// 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 modfetch import ( "archive/zip" "bytes" "errors" "fmt" "io" "io/fs" "os" "path" "sort" "strings" "time" "cmd/go/internal/modfetch/codehost" "golang.org/x/mod/modfile" "golang.org/x/mod/module" "golang.org/x/mod/semver" modzip "golang.org/x/mod/zip" ) // A codeRepo implements modfetch.Repo using an underlying codehost.Repo. type codeRepo struct { modPath string // code is the repository containing this module. code codehost.Repo // codeRoot is the import path at the root of code. codeRoot string // codeDir is the directory (relative to root) at which we expect to find the module. // If pathMajor is non-empty and codeRoot is not the full modPath, // then we look in both codeDir and codeDir/pathMajor[1:]. codeDir string // pathMajor is the suffix of modPath that indicates its major version, // or the empty string if modPath is at major version 0 or 1. // // pathMajor is typically of the form "/vN", but possibly ".vN", or // ".vN-unstable" for modules resolved using gopkg.in. pathMajor string // pathPrefix is the prefix of modPath that excludes pathMajor. // It is used only for logging. pathPrefix string // pseudoMajor is the major version prefix to require when generating // pseudo-versions for this module, derived from the module path. pseudoMajor // is empty if the module path does not include a version suffix (that is, // accepts either v0 or v1). pseudoMajor string } // newCodeRepo returns a Repo that reads the source code for the module with the // given path, from the repo stored in code, with the root of the repo // containing the path given by codeRoot. func newCodeRepo(code codehost.Repo, codeRoot, path string) (Repo, error) { if !hasPathPrefix(path, codeRoot) { return nil, fmt.Errorf("mismatched repo: found %s for %s", codeRoot, path) } pathPrefix, pathMajor, ok := module.SplitPathVersion(path) if !ok { return nil, fmt.Errorf("invalid module path %q", path) } if codeRoot == path { pathPrefix = path } pseudoMajor := module.PathMajorPrefix(pathMajor) // Compute codeDir = bar, the subdirectory within the repo // corresponding to the module root. // // At this point we might have: // path = github.com/rsc/foo/bar/v2 // codeRoot = github.com/rsc/foo // pathPrefix = github.com/rsc/foo/bar // pathMajor = /v2 // pseudoMajor = v2 // // which gives // codeDir = bar // // We know that pathPrefix is a prefix of path, and codeRoot is a prefix of // path, but codeRoot may or may not be a prefix of pathPrefix, because // codeRoot may be the entire path (in which case codeDir should be empty). // That occurs in two situations. // // One is when a go-import meta tag resolves the complete module path, // including the pathMajor suffix: // path = nanomsg.org/go/mangos/v2 // codeRoot = nanomsg.org/go/mangos/v2 // pathPrefix = nanomsg.org/go/mangos // pathMajor = /v2 // pseudoMajor = v2 // // The other is similar: for gopkg.in only, the major version is encoded // with a dot rather than a slash, and thus can't be in a subdirectory. // path = gopkg.in/yaml.v2 // codeRoot = gopkg.in/yaml.v2 // pathPrefix = gopkg.in/yaml // pathMajor = .v2 // pseudoMajor = v2 // codeDir := "" if codeRoot != path { if !hasPathPrefix(pathPrefix, codeRoot) { return nil, fmt.Errorf("repository rooted at %s cannot contain module %s", codeRoot, path) } codeDir = strings.Trim(pathPrefix[len(codeRoot):], "/") } r := &codeRepo{ modPath: path, code: code, codeRoot: codeRoot, codeDir: codeDir, pathPrefix: pathPrefix, pathMajor: pathMajor, pseudoMajor: pseudoMajor, } return r, nil } func (r *codeRepo) ModulePath() string { return r.modPath } func (r *codeRepo) Versions(prefix string) ([]string, error) { // Special case: gopkg.in/macaroon-bakery.v2-unstable // does not use the v2 tags (those are for macaroon-bakery.v2). // It has no possible tags at all. if strings.HasPrefix(r.modPath, "gopkg.in/") && strings.HasSuffix(r.modPath, "-unstable") { return nil, nil } p := prefix if r.codeDir != "" { p = r.codeDir + "/" + p } tags, err := r.code.Tags(p) if err != nil { return nil, &module.ModuleError{ Path: r.modPath, Err: err, } } var list, incompatible []string for _, tag := range tags { if !strings.HasPrefix(tag, p) { continue } v := tag if r.codeDir != "" { v = v[len(r.codeDir)+1:] } if v == "" || v != module.CanonicalVersion(v) || module.IsPseudoVersion(v) { continue } if err := module.CheckPathMajor(v, r.pathMajor); err != nil { if r.codeDir == "" && r.pathMajor == "" && semver.Major(v) > "v1" { incompatible = append(incompatible, v) } continue } list = append(list, v) } semver.Sort(list) semver.Sort(incompatible) return r.appendIncompatibleVersions(list, incompatible) } // appendIncompatibleVersions appends "+incompatible" versions to list if // appropriate, returning the final list. // // The incompatible list contains candidate versions without the '+incompatible' // prefix. // // Both list and incompatible must be sorted in semantic order. func (r *codeRepo) appendIncompatibleVersions(list, incompatible []string) ([]string, error) { if len(incompatible) == 0 || r.pathMajor != "" { // No +incompatible versions are possible, so no need to check them. return list, nil } versionHasGoMod := func(v string) (bool, error) { _, err := r.code.ReadFile(v, "go.mod", codehost.MaxGoMod) if err == nil { return true, nil } if !os.IsNotExist(err) { return false, &module.ModuleError{ Path: r.modPath, Err: err, } } return false, nil } if len(list) > 0 { ok, err := versionHasGoMod(list[len(list)-1]) if err != nil { return nil, err } if ok { // The latest compatible version has a go.mod file, so assume that all // subsequent versions do as well, and do not include any +incompatible // versions. Even if we are wrong, the author clearly intends module // consumers to be on the v0/v1 line instead of a higher +incompatible // version. (See https://golang.org/issue/34189.) // // We know of at least two examples where this behavior is desired // (github.com/russross/blackfriday@v2.0.0 and // github.com/libp2p/go-libp2p@v6.0.23), and (as of 2019-10-29) have no // concrete examples for which it is undesired. return list, nil } } var ( lastMajor string lastMajorHasGoMod bool ) for i, v := range incompatible { major := semver.Major(v) if major != lastMajor { rem := incompatible[i:] j := sort.Search(len(rem), func(j int) bool { return semver.Major(rem[j]) != major }) latestAtMajor := rem[j-1] var err error lastMajor = major lastMajorHasGoMod, err = versionHasGoMod(latestAtMajor) if err != nil { return nil, err } } if lastMajorHasGoMod { // The latest release of this major version has a go.mod file, so it is // not allowed as +incompatible. It would be confusing to include some // minor versions of this major version as +incompatible but require // semantic import versioning for others, so drop all +incompatible // versions for this major version. // // If we're wrong about a minor version in the middle, users will still be // able to 'go get' specific tags for that version explicitly — they just // won't appear in 'go list' or as the results for queries with inequality // bounds. continue } list = append(list, v+"+incompatible") } return list, nil } func (r *codeRepo) Stat(rev string) (*RevInfo, error) { if rev == "latest" { return r.Latest() } codeRev := r.revToRev(rev) info, err := r.code.Stat(codeRev) if err != nil { return nil, &module.ModuleError{ Path: r.modPath, Err: &module.InvalidVersionError{ Version: rev, Err: err, }, } } return r.convert(info, rev) } func (r *codeRepo) Latest() (*RevInfo, error) { info, err := r.code.Latest() if err != nil { return nil, err } return r.convert(info, "") } // convert converts a version as reported by the code host to a version as // interpreted by the module system. // // If statVers is a valid module version, it is used for the Version field. // Otherwise, the Version is derived from the passed-in info and recent tags. func (r *codeRepo) convert(info *codehost.RevInfo, statVers string) (*RevInfo, error) { // If this is a plain tag (no dir/ prefix) // and the module path is unversioned, // and if the underlying file tree has no go.mod, // then allow using the tag with a +incompatible suffix. // // (If the version is +incompatible, then the go.mod file must not exist: // +incompatible is not an ongoing opt-out from semantic import versioning.) incompatibleOk := map[string]bool{} canUseIncompatible := func(v string) bool { if r.codeDir != "" || r.pathMajor != "" { // A non-empty codeDir indicates a module within a subdirectory, // which necessarily has a go.mod file indicating the module boundary. // A non-empty pathMajor indicates a module path with a major-version // suffix, which must match. return false } ok, seen := incompatibleOk[""] if !seen { _, errGoMod := r.code.ReadFile(info.Name, "go.mod", codehost.MaxGoMod) ok = (errGoMod != nil) incompatibleOk[""] = ok } if !ok { // A go.mod file exists at the repo root. return false } // Per https://go.dev/issue/51324, previous versions of the 'go' command // didn't always check for go.mod files in subdirectories, so if the user // requests a +incompatible version explicitly, we should continue to allow // it. Otherwise, if vN/go.mod exists, expect that release tags for that // major version are intended for the vN module. if v != "" && !strings.HasSuffix(statVers, "+incompatible") { major := semver.Major(v) ok, seen = incompatibleOk[major] if !seen { _, errGoModSub := r.code.ReadFile(info.Name, path.Join(major, "go.mod"), codehost.MaxGoMod) ok = (errGoModSub != nil) incompatibleOk[major] = ok } if !ok { return false } } return true } // checkCanonical verifies that the canonical version v is compatible with the // module path represented by r, adding a "+incompatible" suffix if needed. // // If statVers is also canonical, checkCanonical also verifies that v is // either statVers or statVers with the added "+incompatible" suffix. checkCanonical := func(v string) (*RevInfo, error) { // If r.codeDir is non-empty, then the go.mod file must exist: the module // author — not the module consumer, — gets to decide how to carve up the repo // into modules. // // Conversely, if the go.mod file exists, the module author — not the module // consumer — gets to determine the module's path // // r.findDir verifies both of these conditions. Execute it now so that // r.Stat will correctly return a notExistError if the go.mod location or // declared module path doesn't match. _, _, _, err := r.findDir(v) if err != nil { // TODO: It would be nice to return an error like "not a module". // Right now we return "missing go.mod", which is a little confusing. return nil, &module.ModuleError{ Path: r.modPath, Err: &module.InvalidVersionError{ Version: v, Err: notExistError{err: err}, }, } } invalidf := func(format string, args ...any) error { return &module.ModuleError{ Path: r.modPath, Err: &module.InvalidVersionError{ Version: v, Err: fmt.Errorf(format, args...), }, } } // Add the +incompatible suffix if needed or requested explicitly, and // verify that its presence or absence is appropriate for this version // (which depends on whether it has an explicit go.mod file). if v == strings.TrimSuffix(statVers, "+incompatible") { v = statVers } base := strings.TrimSuffix(v, "+incompatible") var errIncompatible error if !module.MatchPathMajor(base, r.pathMajor) { if canUseIncompatible(base) { v = base + "+incompatible" } else { if r.pathMajor != "" { errIncompatible = invalidf("module path includes a major version suffix, so major version must match") } else { errIncompatible = invalidf("module contains a go.mod file, so module path must match major version (%q)", path.Join(r.pathPrefix, semver.Major(v))) } } } else if strings.HasSuffix(v, "+incompatible") { errIncompatible = invalidf("+incompatible suffix not allowed: major version %s is compatible", semver.Major(v)) } if statVers != "" && statVers == module.CanonicalVersion(statVers) { // Since the caller-requested version is canonical, it would be very // confusing to resolve it to anything but itself, possibly with a // "+incompatible" suffix. Error out explicitly. if statBase := strings.TrimSuffix(statVers, "+incompatible"); statBase != base { return nil, &module.ModuleError{ Path: r.modPath, Err: &module.InvalidVersionError{ Version: statVers, Err: fmt.Errorf("resolves to version %v (%s is not a tag)", v, statBase), }, } } } if errIncompatible != nil { return nil, errIncompatible } return &RevInfo{ Name: info.Name, Short: info.Short, Time: info.Time, Version: v, }, nil } // Determine version. if module.IsPseudoVersion(statVers) { if err := r.validatePseudoVersion(info, statVers); err != nil { return nil, err } return checkCanonical(statVers) } // statVers is not a pseudo-version, so we need to either resolve it to a // canonical version or verify that it is already a canonical tag // (not a branch). // Derive or verify a version from a code repo tag. // Tag must have a prefix matching codeDir. tagPrefix := "" if r.codeDir != "" { tagPrefix = r.codeDir + "/" } isRetracted, err := r.retractedVersions() if err != nil { isRetracted = func(string) bool { return false } } // tagToVersion returns the version obtained by trimming tagPrefix from tag. // If the tag is invalid, retracted, or a pseudo-version, tagToVersion returns // an empty version. tagToVersion := func(tag string) (v string, tagIsCanonical bool) { if !strings.HasPrefix(tag, tagPrefix) { return "", false } trimmed := tag[len(tagPrefix):] // Tags that look like pseudo-versions would be confusing. Ignore them. if module.IsPseudoVersion(tag) { return "", false } v = semver.Canonical(trimmed) // Not module.Canonical: we don't want to pick up an explicit "+incompatible" suffix from the tag. if v == "" || !strings.HasPrefix(trimmed, v) { return "", false // Invalid or incomplete version (just vX or vX.Y). } if v == trimmed { tagIsCanonical = true } return v, tagIsCanonical } // If the VCS gave us a valid version, use that. if v, tagIsCanonical := tagToVersion(info.Version); tagIsCanonical { if info, err := checkCanonical(v); err == nil { return info, err } } // Look through the tags on the revision for either a usable canonical version // or an appropriate base for a pseudo-version. var ( highestCanonical string pseudoBase string ) for _, pathTag := range info.Tags { v, tagIsCanonical := tagToVersion(pathTag) if statVers != "" && semver.Compare(v, statVers) == 0 { // The tag is equivalent to the version requested by the user. if tagIsCanonical { // This tag is the canonical form of the requested version, // not some other form with extra build metadata. // Use this tag so that the resolved version will match exactly. // (If it isn't actually allowed, we'll error out in checkCanonical.) return checkCanonical(v) } else { // The user explicitly requested something equivalent to this tag. We // can't use the version from the tag directly: since the tag is not // canonical, it could be ambiguous. For example, tags v0.0.1+a and // v0.0.1+b might both exist and refer to different revisions. // // The tag is otherwise valid for the module, so we can at least use it as // the base of an unambiguous pseudo-version. // // If multiple tags match, tagToVersion will canonicalize them to the same // base version. pseudoBase = v } } // Save the highest non-retracted canonical tag for the revision. // If we don't find a better match, we'll use it as the canonical version. if tagIsCanonical && semver.Compare(highestCanonical, v) < 0 && !isRetracted(v) { if module.MatchPathMajor(v, r.pathMajor) || canUseIncompatible(v) { highestCanonical = v } } } // If we found a valid canonical tag for the revision, return it. // Even if we found a good pseudo-version base, a canonical version is better. if highestCanonical != "" { return checkCanonical(highestCanonical) } // Find the highest tagged version in the revision's history, subject to // major version and +incompatible constraints. Use that version as the // pseudo-version base so that the pseudo-version sorts higher. Ignore // retracted versions. allowedMajor := func(major string) func(v string) bool { return func(v string) bool { return ((major == "" && canUseIncompatible(v)) || semver.Major(v) == major) && !isRetracted(v) } } if pseudoBase == "" { var tag string if r.pseudoMajor != "" || canUseIncompatible("") { tag, _ = r.code.RecentTag(info.Name, tagPrefix, allowedMajor(r.pseudoMajor)) } else { // Allow either v1 or v0, but not incompatible higher versions. tag, _ = r.code.RecentTag(info.Name, tagPrefix, allowedMajor("v1")) if tag == "" { tag, _ = r.code.RecentTag(info.Name, tagPrefix, allowedMajor("v0")) } } pseudoBase, _ = tagToVersion(tag) } return checkCanonical(module.PseudoVersion(r.pseudoMajor, pseudoBase, info.Time, info.Short)) } // validatePseudoVersion checks that version has a major version compatible with // r.modPath and encodes a base version and commit metadata that agrees with // info. // // Note that verifying a nontrivial base version in particular may be somewhat // expensive: in order to do so, r.code.DescendsFrom will need to fetch at least // enough of the commit history to find a path between version and its base. // Fortunately, many pseudo-versions — such as those for untagged repositories — // have trivial bases! func (r *codeRepo) validatePseudoVersion(info *codehost.RevInfo, version string) (err error) { defer func() { if err != nil { if _, ok := err.(*module.ModuleError); !ok { if _, ok := err.(*module.InvalidVersionError); !ok { err = &module.InvalidVersionError{Version: version, Pseudo: true, Err: err} } err = &module.ModuleError{Path: r.modPath, Err: err} } } }() rev, err := module.PseudoVersionRev(version) if err != nil { return err } if rev != info.Short { switch { case strings.HasPrefix(rev, info.Short): return fmt.Errorf("revision is longer than canonical (expected %s)", info.Short) case strings.HasPrefix(info.Short, rev): return fmt.Errorf("revision is shorter than canonical (expected %s)", info.Short) default: return fmt.Errorf("does not match short name of revision (expected %s)", info.Short) } } t, err := module.PseudoVersionTime(version) if err != nil { return err } if !t.Equal(info.Time.Truncate(time.Second)) { return fmt.Errorf("does not match version-control timestamp (expected %s)", info.Time.UTC().Format(module.PseudoVersionTimestampFormat)) } tagPrefix := "" if r.codeDir != "" { tagPrefix = r.codeDir + "/" } // A pseudo-version should have a precedence just above its parent revisions, // and no higher. Otherwise, it would be possible for library authors to "pin" // dependency versions (and bypass the usual minimum version selection) by // naming an extremely high pseudo-version rather than an accurate one. // // Moreover, if we allow a pseudo-version to use any arbitrary pre-release // tag, we end up with infinitely many possible names for each commit. Each // name consumes resources in the module cache and proxies, so we want to // restrict them to a finite set under control of the module author. // // We address both of these issues by requiring the tag upon which the // pseudo-version is based to refer to some ancestor of the revision. We // prefer the highest such tag when constructing a new pseudo-version, but do // not enforce that property when resolving existing pseudo-versions: we don't // know when the parent tags were added, and the highest-tagged parent may not // have existed when the pseudo-version was first resolved. base, err := module.PseudoVersionBase(strings.TrimSuffix(version, "+incompatible")) if err != nil { return err } if base == "" { if r.pseudoMajor == "" && semver.Major(version) == "v1" { return fmt.Errorf("major version without preceding tag must be v0, not v1") } return nil } else { for _, tag := range info.Tags { versionOnly := strings.TrimPrefix(tag, tagPrefix) if versionOnly == base { // The base version is canonical, so if the version from the tag is // literally equal (not just equivalent), then the tag is canonical too. // // We allow pseudo-versions to be derived from non-canonical tags on the // same commit, so that tags like "v1.1.0+some-metadata" resolve as // close as possible to the canonical version ("v1.1.0") while still // enforcing a total ordering ("v1.1.1-0.[…]" with a unique suffix). // // However, canonical tags already have a total ordering, so there is no // reason not to use the canonical tag directly, and we know that the // canonical tag must already exist because the pseudo-version is // derived from it. In that case, referring to the revision by a // pseudo-version derived from its own canonical tag is just confusing. return fmt.Errorf("tag (%s) found on revision %s is already canonical, so should not be replaced with a pseudo-version derived from that tag", tag, rev) } } } tags, err := r.code.Tags(tagPrefix + base) if err != nil { return err } var lastTag string // Prefer to log some real tag rather than a canonically-equivalent base. ancestorFound := false for _, tag := range tags { versionOnly := strings.TrimPrefix(tag, tagPrefix) if semver.Compare(versionOnly, base) == 0 { lastTag = tag ancestorFound, err = r.code.DescendsFrom(info.Name, tag) if ancestorFound { break } } } if lastTag == "" { return fmt.Errorf("preceding tag (%s) not found", base) } if !ancestorFound { if err != nil { return err } rev, err := module.PseudoVersionRev(version) if err != nil { return fmt.Errorf("not a descendent of preceding tag (%s)", lastTag) } return fmt.Errorf("revision %s is not a descendent of preceding tag (%s)", rev, lastTag) } return nil } func (r *codeRepo) revToRev(rev string) string { if semver.IsValid(rev) { if module.IsPseudoVersion(rev) { r, _ := module.PseudoVersionRev(rev) return r } if semver.Build(rev) == "+incompatible" { rev = rev[:len(rev)-len("+incompatible")] } if r.codeDir == "" { return rev } return r.codeDir + "/" + rev } return rev } func (r *codeRepo) versionToRev(version string) (rev string, err error) { if !semver.IsValid(version) { return "", &module.ModuleError{ Path: r.modPath, Err: &module.InvalidVersionError{ Version: version, Err: errors.New("syntax error"), }, } } return r.revToRev(version), nil } // findDir locates the directory within the repo containing the module. // // If r.pathMajor is non-empty, this can be either r.codeDir or — if a go.mod // file exists — r.codeDir/r.pathMajor[1:]. func (r *codeRepo) findDir(version string) (rev, dir string, gomod []byte, err error) { rev, err = r.versionToRev(version) if err != nil { return "", "", nil, err } // Load info about go.mod but delay consideration // (except I/O error) until we rule out v2/go.mod. file1 := path.Join(r.codeDir, "go.mod") gomod1, err1 := r.code.ReadFile(rev, file1, codehost.MaxGoMod) if err1 != nil && !os.IsNotExist(err1) { return "", "", nil, fmt.Errorf("reading %s/%s at revision %s: %v", r.pathPrefix, file1, rev, err1) } mpath1 := modfile.ModulePath(gomod1) found1 := err1 == nil && (isMajor(mpath1, r.pathMajor) || r.canReplaceMismatchedVersionDueToBug(mpath1)) var file2 string if r.pathMajor != "" && r.codeRoot != r.modPath && !strings.HasPrefix(r.pathMajor, ".") { // Suppose pathMajor is "/v2". // Either go.mod should claim v2 and v2/go.mod should not exist, // or v2/go.mod should exist and claim v2. Not both. // Note that we don't check the full path, just the major suffix, // because of replacement modules. This might be a fork of // the real module, found at a different path, usable only in // a replace directive. dir2 := path.Join(r.codeDir, r.pathMajor[1:]) file2 = path.Join(dir2, "go.mod") gomod2, err2 := r.code.ReadFile(rev, file2, codehost.MaxGoMod) if err2 != nil && !os.IsNotExist(err2) { return "", "", nil, fmt.Errorf("reading %s/%s at revision %s: %v", r.pathPrefix, file2, rev, err2) } mpath2 := modfile.ModulePath(gomod2) found2 := err2 == nil && isMajor(mpath2, r.pathMajor) if found1 && found2 { return "", "", nil, fmt.Errorf("%s/%s and ...%s/go.mod both have ...%s module paths at revision %s", r.pathPrefix, file1, r.pathMajor, r.pathMajor, rev) } if found2 { return rev, dir2, gomod2, nil } if err2 == nil { if mpath2 == "" { return "", "", nil, fmt.Errorf("%s/%s is missing module path at revision %s", r.pathPrefix, file2, rev) } return "", "", nil, fmt.Errorf("%s/%s has non-...%s module path %q at revision %s", r.pathPrefix, file2, r.pathMajor, mpath2, rev) } } // Not v2/go.mod, so it's either go.mod or nothing. Which is it? if found1 { // Explicit go.mod with matching major version ok. return rev, r.codeDir, gomod1, nil } if err1 == nil { // Explicit go.mod with non-matching major version disallowed. suffix := "" if file2 != "" { suffix = fmt.Sprintf(" (and ...%s/go.mod does not exist)", r.pathMajor) } if mpath1 == "" { return "", "", nil, fmt.Errorf("%s is missing module path%s at revision %s", file1, suffix, rev) } if r.pathMajor != "" { // ".v1", ".v2" for gopkg.in return "", "", nil, fmt.Errorf("%s has non-...%s module path %q%s at revision %s", file1, r.pathMajor, mpath1, suffix, rev) } if _, _, ok := module.SplitPathVersion(mpath1); !ok { return "", "", nil, fmt.Errorf("%s has malformed module path %q%s at revision %s", file1, mpath1, suffix, rev) } return "", "", nil, fmt.Errorf("%s has post-%s module path %q%s at revision %s", file1, semver.Major(version), mpath1, suffix, rev) } if r.codeDir == "" && (r.pathMajor == "" || strings.HasPrefix(r.pathMajor, ".")) { // Implicit go.mod at root of repo OK for v0/v1 and for gopkg.in. return rev, "", nil, nil } // Implicit go.mod below root of repo or at v2+ disallowed. // Be clear about possibility of using either location for v2+. if file2 != "" { return "", "", nil, fmt.Errorf("missing %s/go.mod and ...%s/go.mod at revision %s", r.pathPrefix, r.pathMajor, rev) } return "", "", nil, fmt.Errorf("missing %s/go.mod at revision %s", r.pathPrefix, rev) } // isMajor reports whether the versions allowed for mpath are compatible with // the major version(s) implied by pathMajor, or false if mpath has an invalid // version suffix. func isMajor(mpath, pathMajor string) bool { if mpath == "" { // If we don't have a path, we don't know what version(s) it is compatible with. return false } _, mpathMajor, ok := module.SplitPathVersion(mpath) if !ok { // An invalid module path is not compatible with any version. return false } if pathMajor == "" { // All of the valid versions for a gopkg.in module that requires major // version v0 or v1 are compatible with the "v0 or v1" implied by an empty // pathMajor. switch module.PathMajorPrefix(mpathMajor) { case "", "v0", "v1": return true default: return false } } if mpathMajor == "" { // Even if pathMajor is ".v0" or ".v1", we can't be sure that a module // without a suffix is tagged appropriately. Besides, we don't expect clones // of non-gopkg.in modules to have gopkg.in paths, so a non-empty, // non-gopkg.in mpath is probably the wrong module for any such pathMajor // anyway. return false } // If both pathMajor and mpathMajor are non-empty, then we only care that they // have the same major-version validation rules. A clone fetched via a /v2 // path might replace a module with path gopkg.in/foo.v2-unstable, and that's // ok. return pathMajor[1:] == mpathMajor[1:] } // canReplaceMismatchedVersionDueToBug reports whether versions of r // could replace versions of mpath with otherwise-mismatched major versions // due to a historical bug in the Go command (golang.org/issue/34254). func (r *codeRepo) canReplaceMismatchedVersionDueToBug(mpath string) bool { // The bug caused us to erroneously accept unversioned paths as replacements // for versioned gopkg.in paths. unversioned := r.pathMajor == "" replacingGopkgIn := strings.HasPrefix(mpath, "gopkg.in/") return unversioned && replacingGopkgIn } func (r *codeRepo) GoMod(version string) (data []byte, err error) { if version != module.CanonicalVersion(version) { return nil, fmt.Errorf("version %s is not canonical", version) } if module.IsPseudoVersion(version) { // findDir ignores the metadata encoded in a pseudo-version, // only using the revision at the end. // Invoke Stat to verify the metadata explicitly so we don't return // a bogus file for an invalid version. _, err := r.Stat(version) if err != nil { return nil, err } } rev, dir, gomod, err := r.findDir(version) if err != nil { return nil, err } if gomod != nil { return gomod, nil } data, err = r.code.ReadFile(rev, path.Join(dir, "go.mod"), codehost.MaxGoMod) if err != nil { if os.IsNotExist(err) { return LegacyGoMod(r.modPath), nil } return nil, err } return data, nil } // LegacyGoMod generates a fake go.mod file for a module that doesn't have one. // The go.mod file contains a module directive and nothing else: no go version, // no requirements. // // We used to try to build a go.mod reflecting pre-existing // package management metadata files, but the conversion // was inherently imperfect (because those files don't have // exactly the same semantics as go.mod) and, when done // for dependencies in the middle of a build, impossible to // correct. So we stopped. func LegacyGoMod(modPath string) []byte { return []byte(fmt.Sprintf("module %s\n", modfile.AutoQuote(modPath))) } func (r *codeRepo) modPrefix(rev string) string { return r.modPath + "@" + rev } func (r *codeRepo) retractedVersions() (func(string) bool, error) { versions, err := r.Versions("") if err != nil { return nil, err } for i, v := range versions { if strings.HasSuffix(v, "+incompatible") { versions = versions[:i] break } } if len(versions) == 0 { return func(string) bool { return false }, nil } var highest string for i := len(versions) - 1; i >= 0; i-- { v := versions[i] if semver.Prerelease(v) == "" { highest = v break } } if highest == "" { highest = versions[len(versions)-1] } data, err := r.GoMod(highest) if err != nil { return nil, err } f, err := modfile.ParseLax("go.mod", data, nil) if err != nil { return nil, err } retractions := make([]modfile.VersionInterval, len(f.Retract)) for _, r := range f.Retract { retractions = append(retractions, r.VersionInterval) } return func(v string) bool { for _, r := range retractions { if semver.Compare(r.Low, v) <= 0 && semver.Compare(v, r.High) <= 0 { return true } } return false }, nil } func (r *codeRepo) Zip(dst io.Writer, version string) error { if version != module.CanonicalVersion(version) { return fmt.Errorf("version %s is not canonical", version) } if module.IsPseudoVersion(version) { // findDir ignores the metadata encoded in a pseudo-version, // only using the revision at the end. // Invoke Stat to verify the metadata explicitly so we don't return // a bogus file for an invalid version. _, err := r.Stat(version) if err != nil { return err } } rev, subdir, _, err := r.findDir(version) if err != nil { return err } dl, err := r.code.ReadZip(rev, subdir, codehost.MaxZipFile) if err != nil { return err } defer dl.Close() subdir = strings.Trim(subdir, "/") // Spool to local file. f, err := os.CreateTemp("", "go-codehost-") if err != nil { dl.Close() return err } defer os.Remove(f.Name()) defer f.Close() maxSize := int64(codehost.MaxZipFile) lr := &io.LimitedReader{R: dl, N: maxSize + 1} if _, err := io.Copy(f, lr); err != nil { dl.Close() return err } dl.Close() if lr.N <= 0 { return fmt.Errorf("downloaded zip file too large") } size := (maxSize + 1) - lr.N if _, err := f.Seek(0, 0); err != nil { return err } // Translate from zip file we have to zip file we want. zr, err := zip.NewReader(f, size) if err != nil { return err } var files []modzip.File if subdir != "" { subdir += "/" } haveLICENSE := false topPrefix := "" for _, zf := range zr.File { if topPrefix == "" { i := strings.Index(zf.Name, "/") if i < 0 { return fmt.Errorf("missing top-level directory prefix") } topPrefix = zf.Name[:i+1] } if !strings.HasPrefix(zf.Name, topPrefix) { return fmt.Errorf("zip file contains more than one top-level directory") } name := strings.TrimPrefix(zf.Name, topPrefix) if !strings.HasPrefix(name, subdir) { continue } name = strings.TrimPrefix(name, subdir) if name == "" || strings.HasSuffix(name, "/") { continue } files = append(files, zipFile{name: name, f: zf}) if name == "LICENSE" { haveLICENSE = true } } if !haveLICENSE && subdir != "" { data, err := r.code.ReadFile(rev, "LICENSE", codehost.MaxLICENSE) if err == nil { files = append(files, dataFile{name: "LICENSE", data: data}) } } return modzip.Create(dst, module.Version{Path: r.modPath, Version: version}, files) } type zipFile struct { name string f *zip.File } func (f zipFile) Path() string { return f.name } func (f zipFile) Lstat() (fs.FileInfo, error) { return f.f.FileInfo(), nil } func (f zipFile) Open() (io.ReadCloser, error) { return f.f.Open() } type dataFile struct { name string data []byte } func (f dataFile) Path() string { return f.name } func (f dataFile) Lstat() (fs.FileInfo, error) { return dataFileInfo{f}, nil } func (f dataFile) Open() (io.ReadCloser, error) { return io.NopCloser(bytes.NewReader(f.data)), nil } type dataFileInfo struct { f dataFile } func (fi dataFileInfo) Name() string { return path.Base(fi.f.name) } func (fi dataFileInfo) Size() int64 { return int64(len(fi.f.data)) } func (fi dataFileInfo) Mode() fs.FileMode { return 0644 } func (fi dataFileInfo) ModTime() time.Time { return time.Time{} } func (fi dataFileInfo) IsDir() bool { return false } func (fi dataFileInfo) Sys() any { return nil } // hasPathPrefix reports whether the path s begins with the // elements in prefix. func hasPathPrefix(s, prefix string) bool { switch { default: return false case len(s) == len(prefix): return s == prefix case len(s) > len(prefix): if prefix != "" && prefix[len(prefix)-1] == '/' { return strings.HasPrefix(s, prefix) } return s[len(prefix)] == '/' && s[:len(prefix)] == prefix } }