// Copyright 2019 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 cache import ( "bytes" "context" "fmt" "go/ast" "go/token" "go/types" "io" "os" "path/filepath" "sort" "strings" "sync" "golang.org/x/tools/go/analysis" "golang.org/x/tools/go/packages" "golang.org/x/tools/internal/event" "golang.org/x/tools/internal/gocommand" "golang.org/x/tools/internal/lsp/debug/tag" "golang.org/x/tools/internal/lsp/source" "golang.org/x/tools/internal/packagesinternal" "golang.org/x/tools/internal/span" "golang.org/x/tools/internal/typesinternal" errors "golang.org/x/xerrors" ) type snapshot struct { id uint64 view *View // mu guards all of the maps in the snapshot. mu sync.Mutex // ids maps file URIs to package IDs. // It may be invalidated on calls to go/packages. ids map[span.URI][]packageID // metadata maps file IDs to their associated metadata. // It may invalidated on calls to go/packages. metadata map[packageID]*metadata // importedBy maps package IDs to the list of packages that import them. importedBy map[packageID][]packageID // files maps file URIs to their corresponding FileHandles. // It may invalidated when a file's content changes. files map[span.URI]source.FileHandle // packages maps a packageKey to a set of packageHandles to which that file belongs. // It may be invalidated when a file's content changes. packages map[packageKey]*packageHandle // actions maps an actionkey to its actionHandle. actions map[actionKey]*actionHandle // workspacePackages contains the workspace's packages, which are loaded // when the view is created. workspacePackages map[packageID]packagePath // unloadableFiles keeps track of files that we've failed to load. unloadableFiles map[span.URI]struct{} // parseModHandles keeps track of any ParseModHandles for the snapshot. // The handles need not refer to only the view's go.mod file. parseModHandles map[span.URI]*parseModHandle // Preserve go.mod-related handles to avoid garbage-collecting the results // of various calls to the go command. // // TODO(rstambler): If we end up with any more such handles, we should // consider creating a struct for them. modTidyHandle *modTidyHandle modWhyHandle *modWhyHandle modUpgradeHandle *modUpgradeHandle } type packageKey struct { mode source.ParseMode id packageID } type actionKey struct { pkg packageKey analyzer *analysis.Analyzer } func (s *snapshot) ID() uint64 { return s.id } func (s *snapshot) View() source.View { return s.view } // config returns the configuration used for the snapshot's interaction with the // go/packages API. func (s *snapshot) config(ctx context.Context) *packages.Config { s.view.optionsMu.Lock() env, buildFlags := s.view.envLocked() verboseOutput := s.view.options.VerboseOutput s.view.optionsMu.Unlock() cfg := &packages.Config{ Env: env, Dir: s.view.folder.Filename(), Context: ctx, BuildFlags: buildFlags, Mode: packages.NeedName | packages.NeedFiles | packages.NeedCompiledGoFiles | packages.NeedImports | packages.NeedDeps | packages.NeedTypesSizes | packages.NeedModule, Fset: s.view.session.cache.fset, Overlay: s.buildOverlay(), ParseFile: func(*token.FileSet, string, []byte) (*ast.File, error) { panic("go/packages must not be used to parse files") }, Logf: func(format string, args ...interface{}) { if verboseOutput { event.Log(ctx, fmt.Sprintf(format, args...)) } }, Tests: true, } // We want to type check cgo code if go/types supports it. if typesinternal.SetUsesCgo(&types.Config{}) { cfg.Mode |= packages.LoadMode(packagesinternal.TypecheckCgo) } packagesinternal.SetGoCmdRunner(cfg, s.view.session.gocmdRunner) return cfg } func (s *snapshot) RunGoCommandDirect(ctx context.Context, verb string, args []string) error { cfg := s.config(ctx) _, _, err := runGoCommand(ctx, cfg, nil, s.view.tmpMod, verb, args) return err } func (s *snapshot) RunGoCommand(ctx context.Context, verb string, args []string) (*bytes.Buffer, error) { cfg := s.config(ctx) var pmh source.ParseModHandle if s.view.tmpMod { modFH, err := s.GetFile(ctx, s.view.modURI) if err != nil { return nil, err } pmh, err = s.ParseModHandle(ctx, modFH) if err != nil { return nil, err } } _, stdout, err := runGoCommand(ctx, cfg, pmh, s.view.tmpMod, verb, args) return stdout, err } func (s *snapshot) RunGoCommandPiped(ctx context.Context, verb string, args []string, stdout, stderr io.Writer) error { cfg := s.config(ctx) var pmh source.ParseModHandle if s.view.tmpMod { modFH, err := s.GetFile(ctx, s.view.modURI) if err != nil { return err } pmh, err = s.ParseModHandle(ctx, modFH) if err != nil { return err } } _, inv, cleanup, err := goCommandInvocation(ctx, cfg, pmh, verb, args) if err != nil { return err } defer cleanup() runner := packagesinternal.GetGoCmdRunner(cfg) return runner.RunPiped(ctx, *inv, stdout, stderr) } // runGoCommand runs the given go command with the given config. // The given go.mod file is used to construct the temporary go.mod file, which // is then passed to the go command via the BuildFlags. // It assumes that modURI is only provided when the -modfile flag is enabled. func runGoCommand(ctx context.Context, cfg *packages.Config, pmh source.ParseModHandle, tmpMod bool, verb string, args []string) (span.URI, *bytes.Buffer, error) { // Don't pass in the ParseModHandle if we are not using the -modfile flag. var tmpPMH source.ParseModHandle if tmpMod { tmpPMH = pmh } tmpURI, inv, cleanup, err := goCommandInvocation(ctx, cfg, tmpPMH, verb, args) if err != nil { return "", nil, err } defer cleanup() runner := packagesinternal.GetGoCmdRunner(cfg) stdout, err := runner.Run(ctx, *inv) return tmpURI, stdout, err } // Assumes that modURI is only provided when the -modfile flag is enabled. func goCommandInvocation(ctx context.Context, cfg *packages.Config, pmh source.ParseModHandle, verb string, args []string) (tmpURI span.URI, inv *gocommand.Invocation, cleanup func(), err error) { cleanup = func() {} // fallback if pmh != nil { tmpURI, cleanup, err = tempModFile(pmh.Mod(), pmh.Sum()) if err != nil { return "", nil, nil, err } cfg.BuildFlags = append(cfg.BuildFlags, fmt.Sprintf("-modfile=%s", tmpURI.Filename())) } return tmpURI, &gocommand.Invocation{ Verb: verb, Args: args, Env: cfg.Env, BuildFlags: cfg.BuildFlags, WorkingDir: cfg.Dir, }, cleanup, nil } func (s *snapshot) buildOverlay() map[string][]byte { s.mu.Lock() defer s.mu.Unlock() overlays := make(map[string][]byte) for uri, fh := range s.files { overlay, ok := fh.(*overlay) if !ok { continue } if overlay.saved { continue } // TODO(rstambler): Make sure not to send overlays outside of the current view. overlays[uri.Filename()] = overlay.text } return overlays } func hashUnsavedOverlays(files map[span.URI]source.FileHandle) string { var unsaved []string for uri, fh := range files { if overlay, ok := fh.(*overlay); ok && !overlay.saved { unsaved = append(unsaved, uri.Filename()) } } sort.Strings(unsaved) return hashContents([]byte(strings.Join(unsaved, ""))) } func (s *snapshot) PackageHandles(ctx context.Context, fh source.FileHandle) ([]source.PackageHandle, error) { if fh.Kind() != source.Go { panic("called PackageHandles on a non-Go FileHandle") } ctx = event.Label(ctx, tag.URI.Of(fh.URI())) // Check if we should reload metadata for the file. We don't invalidate IDs // (though we should), so the IDs will be a better source of truth than the // metadata. If there are no IDs for the file, then we should also reload. ids := s.getIDsForURI(fh.URI()) reload := len(ids) == 0 for _, id := range ids { // Reload package metadata if any of the metadata has missing // dependencies, in case something has changed since the last time we // reloaded it. if m := s.getMetadata(id); m == nil { reload = true break } // TODO(golang/go#36918): Previously, we would reload any package with // missing dependencies. This is expensive and results in too many // calls to packages.Load. Determine what we should do instead. } if reload { if err := s.load(ctx, fileURI(fh.URI())); err != nil { return nil, err } } // Get the list of IDs from the snapshot again, in case it has changed. var phs []source.PackageHandle for _, id := range s.getIDsForURI(fh.URI()) { ph, err := s.packageHandle(ctx, id, source.ParseFull) if err != nil { return nil, err } phs = append(phs, ph) } return phs, nil } // packageHandle returns a PackageHandle for the given ID. It assumes that // the metadata for the given ID has already been loaded, but if the // PackageHandle has not been constructed, it will rebuild it. func (s *snapshot) packageHandle(ctx context.Context, id packageID, mode source.ParseMode) (*packageHandle, error) { ph := s.getPackage(id, mode) if ph != nil { return ph, nil } // Don't reload metadata in this function. // Callers of this function must reload metadata themselves. m := s.getMetadata(id) if m == nil { return nil, errors.Errorf("%s has no metadata", id) } return s.buildPackageHandle(ctx, m.id, mode) } func (s *snapshot) GetReverseDependencies(ctx context.Context, id string) ([]source.PackageHandle, error) { if err := s.awaitLoaded(ctx); err != nil { return nil, err } ids := make(map[packageID]struct{}) s.transitiveReverseDependencies(packageID(id), ids) // Make sure to delete the original package ID from the map. delete(ids, packageID(id)) var results []source.PackageHandle for id := range ids { ph, err := s.packageHandle(ctx, id, source.ParseFull) if err != nil { return nil, err } results = append(results, ph) } return results, nil } // transitiveReverseDependencies populates the uris map with file URIs // belonging to the provided package and its transitive reverse dependencies. func (s *snapshot) transitiveReverseDependencies(id packageID, ids map[packageID]struct{}) { if _, ok := ids[id]; ok { return } if s.getMetadata(id) == nil { return } ids[id] = struct{}{} importedBy := s.getImportedBy(id) for _, parentID := range importedBy { s.transitiveReverseDependencies(parentID, ids) } } func (s *snapshot) getModHandle(uri span.URI) *parseModHandle { s.mu.Lock() defer s.mu.Unlock() return s.parseModHandles[uri] } func (s *snapshot) getModWhyHandle() *modWhyHandle { s.mu.Lock() defer s.mu.Unlock() return s.modWhyHandle } func (s *snapshot) getModUpgradeHandle() *modUpgradeHandle { s.mu.Lock() defer s.mu.Unlock() return s.modUpgradeHandle } func (s *snapshot) getModTidyHandle() *modTidyHandle { s.mu.Lock() defer s.mu.Unlock() return s.modTidyHandle } func (s *snapshot) getImportedBy(id packageID) []packageID { s.mu.Lock() defer s.mu.Unlock() return s.getImportedByLocked(id) } func (s *snapshot) getImportedByLocked(id packageID) []packageID { // If we haven't rebuilt the import graph since creating the snapshot. if len(s.importedBy) == 0 { s.rebuildImportGraph() } return s.importedBy[id] } func (s *snapshot) clearAndRebuildImportGraph() { s.mu.Lock() defer s.mu.Unlock() // Completely invalidate the original map. s.importedBy = make(map[packageID][]packageID) s.rebuildImportGraph() } func (s *snapshot) rebuildImportGraph() { for id, m := range s.metadata { for _, importID := range m.deps { s.importedBy[importID] = append(s.importedBy[importID], id) } } } func (s *snapshot) addPackageHandle(ph *packageHandle) *packageHandle { s.mu.Lock() defer s.mu.Unlock() // If the package handle has already been cached, // return the cached handle instead of overriding it. if ph, ok := s.packages[ph.packageKey()]; ok { return ph } s.packages[ph.packageKey()] = ph return ph } func (s *snapshot) workspacePackageIDs() (ids []packageID) { s.mu.Lock() defer s.mu.Unlock() for id := range s.workspacePackages { ids = append(ids, id) } return ids } func (s *snapshot) WorkspacePackages(ctx context.Context) ([]source.PackageHandle, error) { if err := s.awaitLoaded(ctx); err != nil { return nil, err } var results []source.PackageHandle for _, pkgID := range s.workspacePackageIDs() { ph, err := s.packageHandle(ctx, pkgID, source.ParseFull) if err != nil { return nil, err } results = append(results, ph) } return results, nil } func (s *snapshot) KnownPackages(ctx context.Context) ([]source.PackageHandle, error) { if err := s.awaitLoaded(ctx); err != nil { return nil, err } // Collect PackageHandles for all of the workspace packages first. // They may need to be reloaded if their metadata has been invalidated. wsPackages := make(map[packageID]bool) s.mu.Lock() for id := range s.workspacePackages { wsPackages[id] = true } s.mu.Unlock() var results []source.PackageHandle for pkgID := range wsPackages { ph, err := s.packageHandle(ctx, pkgID, source.ParseFull) if err != nil { return nil, err } results = append(results, ph) } // Once all workspace packages have been checked, the metadata will be up-to-date. // Add all packages known in the workspace (that haven't already been added). pkgIDs := make(map[packageID]bool) s.mu.Lock() for id := range s.metadata { if !wsPackages[id] { pkgIDs[id] = true } } s.mu.Unlock() for pkgID := range pkgIDs { // Metadata for these packages should already be up-to-date, // so just build the package handle directly (without a reload). ph, err := s.buildPackageHandle(ctx, pkgID, source.ParseExported) if err != nil { return nil, err } results = append(results, ph) } return results, nil } func (s *snapshot) CachedImportPaths(ctx context.Context) (map[string]source.Package, error) { // Don't reload workspace package metadata. // This function is meant to only return currently cached information. s.view.awaitInitialized(ctx) s.mu.Lock() defer s.mu.Unlock() results := map[string]source.Package{} for _, ph := range s.packages { cachedPkg, err := ph.cached() if err != nil { continue } for importPath, newPkg := range cachedPkg.imports { if oldPkg, ok := results[string(importPath)]; ok { // Using the same trick as NarrowestPackageHandle, prefer non-variants. if len(newPkg.compiledGoFiles) < len(oldPkg.(*pkg).compiledGoFiles) { results[string(importPath)] = newPkg } } else { results[string(importPath)] = newPkg } } } return results, nil } func (s *snapshot) getPackage(id packageID, mode source.ParseMode) *packageHandle { s.mu.Lock() defer s.mu.Unlock() key := packageKey{ id: id, mode: mode, } return s.packages[key] } func (s *snapshot) getActionHandle(id packageID, m source.ParseMode, a *analysis.Analyzer) *actionHandle { s.mu.Lock() defer s.mu.Unlock() key := actionKey{ pkg: packageKey{ id: id, mode: m, }, analyzer: a, } return s.actions[key] } func (s *snapshot) addActionHandle(ah *actionHandle) *actionHandle { s.mu.Lock() defer s.mu.Unlock() key := actionKey{ analyzer: ah.analyzer, pkg: packageKey{ id: ah.pkg.id, mode: ah.pkg.mode, }, } if ah, ok := s.actions[key]; ok { return ah } s.actions[key] = ah return ah } func (s *snapshot) getIDsForURI(uri span.URI) []packageID { s.mu.Lock() defer s.mu.Unlock() return s.ids[uri] } func (s *snapshot) getMetadataForURILocked(uri span.URI) (metadata []*metadata) { // TODO(matloob): uri can be a file or directory. Should we update the mappings // to map directories to their contained packages? for _, id := range s.ids[uri] { if m, ok := s.metadata[id]; ok { metadata = append(metadata, m) } } return metadata } func (s *snapshot) getMetadata(id packageID) *metadata { s.mu.Lock() defer s.mu.Unlock() return s.metadata[id] } func (s *snapshot) addID(uri span.URI, id packageID) { s.mu.Lock() defer s.mu.Unlock() for i, existingID := range s.ids[uri] { // TODO: We should make sure not to set duplicate IDs, // and instead panic here. This can be done by making sure not to // reset metadata information for packages we've already seen. if existingID == id { return } // If we are setting a real ID, when the package had only previously // had a command-line-arguments ID, we should just replace it. if existingID == "command-line-arguments" { s.ids[uri][i] = id // Delete command-line-arguments if it was a workspace package. delete(s.workspacePackages, existingID) return } } s.ids[uri] = append(s.ids[uri], id) } func (s *snapshot) isWorkspacePackage(id packageID) (packagePath, bool) { s.mu.Lock() defer s.mu.Unlock() scope, ok := s.workspacePackages[id] return scope, ok } func (s *snapshot) FindFile(uri span.URI) source.FileHandle { f, err := s.view.getFile(uri) if err != nil { return nil } s.mu.Lock() defer s.mu.Unlock() return s.files[f.URI()] } // GetFile returns a File for the given URI. It will always succeed because it // adds the file to the managed set if needed. func (s *snapshot) GetFile(ctx context.Context, uri span.URI) (source.FileHandle, error) { f, err := s.view.getFile(uri) if err != nil { return nil, err } s.mu.Lock() defer s.mu.Unlock() if fh, ok := s.files[f.URI()]; ok { return fh, nil } fh, err := s.view.session.cache.getFile(ctx, uri) if err != nil { return nil, err } s.files[f.URI()] = fh return fh, nil } func (s *snapshot) IsOpen(uri span.URI) bool { s.mu.Lock() defer s.mu.Unlock() _, open := s.files[uri].(*overlay) return open } func (s *snapshot) IsSaved(uri span.URI) bool { s.mu.Lock() defer s.mu.Unlock() ovl, open := s.files[uri].(*overlay) return !open || ovl.saved } func (s *snapshot) awaitLoaded(ctx context.Context) error { // Do not return results until the snapshot's view has been initialized. s.view.awaitInitialized(ctx) if err := s.reloadWorkspace(ctx); err != nil { return err } if err := s.reloadOrphanedFiles(ctx); err != nil { return err } // If we still have absolutely no metadata, check if the view failed to // initialize and return any errors. // TODO(rstambler): Should we clear the error after we return it? s.mu.Lock() defer s.mu.Unlock() if len(s.metadata) == 0 { return s.view.initializedErr } return nil } // reloadWorkspace reloads the metadata for all invalidated workspace packages. func (s *snapshot) reloadWorkspace(ctx context.Context) error { // If the view's build configuration is invalid, we cannot reload by package path. // Just reload the directory instead. if !s.view.hasValidBuildConfiguration { return s.load(ctx, viewLoadScope("LOAD_INVALID_VIEW")) } // See which of the workspace packages are missing metadata. s.mu.Lock() var pkgPaths []interface{} for id, pkgPath := range s.workspacePackages { // Don't try to reload "command-line-arguments" directly. if pkgPath == "command-line-arguments" { continue } if s.metadata[id] == nil { pkgPaths = append(pkgPaths, pkgPath) } } s.mu.Unlock() if len(pkgPaths) == 0 { return nil } return s.load(ctx, pkgPaths...) } func (s *snapshot) reloadOrphanedFiles(ctx context.Context) error { // When we load ./... or a package path directly, we may not get packages // that exist only in overlays. As a workaround, we search all of the files // available in the snapshot and reload their metadata individually using a // file= query if the metadata is unavailable. scopes := s.orphanedFileScopes() if len(scopes) == 0 { return nil } err := s.load(ctx, scopes...) // If we failed to load some files, i.e. they have no metadata, // mark the failures so we don't bother retrying until the file's // content changes. // // TODO(rstambler): This may be an overestimate if the load stopped // early for an unrelated errors. Add a fallback? // // Check for context cancellation so that we don't incorrectly mark files // as unloadable, but don't return before setting all workspace packages. if ctx.Err() == nil && err != nil { event.Error(ctx, "reloadOrphanedFiles: failed to load", err, tag.Query.Of(scopes)) s.mu.Lock() for _, scope := range scopes { uri := span.URI(scope.(fileURI)) if s.getMetadataForURILocked(uri) == nil { s.unloadableFiles[uri] = struct{}{} } } s.mu.Unlock() } return nil } func (s *snapshot) orphanedFileScopes() []interface{} { s.mu.Lock() defer s.mu.Unlock() scopeSet := make(map[span.URI]struct{}) for uri, fh := range s.files { // Don't try to reload metadata for go.mod files. if fh.Kind() != source.Go { continue } // If the URI doesn't belong to this view, then it's not in a workspace // package and should not be reloaded directly. if !contains(s.view.session.viewsOf(uri), s.view) { continue } // Don't reload metadata for files we've already deemed unloadable. if _, ok := s.unloadableFiles[uri]; ok { continue } if s.getMetadataForURILocked(uri) == nil { scopeSet[uri] = struct{}{} } } var scopes []interface{} for uri := range scopeSet { scopes = append(scopes, fileURI(uri)) } return scopes } func contains(views []*View, view *View) bool { for _, v := range views { if v == view { return true } } return false } func (s *snapshot) clone(ctx context.Context, withoutURIs map[span.URI]source.FileHandle, forceReloadMetadata bool) *snapshot { s.mu.Lock() defer s.mu.Unlock() result := &snapshot{ id: s.id + 1, view: s.view, ids: make(map[span.URI][]packageID), importedBy: make(map[packageID][]packageID), metadata: make(map[packageID]*metadata), packages: make(map[packageKey]*packageHandle), actions: make(map[actionKey]*actionHandle), files: make(map[span.URI]source.FileHandle), workspacePackages: make(map[packageID]packagePath), unloadableFiles: make(map[span.URI]struct{}), parseModHandles: make(map[span.URI]*parseModHandle), modTidyHandle: s.modTidyHandle, modUpgradeHandle: s.modUpgradeHandle, modWhyHandle: s.modWhyHandle, } // Copy all of the FileHandles. for k, v := range s.files { result.files[k] = v } // Copy the set of unloadable files. for k, v := range s.unloadableFiles { result.unloadableFiles[k] = v } // Copy all of the modHandles. for k, v := range s.parseModHandles { result.parseModHandles[k] = v } // transitiveIDs keeps track of transitive reverse dependencies. // If an ID is present in the map, invalidate its types. // If an ID's value is true, invalidate its metadata too. transitiveIDs := make(map[packageID]bool) for withoutURI, currentFH := range withoutURIs { directIDs := map[packageID]struct{}{} // Collect all of the package IDs that correspond to the given file. // TODO: if the file has moved into a new package, we should invalidate that too. for _, id := range s.ids[withoutURI] { directIDs[id] = struct{}{} } // The original FileHandle for this URI is cached on the snapshot. originalFH := s.files[withoutURI] // Check if the file's package name or imports have changed, // and if so, invalidate this file's packages' metadata. invalidateMetadata := forceReloadMetadata || s.shouldInvalidateMetadata(ctx, originalFH, currentFH) // Invalidate the previous modTidyHandle if any of the files have been // saved or if any of the metadata has been invalidated. if invalidateMetadata || fileWasSaved(originalFH, currentFH) { result.modTidyHandle = nil result.modUpgradeHandle = nil result.modWhyHandle = nil } if currentFH.Kind() == source.Mod { // If the view's go.mod file's contents have changed, invalidate the metadata // for all of the packages in the workspace. if invalidateMetadata { for id := range s.workspacePackages { directIDs[id] = struct{}{} } } delete(result.parseModHandles, withoutURI) } // If this is a file we don't yet know about, // then we do not yet know what packages it should belong to. // Make a rough estimate of what metadata to invalidate by finding the package IDs // of all of the files in the same directory as this one. // TODO(rstambler): Speed this up by mapping directories to filenames. if len(directIDs) == 0 { if dirStat, err := os.Stat(filepath.Dir(withoutURI.Filename())); err == nil { for uri := range s.files { if fdirStat, err := os.Stat(filepath.Dir(uri.Filename())); err == nil { if os.SameFile(dirStat, fdirStat) { for _, id := range s.ids[uri] { directIDs[id] = struct{}{} } } } } } } // Invalidate reverse dependencies too. // TODO(heschi): figure out the locking model and use transitiveReverseDeps? var addRevDeps func(packageID) addRevDeps = func(id packageID) { if _, seen := transitiveIDs[id]; seen { return } transitiveIDs[id] = invalidateMetadata for _, rid := range s.getImportedByLocked(id) { addRevDeps(rid) } } for id := range directIDs { addRevDeps(id) } // Handle the invalidated file; it may have new contents or not exist. if _, err := currentFH.Read(); os.IsNotExist(err) { delete(result.files, withoutURI) } else { result.files[withoutURI] = currentFH } // Make sure to remove the changed file from the unloadable set. delete(result.unloadableFiles, withoutURI) } // Copy the package type information. for k, v := range s.packages { if _, ok := transitiveIDs[k.id]; ok { continue } result.packages[k] = v } // Copy the package analysis information. for k, v := range s.actions { if _, ok := transitiveIDs[k.pkg.id]; ok { continue } result.actions[k] = v } // Copy the package metadata. We only need to invalidate packages directly // containing the affected file, and only if it changed in a relevant way. for k, v := range s.metadata { if invalidateMetadata, ok := transitiveIDs[k]; invalidateMetadata && ok { continue } result.metadata[k] = v } // Copy the URI to package ID mappings, skipping only those URIs whose // metadata will be reloaded in future calls to load. copyIDs: for k, ids := range s.ids { for _, id := range ids { if invalidateMetadata, ok := transitiveIDs[id]; invalidateMetadata && ok { continue copyIDs } } result.ids[k] = ids } // Copy the set of initally loaded packages. for id, pkgPath := range s.workspacePackages { if id == "command-line-arguments" { if invalidateMetadata, ok := transitiveIDs[id]; invalidateMetadata && ok { continue } } // If all the files we know about in a package have been deleted, // the package is gone and we should no longer try to load it. if m := s.metadata[id]; m != nil { hasFiles := false for _, uri := range s.metadata[id].goFiles { if _, ok := result.files[uri]; ok { hasFiles = true break } } if !hasFiles { continue } } result.workspacePackages[id] = pkgPath } // Don't bother copying the importedBy graph, // as it changes each time we update metadata. return result } // fileWasSaved reports whether the FileHandle passed in has been saved. It // accomplishes this by checking to see if the original and current FileHandles // are both overlays, and if the current FileHandle is saved while the original // FileHandle was not saved. func fileWasSaved(originalFH, currentFH source.FileHandle) bool { c, ok := currentFH.(*overlay) if !ok || c == nil { return true } o, ok := originalFH.(*overlay) if !ok || o == nil { return c.saved } return !o.saved && c.saved } // shouldInvalidateMetadata reparses a file's package and import declarations to // determine if the file requires a metadata reload. func (s *snapshot) shouldInvalidateMetadata(ctx context.Context, originalFH, currentFH source.FileHandle) bool { if originalFH == nil { return currentFH.Kind() == source.Go } // If the file hasn't changed, there's no need to reload. if originalFH.Identity().String() == currentFH.Identity().String() { return false } // If a go.mod file's contents have changed, always invalidate metadata. if kind := originalFH.Kind(); kind == source.Mod { return originalFH.URI() == s.view.modURI } // Get the original and current parsed files in order to check package name and imports. original, _, _, _, originalErr := s.view.session.cache.ParseGoHandle(ctx, originalFH, source.ParseHeader).Parse(ctx) current, _, _, _, currentErr := s.view.session.cache.ParseGoHandle(ctx, currentFH, source.ParseHeader).Parse(ctx) if originalErr != nil || currentErr != nil { return (originalErr == nil) != (currentErr == nil) } // Check if the package's metadata has changed. The cases handled are: // 1. A package's name has changed // 2. A file's imports have changed if original.Name.Name != current.Name.Name { return true } // If the package's imports have increased, definitely re-run `go list`. if len(original.Imports) < len(current.Imports) { return true } importSet := make(map[string]struct{}) for _, importSpec := range original.Imports { importSet[importSpec.Path.Value] = struct{}{} } // If any of the current imports were not in the original imports. for _, importSpec := range current.Imports { if _, ok := importSet[importSpec.Path.Value]; !ok { return true } } return false }