single iteration. func (b *Bar) EwmaSetCurrent(current int64, iterDur time.Duration) { if current < 0 { return } select { case b.operateState <- func(s *bState) { if n := current - s.current; n > 0 { s.decoratorEwmaUpdate(n, iterDur) } s.current = current if s.triggerComplete && s.current >= s.total { s.current = s.total s.completed = true b.triggerCompletion(s) } }: case <-b.done: } } // Increment is a shorthand for b.IncrInt64(1). func (b *Bar) Increment() { b.IncrInt64(1) } // IncrBy is a shorthand for b.IncrInt64(int64(n)). func (b *Bar) IncrBy(n int) { b.IncrInt64(int64(n)) } // IncrInt64 increments progress by amount of n. func (b *Bar) IncrInt64(n int64) { if n <= 0 { return } select { case b.operateState <- func(s *bState) { s.current += n if s.triggerComplete && s.current >= s.total { s.current = s.total s.completed = true b.triggerCompletion(s) } }: case <-b.done: } } // EwmaIncrement is a shorthand for b.EwmaIncrInt64(1, iterDur). func (b *Bar) EwmaIncrement(iterDur time.Duration) { b.EwmaIncrInt64(1, iterDur) } // EwmaIncrBy is a shorthand for b.EwmaIncrInt64(int64(n), iterDur). func (b *Bar) EwmaIncrBy(n int, iterDur time.Duration) { b.EwmaIncrInt64(int64(n), iterDur) } // EwmaIncrInt64 increments progress by amount of n and updates EWMA based // decorators by dur of a single iteration. func (b *Bar) EwmaIncrInt64(n int64, iterDur time.Duration) { select { case b.operateState <- func(s *bState) { s.decoratorEwmaUpdate(n, iterDur) s.current += n if s.triggerComplete && s.current >= s.total { s.current = s.total s.completed = true b.triggerCompletion(s) } }: case <-b.done: } } // DecoratorAverageAdjust adjusts all average based decorators. Call // if you need to adjust start time of all average based decorators // or after progress resume. func (b *Bar) DecoratorAverageAdjust(start time.Time) { select { case b.operateState <- func(s *bState) { s.decoratorAverageAdjust(start) }: case <-b.done: } } // SetPriority changes bar's order among multiple bars. Zero is highest // priority, i.e. bar will be on top. If you don't need to set priority // dynamically, better use BarPriority option. func (b *Bar) SetPriority(priority int) { b.container.UpdateBarPriority(b, priority, false) } // Abort interrupts bar's running goroutine. Abort won't be engaged // if bar is already in complete state. If drop is true bar will be // removed as well. To make sure that bar has been removed call // `(*Bar).Wait()` method. func (b *Bar) Abort(drop bool) { select { case b.operateState <- func(s *bState) { if s.completed || s.aborted { return } s.aborted = true s.rmOnComplete = drop b.triggerCompletion(s) }: case <-b.done: } } // Aborted reports whether the bar is in aborted state. func (b *Bar) Aborted() bool { result := make(chan bool) select { case b.operateState <- func(s *bState) { result <- s.aborted }: return <-result case <-b.done: return b.bs.aborted } } // Completed reports whether the bar is in completed state. func (b *Bar) Completed() bool { result := make(chan bool) select { case b.operateState <- func(s *bState) { result <- s.completed }: return <-result case <-b.done: return b.bs.completed } } // IsRunning reports whether the bar is running, i.e. not yet completed // and not yet aborted. func (b *Bar) IsRunning() bool { result := make(chan bool) select { case b.operateState <- func(s *bState) { result <- !s.completed && !s.aborted }: return <-result case <-b.done: return false } } // Wait blocks until bar is completed or aborted. func (b *Bar) Wait() { <-b.done } func (b *Bar) serve(ctx context.Context, bs *bState) { defer b.container.bwg.Done() for { select { case op := <-b.operateState: op(bs) case <-ctx.Done(): bs.aborted = !bs.completed bs.decoratorShutdownNotify() b.bs = bs close(b.done) return } } } func (b *Bar) render(tw int) { fn := func(s *bState) { var rows []io.Reader stat := newStatistics(tw, s) r, err := s.draw(stat) if err != nil { b.frameCh <- &renderFrame{err: err} return } rows = append(rows, r) if s.extender != nil { rows, err = s.extender(rows, stat) if err != nil { b.frameCh <- &renderFrame{err: err} return } } frame := &renderFrame{rows: rows} if s.completed || s.aborted { frame.shutdown = s.shutdown frame.rmOnComplete = s.rmOnComplete frame.noPop = s.noPop // post increment makes sure OnComplete decorators are rendered s.shutdown++ } b.frameCh <- frame } select { case b.operateState <- fn: case <-b.done: fn(b.bs) } } func (b *Bar) triggerCompletion(s *bState) { if s.autoRefresh { // Technically this call isn't required, but if refresh rate is set to // one hour for example and bar completes within a few minutes p.Wait() // will wait for one hour. This call helps to avoid unnecessary waiting. go b.tryEarlyRefresh(s.renderReq) } else { b.cancel() } } func (b *Bar) tryEarlyRefresh(renderReq chan<- time.Time) { var otherRunning int b.container.traverseBars(func(bar *Bar) bool { if b != bar && bar.IsRunning() { otherRunning++ return false // stop traverse } return true // continue traverse }) if otherRunning == 0 { for { select { case renderReq <- time.Now(): case <-b.done: return } } } } func (b *Bar) wSyncTable() syncTable { result := make(chan syncTable) select { case b.operateState <- func(s *bState) { result <- s.wSyncTable() }: return <-result case <-b.done: return b.bs.wSyncTable() } } func (s *bState) draw(stat decor.Statistics) (io.Reader, error) { r, err := s.drawImpl(stat) if err != nil { for _, b := range s.buffers { b.Reset() } return nil, err } return io.MultiReader(r, strings.NewReader("\n")), nil } func (s *bState) drawImpl(stat decor.Statistics) (io.Reader, error) { decorFiller := func(buf *bytes.Buffer, decorators []decor.Decorator) (err error) { for _, d := range decorators { // need to call Decor in any case becase of width synchronization str, width := d.Decor(stat) if err != nil { continue } if w := stat.AvailableWidth - width; w >= 0 { _, err = buf.WriteString(str) stat.AvailableWidth = w } else if stat.AvailableWidth > 0 { trunc := runewidth.Truncate(stripansi.Strip(str), stat.AvailableWidth, "…") _, err = buf.WriteString(trunc) stat.AvailableWidth = 0 } } return err } bufP, bufB, bufA := s.buffers[0], s.buffers[1], s.buffers[2] err := eitherError(decorFiller(bufP, s.pDecorators), decorFiller(bufA, s.aDecorators)) if err != nil { return nil, err } if !s.trimSpace && stat.AvailableWidth >= 2 { stat.AvailableWidth -= 2 writeFiller := func(buf *bytes.Buffer) error { return s.filler.Fill(buf, stat) } for _, fn := range []func(*bytes.Buffer) error{ writeSpace, writeFiller, writeSpace, } { if err := fn(bufB); err != nil { return nil, err } } } else { err := s.filler.Fill(bufB, stat) if err != nil { return nil, err } } return io.MultiReader(bufP, bufB, bufA), nil } func (s *bState) wSyncTable() (table syncTable) { var count int var row []chan int for i, decorators := range [][]decor.Decorator{ s.pDecorators, s.aDecorators, } { for _, d := range decorators { if ch, ok := d.Sync(); ok { row = append(row, ch) count++ } } switch i { case 0: table[i] = row[0:count] default: table[i] = row[len(table[i-1]):count] } } return table } func (s bState) decoratorEwmaUpdate(n int64, dur time.Duration) { var wg sync.WaitGroup for i := 0; i < len(s.ewmaDecorators); i++ { switch d := s.ewmaDecorators[i]; i { case len(s.ewmaDecorators) - 1: d.EwmaUpdate(n, dur) default: wg.Add(1) go func() { d.EwmaUpdate(n, dur) wg.Done() }() } } wg.Wait() } func (s bState) decoratorAverageAdjust(start time.Time) { var wg sync.WaitGroup for i := 0; i < len(s.averageDecorators); i++ { switch d := s.averageDecorators[i]; i { case len(s.averageDecorators) - 1: d.AverageAdjust(start) default: wg.Add(1) go func() { d.AverageAdjust(start) wg.Done() }() } } wg.Wait() } func (s bState) decoratorShutdownNotify() { var wg sync.WaitGroup for i := 0; i < len(s.shutdownListeners); i++ { switch d := s.shutdownListeners[i]; i { case len(s.shutdownListeners) - 1: d.OnShutdown() default: wg.Add(1) go func() { d.OnShutdown() wg.Done() }() } } wg.Wait() } func newStatistics(tw int, s *bState) decor.Statistics { return decor.Statistics{ AvailableWidth: tw, RequestedWidth: s.reqWidth, ID: s.id, Total: s.total, Current: s.current, Refill: s.refill, Completed: s.completed, Aborted: s.aborted, } } func unwrap(d decor.Decorator) decor.Decorator { if d, ok := d.(decor.Wrapper); ok { return unwrap(d.Unwrap()) } return d } func writeSpace(buf *bytes.Buffer) error { return buf.WriteByte(' ') } func eitherError(errors ...error) error { for _, err := range errors { if err != nil { return err } } return nil }