buildkit/solver/jobs.go

991 lines
22 KiB
Go

package solver
import (
"context"
"fmt"
"strings"
"sync"
"time"
"github.com/moby/buildkit/client"
"github.com/moby/buildkit/identity"
"github.com/moby/buildkit/session"
"github.com/moby/buildkit/solver/errdefs"
"github.com/moby/buildkit/util/flightcontrol"
"github.com/moby/buildkit/util/progress"
"github.com/moby/buildkit/util/tracing"
digest "github.com/opencontainers/go-digest"
"github.com/pkg/errors"
"go.opentelemetry.io/otel/trace"
)
// ResolveOpFunc finds an Op implementation for a Vertex
type ResolveOpFunc func(Vertex, Builder) (Op, error)
type Builder interface {
Build(ctx context.Context, e Edge) (CachedResult, BuildSources, error)
InContext(ctx context.Context, f func(ctx context.Context, g session.Group) error) error
EachValue(ctx context.Context, key string, fn func(interface{}) error) error
}
// Solver provides a shared graph of all the vertexes currently being
// processed. Every vertex that is being solved needs to be loaded into job
// first. Vertex operations are invoked and progress tracking happens through
// jobs.
type Solver struct {
mu sync.RWMutex
jobs map[string]*Job
actives map[digest.Digest]*state
opts SolverOpt
updateCond *sync.Cond
s *scheduler
index *edgeIndex
}
type state struct {
jobs map[*Job]struct{}
parents map[digest.Digest]struct{}
childVtx map[digest.Digest]struct{}
mpw *progress.MultiWriter
allPw map[progress.Writer]struct{}
mspan *tracing.MultiSpan
vtx Vertex
clientVertex client.Vertex
origDigest digest.Digest // original LLB digest. TODO: probably better to use string ID so this isn't needed
mu sync.Mutex
op *sharedOp
edges map[Index]*edge
opts SolverOpt
index *edgeIndex
cache map[string]CacheManager
mainCache CacheManager
solver *Solver
}
func (s *state) SessionIterator() session.Iterator {
return s.sessionIterator()
}
func (s *state) sessionIterator() *sessionGroup {
return &sessionGroup{state: s, visited: map[string]struct{}{}}
}
type sessionGroup struct {
*state
visited map[string]struct{}
parents []session.Iterator
mode int
}
func (g *sessionGroup) NextSession() string {
if g.mode == 0 {
g.mu.Lock()
for j := range g.jobs {
if j.SessionID != "" {
if _, ok := g.visited[j.SessionID]; ok {
continue
}
g.visited[j.SessionID] = struct{}{}
g.mu.Unlock()
return j.SessionID
}
}
g.mu.Unlock()
g.mode = 1
}
if g.mode == 1 {
parents := map[digest.Digest]struct{}{}
g.mu.Lock()
for p := range g.state.parents {
parents[p] = struct{}{}
}
g.mu.Unlock()
for p := range parents {
g.solver.mu.Lock()
pst, ok := g.solver.actives[p]
g.solver.mu.Unlock()
if ok {
gg := pst.sessionIterator()
gg.visited = g.visited
g.parents = append(g.parents, gg)
}
}
g.mode = 2
}
for {
if len(g.parents) == 0 {
return ""
}
p := g.parents[0]
id := p.NextSession()
if id != "" {
return id
}
g.parents = g.parents[1:]
}
}
func (s *state) builder() *subBuilder {
return &subBuilder{state: s}
}
func (s *state) getEdge(index Index) *edge {
s.mu.Lock()
defer s.mu.Unlock()
if e, ok := s.edges[index]; ok {
return e
}
if s.op == nil {
s.op = newSharedOp(s.opts.ResolveOpFunc, s.opts.DefaultCache, s)
}
e := newEdge(Edge{Index: index, Vertex: s.vtx}, s.op, s.index)
s.edges[index] = e
return e
}
func (s *state) setEdge(index Index, newEdge *edge) {
s.mu.Lock()
defer s.mu.Unlock()
e, ok := s.edges[index]
if ok {
if e == newEdge {
return
}
e.release()
}
newEdge.incrementReferenceCount()
s.edges[index] = newEdge
}
func (s *state) combinedCacheManager() CacheManager {
s.mu.Lock()
cms := make([]CacheManager, 0, len(s.cache)+1)
cms = append(cms, s.mainCache)
for _, cm := range s.cache {
cms = append(cms, cm)
}
s.mu.Unlock()
if len(cms) == 1 {
return s.mainCache
}
return NewCombinedCacheManager(cms, s.mainCache)
}
func (s *state) Release() {
for _, e := range s.edges {
e.release()
}
if s.op != nil {
s.op.release()
}
}
type subBuilder struct {
*state
mu sync.Mutex
exporters []ExportableCacheKey
}
func (sb *subBuilder) Build(ctx context.Context, e Edge) (CachedResult, BuildSources, error) {
// TODO(@crazy-max): Handle BuildInfo from subbuild
res, err := sb.solver.subBuild(ctx, e, sb.vtx)
if err != nil {
return nil, nil, err
}
sb.mu.Lock()
sb.exporters = append(sb.exporters, res.CacheKeys()[0]) // all keys already have full export chain
sb.mu.Unlock()
return res, nil, nil
}
func (sb *subBuilder) InContext(ctx context.Context, f func(context.Context, session.Group) error) error {
ctx = progress.WithProgress(ctx, sb.mpw)
if sb.mspan.Span != nil {
ctx = trace.ContextWithSpan(ctx, sb.mspan)
}
return f(ctx, sb.state)
}
func (sb *subBuilder) EachValue(ctx context.Context, key string, fn func(interface{}) error) error {
sb.mu.Lock()
defer sb.mu.Unlock()
for j := range sb.jobs {
if err := j.EachValue(ctx, key, fn); err != nil {
return err
}
}
return nil
}
type Job struct {
list *Solver
pr *progress.MultiReader
pw progress.Writer
span trace.Span
values sync.Map
id string
progressCloser func()
SessionID string
}
type SolverOpt struct {
ResolveOpFunc ResolveOpFunc
DefaultCache CacheManager
}
func NewSolver(opts SolverOpt) *Solver {
if opts.DefaultCache == nil {
opts.DefaultCache = NewInMemoryCacheManager()
}
jl := &Solver{
jobs: make(map[string]*Job),
actives: make(map[digest.Digest]*state),
opts: opts,
index: newEdgeIndex(),
}
jl.s = newScheduler(jl)
jl.updateCond = sync.NewCond(jl.mu.RLocker())
return jl
}
func (jl *Solver) setEdge(e Edge, newEdge *edge) {
jl.mu.RLock()
defer jl.mu.RUnlock()
st, ok := jl.actives[e.Vertex.Digest()]
if !ok {
return
}
st.setEdge(e.Index, newEdge)
}
func (jl *Solver) getState(e Edge) *state {
jl.mu.RLock()
defer jl.mu.RUnlock()
st, ok := jl.actives[e.Vertex.Digest()]
if !ok {
return nil
}
return st
}
func (jl *Solver) getEdge(e Edge) *edge {
jl.mu.RLock()
defer jl.mu.RUnlock()
st, ok := jl.actives[e.Vertex.Digest()]
if !ok {
return nil
}
return st.getEdge(e.Index)
}
func (jl *Solver) subBuild(ctx context.Context, e Edge, parent Vertex) (CachedResult, error) {
v, err := jl.load(e.Vertex, parent, nil)
if err != nil {
return nil, err
}
e.Vertex = v
return jl.s.build(ctx, e)
}
func (jl *Solver) Close() {
jl.s.Stop()
}
func (jl *Solver) load(v, parent Vertex, j *Job) (Vertex, error) {
jl.mu.Lock()
defer jl.mu.Unlock()
cache := map[Vertex]Vertex{}
return jl.loadUnlocked(v, parent, j, cache)
}
func (jl *Solver) loadUnlocked(v, parent Vertex, j *Job, cache map[Vertex]Vertex) (Vertex, error) {
if v, ok := cache[v]; ok {
return v, nil
}
origVtx := v
inputs := make([]Edge, len(v.Inputs()))
for i, e := range v.Inputs() {
v, err := jl.loadUnlocked(e.Vertex, parent, j, cache)
if err != nil {
return nil, err
}
inputs[i] = Edge{Index: e.Index, Vertex: v}
}
dgst := v.Digest()
dgstWithoutCache := digest.FromBytes([]byte(fmt.Sprintf("%s-ignorecache", dgst)))
// if same vertex is already loaded without cache just use that
st, ok := jl.actives[dgstWithoutCache]
if !ok {
st, ok = jl.actives[dgst]
// !ignorecache merges with ignorecache but ignorecache doesn't merge with !ignorecache
if ok && !st.vtx.Options().IgnoreCache && v.Options().IgnoreCache {
dgst = dgstWithoutCache
}
v = &vertexWithCacheOptions{
Vertex: v,
dgst: dgst,
inputs: inputs,
}
st, ok = jl.actives[dgst]
}
if !ok {
st = &state{
opts: jl.opts,
jobs: map[*Job]struct{}{},
parents: map[digest.Digest]struct{}{},
childVtx: map[digest.Digest]struct{}{},
allPw: map[progress.Writer]struct{}{},
mpw: progress.NewMultiWriter(progress.WithMetadata("vertex", dgst)),
mspan: tracing.NewMultiSpan(),
vtx: v,
clientVertex: initClientVertex(v),
edges: map[Index]*edge{},
index: jl.index,
mainCache: jl.opts.DefaultCache,
cache: map[string]CacheManager{},
solver: jl,
origDigest: origVtx.Digest(),
}
jl.actives[dgst] = st
}
st.mu.Lock()
for _, cache := range v.Options().CacheSources {
if cache.ID() != st.mainCache.ID() {
if _, ok := st.cache[cache.ID()]; !ok {
st.cache[cache.ID()] = cache
}
}
}
if j != nil {
if _, ok := st.jobs[j]; !ok {
st.jobs[j] = struct{}{}
}
}
st.mu.Unlock()
if parent != nil {
if _, ok := st.parents[parent.Digest()]; !ok {
st.parents[parent.Digest()] = struct{}{}
parentState, ok := jl.actives[parent.Digest()]
if !ok {
return nil, errors.Errorf("inactive parent %s", parent.Digest())
}
parentState.childVtx[dgst] = struct{}{}
for id, c := range parentState.cache {
st.cache[id] = c
}
}
}
jl.connectProgressFromState(st, st)
cache[origVtx] = v
return v, nil
}
func (jl *Solver) connectProgressFromState(target, src *state) {
for j := range src.jobs {
if _, ok := target.allPw[j.pw]; !ok {
target.mpw.Add(j.pw)
target.allPw[j.pw] = struct{}{}
j.pw.Write(identity.NewID(), target.clientVertex)
if j.span != nil && j.span.SpanContext().IsValid() {
target.mspan.Add(j.span)
}
}
}
for p := range src.parents {
jl.connectProgressFromState(target, jl.actives[p])
}
}
func (jl *Solver) NewJob(id string) (*Job, error) {
jl.mu.Lock()
defer jl.mu.Unlock()
if _, ok := jl.jobs[id]; ok {
return nil, errors.Errorf("job ID %s exists", id)
}
pr, ctx, progressCloser := progress.NewContext(context.Background())
pw, _, _ := progress.NewFromContext(ctx) // TODO: expose progress.Pipe()
_, span := trace.NewNoopTracerProvider().Tracer("").Start(ctx, "")
j := &Job{
list: jl,
pr: progress.NewMultiReader(pr),
pw: pw,
progressCloser: progressCloser,
span: span,
id: id,
}
jl.jobs[id] = j
jl.updateCond.Broadcast()
return j, nil
}
func (jl *Solver) Get(id string) (*Job, error) {
ctx, cancel := context.WithTimeout(context.Background(), 6*time.Second)
defer cancel()
go func() {
<-ctx.Done()
jl.mu.Lock()
jl.updateCond.Broadcast()
jl.mu.Unlock()
}()
jl.mu.RLock()
defer jl.mu.RUnlock()
for {
select {
case <-ctx.Done():
return nil, errors.Errorf("no such job %s", id)
default:
}
j, ok := jl.jobs[id]
if !ok {
jl.updateCond.Wait()
continue
}
return j, nil
}
}
// called with solver lock
func (jl *Solver) deleteIfUnreferenced(k digest.Digest, st *state) {
if len(st.jobs) == 0 && len(st.parents) == 0 {
for chKey := range st.childVtx {
chState := jl.actives[chKey]
delete(chState.parents, k)
jl.deleteIfUnreferenced(chKey, chState)
}
st.Release()
delete(jl.actives, k)
}
}
func (j *Job) Build(ctx context.Context, e Edge) (CachedResult, BuildSources, error) {
if span := trace.SpanFromContext(ctx); span.SpanContext().IsValid() {
j.span = span
}
v, err := j.list.load(e.Vertex, nil, j)
if err != nil {
return nil, nil, err
}
e.Vertex = v
res, err := j.list.s.build(ctx, e)
if err != nil {
return nil, nil, err
}
j.list.mu.Lock()
defer j.list.mu.Unlock()
return res, j.walkBuildSources(ctx, e, make(BuildSources)), nil
}
func (j *Job) walkBuildSources(ctx context.Context, e Edge, bsrc BuildSources) BuildSources {
for _, inp := range e.Vertex.Inputs() {
if st, ok := j.list.actives[inp.Vertex.Digest()]; ok {
st.mu.Lock()
for _, cacheRes := range st.op.cacheRes {
for key, val := range cacheRes.BuildSources {
if _, ok := bsrc[key]; !ok {
bsrc[key] = val
}
}
}
st.mu.Unlock()
bsrc = j.walkBuildSources(ctx, inp, bsrc)
}
}
return bsrc
}
func (j *Job) Discard() error {
defer j.progressCloser()
j.list.mu.Lock()
defer j.list.mu.Unlock()
j.pw.Close()
for k, st := range j.list.actives {
st.mu.Lock()
if _, ok := st.jobs[j]; ok {
delete(st.jobs, j)
j.list.deleteIfUnreferenced(k, st)
}
if _, ok := st.allPw[j.pw]; ok {
delete(st.allPw, j.pw)
}
st.mu.Unlock()
}
go func() {
// don't clear job right away. there might still be a status request coming to read progress
time.Sleep(10 * time.Second)
j.list.mu.Lock()
defer j.list.mu.Unlock()
delete(j.list.jobs, j.id)
}()
return nil
}
func (j *Job) InContext(ctx context.Context, f func(context.Context, session.Group) error) error {
return f(progress.WithProgress(ctx, j.pw), session.NewGroup(j.SessionID))
}
func (j *Job) SetValue(key string, v interface{}) {
j.values.Store(key, v)
}
func (j *Job) EachValue(ctx context.Context, key string, fn func(interface{}) error) error {
v, ok := j.values.Load(key)
if ok {
return fn(v)
}
return nil
}
type cacheMapResp struct {
*CacheMap
complete bool
}
type activeOp interface {
CacheMap(context.Context, int) (*cacheMapResp, error)
LoadCache(ctx context.Context, rec *CacheRecord) (Result, error)
Exec(ctx context.Context, inputs []Result) (outputs []Result, exporters []ExportableCacheKey, err error)
IgnoreCache() bool
Cache() CacheManager
CalcSlowCache(context.Context, Index, PreprocessFunc, ResultBasedCacheFunc, Result) (digest.Digest, error)
}
func newSharedOp(resolver ResolveOpFunc, cacheManager CacheManager, st *state) *sharedOp {
so := &sharedOp{
resolver: resolver,
st: st,
slowCacheRes: map[Index]digest.Digest{},
slowCacheErr: map[Index]error{},
}
return so
}
type execRes struct {
execRes []*SharedResult
execExporters []ExportableCacheKey
}
type sharedOp struct {
resolver ResolveOpFunc
st *state
g flightcontrol.Group
opOnce sync.Once
op Op
subBuilder *subBuilder
err error
execRes *execRes
execErr error
cacheRes []*CacheMap
cacheDone bool
cacheErr error
slowMu sync.Mutex
slowCacheRes map[Index]digest.Digest
slowCacheErr map[Index]error
}
func (s *sharedOp) IgnoreCache() bool {
return s.st.vtx.Options().IgnoreCache
}
func (s *sharedOp) Cache() CacheManager {
return s.st.combinedCacheManager()
}
func (s *sharedOp) LoadCache(ctx context.Context, rec *CacheRecord) (Result, error) {
ctx = progress.WithProgress(ctx, s.st.mpw)
if s.st.mspan.Span != nil {
ctx = trace.ContextWithSpan(ctx, s.st.mspan)
}
// no cache hit. start evaluating the node
span, ctx := tracing.StartSpan(ctx, "load cache: "+s.st.vtx.Name())
notifyCompleted := notifyStarted(ctx, &s.st.clientVertex, true)
res, err := s.Cache().Load(withAncestorCacheOpts(ctx, s.st), rec)
tracing.FinishWithError(span, err)
notifyCompleted(err, true)
return res, err
}
// CalcSlowCache computes the digest of an input that is ready and has been
// evaluated, hence "slow" cache.
func (s *sharedOp) CalcSlowCache(ctx context.Context, index Index, p PreprocessFunc, f ResultBasedCacheFunc, res Result) (dgst digest.Digest, err error) {
defer func() {
err = WrapSlowCache(err, index, NewSharedResult(res).Clone())
err = errdefs.WithOp(err, s.st.vtx.Sys())
err = errdefs.WrapVertex(err, s.st.origDigest)
}()
flightControlKey := fmt.Sprintf("slow-compute-%d", index)
key, err := s.g.Do(ctx, flightControlKey, func(ctx context.Context) (interface{}, error) {
s.slowMu.Lock()
// TODO: add helpers for these stored values
if res, ok := s.slowCacheRes[index]; ok {
s.slowMu.Unlock()
return res, nil
}
if err := s.slowCacheErr[index]; err != nil {
s.slowMu.Unlock()
return nil, err
}
s.slowMu.Unlock()
complete := true
if p != nil {
st := s.st.solver.getState(s.st.vtx.Inputs()[index])
if st == nil {
return nil, errors.Errorf("failed to get state for index %d on %v", index, s.st.vtx.Name())
}
ctx2 := progress.WithProgress(ctx, st.mpw)
if st.mspan.Span != nil {
ctx2 = trace.ContextWithSpan(ctx2, st.mspan)
}
err = p(ctx2, res, st)
if err != nil {
f = nil
ctx = ctx2
}
}
var key digest.Digest
if f != nil {
ctx = progress.WithProgress(ctx, s.st.mpw)
if s.st.mspan.Span != nil {
ctx = trace.ContextWithSpan(ctx, s.st.mspan)
}
key, err = f(withAncestorCacheOpts(ctx, s.st), res, s.st)
}
if err != nil {
select {
case <-ctx.Done():
if strings.Contains(err.Error(), context.Canceled.Error()) {
complete = false
releaseError(err)
err = errors.Wrap(ctx.Err(), err.Error())
}
default:
}
}
s.slowMu.Lock()
defer s.slowMu.Unlock()
if complete {
if err == nil {
s.slowCacheRes[index] = key
}
s.slowCacheErr[index] = err
}
return key, err
})
if err != nil {
ctx = progress.WithProgress(ctx, s.st.mpw)
if s.st.mspan.Span != nil {
ctx = trace.ContextWithSpan(ctx, s.st.mspan)
}
notifyCompleted := notifyStarted(ctx, &s.st.clientVertex, false)
notifyCompleted(err, false)
return "", err
}
return key.(digest.Digest), nil
}
func (s *sharedOp) CacheMap(ctx context.Context, index int) (resp *cacheMapResp, err error) {
defer func() {
err = errdefs.WithOp(err, s.st.vtx.Sys())
err = errdefs.WrapVertex(err, s.st.origDigest)
}()
op, err := s.getOp()
if err != nil {
return nil, err
}
flightControlKey := fmt.Sprintf("cachemap-%d", index)
res, err := s.g.Do(ctx, flightControlKey, func(ctx context.Context) (ret interface{}, retErr error) {
if s.cacheRes != nil && s.cacheDone || index < len(s.cacheRes) {
return s.cacheRes, nil
}
if s.cacheErr != nil {
return nil, s.cacheErr
}
ctx = progress.WithProgress(ctx, s.st.mpw)
if s.st.mspan.Span != nil {
ctx = trace.ContextWithSpan(ctx, s.st.mspan)
}
ctx = withAncestorCacheOpts(ctx, s.st)
if len(s.st.vtx.Inputs()) == 0 {
// no cache hit. start evaluating the node
span, ctx := tracing.StartSpan(ctx, "cache request: "+s.st.vtx.Name())
notifyCompleted := notifyStarted(ctx, &s.st.clientVertex, false)
defer func() {
tracing.FinishWithError(span, retErr)
notifyCompleted(retErr, false)
}()
}
res, done, err := op.CacheMap(ctx, s.st, len(s.cacheRes))
complete := true
if err != nil {
select {
case <-ctx.Done():
if strings.Contains(err.Error(), context.Canceled.Error()) {
complete = false
releaseError(err)
err = errors.Wrap(ctx.Err(), err.Error())
}
default:
}
}
if complete {
if err == nil {
s.cacheRes = append(s.cacheRes, res)
s.cacheDone = done
}
s.cacheErr = err
}
return s.cacheRes, err
})
if err != nil {
return nil, err
}
if len(res.([]*CacheMap)) <= index {
return s.CacheMap(ctx, index)
}
return &cacheMapResp{CacheMap: res.([]*CacheMap)[index], complete: s.cacheDone}, nil
}
func (s *sharedOp) Exec(ctx context.Context, inputs []Result) (outputs []Result, exporters []ExportableCacheKey, err error) {
defer func() {
err = errdefs.WithOp(err, s.st.vtx.Sys())
err = errdefs.WrapVertex(err, s.st.origDigest)
}()
op, err := s.getOp()
if err != nil {
return nil, nil, err
}
flightControlKey := "exec"
res, err := s.g.Do(ctx, flightControlKey, func(ctx context.Context) (ret interface{}, retErr error) {
if s.execRes != nil || s.execErr != nil {
return s.execRes, s.execErr
}
release, err := op.Acquire(ctx)
if err != nil {
return nil, errors.Wrap(err, "acquire op resources")
}
defer release()
ctx = progress.WithProgress(ctx, s.st.mpw)
if s.st.mspan.Span != nil {
ctx = trace.ContextWithSpan(ctx, s.st.mspan)
}
ctx = withAncestorCacheOpts(ctx, s.st)
// no cache hit. start evaluating the node
span, ctx := tracing.StartSpan(ctx, s.st.vtx.Name())
notifyCompleted := notifyStarted(ctx, &s.st.clientVertex, false)
defer func() {
tracing.FinishWithError(span, retErr)
notifyCompleted(retErr, false)
}()
res, err := op.Exec(ctx, s.st, inputs)
complete := true
if err != nil {
select {
case <-ctx.Done():
if strings.Contains(err.Error(), context.Canceled.Error()) {
complete = false
releaseError(err)
err = errors.Wrap(ctx.Err(), err.Error())
}
default:
}
}
if complete {
if res != nil {
var subExporters []ExportableCacheKey
s.subBuilder.mu.Lock()
if len(s.subBuilder.exporters) > 0 {
subExporters = append(subExporters, s.subBuilder.exporters...)
}
s.subBuilder.mu.Unlock()
s.execRes = &execRes{execRes: wrapShared(res), execExporters: subExporters}
}
s.execErr = err
}
return s.execRes, err
})
if err != nil {
return nil, nil, err
}
r := res.(*execRes)
return unwrapShared(r.execRes), r.execExporters, nil
}
func (s *sharedOp) getOp() (Op, error) {
s.opOnce.Do(func() {
s.subBuilder = s.st.builder()
s.op, s.err = s.resolver(s.st.vtx, s.subBuilder)
})
if s.err != nil {
return nil, s.err
}
return s.op, nil
}
func (s *sharedOp) release() {
if s.execRes != nil {
for _, r := range s.execRes.execRes {
go r.Release(context.TODO())
}
}
}
func initClientVertex(v Vertex) client.Vertex {
inputDigests := make([]digest.Digest, 0, len(v.Inputs()))
for _, inp := range v.Inputs() {
inputDigests = append(inputDigests, inp.Vertex.Digest())
}
return client.Vertex{
Inputs: inputDigests,
Name: v.Name(),
Digest: v.Digest(),
ProgressGroup: v.Options().ProgressGroup,
}
}
func wrapShared(inp []Result) []*SharedResult {
out := make([]*SharedResult, len(inp))
for i, r := range inp {
out[i] = NewSharedResult(r)
}
return out
}
func unwrapShared(inp []*SharedResult) []Result {
out := make([]Result, len(inp))
for i, r := range inp {
out[i] = r.Clone()
}
return out
}
type vertexWithCacheOptions struct {
Vertex
inputs []Edge
dgst digest.Digest
}
func (v *vertexWithCacheOptions) Digest() digest.Digest {
return v.dgst
}
func (v *vertexWithCacheOptions) Inputs() []Edge {
return v.inputs
}
func notifyStarted(ctx context.Context, v *client.Vertex, cached bool) func(err error, cached bool) {
pw, _, _ := progress.NewFromContext(ctx)
start := time.Now()
v.Started = &start
v.Completed = nil
v.Cached = cached
id := identity.NewID()
pw.Write(id, *v)
return func(err error, cached bool) {
defer pw.Close()
stop := time.Now()
v.Completed = &stop
v.Cached = cached
if err != nil {
v.Error = err.Error()
} else {
v.Error = ""
}
pw.Write(id, *v)
}
}
type SlowCacheError struct {
error
Index Index
Result Result
}
func (e *SlowCacheError) Unwrap() error {
return e.error
}
func (e *SlowCacheError) ToSubject() errdefs.IsSolve_Subject {
return &errdefs.Solve_Cache{
Cache: &errdefs.ContentCache{
Index: int64(e.Index),
},
}
}
func WrapSlowCache(err error, index Index, res Result) error {
if err == nil {
return nil
}
return &SlowCacheError{Index: index, Result: res, error: err}
}
func releaseError(err error) {
if err == nil {
return
}
if re, ok := err.(interface {
Release() error
}); ok {
re.Release()
}
releaseError(errors.Unwrap(err))
}