buildkit/solver/scheduler.go

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package solver
import (
"context"
"sync"
"github.com/moby/buildkit/solver/internal/pipe"
"github.com/moby/buildkit/util/cond"
"github.com/pkg/errors"
"github.com/sirupsen/logrus"
)
const debugScheduler = false // TODO: replace with logs in build trace
func newScheduler(ef edgeFactory) *scheduler {
s := &scheduler{
waitq: map[*edge]struct{}{},
incoming: map[*edge][]*edgePipe{},
outgoing: map[*edge][]*edgePipe{},
stopped: make(chan struct{}),
closed: make(chan struct{}),
ef: ef,
}
s.cond = cond.NewStatefulCond(&s.mu)
go s.loop()
return s
}
type dispatcher struct {
next *dispatcher
e *edge
}
type scheduler struct {
cond *cond.StatefulCond
mu sync.Mutex
muQ sync.Mutex
ef edgeFactory
waitq map[*edge]struct{}
next *dispatcher
last *dispatcher
stopped chan struct{}
stoppedOnce sync.Once
closed chan struct{}
incoming map[*edge][]*edgePipe
outgoing map[*edge][]*edgePipe
}
func (s *scheduler) Stop() {
s.stoppedOnce.Do(func() {
close(s.stopped)
})
<-s.closed
}
func (s *scheduler) loop() {
defer func() {
close(s.closed)
}()
go func() {
<-s.stopped
s.mu.Lock()
s.cond.Signal()
s.mu.Unlock()
}()
s.mu.Lock()
for {
select {
case <-s.stopped:
s.mu.Unlock()
return
default:
}
s.muQ.Lock()
l := s.next
if l != nil {
if l == s.last {
s.last = nil
}
s.next = l.next
delete(s.waitq, l.e)
}
s.muQ.Unlock()
if l == nil {
s.cond.Wait()
continue
}
s.dispatch(l.e)
}
}
// dispatch schedules an edge to be processed
func (s *scheduler) dispatch(e *edge) {
inc := make([]pipe.Sender, len(s.incoming[e]))
for i, p := range s.incoming[e] {
inc[i] = p.Sender
}
out := make([]pipe.Receiver, len(s.outgoing[e]))
for i, p := range s.outgoing[e] {
out[i] = p.Receiver
}
e.hasActiveOutgoing = false
updates := []pipe.Receiver{}
for _, p := range out {
if ok := p.Receive(); ok {
updates = append(updates, p)
}
if !p.Status().Completed {
e.hasActiveOutgoing = true
}
}
// unpark the edge
debugSchedulerPreUnpark(e, inc, updates, out)
e.unpark(inc, updates, out, &pipeFactory{s: s, e: e})
debugSchedulerPostUnpark(e, inc)
// set up new requests that didn't complete/were added by this run
openIncoming := make([]*edgePipe, 0, len(inc))
for _, r := range s.incoming[e] {
if !r.Sender.Status().Completed {
openIncoming = append(openIncoming, r)
}
}
if len(openIncoming) > 0 {
s.incoming[e] = openIncoming
} else {
delete(s.incoming, e)
}
openOutgoing := make([]*edgePipe, 0, len(out))
for _, r := range s.outgoing[e] {
if !r.Receiver.Status().Completed {
openOutgoing = append(openOutgoing, r)
}
}
if len(openOutgoing) > 0 {
s.outgoing[e] = openOutgoing
} else {
delete(s.outgoing, e)
}
// if keys changed there might be possiblity for merge with other edge
if e.keysDidChange {
if k := e.currentIndexKey(); k != nil {
// skip this if not at least 1 key per dep
origEdge := e.index.LoadOrStore(k, e)
if origEdge != nil {
logrus.Debugf("merging edge %s to %s\n", e.edge.Vertex.Name(), origEdge.edge.Vertex.Name())
if s.mergeTo(origEdge, e) {
s.ef.setEdge(e.edge, origEdge)
}
}
}
e.keysDidChange = false
}
// validation to avoid deadlocks/resource leaks:
// TODO: if these start showing up in error reports they can be changed
// to error the edge instead. They can only appear from algorithm bugs in
// unpark(), not for any external input.
if len(openIncoming) > 0 && len(openOutgoing) == 0 {
panic("invalid dispatch: return leaving incoming open")
}
if len(openIncoming) == 0 && len(openOutgoing) > 0 {
panic("invalid dispatch: return leaving outgoing open")
}
}
// signal notifies that an edge needs to be processed again
func (s *scheduler) signal(e *edge) {
s.muQ.Lock()
if _, ok := s.waitq[e]; !ok {
d := &dispatcher{e: e}
if s.last == nil {
s.next = d
} else {
s.last.next = d
}
s.last = d
s.waitq[e] = struct{}{}
s.cond.Signal()
}
s.muQ.Unlock()
}
// build evaluates edge into a result
func (s *scheduler) build(ctx context.Context, edge Edge) (CachedResult, error) {
s.mu.Lock()
e := s.ef.getEdge(edge)
if e == nil {
s.mu.Unlock()
return nil, errors.Errorf("invalid request %v for build", edge)
}
wait := make(chan struct{})
var p *pipe.Pipe
p = s.newPipe(e, nil, pipe.Request{Payload: &edgeRequest{desiredState: edgeStatusComplete}})
p.OnSendCompletion = func() {
p.Receiver.Receive()
if p.Receiver.Status().Completed {
close(wait)
}
}
s.mu.Unlock()
ctx, cancel := context.WithCancel(ctx)
defer cancel()
go func() {
<-ctx.Done()
p.Receiver.Cancel()
}()
<-wait
if err := p.Receiver.Status().Err; err != nil {
return nil, err
}
return p.Receiver.Status().Value.(*edgeState).result.Clone(), nil
}
// newPipe creates a new request pipe between two edges
func (s *scheduler) newPipe(target, from *edge, req pipe.Request) *pipe.Pipe {
p := &edgePipe{
Pipe: pipe.New(req),
Target: target,
From: from,
}
s.signal(target)
if from != nil {
p.OnSendCompletion = func() {
p.mu.Lock()
defer p.mu.Unlock()
s.signal(p.From)
}
s.outgoing[from] = append(s.outgoing[from], p)
}
s.incoming[target] = append(s.incoming[target], p)
p.OnReceiveCompletion = func() {
p.mu.Lock()
defer p.mu.Unlock()
s.signal(p.Target)
}
return p.Pipe
}
// newRequestWithFunc creates a new request pipe that invokes a async function
func (s *scheduler) newRequestWithFunc(e *edge, f func(context.Context) (interface{}, error)) pipe.Receiver {
pp, start := pipe.NewWithFunction(f)
p := &edgePipe{
Pipe: pp,
From: e,
}
p.OnSendCompletion = func() {
p.mu.Lock()
defer p.mu.Unlock()
s.signal(p.From)
}
s.outgoing[e] = append(s.outgoing[e], p)
go start()
return p.Receiver
}
// mergeTo merges the state from one edge to another. source edge is discarded.
func (s *scheduler) mergeTo(target, src *edge) bool {
if !target.edge.Vertex.Options().IgnoreCache && src.edge.Vertex.Options().IgnoreCache {
return false
}
for _, inc := range s.incoming[src] {
inc.mu.Lock()
inc.Target = target
s.incoming[target] = append(s.incoming[target], inc)
inc.mu.Unlock()
}
for _, out := range s.outgoing[src] {
out.mu.Lock()
out.From = target
s.outgoing[target] = append(s.outgoing[target], out)
out.mu.Unlock()
out.Receiver.Cancel()
}
delete(s.incoming, src)
delete(s.outgoing, src)
s.signal(target)
for i, d := range src.deps {
for _, k := range d.keys {
target.secondaryExporters = append(target.secondaryExporters, expDep{i, CacheKeyWithSelector{CacheKey: k, Selector: src.cacheMap.Deps[i].Selector}})
}
if d.slowCacheKey != nil {
target.secondaryExporters = append(target.secondaryExporters, expDep{i, CacheKeyWithSelector{CacheKey: *d.slowCacheKey}})
}
if d.result != nil {
target.secondaryExporters = append(target.secondaryExporters, expDep{i, CacheKeyWithSelector{CacheKey: d.result.CacheKey(), Selector: src.cacheMap.Deps[i].Selector}})
}
}
// TODO(tonistiigi): merge cache providers
return true
}
// edgeFactory allows access to the edges from a shared graph
type edgeFactory interface {
getEdge(Edge) *edge
setEdge(Edge, *edge)
}
type pipeFactory struct {
e *edge
s *scheduler
}
func (pf *pipeFactory) NewInputRequest(ee Edge, req *edgeRequest) pipe.Receiver {
target := pf.s.ef.getEdge(ee)
if target == nil {
panic("failed to get edge") // TODO: return errored pipe
}
p := pf.s.newPipe(target, pf.e, pipe.Request{Payload: req})
if debugScheduler {
logrus.Debugf("> newPipe %s %p desiredState=%s", ee.Vertex.Name(), p, req.desiredState)
}
return p.Receiver
}
func (pf *pipeFactory) NewFuncRequest(f func(context.Context) (interface{}, error)) pipe.Receiver {
p := pf.s.newRequestWithFunc(pf.e, f)
if debugScheduler {
logrus.Debugf("> newFunc %p", p)
}
return p
}
func debugSchedulerPreUnpark(e *edge, inc []pipe.Sender, updates, allPipes []pipe.Receiver) {
if !debugScheduler {
return
}
logrus.Debugf(">> unpark %s req=%d upt=%d out=%d state=%s %s", e.edge.Vertex.Name(), len(inc), len(updates), len(allPipes), e.state, e.edge.Vertex.Digest())
for i, dep := range e.deps {
des := edgeStatusInitial
if dep.req != nil {
des = dep.req.Request().(*edgeRequest).desiredState
}
logrus.Debugf(":: dep%d %s state=%s des=%s keys=%s hasslowcache=%v", i, e.edge.Vertex.Inputs()[i].Vertex.Name(), dep.state, des, len(dep.keys), e.slowCacheFunc(dep) != nil)
}
for i, in := range inc {
req := in.Request()
logrus.Debugf("> incoming-%d: %p dstate=%s canceled=%v", i, in, req.Payload.(*edgeRequest).desiredState, req.Canceled)
}
for i, up := range updates {
if up == e.cacheMapReq {
logrus.Debugf("> update-%d: %p cacheMapReq complete=%v", i, up, up.Status().Completed)
} else if up == e.execReq {
logrus.Debugf("> update-%d: %p execReq complete=%v", i, up, up.Status().Completed)
} else {
st, ok := up.Status().Value.(*edgeState)
if ok {
index := -1
if dep, ok := e.depRequests[up]; ok {
index = int(dep.index)
}
logrus.Debugf("> update-%d: %p input-%d keys=%d state=%s", i, up, index, len(st.keys), st.state)
} else {
logrus.Debugf("> update-%d: unknown", i)
}
}
}
}
func debugSchedulerPostUnpark(e *edge, inc []pipe.Sender) {
if !debugScheduler {
return
}
for i, in := range inc {
logrus.Debugf("< incoming-%d: %p completed=%v", i, in, in.Status().Completed)
}
logrus.Debugf("<< unpark %s\n", e.edge.Vertex.Name())
}