// Copyright 2018 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. // Package mvs implements Minimal Version Selection. // See https://research.swtch.com/vgo-mvs. package mvs import ( "fmt" "reflect" "sort" "sync" "cmd/go/internal/par" "golang.org/x/mod/module" ) // A Reqs is the requirement graph on which Minimal Version Selection (MVS) operates. // // The version strings are opaque except for the special version "none" // (see the documentation for module.Version). In particular, MVS does not // assume that the version strings are semantic versions; instead, the Max method // gives access to the comparison operation. // // It must be safe to call methods on a Reqs from multiple goroutines simultaneously. // Because a Reqs may read the underlying graph from the network on demand, // the MVS algorithms parallelize the traversal to overlap network delays. type Reqs interface { // Required returns the module versions explicitly required by m itself. // The caller must not modify the returned list. Required(m module.Version) ([]module.Version, error) // Max returns the maximum of v1 and v2 (it returns either v1 or v2). // // For all versions v, Max(v, "none") must be v, // and for the target passed as the first argument to MVS functions, // Max(target, v) must be target. // // Note that v1 < v2 can be written Max(v1, v2) != v1 // and similarly v1 <= v2 can be written Max(v1, v2) == v2. Max(v1, v2 string) string } // An UpgradeReqs is a Reqs that can also identify available upgrades. type UpgradeReqs interface { Reqs // Upgrade returns the upgraded version of m, // for use during an UpgradeAll operation. // If m should be kept as is, Upgrade returns m. // If m is not yet used in the build, then m.Version will be "none". // More typically, m.Version will be the version required // by some other module in the build. // // If no module version is available for the given path, // Upgrade returns a non-nil error. // TODO(rsc): Upgrade must be able to return errors, // but should "no latest version" just return m instead? Upgrade(m module.Version) (module.Version, error) } // A DowngradeReqs is a Reqs that can also identify available downgrades. type DowngradeReqs interface { Reqs // Previous returns the version of m.Path immediately prior to m.Version, // or "none" if no such version is known. Previous(m module.Version) (module.Version, error) } // BuildList returns the build list for the target module. // // target is the root vertex of a module requirement graph. For cmd/go, this is // typically the main module, but note that this algorithm is not intended to // be Go-specific: module paths and versions are treated as opaque values. // // reqs describes the module requirement graph and provides an opaque method // for comparing versions. // // BuildList traverses the graph and returns a list containing the highest // version for each visited module. The first element of the returned list is // target itself; reqs.Max requires target.Version to compare higher than all // other versions, so no other version can be selected. The remaining elements // of the list are sorted by path. // // See https://research.swtch.com/vgo-mvs for details. func BuildList(targets []module.Version, reqs Reqs) ([]module.Version, error) { return buildList(targets, reqs, nil) } func buildList(targets []module.Version, reqs Reqs, upgrade func(module.Version) (module.Version, error)) ([]module.Version, error) { cmp := func(v1, v2 string) int { if reqs.Max(v1, v2) != v1 { return -1 } if reqs.Max(v2, v1) != v2 { return 1 } return 0 } var ( mu sync.Mutex g = NewGraph(cmp, targets) upgrades = map[module.Version]module.Version{} errs = map[module.Version]error{} // (non-nil errors only) ) // Explore work graph in parallel in case reqs.Required // does high-latency network operations. var work par.Work for _, target := range targets { work.Add(target) } work.Do(10, func(item interface{}) { m := item.(module.Version) var required []module.Version var err error if m.Version != "none" { required, err = reqs.Required(m) } u := m if upgrade != nil { upgradeTo, upErr := upgrade(m) if upErr == nil { u = upgradeTo } else if err == nil { err = upErr } } mu.Lock() if err != nil { errs[m] = err } if u != m { upgrades[m] = u required = append([]module.Version{u}, required...) } g.Require(m, required) mu.Unlock() for _, r := range required { work.Add(r) } }) // If there was an error, find the shortest path from the target to the // node where the error occurred so we can report a useful error message. if len(errs) > 0 { errPath := g.FindPath(func(m module.Version) bool { return errs[m] != nil }) if len(errPath) == 0 { panic("internal error: could not reconstruct path to module with error") } err := errs[errPath[len(errPath)-1]] isUpgrade := func(from, to module.Version) bool { if u, ok := upgrades[from]; ok { return u == to } return false } return nil, NewBuildListError(err.(error), errPath, isUpgrade) } // The final list is the minimum version of each module found in the graph. list := g.BuildList() if vs := list[:len(targets)]; !reflect.DeepEqual(vs, targets) { // target.Version will be "" for modload, the main client of MVS. // "" denotes the main module, which has no version. However, MVS treats // version strings as opaque, so "" is not a special value here. // See golang.org/issue/31491, golang.org/issue/29773. panic(fmt.Sprintf("mistake: chose versions %+v instead of targets %+v", vs, targets)) } return list, nil } // Req returns the minimal requirement list for the target module, // with the constraint that all module paths listed in base must // appear in the returned list. func Req(mainModule module.Version, base []string, reqs Reqs) ([]module.Version, error) { list, err := BuildList([]module.Version{mainModule}, reqs) if err != nil { return nil, err } // Note: Not running in parallel because we assume // that list came from a previous operation that paged // in all the requirements, so there's no I/O to overlap now. // Compute postorder, cache requirements. var postorder []module.Version reqCache := map[module.Version][]module.Version{} reqCache[mainModule] = nil var walk func(module.Version) error walk = func(m module.Version) error { _, ok := reqCache[m] if ok { return nil } required, err := reqs.Required(m) if err != nil { return err } reqCache[m] = required for _, m1 := range required { if err := walk(m1); err != nil { return err } } postorder = append(postorder, m) return nil } for _, m := range list { if err := walk(m); err != nil { return nil, err } } // Walk modules in reverse post-order, only adding those not implied already. have := map[module.Version]bool{} walk = func(m module.Version) error { if have[m] { return nil } have[m] = true for _, m1 := range reqCache[m] { walk(m1) } return nil } max := map[string]string{} for _, m := range list { if v, ok := max[m.Path]; ok { max[m.Path] = reqs.Max(m.Version, v) } else { max[m.Path] = m.Version } } // First walk the base modules that must be listed. var min []module.Version haveBase := map[string]bool{} for _, path := range base { if haveBase[path] { continue } m := module.Version{Path: path, Version: max[path]} min = append(min, m) walk(m) haveBase[path] = true } // Now the reverse postorder to bring in anything else. for i := len(postorder) - 1; i >= 0; i-- { m := postorder[i] if max[m.Path] != m.Version { // Older version. continue } if !have[m] { min = append(min, m) walk(m) } } sort.Slice(min, func(i, j int) bool { return min[i].Path < min[j].Path }) return min, nil } // UpgradeAll returns a build list for the target module // in which every module is upgraded to its latest version. func UpgradeAll(target module.Version, reqs UpgradeReqs) ([]module.Version, error) { return buildList([]module.Version{target}, reqs, func(m module.Version) (module.Version, error) { if m.Path == target.Path { return target, nil } return reqs.Upgrade(m) }) } // Upgrade returns a build list for the target module // in which the given additional modules are upgraded. func Upgrade(target module.Version, reqs UpgradeReqs, upgrade ...module.Version) ([]module.Version, error) { list, err := reqs.Required(target) if err != nil { return nil, err } pathInList := make(map[string]bool, len(list)) for _, m := range list { pathInList[m.Path] = true } list = append([]module.Version(nil), list...) upgradeTo := make(map[string]string, len(upgrade)) for _, u := range upgrade { if !pathInList[u.Path] { list = append(list, module.Version{Path: u.Path, Version: "none"}) } if prev, dup := upgradeTo[u.Path]; dup { upgradeTo[u.Path] = reqs.Max(prev, u.Version) } else { upgradeTo[u.Path] = u.Version } } return buildList([]module.Version{target}, &override{target, list, reqs}, func(m module.Version) (module.Version, error) { if v, ok := upgradeTo[m.Path]; ok { return module.Version{Path: m.Path, Version: v}, nil } return m, nil }) } // Downgrade returns a build list for the target module // in which the given additional modules are downgraded, // potentially overriding the requirements of the target. // // The versions to be downgraded may be unreachable from reqs.Latest and // reqs.Previous, but the methods of reqs must otherwise handle such versions // correctly. func Downgrade(target module.Version, reqs DowngradeReqs, downgrade ...module.Version) ([]module.Version, error) { // Per https://research.swtch.com/vgo-mvs#algorithm_4: // “To avoid an unnecessary downgrade to E 1.1, we must also add a new // requirement on E 1.2. We can apply Algorithm R to find the minimal set of // new requirements to write to go.mod.” // // In order to generate those new requirements, we need to identify versions // for every module in the build list — not just reqs.Required(target). list, err := BuildList([]module.Version{target}, reqs) if err != nil { return nil, err } list = list[1:] // remove target max := make(map[string]string) for _, r := range list { max[r.Path] = r.Version } for _, d := range downgrade { if v, ok := max[d.Path]; !ok || reqs.Max(v, d.Version) != d.Version { max[d.Path] = d.Version } } var ( added = make(map[module.Version]bool) rdeps = make(map[module.Version][]module.Version) excluded = make(map[module.Version]bool) ) var exclude func(module.Version) exclude = func(m module.Version) { if excluded[m] { return } excluded[m] = true for _, p := range rdeps[m] { exclude(p) } } var add func(module.Version) add = func(m module.Version) { if added[m] { return } added[m] = true if v, ok := max[m.Path]; ok && reqs.Max(m.Version, v) != v { // m would upgrade an existing dependency — it is not a strict downgrade, // and because it was already present as a dependency, it could affect the // behavior of other relevant packages. exclude(m) return } list, err := reqs.Required(m) if err != nil { // If we can't load the requirements, we couldn't load the go.mod file. // There are a number of reasons this can happen, but this usually // means an older version of the module had a missing or invalid // go.mod file. For example, if example.com/mod released v2.0.0 before // migrating to modules (v2.0.0+incompatible), then added a valid go.mod // in v2.0.1, downgrading from v2.0.1 would cause this error. // // TODO(golang.org/issue/31730, golang.org/issue/30134): if the error // is transient (we couldn't download go.mod), return the error from // Downgrade. Currently, we can't tell what kind of error it is. exclude(m) return } for _, r := range list { add(r) if excluded[r] { exclude(m) return } rdeps[r] = append(rdeps[r], m) } } downgraded := make([]module.Version, 0, len(list)+1) downgraded = append(downgraded, target) List: for _, r := range list { add(r) for excluded[r] { p, err := reqs.Previous(r) if err != nil { // This is likely a transient error reaching the repository, // rather than a permanent error with the retrieved version. // // TODO(golang.org/issue/31730, golang.org/issue/30134): // decode what to do based on the actual error. return nil, err } // If the target version is a pseudo-version, it may not be // included when iterating over prior versions using reqs.Previous. // Insert it into the right place in the iteration. // If v is excluded, p should be returned again by reqs.Previous on the next iteration. if v := max[r.Path]; reqs.Max(v, r.Version) != v && reqs.Max(p.Version, v) != p.Version { p.Version = v } if p.Version == "none" { continue List } add(p) r = p } downgraded = append(downgraded, r) } // The downgrades we computed above only downgrade to versions enumerated by // reqs.Previous. However, reqs.Previous omits some versions — such as // pseudo-versions and retracted versions — that may be selected as transitive // requirements of other modules. // // If one of those requirements pulls the version back up above the version // identified by reqs.Previous, then the transitive dependencies of that that // initially-downgraded version should no longer matter — in particular, we // should not add new dependencies on module paths that nothing else in the // updated module graph even requires. // // In order to eliminate those spurious dependencies, we recompute the build // list with the actual versions of the downgraded modules as selected by MVS, // instead of our initial downgrades. // (See the downhiddenartifact and downhiddencross test cases). actual, err := BuildList([]module.Version{target}, &override{ target: target, list: downgraded, Reqs: reqs, }) if err != nil { return nil, err } actualVersion := make(map[string]string, len(actual)) for _, m := range actual { actualVersion[m.Path] = m.Version } downgraded = downgraded[:0] for _, m := range list { if v, ok := actualVersion[m.Path]; ok { downgraded = append(downgraded, module.Version{Path: m.Path, Version: v}) } } return BuildList([]module.Version{target}, &override{ target: target, list: downgraded, Reqs: reqs, }) } type override struct { target module.Version list []module.Version Reqs } func (r *override) Required(m module.Version) ([]module.Version, error) { if m == r.target { return r.list, nil } return r.Reqs.Required(m) }