// 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 modload // This file contains the module-mode package loader, as well as some accessory // functions pertaining to the package import graph. // // There are two exported entry points into package loading — LoadPackages and // ImportFromFiles — both implemented in terms of loadFromRoots, which itself // manipulates an instance of the loader struct. // // Although most of the loading state is maintained in the loader struct, // one key piece - the build list - is a global, so that it can be modified // separate from the loading operation, such as during "go get" // upgrades/downgrades or in "go mod" operations. // TODO(#40775): It might be nice to make the loader take and return // a buildList rather than hard-coding use of the global. // // Loading is an iterative process. On each iteration, we try to load the // requested packages and their transitive imports, then try to resolve modules // for any imported packages that are still missing. // // The first step of each iteration identifies a set of “root” packages. // Normally the root packages are exactly those matching the named pattern // arguments. However, for the "all" meta-pattern, the final set of packages is // computed from the package import graph, and therefore cannot be an initial // input to loading that graph. Instead, the root packages for the "all" pattern // are those contained in the main module, and allPatternIsRoot parameter to the // loader instructs it to dynamically expand those roots to the full "all" // pattern as loading progresses. // // The pkgInAll flag on each loadPkg instance tracks whether that // package is known to match the "all" meta-pattern. // A package matches the "all" pattern if: // - it is in the main module, or // - it is imported by any test in the main module, or // - it is imported by another package in "all", or // - the main module specifies a go version ≤ 1.15, and the package is imported // by a *test of* another package in "all". // // When graph pruning is in effect, we want to spot-check the graph-pruning // invariants — which depend on which packages are known to be in "all" — even // when we are only loading individual packages, so we set the pkgInAll flag // regardless of the whether the "all" pattern is a root. // (This is necessary to maintain the “import invariant” described in // https://golang.org/design/36460-lazy-module-loading.) // // Because "go mod vendor" prunes out the tests of vendored packages, the // behavior of the "all" pattern with -mod=vendor in Go 1.11–1.15 is the same // as the "all" pattern (regardless of the -mod flag) in 1.16+. // The loader uses the GoVersion parameter to determine whether the "all" // pattern should close over tests (as in Go 1.11–1.15) or stop at only those // packages transitively imported by the packages and tests in the main module // ("all" in Go 1.16+ and "go mod vendor" in Go 1.11+). // // Note that it is possible for a loaded package NOT to be in "all" even when we // are loading the "all" pattern. For example, packages that are transitive // dependencies of other roots named on the command line must be loaded, but are // not in "all". (The mod_notall test illustrates this behavior.) // Similarly, if the LoadTests flag is set but the "all" pattern does not close // over test dependencies, then when we load the test of a package that is in // "all" but outside the main module, the dependencies of that test will not // necessarily themselves be in "all". (That configuration does not arise in Go // 1.11–1.15, but it will be possible in Go 1.16+.) // // Loading proceeds from the roots, using a parallel work-queue with a limit on // the amount of active work (to avoid saturating disks, CPU cores, and/or // network connections). Each package is added to the queue the first time it is // imported by another package. When we have finished identifying the imports of // a package, we add the test for that package if it is needed. A test may be // needed if: // - the package matches a root pattern and tests of the roots were requested, or // - the package is in the main module and the "all" pattern is requested // (because the "all" pattern includes the dependencies of tests in the main // module), or // - the package is in "all" and the definition of "all" we are using includes // dependencies of tests (as is the case in Go ≤1.15). // // After all available packages have been loaded, we examine the results to // identify any requested or imported packages that are still missing, and if // so, which modules we could add to the module graph in order to make the // missing packages available. We add those to the module graph and iterate, // until either all packages resolve successfully or we cannot identify any // module that would resolve any remaining missing package. // // If the main module is “tidy” (that is, if "go mod tidy" is a no-op for it) // and all requested packages are in "all", then loading completes in a single // iteration. // TODO(bcmills): We should also be able to load in a single iteration if the // requested packages all come from modules that are themselves tidy, regardless // of whether those packages are in "all". Today, that requires two iterations // if those packages are not found in existing dependencies of the main module. import ( "context" "errors" "fmt" "go/build" "io/fs" "os" "path" pathpkg "path" "path/filepath" "reflect" "runtime" "sort" "strings" "sync" "sync/atomic" "cmd/go/internal/base" "cmd/go/internal/cfg" "cmd/go/internal/fsys" "cmd/go/internal/imports" "cmd/go/internal/modfetch" "cmd/go/internal/modindex" "cmd/go/internal/mvs" "cmd/go/internal/par" "cmd/go/internal/search" "cmd/go/internal/str" "golang.org/x/mod/module" "golang.org/x/mod/semver" ) // loaded is the most recently-used package loader. // It holds details about individual packages. // // This variable should only be accessed directly in top-level exported // functions. All other functions that require or produce a *loader should pass // or return it as an explicit parameter. var loaded *loader // PackageOpts control the behavior of the LoadPackages function. type PackageOpts struct { // GoVersion is the Go version to which the go.mod file should be updated // after packages have been loaded. // // An empty GoVersion means to use the Go version already specified in the // main module's go.mod file, or the latest Go version if there is no main // module. GoVersion string // Tags are the build tags in effect (as interpreted by the // cmd/go/internal/imports package). // If nil, treated as equivalent to imports.Tags(). Tags map[string]bool // Tidy, if true, requests that the build list and go.sum file be reduced to // the minimial dependencies needed to reproducibly reload the requested // packages. Tidy bool // TidyCompatibleVersion is the oldest Go version that must be able to // reproducibly reload the requested packages. // // If empty, the compatible version is the Go version immediately prior to the // 'go' version listed in the go.mod file. TidyCompatibleVersion string // VendorModulesInGOROOTSrc indicates that if we are within a module in // GOROOT/src, packages in the module's vendor directory should be resolved as // actual module dependencies (instead of standard-library packages). VendorModulesInGOROOTSrc bool // ResolveMissingImports indicates that we should attempt to add module // dependencies as needed to resolve imports of packages that are not found. // // For commands that support the -mod flag, resolving imports may still fail // if the flag is set to "readonly" (the default) or "vendor". ResolveMissingImports bool // AssumeRootsImported indicates that the transitive dependencies of the root // packages should be treated as if those roots will be imported by the main // module. AssumeRootsImported bool // AllowPackage, if non-nil, is called after identifying the module providing // each package. If AllowPackage returns a non-nil error, that error is set // for the package, and the imports and test of that package will not be // loaded. // // AllowPackage may be invoked concurrently by multiple goroutines, // and may be invoked multiple times for a given package path. AllowPackage func(ctx context.Context, path string, mod module.Version) error // LoadTests loads the test dependencies of each package matching a requested // pattern. If ResolveMissingImports is also true, test dependencies will be // resolved if missing. LoadTests bool // UseVendorAll causes the "all" package pattern to be interpreted as if // running "go mod vendor" (or building with "-mod=vendor"). // // This is a no-op for modules that declare 'go 1.16' or higher, for which this // is the default (and only) interpretation of the "all" pattern in module mode. UseVendorAll bool // AllowErrors indicates that LoadPackages should not terminate the process if // an error occurs. AllowErrors bool // SilencePackageErrors indicates that LoadPackages should not print errors // that occur while matching or loading packages, and should not terminate the // process if such an error occurs. // // Errors encountered in the module graph will still be reported. // // The caller may retrieve the silenced package errors using the Lookup // function, and matching errors are still populated in the Errs field of the // associated search.Match.) SilencePackageErrors bool // SilenceMissingStdImports indicates that LoadPackages should not print // errors or terminate the process if an imported package is missing, and the // import path looks like it might be in the standard library (perhaps in a // future version). SilenceMissingStdImports bool // SilenceNoGoErrors indicates that LoadPackages should not print // imports.ErrNoGo errors. // This allows the caller to invoke LoadPackages (and report other errors) // without knowing whether the requested packages exist for the given tags. // // Note that if a requested package does not exist *at all*, it will fail // during module resolution and the error will not be suppressed. SilenceNoGoErrors bool // SilenceUnmatchedWarnings suppresses the warnings normally emitted for // patterns that did not match any packages. SilenceUnmatchedWarnings bool // Resolve the query against this module. MainModule module.Version } // LoadPackages identifies the set of packages matching the given patterns and // loads the packages in the import graph rooted at that set. func LoadPackages(ctx context.Context, opts PackageOpts, patterns ...string) (matches []*search.Match, loadedPackages []string) { if opts.Tags == nil { opts.Tags = imports.Tags() } patterns = search.CleanPatterns(patterns) matches = make([]*search.Match, 0, len(patterns)) allPatternIsRoot := false for _, pattern := range patterns { matches = append(matches, search.NewMatch(pattern)) if pattern == "all" { allPatternIsRoot = true } } updateMatches := func(rs *Requirements, ld *loader) { for _, m := range matches { switch { case m.IsLocal(): // Evaluate list of file system directories on first iteration. if m.Dirs == nil { matchModRoots := modRoots if opts.MainModule != (module.Version{}) { matchModRoots = []string{MainModules.ModRoot(opts.MainModule)} } matchLocalDirs(ctx, matchModRoots, m, rs) } // Make a copy of the directory list and translate to import paths. // Note that whether a directory corresponds to an import path // changes as the build list is updated, and a directory can change // from not being in the build list to being in it and back as // the exact version of a particular module increases during // the loader iterations. m.Pkgs = m.Pkgs[:0] for _, dir := range m.Dirs { pkg, err := resolveLocalPackage(ctx, dir, rs) if err != nil { if !m.IsLiteral() && (err == errPkgIsBuiltin || err == errPkgIsGorootSrc) { continue // Don't include "builtin" or GOROOT/src in wildcard patterns. } // If we're outside of a module, ensure that the failure mode // indicates that. if !HasModRoot() { die() } if ld != nil { m.AddError(err) } continue } m.Pkgs = append(m.Pkgs, pkg) } case m.IsLiteral(): m.Pkgs = []string{m.Pattern()} case strings.Contains(m.Pattern(), "..."): m.Errs = m.Errs[:0] mg, err := rs.Graph(ctx) if err != nil { // The module graph is (or may be) incomplete — perhaps we failed to // load the requirements of some module. This is an error in matching // the patterns to packages, because we may be missing some packages // or we may erroneously match packages in the wrong versions of // modules. However, for cases like 'go list -e', the error should not // necessarily prevent us from loading the packages we could find. m.Errs = append(m.Errs, err) } matchPackages(ctx, m, opts.Tags, includeStd, mg.BuildList()) case m.Pattern() == "all": if ld == nil { // The initial roots are the packages in the main module. // loadFromRoots will expand that to "all". m.Errs = m.Errs[:0] matchModules := MainModules.Versions() if opts.MainModule != (module.Version{}) { matchModules = []module.Version{opts.MainModule} } matchPackages(ctx, m, opts.Tags, omitStd, matchModules) } else { // Starting with the packages in the main module, // enumerate the full list of "all". m.Pkgs = ld.computePatternAll() } case m.Pattern() == "std" || m.Pattern() == "cmd": if m.Pkgs == nil { m.MatchPackages() // Locate the packages within GOROOT/src. } default: panic(fmt.Sprintf("internal error: modload missing case for pattern %s", m.Pattern())) } } } initialRS := LoadModFile(ctx) ld := loadFromRoots(ctx, loaderParams{ PackageOpts: opts, requirements: initialRS, allPatternIsRoot: allPatternIsRoot, listRoots: func(rs *Requirements) (roots []string) { updateMatches(rs, nil) for _, m := range matches { roots = append(roots, m.Pkgs...) } return roots }, }) // One last pass to finalize wildcards. updateMatches(ld.requirements, ld) // List errors in matching patterns (such as directory permission // errors for wildcard patterns). if !ld.SilencePackageErrors { for _, match := range matches { for _, err := range match.Errs { ld.errorf("%v\n", err) } } } base.ExitIfErrors() if !opts.SilenceUnmatchedWarnings { search.WarnUnmatched(matches) } if opts.Tidy { if cfg.BuildV { mg, _ := ld.requirements.Graph(ctx) for _, m := range initialRS.rootModules { var unused bool if ld.requirements.pruning == unpruned { // m is unused if it was dropped from the module graph entirely. If it // was only demoted from direct to indirect, it may still be in use via // a transitive import. unused = mg.Selected(m.Path) == "none" } else { // m is unused if it was dropped from the roots. If it is still present // as a transitive dependency, that transitive dependency is not needed // by any package or test in the main module. _, ok := ld.requirements.rootSelected(m.Path) unused = !ok } if unused { fmt.Fprintf(os.Stderr, "unused %s\n", m.Path) } } } keep := keepSums(ctx, ld, ld.requirements, loadedZipSumsOnly) if compatDepth := pruningForGoVersion(ld.TidyCompatibleVersion); compatDepth != ld.requirements.pruning { compatRS := newRequirements(compatDepth, ld.requirements.rootModules, ld.requirements.direct) ld.checkTidyCompatibility(ctx, compatRS) for m := range keepSums(ctx, ld, compatRS, loadedZipSumsOnly) { keep[m] = true } } if !ExplicitWriteGoMod { modfetch.TrimGoSum(keep) // commitRequirements below will also call WriteGoSum, but the "keep" map // we have here could be strictly larger: commitRequirements only commits // loaded.requirements, but here we may have also loaded (and want to // preserve checksums for) additional entities from compatRS, which are // only needed for compatibility with ld.TidyCompatibleVersion. if err := modfetch.WriteGoSum(keep, mustHaveCompleteRequirements()); err != nil { base.Fatalf("go: %v", err) } } // Update the go.mod file's Go version if necessary. if modFile := ModFile(); modFile != nil && ld.GoVersion != "" { modFile.AddGoStmt(ld.GoVersion) } } // Success! Update go.mod and go.sum (if needed) and return the results. // We'll skip updating if ExplicitWriteGoMod is true (the caller has opted // to call WriteGoMod itself) or if ResolveMissingImports is false (the // command wants to examine the package graph as-is). loaded = ld requirements = loaded.requirements for _, pkg := range ld.pkgs { if !pkg.isTest() { loadedPackages = append(loadedPackages, pkg.path) } } sort.Strings(loadedPackages) if !ExplicitWriteGoMod && opts.ResolveMissingImports { if err := commitRequirements(ctx); err != nil { base.Fatalf("go: %v", err) } } return matches, loadedPackages } // matchLocalDirs is like m.MatchDirs, but tries to avoid scanning directories // outside of the standard library and active modules. func matchLocalDirs(ctx context.Context, modRoots []string, m *search.Match, rs *Requirements) { if !m.IsLocal() { panic(fmt.Sprintf("internal error: resolveLocalDirs on non-local pattern %s", m.Pattern())) } if i := strings.Index(m.Pattern(), "..."); i >= 0 { // The pattern is local, but it is a wildcard. Its packages will // only resolve to paths if they are inside of the standard // library, the main module, or some dependency of the main // module. Verify that before we walk the filesystem: a filesystem // walk in a directory like /var or /etc can be very expensive! dir := filepath.Dir(filepath.Clean(m.Pattern()[:i+3])) absDir := dir if !filepath.IsAbs(dir) { absDir = filepath.Join(base.Cwd(), dir) } modRoot := findModuleRoot(absDir) found := false for _, mainModuleRoot := range modRoots { if mainModuleRoot == modRoot { found = true break } } if !found && search.InDir(absDir, cfg.GOROOTsrc) == "" && pathInModuleCache(ctx, absDir, rs) == "" { m.Dirs = []string{} scope := "main module or its selected dependencies" if inWorkspaceMode() { scope = "modules listed in go.work or their selected dependencies" } m.AddError(fmt.Errorf("directory prefix %s does not contain %s", base.ShortPath(absDir), scope)) return } } m.MatchDirs(modRoots) } // resolveLocalPackage resolves a filesystem path to a package path. func resolveLocalPackage(ctx context.Context, dir string, rs *Requirements) (string, error) { var absDir string if filepath.IsAbs(dir) { absDir = filepath.Clean(dir) } else { absDir = filepath.Join(base.Cwd(), dir) } bp, err := cfg.BuildContext.ImportDir(absDir, 0) if err != nil && (bp == nil || len(bp.IgnoredGoFiles) == 0) { // golang.org/issue/32917: We should resolve a relative path to a // package path only if the relative path actually contains the code // for that package. // // If the named directory does not exist or contains no Go files, // the package does not exist. // Other errors may affect package loading, but not resolution. if _, err := fsys.Stat(absDir); err != nil { if os.IsNotExist(err) { // Canonicalize OS-specific errors to errDirectoryNotFound so that error // messages will be easier for users to search for. return "", &fs.PathError{Op: "stat", Path: absDir, Err: errDirectoryNotFound} } return "", err } if _, noGo := err.(*build.NoGoError); noGo { // A directory that does not contain any Go source files — even ignored // ones! — is not a Go package, and we can't resolve it to a package // path because that path could plausibly be provided by some other // module. // // Any other error indicates that the package “exists” (at least in the // sense that it cannot exist in any other module), but has some other // problem (such as a syntax error). return "", err } } for _, mod := range MainModules.Versions() { modRoot := MainModules.ModRoot(mod) if modRoot != "" && absDir == modRoot { if absDir == cfg.GOROOTsrc { return "", errPkgIsGorootSrc } return MainModules.PathPrefix(mod), nil } } // Note: The checks for @ here are just to avoid misinterpreting // the module cache directories (formerly GOPATH/src/mod/foo@v1.5.2/bar). // It's not strictly necessary but helpful to keep the checks. var pkgNotFoundErr error pkgNotFoundLongestPrefix := "" for _, mainModule := range MainModules.Versions() { modRoot := MainModules.ModRoot(mainModule) if modRoot != "" && strings.HasPrefix(absDir, modRoot+string(filepath.Separator)) && !strings.Contains(absDir[len(modRoot):], "@") { suffix := filepath.ToSlash(absDir[len(modRoot):]) if pkg, found := strings.CutPrefix(suffix, "/vendor/"); found { if cfg.BuildMod != "vendor" { return "", fmt.Errorf("without -mod=vendor, directory %s has no package path", absDir) } readVendorList(mainModule) if _, ok := vendorPkgModule[pkg]; !ok { return "", fmt.Errorf("directory %s is not a package listed in vendor/modules.txt", absDir) } return pkg, nil } mainModulePrefix := MainModules.PathPrefix(mainModule) if mainModulePrefix == "" { pkg := strings.TrimPrefix(suffix, "/") if pkg == "builtin" { // "builtin" is a pseudo-package with a real source file. // It's not included in "std", so it shouldn't resolve from "." // within module "std" either. return "", errPkgIsBuiltin } return pkg, nil } pkg := mainModulePrefix + suffix if _, ok, err := dirInModule(pkg, mainModulePrefix, modRoot, true); err != nil { return "", err } else if !ok { // This main module could contain the directory but doesn't. Other main // modules might contain the directory, so wait till we finish the loop // to see if another main module contains directory. But if not, // return an error. if len(mainModulePrefix) > len(pkgNotFoundLongestPrefix) { pkgNotFoundLongestPrefix = mainModulePrefix pkgNotFoundErr = &PackageNotInModuleError{MainModules: []module.Version{mainModule}, Pattern: pkg} } continue } return pkg, nil } } if pkgNotFoundErr != nil { return "", pkgNotFoundErr } if sub := search.InDir(absDir, cfg.GOROOTsrc); sub != "" && sub != "." && !strings.Contains(sub, "@") { pkg := filepath.ToSlash(sub) if pkg == "builtin" { return "", errPkgIsBuiltin } return pkg, nil } pkg := pathInModuleCache(ctx, absDir, rs) if pkg == "" { dirstr := fmt.Sprintf("directory %s", base.ShortPath(absDir)) if dirstr == "directory ." { dirstr = "current directory" } if inWorkspaceMode() { if mr := findModuleRoot(absDir); mr != "" { return "", fmt.Errorf("%s is contained in a module that is not one of the workspace modules listed in go.work. You can add the module to the workspace using:\n\tgo work use %s", dirstr, base.ShortPath(mr)) } return "", fmt.Errorf("%s outside modules listed in go.work or their selected dependencies", dirstr) } return "", fmt.Errorf("%s outside main module or its selected dependencies", dirstr) } return pkg, nil } var ( errDirectoryNotFound = errors.New("directory not found") errPkgIsGorootSrc = errors.New("GOROOT/src is not an importable package") errPkgIsBuiltin = errors.New(`"builtin" is a pseudo-package, not an importable package`) ) // pathInModuleCache returns the import path of the directory dir, // if dir is in the module cache copy of a module in our build list. func pathInModuleCache(ctx context.Context, dir string, rs *Requirements) string { tryMod := func(m module.Version) (string, bool) { var root string var err error if repl := Replacement(m); repl.Path != "" && repl.Version == "" { root = repl.Path if !filepath.IsAbs(root) { root = filepath.Join(replaceRelativeTo(), root) } } else if repl.Path != "" { root, err = modfetch.DownloadDir(repl) } else { root, err = modfetch.DownloadDir(m) } if err != nil { return "", false } sub := search.InDir(dir, root) if sub == "" { return "", false } sub = filepath.ToSlash(sub) if strings.Contains(sub, "/vendor/") || strings.HasPrefix(sub, "vendor/") || strings.Contains(sub, "@") { return "", false } return path.Join(m.Path, filepath.ToSlash(sub)), true } if rs.pruning == pruned { for _, m := range rs.rootModules { if v, _ := rs.rootSelected(m.Path); v != m.Version { continue // m is a root, but we have a higher root for the same path. } if importPath, ok := tryMod(m); ok { // checkMultiplePaths ensures that a module can be used for at most one // requirement, so this must be it. return importPath } } } // None of the roots contained dir, or the graph is unpruned (so we don't want // to distinguish between roots and transitive dependencies). Either way, // check the full graph to see if the directory is a non-root dependency. // // If the roots are not consistent with the full module graph, the selected // versions of root modules may differ from what we already checked above. // Re-check those paths too. mg, _ := rs.Graph(ctx) var importPath string for _, m := range mg.BuildList() { var found bool importPath, found = tryMod(m) if found { break } } return importPath } // ImportFromFiles adds modules to the build list as needed // to satisfy the imports in the named Go source files. // // Errors in missing dependencies are silenced. // // TODO(bcmills): Silencing errors seems off. Take a closer look at this and // figure out what the error-reporting actually ought to be. func ImportFromFiles(ctx context.Context, gofiles []string) { rs := LoadModFile(ctx) tags := imports.Tags() imports, testImports, err := imports.ScanFiles(gofiles, tags) if err != nil { base.Fatalf("go: %v", err) } loaded = loadFromRoots(ctx, loaderParams{ PackageOpts: PackageOpts{ Tags: tags, ResolveMissingImports: true, SilencePackageErrors: true, }, requirements: rs, listRoots: func(*Requirements) (roots []string) { roots = append(roots, imports...) roots = append(roots, testImports...) return roots }, }) requirements = loaded.requirements if !ExplicitWriteGoMod { if err := commitRequirements(ctx); err != nil { base.Fatalf("go: %v", err) } } } // DirImportPath returns the effective import path for dir, // provided it is within a main module, or else returns ".". func (mms *MainModuleSet) DirImportPath(ctx context.Context, dir string) (path string, m module.Version) { if !HasModRoot() { return ".", module.Version{} } LoadModFile(ctx) // Sets targetPrefix. if !filepath.IsAbs(dir) { dir = filepath.Join(base.Cwd(), dir) } else { dir = filepath.Clean(dir) } var longestPrefix string var longestPrefixPath string var longestPrefixVersion module.Version for _, v := range mms.Versions() { modRoot := mms.ModRoot(v) if dir == modRoot { return mms.PathPrefix(v), v } if strings.HasPrefix(dir, modRoot+string(filepath.Separator)) { pathPrefix := MainModules.PathPrefix(v) if pathPrefix > longestPrefix { longestPrefix = pathPrefix longestPrefixVersion = v suffix := filepath.ToSlash(dir[len(modRoot):]) if strings.HasPrefix(suffix, "/vendor/") { longestPrefixPath = strings.TrimPrefix(suffix, "/vendor/") continue } longestPrefixPath = mms.PathPrefix(v) + suffix } } } if len(longestPrefix) > 0 { return longestPrefixPath, longestPrefixVersion } return ".", module.Version{} } // PackageModule returns the module providing the package named by the import path. func PackageModule(path string) module.Version { pkg, ok := loaded.pkgCache.Get(path).(*loadPkg) if !ok { return module.Version{} } return pkg.mod } // Lookup returns the source directory, import path, and any loading error for // the package at path as imported from the package in parentDir. // Lookup requires that one of the Load functions in this package has already // been called. func Lookup(parentPath string, parentIsStd bool, path string) (dir, realPath string, err error) { if path == "" { panic("Lookup called with empty package path") } if parentIsStd { path = loaded.stdVendor(parentPath, path) } pkg, ok := loaded.pkgCache.Get(path).(*loadPkg) if !ok { // The loader should have found all the relevant paths. // There are a few exceptions, though: // - during go list without -test, the p.Resolve calls to process p.TestImports and p.XTestImports // end up here to canonicalize the import paths. // - during any load, non-loaded packages like "unsafe" end up here. // - during any load, build-injected dependencies like "runtime/cgo" end up here. // - because we ignore appengine/* in the module loader, // the dependencies of any actual appengine/* library end up here. dir := findStandardImportPath(path) if dir != "" { return dir, path, nil } return "", "", errMissing } return pkg.dir, pkg.path, pkg.err } // A loader manages the process of loading information about // the required packages for a particular build, // checking that the packages are available in the module set, // and updating the module set if needed. type loader struct { loaderParams // allClosesOverTests indicates whether the "all" pattern includes // dependencies of tests outside the main module (as in Go 1.11–1.15). // (Otherwise — as in Go 1.16+ — the "all" pattern includes only the packages // transitively *imported by* the packages and tests in the main module.) allClosesOverTests bool // skipImportModFiles indicates whether we may skip loading go.mod files // for imported packages (as in 'go mod tidy' in Go 1.17–1.20). skipImportModFiles bool work *par.Queue // reset on each iteration roots []*loadPkg pkgCache *par.Cache // package path (string) → *loadPkg pkgs []*loadPkg // transitive closure of loaded packages and tests; populated in buildStacks } // loaderParams configure the packages loaded by, and the properties reported // by, a loader instance. type loaderParams struct { PackageOpts requirements *Requirements allPatternIsRoot bool // Is the "all" pattern an additional root? listRoots func(rs *Requirements) []string } func (ld *loader) reset() { select { case <-ld.work.Idle(): default: panic("loader.reset when not idle") } ld.roots = nil ld.pkgCache = new(par.Cache) ld.pkgs = nil } // errorf reports an error via either os.Stderr or base.Errorf, // according to whether ld.AllowErrors is set. func (ld *loader) errorf(format string, args ...any) { if ld.AllowErrors { fmt.Fprintf(os.Stderr, format, args...) } else { base.Errorf(format, args...) } } // A loadPkg records information about a single loaded package. type loadPkg struct { // Populated at construction time: path string // import path testOf *loadPkg // Populated at construction time and updated by (*loader).applyPkgFlags: flags atomicLoadPkgFlags // Populated by (*loader).load: mod module.Version // module providing package dir string // directory containing source code err error // error loading package imports []*loadPkg // packages imported by this one testImports []string // test-only imports, saved for use by pkg.test. inStd bool altMods []module.Version // modules that could have contained the package but did not // Populated by (*loader).pkgTest: testOnce sync.Once test *loadPkg // Populated by postprocessing in (*loader).buildStacks: stack *loadPkg // package importing this one in minimal import stack for this pkg } // loadPkgFlags is a set of flags tracking metadata about a package. type loadPkgFlags int8 const ( // pkgInAll indicates that the package is in the "all" package pattern, // regardless of whether we are loading the "all" package pattern. // // When the pkgInAll flag and pkgImportsLoaded flags are both set, the caller // who set the last of those flags must propagate the pkgInAll marking to all // of the imports of the marked package. // // A test is marked with pkgInAll if that test would promote the packages it // imports to be in "all" (such as when the test is itself within the main // module, or when ld.allClosesOverTests is true). pkgInAll loadPkgFlags = 1 << iota // pkgIsRoot indicates that the package matches one of the root package // patterns requested by the caller. // // If LoadTests is set, then when pkgIsRoot and pkgImportsLoaded are both set, // the caller who set the last of those flags must populate a test for the // package (in the pkg.test field). // // If the "all" pattern is included as a root, then non-test packages in "all" // are also roots (and must be marked pkgIsRoot). pkgIsRoot // pkgFromRoot indicates that the package is in the transitive closure of // imports starting at the roots. (Note that every package marked as pkgIsRoot // is also trivially marked pkgFromRoot.) pkgFromRoot // pkgImportsLoaded indicates that the imports and testImports fields of a // loadPkg have been populated. pkgImportsLoaded ) // has reports whether all of the flags in cond are set in f. func (f loadPkgFlags) has(cond loadPkgFlags) bool { return f&cond == cond } // An atomicLoadPkgFlags stores a loadPkgFlags for which individual flags can be // added atomically. type atomicLoadPkgFlags struct { bits atomic.Int32 } // update sets the given flags in af (in addition to any flags already set). // // update returns the previous flag state so that the caller may determine which // flags were newly-set. func (af *atomicLoadPkgFlags) update(flags loadPkgFlags) (old loadPkgFlags) { for { old := af.bits.Load() new := old | int32(flags) if new == old || af.bits.CompareAndSwap(old, new) { return loadPkgFlags(old) } } } // has reports whether all of the flags in cond are set in af. func (af *atomicLoadPkgFlags) has(cond loadPkgFlags) bool { return loadPkgFlags(af.bits.Load())&cond == cond } // isTest reports whether pkg is a test of another package. func (pkg *loadPkg) isTest() bool { return pkg.testOf != nil } // fromExternalModule reports whether pkg was loaded from a module other than // the main module. func (pkg *loadPkg) fromExternalModule() bool { if pkg.mod.Path == "" { return false // loaded from the standard library, not a module } return !MainModules.Contains(pkg.mod.Path) } var errMissing = errors.New("cannot find package") // loadFromRoots attempts to load the build graph needed to process a set of // root packages and their dependencies. // // The set of root packages is returned by the params.listRoots function, and // expanded to the full set of packages by tracing imports (and possibly tests) // as needed. func loadFromRoots(ctx context.Context, params loaderParams) *loader { ld := &loader{ loaderParams: params, work: par.NewQueue(runtime.GOMAXPROCS(0)), } if ld.GoVersion == "" { ld.GoVersion = MainModules.GoVersion() if ld.Tidy && versionLess(LatestGoVersion(), ld.GoVersion) { ld.errorf("go: go.mod file indicates go %s, but maximum version supported by tidy is %s\n", ld.GoVersion, LatestGoVersion()) base.ExitIfErrors() } } if ld.Tidy { if ld.TidyCompatibleVersion == "" { ld.TidyCompatibleVersion = priorGoVersion(ld.GoVersion) } else if versionLess(ld.GoVersion, ld.TidyCompatibleVersion) { // Each version of the Go toolchain knows how to interpret go.mod and // go.sum files produced by all previous versions, so a compatibility // version higher than the go.mod version adds nothing. ld.TidyCompatibleVersion = ld.GoVersion } if semver.Compare("v"+ld.GoVersion, tidyGoModSumVersionV) < 0 { ld.skipImportModFiles = true } } if semver.Compare("v"+ld.GoVersion, narrowAllVersionV) < 0 && !ld.UseVendorAll { // The module's go version explicitly predates the change in "all" for graph // pruning, so continue to use the older interpretation. ld.allClosesOverTests = true } var err error desiredPruning := pruningForGoVersion(ld.GoVersion) if ld.requirements.pruning == workspace { desiredPruning = workspace } ld.requirements, err = convertPruning(ctx, ld.requirements, desiredPruning) if err != nil { ld.errorf("go: %v\n", err) } if ld.requirements.pruning == unpruned { // If the module graph does not support pruning, we assume that we will need // the full module graph in order to load package dependencies. // // This might not be strictly necessary, but it matches the historical // behavior of the 'go' command and keeps the go.mod file more consistent in // case of erroneous hand-edits — which are less likely to be detected by // spot-checks in modules that do not maintain the expanded go.mod // requirements needed for graph pruning. var err error ld.requirements, _, err = expandGraph(ctx, ld.requirements) if err != nil { ld.errorf("go: %v\n", err) } } for { ld.reset() // Load the root packages and their imports. // Note: the returned roots can change on each iteration, // since the expansion of package patterns depends on the // build list we're using. rootPkgs := ld.listRoots(ld.requirements) if ld.requirements.pruning == pruned && cfg.BuildMod == "mod" { // Before we start loading transitive imports of packages, locate all of // the root packages and promote their containing modules to root modules // dependencies. If their go.mod files are tidy (the common case) and the // set of root packages does not change then we can select the correct // versions of all transitive imports on the first try and complete // loading in a single iteration. changedBuildList := ld.preloadRootModules(ctx, rootPkgs) if changedBuildList { // The build list has changed, so the set of root packages may have also // changed. Start over to pick up the changes. (Preloading roots is much // cheaper than loading the full import graph, so we would rather pay // for an extra iteration of preloading than potentially end up // discarding the result of a full iteration of loading.) continue } } inRoots := map[*loadPkg]bool{} for _, path := range rootPkgs { root := ld.pkg(ctx, path, pkgIsRoot) if !inRoots[root] { ld.roots = append(ld.roots, root) inRoots[root] = true } } // ld.pkg adds imported packages to the work queue and calls applyPkgFlags, // which adds tests (and test dependencies) as needed. // // When all of the work in the queue has completed, we'll know that the // transitive closure of dependencies has been loaded. <-ld.work.Idle() ld.buildStacks() changed, err := ld.updateRequirements(ctx) if err != nil { ld.errorf("go: %v\n", err) break } if changed { // Don't resolve missing imports until the module graph has stabilized. // If the roots are still changing, they may turn out to specify a // requirement on the missing package(s), and we would rather use a // version specified by a new root than add a new dependency on an // unrelated version. continue } if !ld.ResolveMissingImports || (!HasModRoot() && !allowMissingModuleImports) { // We've loaded as much as we can without resolving missing imports. break } modAddedBy := ld.resolveMissingImports(ctx) if len(modAddedBy) == 0 { // The roots are stable, and we've resolved all of the missing packages // that we can. break } toAdd := make([]module.Version, 0, len(modAddedBy)) for m := range modAddedBy { toAdd = append(toAdd, m) } module.Sort(toAdd) // to make errors deterministic // We ran updateRequirements before resolving missing imports and it didn't // make any changes, so we know that the requirement graph is already // consistent with ld.pkgs: we don't need to pass ld.pkgs to updateRoots // again. (That would waste time looking for changes that we have already // applied.) var noPkgs []*loadPkg // We also know that we're going to call updateRequirements again next // iteration so we don't need to also update it here. (That would waste time // computing a "direct" map that we'll have to recompute later anyway.) direct := ld.requirements.direct rs, err := updateRoots(ctx, direct, ld.requirements, noPkgs, toAdd, ld.AssumeRootsImported) if err != nil { // If an error was found in a newly added module, report the package // import stack instead of the module requirement stack. Packages // are more descriptive. if err, ok := err.(*mvs.BuildListError); ok { if pkg := modAddedBy[err.Module()]; pkg != nil { ld.errorf("go: %s: %v\n", pkg.stackText(), err.Err) break } } ld.errorf("go: %v\n", err) break } if reflect.DeepEqual(rs.rootModules, ld.requirements.rootModules) { // Something is deeply wrong. resolveMissingImports gave us a non-empty // set of modules to add to the graph, but adding those modules had no // effect — either they were already in the graph, or updateRoots did not // add them as requested. panic(fmt.Sprintf("internal error: adding %v to module graph had no effect on root requirements (%v)", toAdd, rs.rootModules)) } ld.requirements = rs } base.ExitIfErrors() // TODO(bcmills): Is this actually needed? // Tidy the build list, if applicable, before we report errors. // (The process of tidying may remove errors from irrelevant dependencies.) if ld.Tidy { rs, err := tidyRoots(ctx, ld.requirements, ld.pkgs) if err != nil { ld.errorf("go: %v\n", err) base.ExitIfErrors() } else { if ld.requirements.pruning == pruned { // We continuously add tidy roots to ld.requirements during loading, so at // this point the tidy roots should be a subset of the roots of // ld.requirements, ensuring that no new dependencies are brought inside // the graph-pruning horizon. // If that is not the case, there is a bug in the loading loop above. for _, m := range rs.rootModules { if v, ok := ld.requirements.rootSelected(m.Path); !ok || v != m.Version { ld.errorf("go: internal error: a requirement on %v is needed but was not added during package loading\n", m) base.ExitIfErrors() } } } ld.requirements = rs } } // Report errors, if any. for _, pkg := range ld.pkgs { if pkg.err == nil { continue } // Add importer information to checksum errors. if sumErr := (*ImportMissingSumError)(nil); errors.As(pkg.err, &sumErr) { if importer := pkg.stack; importer != nil { sumErr.importer = importer.path sumErr.importerVersion = importer.mod.Version sumErr.importerIsTest = importer.testOf != nil } } if stdErr := (*ImportMissingError)(nil); errors.As(pkg.err, &stdErr) && stdErr.isStd { // Add importer go version information to import errors of standard // library packages arising from newer releases. if importer := pkg.stack; importer != nil { if v, ok := rawGoVersion.Load(importer.mod); ok && versionLess(LatestGoVersion(), v.(string)) { stdErr.importerGoVersion = v.(string) } } if ld.SilenceMissingStdImports { continue } } if ld.SilencePackageErrors { continue } if ld.SilenceNoGoErrors && errors.Is(pkg.err, imports.ErrNoGo) { continue } ld.errorf("%s: %v\n", pkg.stackText(), pkg.err) } ld.checkMultiplePaths() return ld } // versionLess returns whether a < b according to semantic version precedence. // Both strings are interpreted as go version strings, e.g. "1.19". func versionLess(a, b string) bool { return semver.Compare("v"+a, "v"+b) < 0 } // updateRequirements ensures that ld.requirements is consistent with the // information gained from ld.pkgs. // // In particular: // // - Modules that provide packages directly imported from the main module are // marked as direct, and are promoted to explicit roots. If a needed root // cannot be promoted due to -mod=readonly or -mod=vendor, the importing // package is marked with an error. // // - If ld scanned the "all" pattern independent of build constraints, it is // guaranteed to have seen every direct import. Module dependencies that did // not provide any directly-imported package are then marked as indirect. // // - Root dependencies are updated to their selected versions. // // The "changed" return value reports whether the update changed the selected // version of any module that either provided a loaded package or may now // provide a package that was previously unresolved. func (ld *loader) updateRequirements(ctx context.Context) (changed bool, err error) { rs := ld.requirements // direct contains the set of modules believed to provide packages directly // imported by the main module. var direct map[string]bool // If we didn't scan all of the imports from the main module, or didn't use // imports.AnyTags, then we didn't necessarily load every package that // contributes “direct” imports — so we can't safely mark existing direct // dependencies in ld.requirements as indirect-only. Propagate them as direct. loadedDirect := ld.allPatternIsRoot && reflect.DeepEqual(ld.Tags, imports.AnyTags()) if loadedDirect { direct = make(map[string]bool) } else { // TODO(bcmills): It seems like a shame to allocate and copy a map here when // it will only rarely actually vary from rs.direct. Measure this cost and // maybe avoid the copy. direct = make(map[string]bool, len(rs.direct)) for mPath := range rs.direct { direct[mPath] = true } } for _, pkg := range ld.pkgs { if pkg.mod.Version != "" || !MainModules.Contains(pkg.mod.Path) { continue } for _, dep := range pkg.imports { if !dep.fromExternalModule() { continue } if inWorkspaceMode() { // In workspace mode / workspace pruning mode, the roots are the main modules // rather than the main module's direct dependencies. The check below on the selected // roots does not apply. if mg, err := rs.Graph(ctx); err != nil { return false, err } else if _, ok := mg.RequiredBy(dep.mod); !ok { // dep.mod is not an explicit dependency, but needs to be. // See comment on error returned below. pkg.err = &DirectImportFromImplicitDependencyError{ ImporterPath: pkg.path, ImportedPath: dep.path, Module: dep.mod, } } continue } if pkg.err == nil && cfg.BuildMod != "mod" { if v, ok := rs.rootSelected(dep.mod.Path); !ok || v != dep.mod.Version { // dep.mod is not an explicit dependency, but needs to be. // Because we are not in "mod" mode, we will not be able to update it. // Instead, mark the importing package with an error. // // TODO(#41688): The resulting error message fails to include the file // position of the import statement (because that information is not // tracked by the module loader). Figure out how to plumb the import // position through. pkg.err = &DirectImportFromImplicitDependencyError{ ImporterPath: pkg.path, ImportedPath: dep.path, Module: dep.mod, } // cfg.BuildMod does not allow us to change dep.mod to be a direct // dependency, so don't mark it as such. continue } } // dep is a package directly imported by a package or test in the main // module and loaded from some other module (not the standard library). // Mark its module as a direct dependency. direct[dep.mod.Path] = true } } var addRoots []module.Version if ld.Tidy { // When we are tidying a module with a pruned dependency graph, we may need // to add roots to preserve the versions of indirect, test-only dependencies // that are upgraded above or otherwise missing from the go.mod files of // direct dependencies. (For example, the direct dependency might be a very // stable codebase that predates modules and thus lacks a go.mod file, or // the author of the direct dependency may have forgotten to commit a change // to the go.mod file, or may have made an erroneous hand-edit that causes // it to be untidy.) // // Promoting an indirect dependency to a root adds the next layer of its // dependencies to the module graph, which may increase the selected // versions of other modules from which we have already loaded packages. // So after we promote an indirect dependency to a root, we need to reload // packages, which means another iteration of loading. // // As an extra wrinkle, the upgrades due to promoting a root can cause // previously-resolved packages to become unresolved. For example, the // module providing an unstable package might be upgraded to a version // that no longer contains that package. If we then resolve the missing // package, we might add yet another root that upgrades away some other // dependency. (The tests in mod_tidy_convergence*.txt illustrate some // particularly worrisome cases.) // // To ensure that this process of promoting, adding, and upgrading roots // eventually terminates, during iteration we only ever add modules to the // root set — we only remove irrelevant roots at the very end of // iteration, after we have already added every root that we plan to need // in the (eventual) tidy root set. // // Since we do not remove any roots during iteration, even if they no // longer provide any imported packages, the selected versions of the // roots can only increase and the set of roots can only expand. The set // of extant root paths is finite and the set of versions of each path is // finite, so the iteration *must* reach a stable fixed-point. tidy, err := tidyRoots(ctx, rs, ld.pkgs) if err != nil { return false, err } addRoots = tidy.rootModules } rs, err = updateRoots(ctx, direct, rs, ld.pkgs, addRoots, ld.AssumeRootsImported) if err != nil { // We don't actually know what even the root requirements are supposed to be, // so we can't proceed with loading. Return the error to the caller return false, err } if rs != ld.requirements && !reflect.DeepEqual(rs.rootModules, ld.requirements.rootModules) { // The roots of the module graph have changed in some way (not just the // "direct" markings). Check whether the changes affected any of the loaded // packages. mg, err := rs.Graph(ctx) if err != nil { return false, err } for _, pkg := range ld.pkgs { if pkg.fromExternalModule() && mg.Selected(pkg.mod.Path) != pkg.mod.Version { changed = true break } if pkg.err != nil { // Promoting a module to a root may resolve an import that was // previously missing (by pulling in a previously-prune dependency that // provides it) or ambiguous (by promoting exactly one of the // alternatives to a root and ignoring the second-level alternatives) or // otherwise errored out (by upgrading from a version that cannot be // fetched to one that can be). // // Instead of enumerating all of the possible errors, we'll just check // whether importFromModules returns nil for the package. // False-positives are ok: if we have a false-positive here, we'll do an // extra iteration of package loading this time, but we'll still // converge when the root set stops changing. // // In some sense, we can think of this as ‘upgraded the module providing // pkg.path from "none" to a version higher than "none"’. if _, _, _, _, err = importFromModules(ctx, pkg.path, rs, nil, ld.skipImportModFiles); err == nil { changed = true break } } } } ld.requirements = rs return changed, nil } // resolveMissingImports returns a set of modules that could be added as // dependencies in order to resolve missing packages from pkgs. // // The newly-resolved packages are added to the addedModuleFor map, and // resolveMissingImports returns a map from each new module version to // the first missing package that module would resolve. func (ld *loader) resolveMissingImports(ctx context.Context) (modAddedBy map[module.Version]*loadPkg) { type pkgMod struct { pkg *loadPkg mod *module.Version } var pkgMods []pkgMod for _, pkg := range ld.pkgs { if pkg.err == nil { continue } if pkg.isTest() { // If we are missing a test, we are also missing its non-test version, and // we should only add the missing import once. continue } if !errors.As(pkg.err, new(*ImportMissingError)) { // Leave other errors for Import or load.Packages to report. continue } pkg := pkg var mod module.Version ld.work.Add(func() { var err error mod, err = queryImport(ctx, pkg.path, ld.requirements) if err != nil { var ime *ImportMissingError if errors.As(err, &ime) { for curstack := pkg.stack; curstack != nil; curstack = curstack.stack { if MainModules.Contains(curstack.mod.Path) { ime.ImportingMainModule = curstack.mod break } } } // pkg.err was already non-nil, so we can reasonably attribute the error // for pkg to either the original error or the one returned by // queryImport. The existing error indicates only that we couldn't find // the package, whereas the query error also explains why we didn't fix // the problem — so we prefer the latter. pkg.err = err } // err is nil, but we intentionally leave pkg.err non-nil and pkg.mod // unset: we still haven't satisfied other invariants of a // successfully-loaded package, such as scanning and loading the imports // of that package. If we succeed in resolving the new dependency graph, // the caller can reload pkg and update the error at that point. // // Even then, the package might not be loaded from the version we've // identified here. The module may be upgraded by some other dependency, // or by a transitive dependency of mod itself, or — less likely — the // package may be rejected by an AllowPackage hook or rendered ambiguous // by some other newly-added or newly-upgraded dependency. }) pkgMods = append(pkgMods, pkgMod{pkg: pkg, mod: &mod}) } <-ld.work.Idle() modAddedBy = map[module.Version]*loadPkg{} for _, pm := range pkgMods { pkg, mod := pm.pkg, *pm.mod if mod.Path == "" { continue } fmt.Fprintf(os.Stderr, "go: found %s in %s %s\n", pkg.path, mod.Path, mod.Version) if modAddedBy[mod] == nil { modAddedBy[mod] = pkg } } return modAddedBy } // pkg locates the *loadPkg for path, creating and queuing it for loading if // needed, and updates its state to reflect the given flags. // // The imports of the returned *loadPkg will be loaded asynchronously in the // ld.work queue, and its test (if requested) will also be populated once // imports have been resolved. When ld.work goes idle, all transitive imports of // the requested package (and its test, if requested) will have been loaded. func (ld *loader) pkg(ctx context.Context, path string, flags loadPkgFlags) *loadPkg { if flags.has(pkgImportsLoaded) { panic("internal error: (*loader).pkg called with pkgImportsLoaded flag set") } pkg := ld.pkgCache.Do(path, func() any { pkg := &loadPkg{ path: path, } ld.applyPkgFlags(ctx, pkg, flags) ld.work.Add(func() { ld.load(ctx, pkg) }) return pkg }).(*loadPkg) ld.applyPkgFlags(ctx, pkg, flags) return pkg } // applyPkgFlags updates pkg.flags to set the given flags and propagate the // (transitive) effects of those flags, possibly loading or enqueueing further // packages as a result. func (ld *loader) applyPkgFlags(ctx context.Context, pkg *loadPkg, flags loadPkgFlags) { if flags == 0 { return } if flags.has(pkgInAll) && ld.allPatternIsRoot && !pkg.isTest() { // This package matches a root pattern by virtue of being in "all". flags |= pkgIsRoot } if flags.has(pkgIsRoot) { flags |= pkgFromRoot } old := pkg.flags.update(flags) new := old | flags if new == old || !new.has(pkgImportsLoaded) { // We either didn't change the state of pkg, or we don't know anything about // its dependencies yet. Either way, we can't usefully load its test or // update its dependencies. return } if !pkg.isTest() { // Check whether we should add (or update the flags for) a test for pkg. // ld.pkgTest is idempotent and extra invocations are inexpensive, // so it's ok if we call it more than is strictly necessary. wantTest := false switch { case ld.allPatternIsRoot && MainModules.Contains(pkg.mod.Path): // We are loading the "all" pattern, which includes packages imported by // tests in the main module. This package is in the main module, so we // need to identify the imports of its test even if LoadTests is not set. // // (We will filter out the extra tests explicitly in computePatternAll.) wantTest = true case ld.allPatternIsRoot && ld.allClosesOverTests && new.has(pkgInAll): // This variant of the "all" pattern includes imports of tests of every // package that is itself in "all", and pkg is in "all", so its test is // also in "all" (as above). wantTest = true case ld.LoadTests && new.has(pkgIsRoot): // LoadTest explicitly requests tests of “the root packages”. wantTest = true } if wantTest { var testFlags loadPkgFlags if MainModules.Contains(pkg.mod.Path) || (ld.allClosesOverTests && new.has(pkgInAll)) { // Tests of packages in the main module are in "all", in the sense that // they cause the packages they import to also be in "all". So are tests // of packages in "all" if "all" closes over test dependencies. testFlags |= pkgInAll } ld.pkgTest(ctx, pkg, testFlags) } } if new.has(pkgInAll) && !old.has(pkgInAll|pkgImportsLoaded) { // We have just marked pkg with pkgInAll, or we have just loaded its // imports, or both. Now is the time to propagate pkgInAll to the imports. for _, dep := range pkg.imports { ld.applyPkgFlags(ctx, dep, pkgInAll) } } if new.has(pkgFromRoot) && !old.has(pkgFromRoot|pkgImportsLoaded) { for _, dep := range pkg.imports { ld.applyPkgFlags(ctx, dep, pkgFromRoot) } } } // preloadRootModules loads the module requirements needed to identify the // selected version of each module providing a package in rootPkgs, // adding new root modules to the module graph if needed. func (ld *loader) preloadRootModules(ctx context.Context, rootPkgs []string) (changedBuildList bool) { needc := make(chan map[module.Version]bool, 1) needc <- map[module.Version]bool{} for _, path := range rootPkgs { path := path ld.work.Add(func() { // First, try to identify the module containing the package using only roots. // // If the main module is tidy and the package is in "all" — or if we're // lucky — we can identify all of its imports without actually loading the // full module graph. m, _, _, _, err := importFromModules(ctx, path, ld.requirements, nil, ld.skipImportModFiles) if err != nil { var missing *ImportMissingError if errors.As(err, &missing) && ld.ResolveMissingImports { // This package isn't provided by any selected module. // If we can find it, it will be a new root dependency. m, err = queryImport(ctx, path, ld.requirements) } if err != nil { // We couldn't identify the root module containing this package. // Leave it unresolved; we will report it during loading. return } } if m.Path == "" { // The package is in std or cmd. We don't need to change the root set. return } v, ok := ld.requirements.rootSelected(m.Path) if !ok || v != m.Version { // We found the requested package in m, but m is not a root, so // loadModGraph will not load its requirements. We need to promote the // module to a root to ensure that any other packages this package // imports are resolved from correct dependency versions. // // (This is the “argument invariant” from // https://golang.org/design/36460-lazy-module-loading.) need := <-needc need[m] = true needc <- need } }) } <-ld.work.Idle() need := <-needc if len(need) == 0 { return false // No roots to add. } toAdd := make([]module.Version, 0, len(need)) for m := range need { toAdd = append(toAdd, m) } module.Sort(toAdd) rs, err := updateRoots(ctx, ld.requirements.direct, ld.requirements, nil, toAdd, ld.AssumeRootsImported) if err != nil { // We are missing some root dependency, and for some reason we can't load // enough of the module dependency graph to add the missing root. Package // loading is doomed to fail, so fail quickly. ld.errorf("go: %v\n", err) base.ExitIfErrors() return false } if reflect.DeepEqual(rs.rootModules, ld.requirements.rootModules) { // Something is deeply wrong. resolveMissingImports gave us a non-empty // set of modules to add to the graph, but adding those modules had no // effect — either they were already in the graph, or updateRoots did not // add them as requested. panic(fmt.Sprintf("internal error: adding %v to module graph had no effect on root requirements (%v)", toAdd, rs.rootModules)) } ld.requirements = rs return true } // load loads an individual package. func (ld *loader) load(ctx context.Context, pkg *loadPkg) { var mg *ModuleGraph if ld.requirements.pruning == unpruned { var err error mg, err = ld.requirements.Graph(ctx) if err != nil { // We already checked the error from Graph in loadFromRoots and/or // updateRequirements, so we ignored the error on purpose and we should // keep trying to push past it. // // However, because mg may be incomplete (and thus may select inaccurate // versions), we shouldn't use it to load packages. Instead, we pass a nil // *ModuleGraph, which will cause mg to first try loading from only the // main module and root dependencies. mg = nil } } var modroot string pkg.mod, modroot, pkg.dir, pkg.altMods, pkg.err = importFromModules(ctx, pkg.path, ld.requirements, mg, ld.skipImportModFiles) if pkg.dir == "" { return } if MainModules.Contains(pkg.mod.Path) { // Go ahead and mark pkg as in "all". This provides the invariant that a // package that is *only* imported by other packages in "all" is always // marked as such before loading its imports. // // We don't actually rely on that invariant at the moment, but it may // improve efficiency somewhat and makes the behavior a bit easier to reason // about (by reducing churn on the flag bits of dependencies), and costs // essentially nothing (these atomic flag ops are essentially free compared // to scanning source code for imports). ld.applyPkgFlags(ctx, pkg, pkgInAll) } if ld.AllowPackage != nil { if err := ld.AllowPackage(ctx, pkg.path, pkg.mod); err != nil { pkg.err = err } } pkg.inStd = (search.IsStandardImportPath(pkg.path) && search.InDir(pkg.dir, cfg.GOROOTsrc) != "") var imports, testImports []string if cfg.BuildContext.Compiler == "gccgo" && pkg.inStd { // We can't scan standard packages for gccgo. } else { var err error imports, testImports, err = scanDir(modroot, pkg.dir, ld.Tags) if err != nil { pkg.err = err return } } pkg.imports = make([]*loadPkg, 0, len(imports)) var importFlags loadPkgFlags if pkg.flags.has(pkgInAll) { importFlags = pkgInAll } for _, path := range imports { if pkg.inStd { // Imports from packages in "std" and "cmd" should resolve using // GOROOT/src/vendor even when "std" is not the main module. path = ld.stdVendor(pkg.path, path) } pkg.imports = append(pkg.imports, ld.pkg(ctx, path, importFlags)) } pkg.testImports = testImports ld.applyPkgFlags(ctx, pkg, pkgImportsLoaded) } // pkgTest locates the test of pkg, creating it if needed, and updates its state // to reflect the given flags. // // pkgTest requires that the imports of pkg have already been loaded (flagged // with pkgImportsLoaded). func (ld *loader) pkgTest(ctx context.Context, pkg *loadPkg, testFlags loadPkgFlags) *loadPkg { if pkg.isTest() { panic("pkgTest called on a test package") } createdTest := false pkg.testOnce.Do(func() { pkg.test = &loadPkg{ path: pkg.path, testOf: pkg, mod: pkg.mod, dir: pkg.dir, err: pkg.err, inStd: pkg.inStd, } ld.applyPkgFlags(ctx, pkg.test, testFlags) createdTest = true }) test := pkg.test if createdTest { test.imports = make([]*loadPkg, 0, len(pkg.testImports)) var importFlags loadPkgFlags if test.flags.has(pkgInAll) { importFlags = pkgInAll } for _, path := range pkg.testImports { if pkg.inStd { path = ld.stdVendor(test.path, path) } test.imports = append(test.imports, ld.pkg(ctx, path, importFlags)) } pkg.testImports = nil ld.applyPkgFlags(ctx, test, pkgImportsLoaded) } else { ld.applyPkgFlags(ctx, test, testFlags) } return test } // stdVendor returns the canonical import path for the package with the given // path when imported from the standard-library package at parentPath. func (ld *loader) stdVendor(parentPath, path string) string { if search.IsStandardImportPath(path) { return path } if str.HasPathPrefix(parentPath, "cmd") { if !ld.VendorModulesInGOROOTSrc || !MainModules.Contains("cmd") { vendorPath := pathpkg.Join("cmd", "vendor", path) if _, err := os.Stat(filepath.Join(cfg.GOROOTsrc, filepath.FromSlash(vendorPath))); err == nil { return vendorPath } } } else if !ld.VendorModulesInGOROOTSrc || !MainModules.Contains("std") || str.HasPathPrefix(parentPath, "vendor") { // If we are outside of the 'std' module, resolve imports from within 'std' // to the vendor directory. // // Do the same for importers beginning with the prefix 'vendor/' even if we // are *inside* of the 'std' module: the 'vendor/' packages that resolve // globally from GOROOT/src/vendor (and are listed as part of 'go list std') // are distinct from the real module dependencies, and cannot import // internal packages from the real module. // // (Note that although the 'vendor/' packages match the 'std' *package* // pattern, they are not part of the std *module*, and do not affect // 'go mod tidy' and similar module commands when working within std.) vendorPath := pathpkg.Join("vendor", path) if _, err := os.Stat(filepath.Join(cfg.GOROOTsrc, filepath.FromSlash(vendorPath))); err == nil { return vendorPath } } // Not vendored: resolve from modules. return path } // computePatternAll returns the list of packages matching pattern "all", // starting with a list of the import paths for the packages in the main module. func (ld *loader) computePatternAll() (all []string) { for _, pkg := range ld.pkgs { if pkg.flags.has(pkgInAll) && !pkg.isTest() { all = append(all, pkg.path) } } sort.Strings(all) return all } // checkMultiplePaths verifies that a given module path is used as itself // or as a replacement for another module, but not both at the same time. // // (See https://golang.org/issue/26607 and https://golang.org/issue/34650.) func (ld *loader) checkMultiplePaths() { mods := ld.requirements.rootModules if cached := ld.requirements.graph.Load(); cached != nil { if mg := cached.mg; mg != nil { mods = mg.BuildList() } } firstPath := map[module.Version]string{} for _, mod := range mods { src := resolveReplacement(mod) if prev, ok := firstPath[src]; !ok { firstPath[src] = mod.Path } else if prev != mod.Path { ld.errorf("go: %s@%s used for two different module paths (%s and %s)\n", src.Path, src.Version, prev, mod.Path) } } } // checkTidyCompatibility emits an error if any package would be loaded from a // different module under rs than under ld.requirements. func (ld *loader) checkTidyCompatibility(ctx context.Context, rs *Requirements) { suggestUpgrade := false suggestEFlag := false suggestFixes := func() { if ld.AllowErrors { // The user is explicitly ignoring these errors, so don't bother them with // other options. return } // We print directly to os.Stderr because this information is advice about // how to fix errors, not actually an error itself. // (The actual errors should have been logged already.) fmt.Fprintln(os.Stderr) goFlag := "" if ld.GoVersion != MainModules.GoVersion() { goFlag = " -go=" + ld.GoVersion } compatFlag := "" if ld.TidyCompatibleVersion != priorGoVersion(ld.GoVersion) { compatFlag = " -compat=" + ld.TidyCompatibleVersion } if suggestUpgrade { eDesc := "" eFlag := "" if suggestEFlag { eDesc = ", leaving some packages unresolved" eFlag = " -e" } fmt.Fprintf(os.Stderr, "To upgrade to the versions selected by go %s%s:\n\tgo mod tidy%s -go=%s && go mod tidy%s -go=%s%s\n", ld.TidyCompatibleVersion, eDesc, eFlag, ld.TidyCompatibleVersion, eFlag, ld.GoVersion, compatFlag) } else if suggestEFlag { // If some packages are missing but no package is upgraded, then we // shouldn't suggest upgrading to the Go 1.16 versions explicitly — that // wouldn't actually fix anything for Go 1.16 users, and *would* break // something for Go 1.17 users. fmt.Fprintf(os.Stderr, "To proceed despite packages unresolved in go %s:\n\tgo mod tidy -e%s%s\n", ld.TidyCompatibleVersion, goFlag, compatFlag) } fmt.Fprintf(os.Stderr, "If reproducibility with go %s is not needed:\n\tgo mod tidy%s -compat=%s\n", ld.TidyCompatibleVersion, goFlag, ld.GoVersion) // TODO(#46141): Populate the linked wiki page. fmt.Fprintf(os.Stderr, "For other options, see:\n\thttps://golang.org/doc/modules/pruning\n") } mg, err := rs.Graph(ctx) if err != nil { ld.errorf("go: error loading go %s module graph: %v\n", ld.TidyCompatibleVersion, err) suggestFixes() return } // Re-resolve packages in parallel. // // We re-resolve each package — rather than just checking versions — to ensure // that we have fetched module source code (and, importantly, checksums for // that source code) for all modules that are necessary to ensure that imports // are unambiguous. That also produces clearer diagnostics, since we can say // exactly what happened to the package if it became ambiguous or disappeared // entirely. // // We re-resolve the packages in parallel because this process involves disk // I/O to check for package sources, and because the process of checking for // ambiguous imports may require us to download additional modules that are // otherwise pruned out in Go 1.17 — we don't want to block progress on other // packages while we wait for a single new download. type mismatch struct { mod module.Version err error } mismatchMu := make(chan map[*loadPkg]mismatch, 1) mismatchMu <- map[*loadPkg]mismatch{} for _, pkg := range ld.pkgs { if pkg.mod.Path == "" && pkg.err == nil { // This package is from the standard library (which does not vary based on // the module graph). continue } pkg := pkg ld.work.Add(func() { mod, _, _, _, err := importFromModules(ctx, pkg.path, rs, mg, ld.skipImportModFiles) if mod != pkg.mod { mismatches := <-mismatchMu mismatches[pkg] = mismatch{mod: mod, err: err} mismatchMu <- mismatches } }) } <-ld.work.Idle() mismatches := <-mismatchMu if len(mismatches) == 0 { // Since we're running as part of 'go mod tidy', the roots of the module // graph should contain only modules that are relevant to some package in // the package graph. We checked every package in the package graph and // didn't find any mismatches, so that must mean that all of the roots of // the module graph are also consistent. // // If we're wrong, Go 1.16 in -mod=readonly mode will error out with // "updates to go.mod needed", which would be very confusing. So instead, // we'll double-check that our reasoning above actually holds — if it // doesn't, we'll emit an internal error and hopefully the user will report // it as a bug. for _, m := range ld.requirements.rootModules { if v := mg.Selected(m.Path); v != m.Version { fmt.Fprintln(os.Stderr) base.Fatalf("go: internal error: failed to diagnose selected-version mismatch for module %s: go %s selects %s, but go %s selects %s\n\tPlease report this at https://golang.org/issue.", m.Path, ld.GoVersion, m.Version, ld.TidyCompatibleVersion, v) } } return } // Iterate over the packages (instead of the mismatches map) to emit errors in // deterministic order. for _, pkg := range ld.pkgs { mismatch, ok := mismatches[pkg] if !ok { continue } if pkg.isTest() { // We already did (or will) report an error for the package itself, // so don't report a duplicate (and more vebose) error for its test. if _, ok := mismatches[pkg.testOf]; !ok { base.Fatalf("go: internal error: mismatch recorded for test %s, but not its non-test package", pkg.path) } continue } switch { case mismatch.err != nil: // pkg resolved successfully, but errors out using the requirements in rs. // // This could occur because the import is provided by a single root (and // is thus unambiguous in a main module with a pruned module graph) and // also one or more transitive dependencies (and is ambiguous with an // unpruned graph). // // It could also occur because some transitive dependency upgrades the // module that previously provided the package to a version that no // longer does, or to a version for which the module source code (but // not the go.mod file in isolation) has a checksum error. if missing := (*ImportMissingError)(nil); errors.As(mismatch.err, &missing) { selected := module.Version{ Path: pkg.mod.Path, Version: mg.Selected(pkg.mod.Path), } ld.errorf("%s loaded from %v,\n\tbut go %s would fail to locate it in %s\n", pkg.stackText(), pkg.mod, ld.TidyCompatibleVersion, selected) } else { if ambiguous := (*AmbiguousImportError)(nil); errors.As(mismatch.err, &ambiguous) { // TODO: Is this check needed? } ld.errorf("%s loaded from %v,\n\tbut go %s would fail to locate it:\n\t%v\n", pkg.stackText(), pkg.mod, ld.TidyCompatibleVersion, mismatch.err) } suggestEFlag = true // Even if we press ahead with the '-e' flag, the older version will // error out in readonly mode if it thinks the go.mod file contains // any *explicit* dependency that is not at its selected version, // even if that dependency is not relevant to any package being loaded. // // We check for that condition here. If all of the roots are consistent // the '-e' flag suffices, but otherwise we need to suggest an upgrade. if !suggestUpgrade { for _, m := range ld.requirements.rootModules { if v := mg.Selected(m.Path); v != m.Version { suggestUpgrade = true break } } } case pkg.err != nil: // pkg had an error in with a pruned module graph (presumably suppressed // with the -e flag), but the error went away using an unpruned graph. // // This is possible, if, say, the import is unresolved in the pruned graph // (because the "latest" version of each candidate module either is // unavailable or does not contain the package), but is resolved in the // unpruned graph due to a newer-than-latest dependency that is normally // pruned out. // // This could also occur if the source code for the module providing the // package in the pruned graph has a checksum error, but the unpruned // graph upgrades that module to a version with a correct checksum. // // pkg.err should have already been logged elsewhere — along with a // stack trace — so log only the import path and non-error info here. suggestUpgrade = true ld.errorf("%s failed to load from any module,\n\tbut go %s would load it from %v\n", pkg.path, ld.TidyCompatibleVersion, mismatch.mod) case pkg.mod != mismatch.mod: // The package is loaded successfully by both Go versions, but from a // different module in each. This could lead to subtle (and perhaps even // unnoticed!) variations in behavior between builds with different // toolchains. suggestUpgrade = true ld.errorf("%s loaded from %v,\n\tbut go %s would select %v\n", pkg.stackText(), pkg.mod, ld.TidyCompatibleVersion, mismatch.mod.Version) default: base.Fatalf("go: internal error: mismatch recorded for package %s, but no differences found", pkg.path) } } suggestFixes() base.ExitIfErrors() } // scanDir is like imports.ScanDir but elides known magic imports from the list, // so that we do not go looking for packages that don't really exist. // // The standard magic import is "C", for cgo. // // The only other known magic imports are appengine and appengine/*. // These are so old that they predate "go get" and did not use URL-like paths. // Most code today now uses google.golang.org/appengine instead, // but not all code has been so updated. When we mostly ignore build tags // during "go vendor", we look into "// +build appengine" files and // may see these legacy imports. We drop them so that the module // search does not look for modules to try to satisfy them. func scanDir(modroot string, dir string, tags map[string]bool) (imports_, testImports []string, err error) { if ip, mierr := modindex.GetPackage(modroot, dir); mierr == nil { imports_, testImports, err = ip.ScanDir(tags) goto Happy } else if !errors.Is(mierr, modindex.ErrNotIndexed) { return nil, nil, mierr } imports_, testImports, err = imports.ScanDir(dir, tags) Happy: filter := func(x []string) []string { w := 0 for _, pkg := range x { if pkg != "C" && pkg != "appengine" && !strings.HasPrefix(pkg, "appengine/") && pkg != "appengine_internal" && !strings.HasPrefix(pkg, "appengine_internal/") { x[w] = pkg w++ } } return x[:w] } return filter(imports_), filter(testImports), err } // buildStacks computes minimal import stacks for each package, // for use in error messages. When it completes, packages that // are part of the original root set have pkg.stack == nil, // and other packages have pkg.stack pointing at the next // package up the import stack in their minimal chain. // As a side effect, buildStacks also constructs ld.pkgs, // the list of all packages loaded. func (ld *loader) buildStacks() { if len(ld.pkgs) > 0 { panic("buildStacks") } for _, pkg := range ld.roots { pkg.stack = pkg // sentinel to avoid processing in next loop ld.pkgs = append(ld.pkgs, pkg) } for i := 0; i < len(ld.pkgs); i++ { // not range: appending to ld.pkgs in loop pkg := ld.pkgs[i] for _, next := range pkg.imports { if next.stack == nil { next.stack = pkg ld.pkgs = append(ld.pkgs, next) } } if next := pkg.test; next != nil && next.stack == nil { next.stack = pkg ld.pkgs = append(ld.pkgs, next) } } for _, pkg := range ld.roots { pkg.stack = nil } } // stackText builds the import stack text to use when // reporting an error in pkg. It has the general form // // root imports // other imports // other2 tested by // other2.test imports // pkg func (pkg *loadPkg) stackText() string { var stack []*loadPkg for p := pkg; p != nil; p = p.stack { stack = append(stack, p) } var buf strings.Builder for i := len(stack) - 1; i >= 0; i-- { p := stack[i] fmt.Fprint(&buf, p.path) if p.testOf != nil { fmt.Fprint(&buf, ".test") } if i > 0 { if stack[i-1].testOf == p { fmt.Fprint(&buf, " tested by\n\t") } else { fmt.Fprint(&buf, " imports\n\t") } } } return buf.String() } // why returns the text to use in "go mod why" output about the given package. // It is less ornate than the stackText but contains the same information. func (pkg *loadPkg) why() string { var buf strings.Builder var stack []*loadPkg for p := pkg; p != nil; p = p.stack { stack = append(stack, p) } for i := len(stack) - 1; i >= 0; i-- { p := stack[i] if p.testOf != nil { fmt.Fprintf(&buf, "%s.test\n", p.testOf.path) } else { fmt.Fprintf(&buf, "%s\n", p.path) } } return buf.String() } // Why returns the "go mod why" output stanza for the given package, // without the leading # comment. // The package graph must have been loaded already, usually by LoadPackages. // If there is no reason for the package to be in the current build, // Why returns an empty string. func Why(path string) string { pkg, ok := loaded.pkgCache.Get(path).(*loadPkg) if !ok { return "" } return pkg.why() } // WhyDepth returns the number of steps in the Why listing. // If there is no reason for the package to be in the current build, // WhyDepth returns 0. func WhyDepth(path string) int { n := 0 pkg, _ := loaded.pkgCache.Get(path).(*loadPkg) for p := pkg; p != nil; p = p.stack { n++ } return n }