blob: 7e0a9ba196b81c13cfb7a9aae2659aa776e14a62 [file] [log] [blame]
// 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"
"errors"
"fmt"
"go/ast"
"go/build/constraint"
"go/token"
"go/types"
"io"
"io/ioutil"
"log"
"os"
"path/filepath"
"regexp"
"runtime"
"sort"
"strconv"
"strings"
"sync"
"sync/atomic"
"unsafe"
"golang.org/x/sync/errgroup"
"golang.org/x/tools/go/packages"
"golang.org/x/tools/go/types/objectpath"
"golang.org/x/tools/gopls/internal/bug"
"golang.org/x/tools/gopls/internal/lsp/command"
"golang.org/x/tools/gopls/internal/lsp/filecache"
"golang.org/x/tools/gopls/internal/lsp/protocol"
"golang.org/x/tools/gopls/internal/lsp/source"
"golang.org/x/tools/gopls/internal/lsp/source/methodsets"
"golang.org/x/tools/gopls/internal/lsp/source/typerefs"
"golang.org/x/tools/gopls/internal/lsp/source/xrefs"
"golang.org/x/tools/gopls/internal/span"
"golang.org/x/tools/internal/event"
"golang.org/x/tools/internal/event/tag"
"golang.org/x/tools/internal/gocommand"
"golang.org/x/tools/internal/memoize"
"golang.org/x/tools/internal/packagesinternal"
"golang.org/x/tools/internal/persistent"
"golang.org/x/tools/internal/typesinternal"
)
type snapshot struct {
sequenceID uint64
globalID source.GlobalSnapshotID
// TODO(rfindley): the snapshot holding a reference to the view poses
// lifecycle problems: a view may be shut down and waiting for work
// associated with this snapshot to complete. While most accesses of the view
// are benign (options or workspace information), this is not formalized and
// it is wrong for the snapshot to use a shutdown view.
//
// Fix this by passing options and workspace information to the snapshot,
// both of which should be immutable for the snapshot.
view *View
cancel func()
backgroundCtx context.Context
store *memoize.Store // cache of handles shared by all snapshots
refcount sync.WaitGroup // number of references
destroyedBy *string // atomically set to non-nil in Destroy once refcount = 0
// initialized reports whether the snapshot has been initialized. Concurrent
// initialization is guarded by the view.initializationSema. Each snapshot is
// initialized at most once: concurrent initialization is guarded by
// view.initializationSema.
initialized bool
// initializedErr holds the last error resulting from initialization. If
// initialization fails, we only retry when the workspace modules change,
// to avoid too many go/packages calls.
initializedErr *source.CriticalError
// mu guards all of the maps in the snapshot, as well as the builtin URI.
mu sync.Mutex
// builtin is the location of builtin.go in GOROOT.
//
// TODO(rfindley): would it make more sense to eagerly parse builtin, and
// instead store a *ParsedGoFile here?
builtin span.URI
// meta holds loaded metadata.
//
// meta is guarded by mu, but the metadataGraph itself is immutable.
// TODO(rfindley): in many places we hold mu while operating on meta, even
// though we only need to hold mu while reading the pointer.
meta *metadataGraph
// files maps file URIs to their corresponding FileHandles.
// It may invalidated when a file's content changes.
files filesMap
// parseCache holds an LRU cache of recently parsed files.
parseCache *parseCache
// symbolizeHandles maps each file URI to a handle for the future
// result of computing the symbols declared in that file.
symbolizeHandles *persistent.Map // from span.URI to *memoize.Promise[symbolizeResult]
// packages maps a packageKey to a *packageHandle.
// It may be invalidated when a file's content changes.
//
// Invariants to preserve:
// - packages.Get(id).meta == meta.metadata[id] for all ids
// - if a package is in packages, then all of its dependencies should also
// be in packages, unless there is a missing import
packages *persistent.Map // from packageID to *packageHandle
// activePackages maps a package ID to a memoized active package, or nil if
// the package is known not to be open.
//
// IDs not contained in the map are not known to be open or not open.
activePackages *persistent.Map // from packageID to *Package
// analyses maps an analysisKey (which identifies a package
// and a set of analyzers) to the handle for the future result
// of loading the package and analyzing it.
analyses *persistent.Map // from analysisKey to analysisPromise
// workspacePackages contains the workspace's packages, which are loaded
// when the view is created. It contains no intermediate test variants.
workspacePackages map[PackageID]PackagePath
// shouldLoad tracks packages that need to be reloaded, mapping a PackageID
// to the package paths that should be used to reload it
//
// When we try to load a package, we clear it from the shouldLoad map
// regardless of whether the load succeeded, to prevent endless loads.
shouldLoad map[PackageID][]PackagePath
// unloadableFiles keeps track of files that we've failed to load.
unloadableFiles map[span.URI]struct{}
// TODO(rfindley): rename the handles below to "promises". A promise is
// different from a handle (we mutate the package handle.)
// parseModHandles keeps track of any parseModHandles for the snapshot.
// The handles need not refer to only the view's go.mod file.
parseModHandles *persistent.Map // from span.URI to *memoize.Promise[parseModResult]
// parseWorkHandles keeps track of any parseWorkHandles for the snapshot.
// The handles need not refer to only the view's go.work file.
parseWorkHandles *persistent.Map // from span.URI to *memoize.Promise[parseWorkResult]
// Preserve go.mod-related handles to avoid garbage-collecting the results
// of various calls to the go command. The handles need not refer to only
// the view's go.mod file.
modTidyHandles *persistent.Map // from span.URI to *memoize.Promise[modTidyResult]
modWhyHandles *persistent.Map // from span.URI to *memoize.Promise[modWhyResult]
modVulnHandles *persistent.Map // from span.URI to *memoize.Promise[modVulnResult]
// knownSubdirs is the set of subdirectory URIs in the workspace,
// used to create glob patterns for file watching.
knownSubdirs knownDirsSet
knownSubdirsCache map[string]struct{} // memo of knownSubdirs as a set of filenames
// unprocessedSubdirChanges are any changes that might affect the set of
// subdirectories in the workspace. They are not reflected to knownSubdirs
// during the snapshot cloning step as it can slow down cloning.
unprocessedSubdirChanges []*fileChange
// workspaceModFiles holds the set of mod files active in this snapshot.
//
// This is either empty, a single entry for the workspace go.mod file, or the
// set of mod files used by the workspace go.work file.
//
// This set is immutable inside the snapshot, and therefore is not guarded by mu.
workspaceModFiles map[span.URI]struct{}
workspaceModFilesErr error // error encountered computing workspaceModFiles
// importGraph holds a shared import graph to use for type-checking. Adding
// more packages to this import graph can speed up type checking, at the
// expense of in-use memory.
//
// See getImportGraph for additional documentation.
importGraphDone chan struct{} // closed when importGraph is set; may be nil
importGraph *importGraph // copied from preceding snapshot and re-evaluated
// pkgIndex is an index of package IDs, for efficient storage of typerefs.
pkgIndex *typerefs.PackageIndex
// Only compute module prefixes once, as they are used with high frequency to
// detect ignored files.
ignoreFilterOnce sync.Once
ignoreFilter *ignoreFilter
// If non-nil, the result of computing orphaned file diagnostics.
//
// Only the field, not the map itself, is guarded by the mutex. The map must
// not be mutated.
//
// Used to save work across diagnostics+code action passes.
// TODO(rfindley): refactor all of this so there's no need to re-evaluate
// diagnostics during code-action.
orphanedFileDiagnostics map[span.URI]*source.Diagnostic
}
var globalSnapshotID uint64
func nextSnapshotID() source.GlobalSnapshotID {
return source.GlobalSnapshotID(atomic.AddUint64(&globalSnapshotID, 1))
}
var _ memoize.RefCounted = (*snapshot)(nil) // snapshots are reference-counted
// Acquire prevents the snapshot from being destroyed until the returned function is called.
//
// (s.Acquire().release() could instead be expressed as a pair of
// method calls s.IncRef(); s.DecRef(). The latter has the advantage
// that the DecRefs are fungible and don't require holding anything in
// addition to the refcounted object s, but paradoxically that is also
// an advantage of the current approach, which forces the caller to
// consider the release function at every stage, making a reference
// leak more obvious.)
func (s *snapshot) Acquire() func() {
type uP = unsafe.Pointer
if destroyedBy := atomic.LoadPointer((*uP)(uP(&s.destroyedBy))); destroyedBy != nil {
log.Panicf("%d: acquire() after Destroy(%q)", s.globalID, *(*string)(destroyedBy))
}
s.refcount.Add(1)
return s.refcount.Done
}
func (s *snapshot) awaitPromise(ctx context.Context, p *memoize.Promise) (interface{}, error) {
return p.Get(ctx, s)
}
// destroy waits for all leases on the snapshot to expire then releases
// any resources (reference counts and files) associated with it.
// Snapshots being destroyed can be awaited using v.destroyWG.
//
// TODO(adonovan): move this logic into the release function returned
// by Acquire when the reference count becomes zero. (This would cost
// us the destroyedBy debug info, unless we add it to the signature of
// memoize.RefCounted.Acquire.)
//
// The destroyedBy argument is used for debugging.
//
// v.snapshotMu must be held while calling this function, in order to preserve
// the invariants described by the docstring for v.snapshot.
func (v *View) destroy(s *snapshot, destroyedBy string) {
v.snapshotWG.Add(1)
go func() {
defer v.snapshotWG.Done()
s.destroy(destroyedBy)
}()
}
func (s *snapshot) destroy(destroyedBy string) {
// Wait for all leases to end before commencing destruction.
s.refcount.Wait()
// Report bad state as a debugging aid.
// Not foolproof: another thread could acquire() at this moment.
type uP = unsafe.Pointer // looking forward to generics...
if old := atomic.SwapPointer((*uP)(uP(&s.destroyedBy)), uP(&destroyedBy)); old != nil {
log.Panicf("%d: Destroy(%q) after Destroy(%q)", s.globalID, destroyedBy, *(*string)(old))
}
s.packages.Destroy()
s.activePackages.Destroy()
s.analyses.Destroy()
s.files.Destroy()
s.knownSubdirs.Destroy()
s.symbolizeHandles.Destroy()
s.parseModHandles.Destroy()
s.parseWorkHandles.Destroy()
s.modTidyHandles.Destroy()
s.modVulnHandles.Destroy()
s.modWhyHandles.Destroy()
}
func (s *snapshot) SequenceID() uint64 {
return s.sequenceID
}
func (s *snapshot) GlobalID() source.GlobalSnapshotID {
return s.globalID
}
func (s *snapshot) View() source.View {
return s.view
}
func (s *snapshot) BackgroundContext() context.Context {
return s.backgroundCtx
}
func (s *snapshot) ModFiles() []span.URI {
var uris []span.URI
for modURI := range s.workspaceModFiles {
uris = append(uris, modURI)
}
return uris
}
func (s *snapshot) WorkFile() span.URI {
gowork, _ := s.view.GOWORK()
return gowork
}
func (s *snapshot) Templates() map[span.URI]source.FileHandle {
s.mu.Lock()
defer s.mu.Unlock()
tmpls := map[span.URI]source.FileHandle{}
s.files.Range(func(k span.URI, fh source.FileHandle) {
if s.view.FileKind(fh) == source.Tmpl {
tmpls[k] = fh
}
})
return tmpls
}
func (s *snapshot) validBuildConfiguration() bool {
// Since we only really understand the `go` command, if the user has a
// different GOPACKAGESDRIVER, assume that their configuration is valid.
if s.view.hasGopackagesDriver {
return true
}
// Check if the user is working within a module or if we have found
// multiple modules in the workspace.
if len(s.workspaceModFiles) > 0 {
return true
}
// TODO(rfindley): this should probably be subject to "if GO111MODULES = off {...}".
if s.view.inGOPATH {
return true
}
return false
}
// workspaceMode describes the way in which the snapshot's workspace should
// be loaded.
//
// TODO(rfindley): remove this, in favor of specific methods.
func (s *snapshot) workspaceMode() workspaceMode {
var mode workspaceMode
// If the view has an invalid configuration, don't build the workspace
// module.
validBuildConfiguration := s.validBuildConfiguration()
if !validBuildConfiguration {
return mode
}
// If the view is not in a module and contains no modules, but still has a
// valid workspace configuration, do not create the workspace module.
// It could be using GOPATH or a different build system entirely.
if len(s.workspaceModFiles) == 0 && validBuildConfiguration {
return mode
}
mode |= moduleMode
options := s.view.Options()
if options.TempModfile {
mode |= tempModfile
}
return mode
}
// config returns the configuration used for the snapshot's interaction with
// the go/packages API. It uses the given working directory.
//
// TODO(rstambler): go/packages requires that we do not provide overlays for
// multiple modules in on config, so buildOverlay needs to filter overlays by
// module.
func (s *snapshot) config(ctx context.Context, inv *gocommand.Invocation) *packages.Config {
s.view.optionsMu.Lock()
verboseOutput := s.view.options.VerboseOutput
s.view.optionsMu.Unlock()
cfg := &packages.Config{
Context: ctx,
Dir: inv.WorkingDir,
Env: inv.Env,
BuildFlags: inv.BuildFlags,
Mode: packages.NeedName |
packages.NeedFiles |
packages.NeedCompiledGoFiles |
packages.NeedImports |
packages.NeedDeps |
packages.NeedTypesSizes |
packages.NeedModule |
packages.NeedEmbedFiles |
packages.LoadMode(packagesinternal.DepsErrors) |
packages.LoadMode(packagesinternal.ForTest),
Fset: nil, // we do our own parsing
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,
}
packagesinternal.SetModFile(cfg, inv.ModFile)
packagesinternal.SetModFlag(cfg, inv.ModFlag)
// 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.gocmdRunner)
return cfg
}
func (s *snapshot) RunGoCommandDirect(ctx context.Context, mode source.InvocationFlags, inv *gocommand.Invocation) (*bytes.Buffer, error) {
_, inv, cleanup, err := s.goCommandInvocation(ctx, mode, inv)
if err != nil {
return nil, err
}
defer cleanup()
return s.view.gocmdRunner.Run(ctx, *inv)
}
func (s *snapshot) RunGoCommandPiped(ctx context.Context, mode source.InvocationFlags, inv *gocommand.Invocation, stdout, stderr io.Writer) error {
_, inv, cleanup, err := s.goCommandInvocation(ctx, mode, inv)
if err != nil {
return err
}
defer cleanup()
return s.view.gocmdRunner.RunPiped(ctx, *inv, stdout, stderr)
}
func (s *snapshot) RunGoCommands(ctx context.Context, allowNetwork bool, wd string, run func(invoke func(...string) (*bytes.Buffer, error)) error) (bool, []byte, []byte, error) {
var flags source.InvocationFlags
if s.workspaceMode()&tempModfile != 0 {
flags = source.WriteTemporaryModFile
} else {
flags = source.Normal
}
if allowNetwork {
flags |= source.AllowNetwork
}
tmpURI, inv, cleanup, err := s.goCommandInvocation(ctx, flags, &gocommand.Invocation{WorkingDir: wd})
if err != nil {
return false, nil, nil, err
}
defer cleanup()
invoke := func(args ...string) (*bytes.Buffer, error) {
inv.Verb = args[0]
inv.Args = args[1:]
return s.view.gocmdRunner.Run(ctx, *inv)
}
if err := run(invoke); err != nil {
return false, nil, nil, err
}
if flags.Mode() != source.WriteTemporaryModFile {
return false, nil, nil, nil
}
var modBytes, sumBytes []byte
modBytes, err = ioutil.ReadFile(tmpURI.Filename())
if err != nil && !os.IsNotExist(err) {
return false, nil, nil, err
}
sumBytes, err = ioutil.ReadFile(strings.TrimSuffix(tmpURI.Filename(), ".mod") + ".sum")
if err != nil && !os.IsNotExist(err) {
return false, nil, nil, err
}
return true, modBytes, sumBytes, nil
}
// goCommandInvocation populates inv with configuration for running go commands on the snapshot.
//
// TODO(rfindley): refactor this function to compose the required configuration
// explicitly, rather than implicitly deriving it from flags and inv.
//
// TODO(adonovan): simplify cleanup mechanism. It's hard to see, but
// it used only after call to tempModFile. Clarify that it is only
// non-nil on success.
func (s *snapshot) goCommandInvocation(ctx context.Context, flags source.InvocationFlags, inv *gocommand.Invocation) (tmpURI span.URI, updatedInv *gocommand.Invocation, cleanup func(), err error) {
s.view.optionsMu.Lock()
allowModfileModificationOption := s.view.options.AllowModfileModifications
allowNetworkOption := s.view.options.AllowImplicitNetworkAccess
// TODO(rfindley): this is very hard to follow, and may not even be doing the
// right thing: should inv.Env really trample view.options? Do we ever invoke
// this with a non-empty inv.Env?
//
// We should refactor to make it clearer that the correct env is being used.
inv.Env = append(append(append(os.Environ(), s.view.options.EnvSlice()...), inv.Env...), "GO111MODULE="+s.view.GO111MODULE())
inv.BuildFlags = append([]string{}, s.view.options.BuildFlags...)
s.view.optionsMu.Unlock()
cleanup = func() {} // fallback
// All logic below is for module mode.
if s.workspaceMode()&moduleMode == 0 {
return "", inv, cleanup, nil
}
mode, allowNetwork := flags.Mode(), flags.AllowNetwork()
if !allowNetwork && !allowNetworkOption {
inv.Env = append(inv.Env, "GOPROXY=off")
}
// What follows is rather complicated logic for how to actually run the go
// command. A word of warning: this is the result of various incremental
// features added to gopls, and varying behavior of the Go command across Go
// versions. It can surely be cleaned up significantly, but tread carefully.
//
// Roughly speaking we need to resolve four things:
// - the working directory.
// - the -mod flag
// - the -modfile flag
//
// These are dependent on a number of factors: whether we need to run in a
// synthetic workspace, whether flags are supported at the current go
// version, and what we're actually trying to achieve (the
// source.InvocationFlags).
var modURI span.URI
// Select the module context to use.
// If we're type checking, we need to use the workspace context, meaning
// the main (workspace) module. Otherwise, we should use the module for
// the passed-in working dir.
if mode == source.LoadWorkspace {
if gowork, _ := s.view.GOWORK(); gowork == "" && s.view.gomod != "" {
modURI = s.view.gomod
}
} else {
modURI = s.GoModForFile(span.URIFromPath(inv.WorkingDir))
}
var modContent []byte
if modURI != "" {
modFH, err := s.ReadFile(ctx, modURI)
if err != nil {
return "", nil, cleanup, err
}
modContent, err = modFH.Content()
if err != nil {
return "", nil, cleanup, err
}
}
// TODO(rfindley): in the case of go.work mode, modURI is empty and we fall
// back on the default behavior of vendorEnabled with an empty modURI. Figure
// out what is correct here and implement it explicitly.
vendorEnabled, err := s.vendorEnabled(ctx, modURI, modContent)
if err != nil {
return "", nil, cleanup, err
}
const mutableModFlag = "mod"
// If the mod flag isn't set, populate it based on the mode and workspace.
// TODO(rfindley): this doesn't make sense if we're not in module mode
if inv.ModFlag == "" {
switch mode {
case source.LoadWorkspace, source.Normal:
if vendorEnabled {
inv.ModFlag = "vendor"
} else if !allowModfileModificationOption {
inv.ModFlag = "readonly"
} else {
inv.ModFlag = mutableModFlag
}
case source.WriteTemporaryModFile:
inv.ModFlag = mutableModFlag
// -mod must be readonly when using go.work files - see issue #48941
inv.Env = append(inv.Env, "GOWORK=off")
}
}
// Only use a temp mod file if the modfile can actually be mutated.
needTempMod := inv.ModFlag == mutableModFlag
useTempMod := s.workspaceMode()&tempModfile != 0
if needTempMod && !useTempMod {
return "", nil, cleanup, source.ErrTmpModfileUnsupported
}
// We should use -modfile if:
// - the workspace mode supports it
// - we're using a go.work file on go1.18+, or we need a temp mod file (for
// example, if running go mod tidy in a go.work workspace)
//
// TODO(rfindley): this is very hard to follow. Refactor.
if !needTempMod && s.view.gowork != "" {
// Since we're running in the workspace root, the go command will resolve GOWORK automatically.
} else if useTempMod {
if modURI == "" {
return "", nil, cleanup, fmt.Errorf("no go.mod file found in %s", inv.WorkingDir)
}
modFH, err := s.ReadFile(ctx, modURI)
if err != nil {
return "", nil, cleanup, err
}
// Use the go.sum if it happens to be available.
gosum := s.goSum(ctx, modURI)
tmpURI, cleanup, err = tempModFile(modFH, gosum)
if err != nil {
return "", nil, cleanup, err
}
inv.ModFile = tmpURI.Filename()
}
return tmpURI, inv, cleanup, nil
}
func (s *snapshot) buildOverlay() map[string][]byte {
overlays := make(map[string][]byte)
for _, overlay := range s.overlays() {
if overlay.saved {
continue
}
// TODO(rfindley): previously, there was a todo here to make sure we don't
// send overlays outside of the current view. IMO we should instead make
// sure this doesn't matter.
overlays[overlay.URI().Filename()] = overlay.content
}
return overlays
}
func (s *snapshot) overlays() []*Overlay {
s.mu.Lock()
defer s.mu.Unlock()
return s.files.overlays()
}
// Package data kinds, identifying various package data that may be stored in
// the file cache.
const (
xrefsKind = "xrefs"
methodSetsKind = "methodsets"
exportDataKind = "export"
diagnosticsKind = "diagnostics"
typerefsKind = "typerefs"
)
func (s *snapshot) PackageDiagnostics(ctx context.Context, ids ...PackageID) (map[span.URI][]*source.Diagnostic, error) {
ctx, done := event.Start(ctx, "cache.snapshot.PackageDiagnostics")
defer done()
var mu sync.Mutex
perFile := make(map[span.URI][]*source.Diagnostic)
collect := func(diags []*source.Diagnostic) {
mu.Lock()
defer mu.Unlock()
for _, diag := range diags {
perFile[diag.URI] = append(perFile[diag.URI], diag)
}
}
pre := func(i int, ph *packageHandle) bool {
data, err := filecache.Get(diagnosticsKind, ph.key)
if err == nil { // hit
collect(ph.m.Diagnostics)
collect(decodeDiagnostics(data))
return false
} else if err != filecache.ErrNotFound {
event.Error(ctx, "reading diagnostics from filecache", err)
}
return true
}
post := func(_ int, pkg *Package) {
collect(pkg.ph.m.Diagnostics)
collect(pkg.pkg.diagnostics)
}
return perFile, s.forEachPackage(ctx, ids, pre, post)
}
func (s *snapshot) References(ctx context.Context, ids ...PackageID) ([]source.XrefIndex, error) {
ctx, done := event.Start(ctx, "cache.snapshot.References")
defer done()
indexes := make([]source.XrefIndex, len(ids))
pre := func(i int, ph *packageHandle) bool {
data, err := filecache.Get(xrefsKind, ph.key)
if err == nil { // hit
indexes[i] = XrefIndex{m: ph.m, data: data}
return false
} else if err != filecache.ErrNotFound {
event.Error(ctx, "reading xrefs from filecache", err)
}
return true
}
post := func(i int, pkg *Package) {
indexes[i] = XrefIndex{m: pkg.ph.m, data: pkg.pkg.xrefs}
}
return indexes, s.forEachPackage(ctx, ids, pre, post)
}
// An XrefIndex is a helper for looking up a package in a given package.
type XrefIndex struct {
m *source.Metadata
data []byte
}
func (index XrefIndex) Lookup(targets map[PackagePath]map[objectpath.Path]struct{}) []protocol.Location {
return xrefs.Lookup(index.m, index.data, targets)
}
func (s *snapshot) MethodSets(ctx context.Context, ids ...PackageID) ([]*methodsets.Index, error) {
ctx, done := event.Start(ctx, "cache.snapshot.MethodSets")
defer done()
indexes := make([]*methodsets.Index, len(ids))
pre := func(i int, ph *packageHandle) bool {
data, err := filecache.Get(methodSetsKind, ph.key)
if err == nil { // hit
indexes[i] = methodsets.Decode(data)
return false
} else if err != filecache.ErrNotFound {
event.Error(ctx, "reading methodsets from filecache", err)
}
return true
}
post := func(i int, pkg *Package) {
indexes[i] = pkg.pkg.methodsets
}
return indexes, s.forEachPackage(ctx, ids, pre, post)
}
func (s *snapshot) MetadataForFile(ctx context.Context, uri span.URI) ([]*source.Metadata, error) {
if s.view.ViewType() == AdHocView {
// As described in golang/go#57209, in ad-hoc workspaces (where we load ./
// rather than ./...), preempting the directory load with file loads can
// lead to an inconsistent outcome, where certain files are loaded with
// command-line-arguments packages and others are loaded only in the ad-hoc
// package. Therefore, ensure that the workspace is loaded before doing any
// file loads.
if err := s.awaitLoaded(ctx); err != nil {
return nil, err
}
}
s.mu.Lock()
// Start with the set of package associations derived from the last load.
ids := s.meta.ids[uri]
shouldLoad := false // whether any packages containing uri are marked 'shouldLoad'
for _, id := range ids {
if len(s.shouldLoad[id]) > 0 {
shouldLoad = true
}
}
// Check if uri is known to be unloadable.
_, unloadable := s.unloadableFiles[uri]
s.mu.Unlock()
// Reload if loading is likely to improve the package associations for uri:
// - uri is not contained in any valid packages
// - ...or one of the packages containing uri is marked 'shouldLoad'
// - ...but uri is not unloadable
if (shouldLoad || len(ids) == 0) && !unloadable {
scope := fileLoadScope(uri)
err := s.load(ctx, false, scope)
// Guard against failed loads due to context cancellation.
//
// Return the context error here as the current operation is no longer
// valid.
if ctxErr := ctx.Err(); ctxErr != nil {
return nil, ctxErr
}
// We must clear scopes after loading.
//
// TODO(rfindley): unlike reloadWorkspace, this is simply marking loaded
// packages as loaded. We could do this from snapshot.load and avoid
// raciness.
s.clearShouldLoad(scope)
// Don't return an error here, as we may still return stale IDs.
// Furthermore, the result of MetadataForFile should be consistent upon
// subsequent calls, even if the file is marked as unloadable.
if err != nil && !errors.Is(err, errNoPackages) {
event.Error(ctx, "MetadataForFile", err)
}
}
// Retrieve the metadata.
s.mu.Lock()
defer s.mu.Unlock()
ids = s.meta.ids[uri]
metas := make([]*source.Metadata, len(ids))
for i, id := range ids {
metas[i] = s.meta.metadata[id]
if metas[i] == nil {
panic("nil metadata")
}
}
// Metadata is only ever added by loading,
// so if we get here and still have
// no IDs, uri is unloadable.
if !unloadable && len(ids) == 0 {
s.unloadableFiles[uri] = struct{}{}
}
// Sort packages "narrowest" to "widest" (in practice:
// non-tests before tests), and regular packages before
// their intermediate test variants (which have the same
// files but different imports).
sort.Slice(metas, func(i, j int) bool {
x, y := metas[i], metas[j]
xfiles, yfiles := len(x.CompiledGoFiles), len(y.CompiledGoFiles)
if xfiles != yfiles {
return xfiles < yfiles
}
return boolLess(x.IsIntermediateTestVariant(), y.IsIntermediateTestVariant())
})
return metas, nil
}
func boolLess(x, y bool) bool { return !x && y } // false < true
func (s *snapshot) ReverseDependencies(ctx context.Context, id PackageID, transitive bool) (map[PackageID]*source.Metadata, error) {
if err := s.awaitLoaded(ctx); err != nil {
return nil, err
}
s.mu.Lock()
meta := s.meta
s.mu.Unlock()
var rdeps map[PackageID]*source.Metadata
if transitive {
rdeps = meta.reverseReflexiveTransitiveClosure(id)
// Remove the original package ID from the map.
// (Callers all want irreflexivity but it's easier
// to compute reflexively then subtract.)
delete(rdeps, id)
} else {
// direct reverse dependencies
rdeps = make(map[PackageID]*source.Metadata)
for _, rdepID := range meta.importedBy[id] {
if rdep := meta.metadata[rdepID]; rdep != nil {
rdeps[rdepID] = rdep
}
}
}
return rdeps, nil
}
// -- Active package tracking --
//
// We say a package is "active" if any of its files are open.
// This is an optimization: the "active" concept is an
// implementation detail of the cache and is not exposed
// in the source or Snapshot API.
// After type-checking we keep active packages in memory.
// The activePackages persistent map does bookkeeping for
// the set of active packages.
// getActivePackage returns a the memoized active package for id, if it exists.
// If id is not active or has not yet been type-checked, it returns nil.
func (s *snapshot) getActivePackage(id PackageID) *Package {
s.mu.Lock()
defer s.mu.Unlock()
if value, ok := s.activePackages.Get(id); ok {
return value.(*Package) // possibly nil, if we have already checked this id.
}
return nil
}
// memoizeActivePackage checks if pkg is active, and if so either records it in
// the active packages map or returns the existing memoized active package for id.
//
// The resulting package is non-nil if and only if the specified package is open.
func (s *snapshot) memoizeActivePackage(id PackageID, pkg *Package) (active *Package) {
s.mu.Lock()
defer s.mu.Unlock()
if value, ok := s.activePackages.Get(id); ok {
return value.(*Package) // possibly nil, if we have already checked this id.
}
defer func() {
s.activePackages.Set(id, active, nil) // store the result either way: remember that pkg is not open
}()
if containsOpenFileLocked(s, pkg.Metadata()) {
return pkg
}
return nil
}
func (s *snapshot) resetActivePackagesLocked() {
s.activePackages.Destroy()
s.activePackages = persistent.NewMap(packageIDLessInterface)
}
const fileExtensions = "go,mod,sum,work"
func (s *snapshot) fileWatchingGlobPatterns(ctx context.Context) map[string]struct{} {
extensions := fileExtensions
for _, ext := range s.View().Options().TemplateExtensions {
extensions += "," + ext
}
// Work-around microsoft/vscode#100870 by making sure that we are,
// at least, watching the user's entire workspace. This will still be
// applied to every folder in the workspace.
patterns := map[string]struct{}{
fmt.Sprintf("**/*.{%s}", extensions): {},
}
// If GOWORK is outside the folder, ensure we are watching it.
gowork, _ := s.view.GOWORK()
if gowork != "" && !source.InDir(s.view.folder.Filename(), gowork.Filename()) {
patterns[gowork.Filename()] = struct{}{}
}
// Add a pattern for each Go module in the workspace that is not within the view.
dirs := s.dirs(ctx)
for _, dir := range dirs {
dirName := dir.Filename()
// If the directory is within the view's folder, we're already watching
// it with the first pattern above.
if source.InDir(s.view.folder.Filename(), dirName) {
continue
}
// TODO(rstambler): If microsoft/vscode#3025 is resolved before
// microsoft/vscode#101042, we will need a work-around for Windows
// drive letter casing.
patterns[fmt.Sprintf("%s/**/*.{%s}", dirName, extensions)] = struct{}{}
}
if s.watchSubdirs() {
// Some clients (e.g. VS Code) do not send notifications for changes to
// directories that contain Go code (golang/go#42348). To handle this,
// explicitly watch all of the directories in the workspace. We find them
// by adding the directories of every file in the snapshot's workspace
// directories. There may be thousands of patterns, each a single
// directory.
//
// (A previous iteration created a single glob pattern holding a union of
// all the directories, but this was found to cause VS Code to get stuck
// for several minutes after a buffer was saved twice in a workspace that
// had >8000 watched directories.)
//
// Some clients (notably coc.nvim, which uses watchman for globs) perform
// poorly with a large list of individual directories.
s.addKnownSubdirs(patterns, dirs)
}
return patterns
}
// watchSubdirs reports whether gopls should request separate file watchers for
// each relevant subdirectory. This is necessary only for clients (namely VS
// Code) that do not send notifications for individual files in a directory
// when the entire directory is deleted.
func (s *snapshot) watchSubdirs() bool {
opts := s.view.Options()
switch p := opts.SubdirWatchPatterns; p {
case source.SubdirWatchPatternsOn:
return true
case source.SubdirWatchPatternsOff:
return false
case source.SubdirWatchPatternsAuto:
// See the documentation of InternalOptions.SubdirWatchPatterns for an
// explanation of why VS Code gets a different default value here.
//
// Unfortunately, there is no authoritative list of client names, nor any
// requirements that client names do not change. We should update the VS
// Code extension to set a default value of "subdirWatchPatterns" to "on",
// so that this workaround is only temporary.
if opts.ClientInfo != nil && opts.ClientInfo.Name == "Visual Studio Code" {
return true
}
return false
default:
bug.Reportf("invalid subdirWatchPatterns: %q", p)
return false
}
}
func (s *snapshot) addKnownSubdirs(patterns map[string]struct{}, wsDirs []span.URI) {
s.mu.Lock()
defer s.mu.Unlock()
// First, process any pending changes and update the set of known
// subdirectories.
// It may change list of known subdirs and therefore invalidate the cache.
s.applyKnownSubdirsChangesLocked(wsDirs)
// TODO(adonovan): is it still necessary to memoize the Range
// and URI.Filename operations?
if s.knownSubdirsCache == nil {
s.knownSubdirsCache = make(map[string]struct{})
s.knownSubdirs.Range(func(uri span.URI) {
s.knownSubdirsCache[uri.Filename()] = struct{}{}
})
}
for pattern := range s.knownSubdirsCache {
patterns[pattern] = struct{}{}
}
}
// collectAllKnownSubdirs collects all of the subdirectories within the
// snapshot's workspace directories. None of the workspace directories are
// included.
func (s *snapshot) collectAllKnownSubdirs(ctx context.Context) {
dirs := s.dirs(ctx)
s.mu.Lock()
defer s.mu.Unlock()
s.knownSubdirs.Destroy()
s.knownSubdirs = newKnownDirsSet()
s.knownSubdirsCache = nil
s.files.Range(func(uri span.URI, fh source.FileHandle) {
s.addKnownSubdirLocked(uri, dirs)
})
}
func (s *snapshot) getKnownSubdirs(wsDirs []span.URI) knownDirsSet {
s.mu.Lock()
defer s.mu.Unlock()
// First, process any pending changes and update the set of known
// subdirectories.
s.applyKnownSubdirsChangesLocked(wsDirs)
return s.knownSubdirs.Clone()
}
func (s *snapshot) applyKnownSubdirsChangesLocked(wsDirs []span.URI) {
for _, c := range s.unprocessedSubdirChanges {
if c.isUnchanged {
continue
}
if !c.exists {
s.removeKnownSubdirLocked(c.fileHandle.URI())
} else {
s.addKnownSubdirLocked(c.fileHandle.URI(), wsDirs)
}
}
s.unprocessedSubdirChanges = nil
}
func (s *snapshot) addKnownSubdirLocked(uri span.URI, dirs []span.URI) {
dir := filepath.Dir(uri.Filename())
// First check if the directory is already known, because then we can
// return early.
if s.knownSubdirs.Contains(span.URIFromPath(dir)) {
return
}
var matched span.URI
for _, wsDir := range dirs {
if source.InDir(wsDir.Filename(), dir) {
matched = wsDir
break
}
}
// Don't watch any directory outside of the workspace directories.
if matched == "" {
return
}
for {
if dir == "" || dir == matched.Filename() {
break
}
uri := span.URIFromPath(dir)
if s.knownSubdirs.Contains(uri) {
break
}
s.knownSubdirs.Insert(uri)
dir = filepath.Dir(dir)
s.knownSubdirsCache = nil
}
}
func (s *snapshot) removeKnownSubdirLocked(uri span.URI) {
dir := filepath.Dir(uri.Filename())
for dir != "" {
uri := span.URIFromPath(dir)
if !s.knownSubdirs.Contains(uri) {
break
}
if info, _ := os.Stat(dir); info == nil {
s.knownSubdirs.Remove(uri)
s.knownSubdirsCache = nil
}
dir = filepath.Dir(dir)
}
}
// knownFilesInDir returns the files known to the given snapshot that are in
// the given directory. It does not respect symlinks.
func (s *snapshot) knownFilesInDir(ctx context.Context, dir span.URI) []span.URI {
var files []span.URI
s.mu.Lock()
defer s.mu.Unlock()
s.files.Range(func(uri span.URI, fh source.FileHandle) {
if source.InDir(dir.Filename(), uri.Filename()) {
files = append(files, uri)
}
})
return files
}
func (s *snapshot) WorkspaceMetadata(ctx context.Context) ([]*source.Metadata, error) {
if err := s.awaitLoaded(ctx); err != nil {
return nil, err
}
s.mu.Lock()
defer s.mu.Unlock()
meta := make([]*source.Metadata, 0, len(s.workspacePackages))
for id := range s.workspacePackages {
meta = append(meta, s.meta.metadata[id])
}
return meta, nil
}
// Symbols extracts and returns symbol information for every file contained in
// a loaded package. It awaits snapshot loading.
//
// TODO(rfindley): move this to the top of cache/symbols.go
func (s *snapshot) Symbols(ctx context.Context, workspaceOnly bool) (map[span.URI][]source.Symbol, error) {
if err := s.awaitLoaded(ctx); err != nil {
return nil, err
}
var (
meta []*source.Metadata
err error
)
if workspaceOnly {
meta, err = s.WorkspaceMetadata(ctx)
} else {
meta, err = s.AllMetadata(ctx)
}
if err != nil {
return nil, fmt.Errorf("loading metadata: %v", err)
}
goFiles := make(map[span.URI]struct{})
for _, m := range meta {
for _, uri := range m.GoFiles {
goFiles[uri] = struct{}{}
}
for _, uri := range m.CompiledGoFiles {
goFiles[uri] = struct{}{}
}
}
// Symbolize them in parallel.
var (
group errgroup.Group
nprocs = 2 * runtime.GOMAXPROCS(-1) // symbolize is a mix of I/O and CPU
resultMu sync.Mutex
result = make(map[span.URI][]source.Symbol)
)
group.SetLimit(nprocs)
for uri := range goFiles {
uri := uri
group.Go(func() error {
symbols, err := s.symbolize(ctx, uri)
if err != nil {
return err
}
resultMu.Lock()
result[uri] = symbols
resultMu.Unlock()
return nil
})
}
// Keep going on errors, but log the first failure.
// Partial results are better than no symbol results.
if err := group.Wait(); err != nil {
event.Error(ctx, "getting snapshot symbols", err)
}
return result, nil
}
func (s *snapshot) AllMetadata(ctx context.Context) ([]*source.Metadata, error) {
if err := s.awaitLoaded(ctx); err != nil {
return nil, err
}
s.mu.Lock()
g := s.meta
s.mu.Unlock()
meta := make([]*source.Metadata, 0, len(g.metadata))
for _, m := range g.metadata {
meta = append(meta, m)
}
return meta, nil
}
// TODO(rfindley): clarify that this is only active modules. Or update to just
// use findRootPattern.
func (s *snapshot) GoModForFile(uri span.URI) span.URI {
return moduleForURI(s.workspaceModFiles, uri)
}
func moduleForURI(modFiles map[span.URI]struct{}, uri span.URI) span.URI {
var match span.URI
for modURI := range modFiles {
if !source.InDir(filepath.Dir(modURI.Filename()), uri.Filename()) {
continue
}
if len(modURI) > len(match) {
match = modURI
}
}
return match
}
// nearestModFile finds the nearest go.mod file contained in the directory
// containing uri, or a parent of that directory.
//
// The given uri must be a file, not a directory.
func nearestModFile(ctx context.Context, uri span.URI, fs source.FileSource) (span.URI, error) {
dir := filepath.Dir(uri.Filename())
mod, err := findRootPattern(ctx, dir, "go.mod", fs)
if err != nil {
return "", err
}
return span.URIFromPath(mod), nil
}
func (s *snapshot) Metadata(id PackageID) *source.Metadata {
s.mu.Lock()
defer s.mu.Unlock()
return s.meta.metadata[id]
}
// clearShouldLoad clears package IDs that no longer need to be reloaded after
// scopes has been loaded.
func (s *snapshot) clearShouldLoad(scopes ...loadScope) {
s.mu.Lock()
defer s.mu.Unlock()
for _, scope := range scopes {
switch scope := scope.(type) {
case packageLoadScope:
scopePath := PackagePath(scope)
var toDelete []PackageID
for id, pkgPaths := range s.shouldLoad {
for _, pkgPath := range pkgPaths {
if pkgPath == scopePath {
toDelete = append(toDelete, id)
}
}
}
for _, id := range toDelete {
delete(s.shouldLoad, id)
}
case fileLoadScope:
uri := span.URI(scope)
ids := s.meta.ids[uri]
for _, id := range ids {
delete(s.shouldLoad, id)
}
}
}
}
// noRealPackagesForURILocked reports whether there are any
// non-command-line-arguments packages containing the given URI.
func (s *snapshot) noRealPackagesForURILocked(uri span.URI) bool {
for _, id := range s.meta.ids[uri] {
if !source.IsCommandLineArguments(id) || s.meta.metadata[id].Standalone {
return false
}
}
return true
}
func (s *snapshot) FindFile(uri span.URI) source.FileHandle {
s.view.markKnown(uri)
s.mu.Lock()
defer s.mu.Unlock()
result, _ := s.files.Get(uri)
return result
}
// ReadFile returns a File for the given URI. If the file is unknown it is added
// to the managed set.
//
// ReadFile succeeds even if the file does not exist. A non-nil error return
// indicates some type of internal error, for example if ctx is cancelled.
func (s *snapshot) ReadFile(ctx context.Context, uri span.URI) (source.FileHandle, error) {
s.mu.Lock()
defer s.mu.Unlock()
return lockedSnapshot{s}.ReadFile(ctx, uri)
}
// preloadFiles delegates to the view FileSource to read the requested uris in
// parallel, without holding the snapshot lock.
func (s *snapshot) preloadFiles(ctx context.Context, uris []span.URI) {
files := make([]source.FileHandle, len(uris))
var wg sync.WaitGroup
iolimit := make(chan struct{}, 20) // I/O concurrency limiting semaphore
for i, uri := range uris {
wg.Add(1)
iolimit <- struct{}{}
go func(i int, uri span.URI) {
defer wg.Done()
fh, err := s.view.fs.ReadFile(ctx, uri)
<-iolimit
if err != nil && ctx.Err() == nil {
event.Error(ctx, fmt.Sprintf("reading %s", uri), err)
return
}
files[i] = fh
}(i, uri)
}
wg.Wait()
s.mu.Lock()
defer s.mu.Unlock()
for i, fh := range files {
if fh == nil {
continue // error logged above
}
uri := uris[i]
if _, ok := s.files.Get(uri); !ok {
s.files.Set(uri, fh)
}
}
}
// A lockedSnapshot implements the source.FileSource interface while holding
// the lock for the wrapped snapshot.
type lockedSnapshot struct{ wrapped *snapshot }
func (s lockedSnapshot) ReadFile(ctx context.Context, uri span.URI) (source.FileHandle, error) {
s.wrapped.view.markKnown(uri)
if fh, ok := s.wrapped.files.Get(uri); ok {
return fh, nil
}
fh, err := s.wrapped.view.fs.ReadFile(ctx, uri)
if err != nil {
return nil, err
}
s.wrapped.files.Set(uri, fh)
return fh, nil
}
func (s *snapshot) IsOpen(uri span.URI) bool {
s.mu.Lock()
defer s.mu.Unlock()
fh, _ := s.files.Get(uri)
_, open := fh.(*Overlay)
return open
}
func isFileOpen(fh source.FileHandle) bool {
_, open := fh.(*Overlay)
return open
}
// TODO(rfindley): it would make sense for awaitLoaded to return metadata.
func (s *snapshot) awaitLoaded(ctx context.Context) error {
loadErr := s.awaitLoadedAllErrors(ctx)
// TODO(rfindley): eliminate this function as part of simplifying
// CriticalErrors.
if loadErr != nil {
return loadErr.MainError
}
return nil
}
func (s *snapshot) CriticalError(ctx context.Context) *source.CriticalError {
// If we couldn't compute workspace mod files, then the load below is
// invalid.
//
// TODO(rfindley): is this a clear error to present to the user?
if s.workspaceModFilesErr != nil {
return &source.CriticalError{MainError: s.workspaceModFilesErr}
}
loadErr := s.awaitLoadedAllErrors(ctx)
if loadErr != nil && errors.Is(loadErr.MainError, context.Canceled) {
return nil
}
// Even if packages didn't fail to load, we still may want to show
// additional warnings.
if loadErr == nil {
active, _ := s.WorkspaceMetadata(ctx)
if msg := shouldShowAdHocPackagesWarning(s, active); msg != "" {
return &source.CriticalError{
MainError: errors.New(msg),
}
}
// Even if workspace packages were returned, there still may be an error
// with the user's workspace layout. Workspace packages that only have the
// ID "command-line-arguments" are usually a symptom of a bad workspace
// configuration.
//
// This heuristic is path-dependent: we only get command-line-arguments
// packages when we've loaded using file scopes, which only occurs
// on-demand or via orphaned file reloading.
//
// TODO(rfindley): re-evaluate this heuristic.
if containsCommandLineArguments(active) {
err, diags := s.workspaceLayoutError(ctx)
if err != nil {
if ctx.Err() != nil {
return nil // see the API documentation for source.Snapshot
}
return &source.CriticalError{
MainError: err,
Diagnostics: diags,
}
}
}
return nil
}
if errMsg := loadErr.MainError.Error(); strings.Contains(errMsg, "cannot find main module") || strings.Contains(errMsg, "go.mod file not found") {
err, diags := s.workspaceLayoutError(ctx)
if err != nil {
if ctx.Err() != nil {
return nil // see the API documentation for source.Snapshot
}
return &source.CriticalError{
MainError: err,
Diagnostics: diags,
}
}
}
return loadErr
}
// A portion of this text is expected by TestBrokenWorkspace_OutsideModule.
const adHocPackagesWarning = `You are outside of a module and outside of $GOPATH/src.
If you are using modules, please open your editor to a directory in your module.
If you believe this warning is incorrect, please file an issue: https://github.com/golang/go/issues/new.`
func shouldShowAdHocPackagesWarning(snapshot *snapshot, active []*source.Metadata) string {
if !snapshot.validBuildConfiguration() {
for _, m := range active {
// A blank entry in DepsByImpPath
// indicates a missing dependency.
for _, importID := range m.DepsByImpPath {
if importID == "" {
return adHocPackagesWarning
}
}
}
}
return ""
}
func containsCommandLineArguments(metas []*source.Metadata) bool {
for _, m := range metas {
if source.IsCommandLineArguments(m.ID) {
return true
}
}
return false
}
func (s *snapshot) awaitLoadedAllErrors(ctx context.Context) *source.CriticalError {
// Do not return results until the snapshot's view has been initialized.
s.AwaitInitialized(ctx)
// TODO(rfindley): Should we be more careful about returning the
// initialization error? Is it possible for the initialization error to be
// corrected without a successful reinitialization?
if err := s.getInitializationError(); err != nil {
return err
}
// TODO(rfindley): revisit this handling. Calling reloadWorkspace with a
// cancelled context should have the same effect, so this preemptive handling
// should not be necessary.
//
// Also: GetCriticalError ignores context cancellation errors. Should we be
// returning nil here?
if ctx.Err() != nil {
return &source.CriticalError{MainError: ctx.Err()}
}
// TODO(rfindley): reloading is not idempotent: if we try to reload or load
// orphaned files below and fail, we won't try again. For that reason, we
// could get different results from subsequent calls to this function, which
// may cause critical errors to be suppressed.
if err := s.reloadWorkspace(ctx); err != nil {
diags := s.extractGoCommandErrors(ctx, err)
return &source.CriticalError{
MainError: err,
Diagnostics: diags,
}
}
if err := s.reloadOrphanedOpenFiles(ctx); err != nil {
diags := s.extractGoCommandErrors(ctx, err)
return &source.CriticalError{
MainError: err,
Diagnostics: diags,
}
}
return nil
}
func (s *snapshot) getInitializationError() *source.CriticalError {
s.mu.Lock()
defer s.mu.Unlock()
return s.initializedErr
}
func (s *snapshot) AwaitInitialized(ctx context.Context) {
select {
case <-ctx.Done():
return
case <-s.view.initialWorkspaceLoad:
}
// We typically prefer to run something as intensive as the IWL without
// blocking. I'm not sure if there is a way to do that here.
s.initialize(ctx, false)
}
// reloadWorkspace reloads the metadata for all invalidated workspace packages.
func (s *snapshot) reloadWorkspace(ctx context.Context) error {
var scopes []loadScope
var seen map[PackagePath]bool
s.mu.Lock()
for _, pkgPaths := range s.shouldLoad {
for _, pkgPath := range pkgPaths {
if seen == nil {
seen = make(map[PackagePath]bool)
}
if seen[pkgPath] {
continue
}
seen[pkgPath] = true
scopes = append(scopes, packageLoadScope(pkgPath))
}
}
s.mu.Unlock()
if len(scopes) == 0 {
return nil
}
// If the view's build configuration is invalid, we cannot reload by
// package path. Just reload the directory instead.
if !s.validBuildConfiguration() {
scopes = []loadScope{viewLoadScope("LOAD_INVALID_VIEW")}
}
err := s.load(ctx, false, scopes...)
// Unless the context was canceled, set "shouldLoad" to false for all
// of the metadata we attempted to load.
if !errors.Is(err, context.Canceled) {
s.clearShouldLoad(scopes...)
}
return err
}
// reloadOrphanedOpenFiles attempts to load a package for each open file that
// does not yet have an associated package. If loading finishes without being
// canceled, any files still not contained in a package are marked as unloadable.
//
// An error is returned if the load is canceled.
func (s *snapshot) reloadOrphanedOpenFiles(ctx context.Context) error {
s.mu.Lock()
meta := s.meta
s.mu.Unlock()
// 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.
open := s.overlays()
var files []*Overlay
for _, o := range open {
uri := o.URI()
if s.IsBuiltin(uri) || s.view.FileKind(o) != source.Go {
continue
}
if len(meta.ids[uri]) == 0 {
files = append(files, o)
}
}
if len(files) == 0 {
return nil
}
// Filter to files that are not known to be unloadable.
s.mu.Lock()
loadable := files[:0]
for _, file := range files {
if _, unloadable := s.unloadableFiles[file.URI()]; !unloadable {
loadable = append(loadable, file)
}
}
files = loadable
s.mu.Unlock()
var uris []span.URI
for _, file := range files {
uris = append(uris, file.URI())
}
event.Log(ctx, "reloadOrphanedFiles reloading", tag.Files.Of(uris))
var g errgroup.Group
cpulimit := runtime.GOMAXPROCS(0)
g.SetLimit(cpulimit)
// Load files one-at-a-time. go/packages can return at most one
// command-line-arguments package per query.
for _, file := range files {
file := file
g.Go(func() error {
pgf, err := s.ParseGo(ctx, file, source.ParseHeader)
if err != nil || !pgf.File.Package.IsValid() {
return nil // need a valid header
}
return s.load(ctx, false, fileLoadScope(file.URI()))
})
}
// 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(rfindley): is it possible that the load stopped early for an
// unrelated errors? If so, add a fallback?
if err := g.Wait(); err != nil {
// 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 {
return ctx.Err()
}
if !errors.Is(err, errNoPackages) {
event.Error(ctx, "reloadOrphanedFiles: failed to load", err, tag.Files.Of(uris))
}
}
// If the context was not canceled, we assume that the result of loading
// packages is deterministic (though as we saw in golang/go#59318, it may not
// be in the presence of bugs). Marking all unloaded files as unloadable here
// prevents us from falling into recursive reloading where we only make a bit
// of progress each time.
s.mu.Lock()
defer s.mu.Unlock()
for _, file := range files {
// TODO(rfindley): instead of locking here, we should have load return the
// metadata graph that resulted from loading.
uri := file.URI()
if len(s.meta.ids) == 0 {
s.unloadableFiles[uri] = struct{}{}
}
}
return nil
}
// OrphanedFileDiagnostics reports diagnostics describing why open files have
// no packages or have only command-line-arguments packages.
//
// If the resulting diagnostic is nil, the file is either not orphaned or we
// can't produce a good diagnostic.
//
// TODO(rfindley): reconcile the definition of "orphaned" here with
// reloadOrphanedFiles. The latter does not include files with
// command-line-arguments packages.
func (s *snapshot) OrphanedFileDiagnostics(ctx context.Context) (map[span.URI]*source.Diagnostic, error) {
// Orphaned file diagnostics are queried from code actions to produce
// quick-fixes (and may be queried many times, once for each file).
//
// Because they are non-trivial to compute, record them optimistically to
// avoid most redundant work.
//
// This is a hacky workaround: in the future we should avoid recomputing
// anything when codeActions provide a diagnostic: simply read the published
// diagnostic, if it exists.
s.mu.Lock()
existing := s.orphanedFileDiagnostics
s.mu.Unlock()
if existing != nil {
return existing, nil
}
if err := s.awaitLoaded(ctx); err != nil {
return nil, err
}
var files []*Overlay
searchOverlays:
for _, o := range s.overlays() {
uri := o.URI()
if s.IsBuiltin(uri) || s.view.FileKind(o) != source.Go {
continue
}
md, err := s.MetadataForFile(ctx, uri)
if err != nil {
return nil, err
}
for _, m := range md {
if !source.IsCommandLineArguments(m.ID) || m.Standalone {
continue searchOverlays
}
}
files = append(files, o)
}
if len(files) == 0 {
return nil, nil
}
loadedModFiles := make(map[span.URI]struct{}) // all mod files, including dependencies
ignoredFiles := make(map[span.URI]bool) // files reported in packages.Package.IgnoredFiles
meta, err := s.AllMetadata(ctx)
if err != nil {
return nil, err
}
for _, meta := range meta {
if meta.Module != nil && meta.Module.GoMod != "" {
gomod := span.URIFromPath(meta.Module.GoMod)
loadedModFiles[gomod] = struct{}{}
}
for _, ignored := range meta.IgnoredFiles {
ignoredFiles[ignored] = true
}
}
diagnostics := make(map[span.URI]*source.Diagnostic)
for _, fh := range files {
// Only warn about orphaned files if the file is well-formed enough to
// actually be part of a package.
//
// Use ParseGo as for open files this is likely to be a cache hit (we'll have )
pgf, err := s.ParseGo(ctx, fh, source.ParseHeader)
if err != nil {
continue
}
if !pgf.File.Name.Pos().IsValid() {
continue
}
rng, err := pgf.PosRange(pgf.File.Name.Pos(), pgf.File.Name.End())
if err != nil {
continue
}
var (
msg string // if non-empty, report a diagnostic with this message
suggestedFixes []source.SuggestedFix // associated fixes, if any
)
// If we have a relevant go.mod file, check whether the file is orphaned
// due to its go.mod file being inactive. We could also offer a
// prescriptive diagnostic in the case that there is no go.mod file, but it
// is harder to be precise in that case, and less important.
if goMod, err := nearestModFile(ctx, fh.URI(), s); err == nil && goMod != "" {
if _, ok := loadedModFiles[goMod]; !ok {
modDir := filepath.Dir(goMod.Filename())
viewDir := s.view.folder.Filename()
// When the module is underneath the view dir, we offer
// "use all modules" quick-fixes.
inDir := source.InDir(viewDir, modDir)
if rel, err := filepath.Rel(viewDir, modDir); err == nil {
modDir = rel
}
var fix string
if s.view.goversion >= 18 {
if s.view.gowork != "" {
fix = fmt.Sprintf("To fix this problem, you can add this module to your go.work file (%s)", s.view.gowork)
if cmd, err := command.NewRunGoWorkCommandCommand("Run `go work use`", command.RunGoWorkArgs{
ViewID: s.view.ID(),
Args: []string{"use", modDir},
}); err == nil {
suggestedFixes = append(suggestedFixes, source.SuggestedFix{
Title: "Use this module in your go.work file",
Command: &cmd,
ActionKind: protocol.QuickFix,
})
}
if inDir {
if cmd, err := command.NewRunGoWorkCommandCommand("Run `go work use -r`", command.RunGoWorkArgs{
ViewID: s.view.ID(),
Args: []string{"use", "-r", "."},
}); err == nil {
suggestedFixes = append(suggestedFixes, source.SuggestedFix{
Title: "Use all modules in your workspace",
Command: &cmd,
ActionKind: protocol.QuickFix,
})
}
}
} else {
fix = "To fix this problem, you can add a go.work file that uses this directory."
if cmd, err := command.NewRunGoWorkCommandCommand("Run `go work init && go work use`", command.RunGoWorkArgs{
ViewID: s.view.ID(),
InitFirst: true,
Args: []string{"use", modDir},
}); err == nil {
suggestedFixes = []source.SuggestedFix{
{
Title: "Add a go.work file using this module",
Command: &cmd,
ActionKind: protocol.QuickFix,
},
}
}
if inDir {
if cmd, err := command.NewRunGoWorkCommandCommand("Run `go work init && go work use -r`", command.RunGoWorkArgs{
ViewID: s.view.ID(),
InitFirst: true,
Args: []string{"use", "-r", "."},
}); err == nil {
suggestedFixes = append(suggestedFixes, source.SuggestedFix{
Title: "Add a go.work file using all modules in your workspace",
Command: &cmd,
ActionKind: protocol.QuickFix,
})
}
}
}
} else {
fix = `To work with multiple modules simultaneously, please upgrade to Go 1.18 or
later, reinstall gopls, and use a go.work file.`
}
msg = fmt.Sprintf(`This file is within module %q, which is not included in your workspace.
%s
See the documentation for more information on setting up your workspace:
https://github.com/golang/tools/blob/master/gopls/doc/workspace.md.`, modDir, fix)
}
}
if msg == "" && ignoredFiles[fh.URI()] {
// TODO(rfindley): use the constraint package to check if the file
// _actually_ satisfies the current build context.
hasConstraint := false
walkConstraints(pgf.File, func(constraint.Expr) bool {
hasConstraint = true
return false
})
var fix string
if hasConstraint {
fix = `This file may be excluded due to its build tags; try adding "-tags=<build tag>" to your gopls "buildFlags" configuration
See the documentation for more information on working with build tags:
https://github.com/golang/tools/blob/master/gopls/doc/settings.md#buildflags-string.`
} else if strings.Contains(filepath.Base(fh.URI().Filename()), "_") {
fix = `This file may be excluded due to its GOOS/GOARCH, or other build constraints.`
} else {
fix = `This file is ignored by your gopls build.` // we don't know why
}
msg = fmt.Sprintf("No packages found for open file %s.\n%s", fh.URI().Filename(), fix)
}
if msg != "" {
// Only report diagnostics if we detect an actual exclusion.
diagnostics[fh.URI()] = &source.Diagnostic{
URI: fh.URI(),
Range: rng,
Severity: protocol.SeverityWarning,
Source: source.ListError,
Message: msg,
SuggestedFixes: suggestedFixes,
}
}
}
s.mu.Lock()
defer s.mu.Unlock()
if s.orphanedFileDiagnostics == nil { // another thread may have won the race
s.orphanedFileDiagnostics = diagnostics
}
return s.orphanedFileDiagnostics, nil
}
// TODO(golang/go#53756): this function needs to consider more than just the
// absolute URI, for example:
// - the position of /vendor/ with respect to the relevant module root
// - whether or not go.work is in use (as vendoring isn't supported in workspace mode)
//
// Most likely, each call site of inVendor needs to be reconsidered to
// understand and correctly implement the desired behavior.
func inVendor(uri span.URI) bool {
_, after, found := cut(string(uri), "/vendor/")
// Only subdirectories of /vendor/ are considered vendored
// (/vendor/a/foo.go is vendored, /vendor/foo.go is not).
return found && strings.Contains(after, "/")
}
// TODO(adonovan): replace with strings.Cut when we can assume go1.18.
func cut(s, sep string) (before, after string, found bool) {
if i := strings.Index(s, sep); i >= 0 {
return s[:i], s[i+len(sep):], true
}
return s, "", false
}
// unappliedChanges is a file source that handles an uncloned snapshot.
type unappliedChanges struct {
originalSnapshot *snapshot
changes map[span.URI]*fileChange
}
func (ac *unappliedChanges) ReadFile(ctx context.Context, uri span.URI) (source.FileHandle, error) {
if c, ok := ac.changes[uri]; ok {
return c.fileHandle, nil
}
return ac.originalSnapshot.ReadFile(ctx, uri)
}
func (s *snapshot) clone(ctx, bgCtx context.Context, changes map[span.URI]*fileChange, forceReloadMetadata bool) (*snapshot, func()) {
ctx, done := event.Start(ctx, "cache.snapshot.clone")
defer done()
reinit := false
wsModFiles, wsModFilesErr := s.workspaceModFiles, s.workspaceModFilesErr
if workURI, _ := s.view.GOWORK(); workURI != "" {
if change, ok := changes[workURI]; ok {
wsModFiles, wsModFilesErr = computeWorkspaceModFiles(ctx, s.view.gomod, workURI, s.view.effectiveGO111MODULE(), &unappliedChanges{
originalSnapshot: s,
changes: changes,
})
// TODO(rfindley): don't rely on 'isUnchanged' here. Use a content hash instead.
reinit = change.fileHandle.Saved() && !change.isUnchanged
}
}
// Reinitialize if any workspace mod file has changed on disk.
for uri, change := range changes {
if _, ok := wsModFiles[uri]; ok && change.fileHandle.Saved() && !change.isUnchanged {
reinit = true
}
}
// Finally, process sumfile changes that may affect loading.
for uri, change := range changes {
if !change.fileHandle.Saved() {
continue // like with go.mod files, we only reinit when things are saved
}
if filepath.Base(uri.Filename()) == "go.work.sum" && s.view.gowork != "" {
if filepath.Dir(uri.Filename()) == filepath.Dir(s.view.gowork) {
reinit = true
}
}
if filepath.Base(uri.Filename()) == "go.sum" {
dir := filepath.Dir(uri.Filename())
modURI := span.URIFromPath(filepath.Join(dir, "go.mod"))
if _, active := wsModFiles[modURI]; active {
reinit = true
}
}
}
s.mu.Lock()
defer s.mu.Unlock()
// Changes to vendor tree may require reinitialization,
// either because of an initialization error
// (e.g. "inconsistent vendoring detected"), or because
// one or more modules may have moved into or out of the
// vendor tree after 'go mod vendor' or 'rm -fr vendor/'.
for uri := range changes {
if inVendor(uri) && s.initializedErr != nil ||
strings.HasSuffix(string(uri), "/vendor/modules.txt") {
reinit = true
break
}
}
bgCtx, cancel := context.WithCancel(bgCtx)
result := &snapshot{
sequenceID: s.sequenceID + 1,
globalID: nextSnapshotID(),
store: s.store,
view: s.view,
backgroundCtx: bgCtx,
cancel: cancel,
builtin: s.builtin,
initialized: s.initialized,
initializedErr: s.initializedErr,
packages: s.packages.Clone(),
activePackages: s.activePackages.Clone(),
analyses: s.analyses.Clone(),
files: s.files.Clone(),
parseCache: s.parseCache,
symbolizeHandles: s.symbolizeHandles.Clone(),
workspacePackages: make(map[PackageID]PackagePath, len(s.workspacePackages)),
unloadableFiles: make(map[span.URI]struct{}, len(s.unloadableFiles)),
parseModHandles: s.parseModHandles.Clone(),
parseWorkHandles: s.parseWorkHandles.Clone(),
modTidyHandles: s.modTidyHandles.Clone(),
modWhyHandles: s.modWhyHandles.Clone(),
modVulnHandles: s.modVulnHandles.Clone(),
knownSubdirs: s.knownSubdirs.Clone(),
workspaceModFiles: wsModFiles,
workspaceModFilesErr: wsModFilesErr,
importGraph: s.importGraph,
pkgIndex: s.pkgIndex,
}
// The snapshot should be initialized if either s was uninitialized, or we've
// detected a change that triggers reinitialization.
if reinit {
result.initialized = false
}
// Create a lease on the new snapshot.
// (Best to do this early in case the code below hides an
// incref/decref operation that might destroy it prematurely.)
release := result.Acquire()
// Copy the set of unloadable files.
//
// TODO(rfindley): this looks wrong. Shouldn't we clear unloadableFiles on
// changes to environment or workspace layout, or more generally on any
// metadata change?
//
// Maybe not, as major configuration changes cause a new view.
for k, v := range s.unloadableFiles {
result.unloadableFiles[k] = v
}
// Add all of the known subdirectories, but don't update them for the
// changed files. We need to rebuild the workspace module to know the
// true set of known subdirectories, but we don't want to do that in clone.
result.knownSubdirs = s.knownSubdirs.Clone()
result.knownSubdirsCache = s.knownSubdirsCache
for _, c := range changes {
result.unprocessedSubdirChanges = append(result.unprocessedSubdirChanges, c)
}
// directIDs keeps track of package IDs that have directly changed.
// Note: this is not a set, it's a map from id to invalidateMetadata.
directIDs := map[PackageID]bool{}
// Invalidate all package metadata if the workspace module has changed.
if reinit {
for k := range s.meta.metadata {
directIDs[k] = true
}
}
// Compute invalidations based on file changes.
anyImportDeleted := false // import deletions can resolve cycles
anyFileOpenedOrClosed := false // opened files affect workspace packages
anyFileAdded := false // adding a file can resolve missing dependencies
for uri, change := range changes {
// Invalidate go.mod-related handles.
result.modTidyHandles.Delete(uri)
result.modWhyHandles.Delete(uri)
result.modVulnHandles.Delete(uri)
// Invalidate handles for cached symbols.
result.symbolizeHandles.Delete(uri)
// The original FileHandle for this URI is cached on the snapshot.
originalFH, _ := s.files.Get(uri)
var originalOpen, newOpen bool
_, originalOpen = originalFH.(*Overlay)
_, newOpen = change.fileHandle.(*Overlay)
anyFileOpenedOrClosed = anyFileOpenedOrClosed || (originalOpen != newOpen)
anyFileAdded = anyFileAdded || (originalFH == nil && change.fileHandle != nil)
// If uri is a Go file, check if it has changed in a way that would
// invalidate metadata. Note that we can't use s.view.FileKind here,
// because the file type that matters is not what the *client* tells us,
// but what the Go command sees.
var invalidateMetadata, pkgFileChanged, importDeleted bool
if strings.HasSuffix(uri.Filename(), ".go") {
invalidateMetadata, pkgFileChanged, importDeleted = metadataChanges(ctx, s, originalFH, change.fileHandle)
}
invalidateMetadata = invalidateMetadata || forceReloadMetadata || reinit
anyImportDeleted = anyImportDeleted || importDeleted
// Mark all of the package IDs containing the given file.
filePackageIDs := invalidatedPackageIDs(uri, s.meta.ids, pkgFileChanged)
for id := range filePackageIDs {
directIDs[id] = directIDs[id] || invalidateMetadata // may insert 'false'
}
// 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, change.fileHandle) {
// Only invalidate mod tidy results for the most relevant modfile in the
// workspace. This is a potentially lossy optimization for workspaces
// with many modules (such as google-cloud-go, which has 145 modules as
// of writing).
//
// While it is theoretically possible that a change in workspace module A
// could affect the mod-tidiness of workspace module B (if B transitively
// requires A), such changes are probably unlikely and not worth the
// penalty of re-running go mod tidy for everything. Note that mod tidy
// ignores GOWORK, so the two modules would have to be related by a chain
// of replace directives.
//
// We could improve accuracy by inspecting replace directives, using
// overlays in go mod tidy, and/or checking for metadata changes from the
// on-disk content.
//
// Note that we iterate the modTidyHandles map here, rather than e.g.
// using nearestModFile, because we don't have access to an accurate
// FileSource at this point in the snapshot clone.
const onlyInvalidateMostRelevant = true
if onlyInvalidateMostRelevant {
deleteMostRelevantModFile(result.modTidyHandles, uri)
} else {
result.modTidyHandles.Clear()
}
// TODO(rfindley): should we apply the above heuristic to mod vuln
// or mod handles as well?
//
// TODO(rfindley): no tests fail if I delete the below line.
result.modWhyHandles.Clear()
result.modVulnHandles.Clear()
}
result.parseModHandles.Delete(uri)
result.parseWorkHandles.Delete(uri)
// Handle the invalidated file; it may have new contents or not exist.
if !change.exists {
result.files.Delete(uri)
} else {
// TODO(golang/go#57558): the line below is strictly necessary to ensure
// that snapshots have each overlay, but it is problematic that we must
// set any content in snapshot.clone: if the file has changed, let it be
// re-read.
result.files.Set(uri, change.fileHandle)
}
// Make sure to remove the changed file from the unloadable set.
delete(result.unloadableFiles, uri)
}
// Deleting an import can cause list errors due to import cycles to be
// resolved. The best we can do without parsing the list error message is to
// hope that list errors may have been resolved by a deleted import.
//
// We could do better by parsing the list error message. We already do this
// to assign a better range to the list error, but for such critical
// functionality as metadata, it's better to be conservative until it proves
// impractical.
//
// We could also do better by looking at which imports were deleted and
// trying to find cycles they are involved in. This fails when the file goes
// from an unparseable state to a parseable state, as we don't have a
// starting point to compare with.
if anyImportDeleted {
for id, metadata := range s.meta.metadata {
if len(metadata.Errors) > 0 {
directIDs[id] = true
}
}
}
// Adding a file can resolve missing dependencies from existing packages.
//
// We could be smart here and try to guess which packages may have been
// fixed, but until that proves necessary, just invalidate metadata for any
// package with missing dependencies.
if anyFileAdded {
for id, metadata := range s.meta.metadata {
for _, impID := range metadata.DepsByImpPath {
if impID == "" { // missing import
directIDs[id] = true
break
}
}
}
}
// Invalidate reverse dependencies too.
// idsToInvalidate 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.
idsToInvalidate := map[PackageID]bool{}
var addRevDeps func(PackageID, bool)
addRevDeps = func(id PackageID, invalidateMetadata bool) {
current, seen := idsToInvalidate[id]
newInvalidateMetadata := current || invalidateMetadata
// If we've already seen this ID, and the value of invalidate
// metadata has not changed, we can return early.
if seen && current == newInvalidateMetadata {
return
}
idsToInvalidate[id] = newInvalidateMetadata
for _, rid := range s.meta.importedBy[id] {
addRevDeps(rid, invalidateMetadata)
}
}
for id, invalidateMetadata := range directIDs {
addRevDeps(id, invalidateMetadata)
}
// Invalidated package information.
for id, invalidateMetadata := range idsToInvalidate {
if _, ok := directIDs[id]; ok || invalidateMetadata {
result.packages.Delete(id)
} else {
if entry, hit := result.packages.Get(id); hit {
ph := entry.(*packageHandle).clone(false)
result.packages.Set(id, ph, nil)
}
}
result.activePackages.Delete(id)
}
// Delete invalidated analysis actions.
var actionsToDelete []analysisKey
result.analyses.Range(func(k, _ interface{}) {
key := k.(analysisKey)
if _, ok := idsToInvalidate[key.pkgid]; ok {
actionsToDelete = append(actionsToDelete, key)
}
})
for _, key := range actionsToDelete {
result.analyses.Delete(key)
}
// If a file has been deleted, we must delete metadata for all packages
// containing that file.
//
// TODO(rfindley): why not keep invalid metadata in this case? If we
// otherwise allow operate on invalid metadata, why not continue to do so,
// skipping the missing file?
skipID := map[PackageID]bool{}
for _, c := range changes {
if c.exists {
continue
}
// The file has been deleted.
if ids, ok := s.meta.ids[c.fileHandle.URI()]; ok {
for _, id := range ids {
skipID[id] = true
}
}
}
// Any packages that need loading in s still need loading in the new
// snapshot.
for k, v := range s.shouldLoad {
if result.shouldLoad == nil {
result.shouldLoad = make(map[PackageID][]PackagePath)
}
result.shouldLoad[k] = v
}
// Compute which metadata updates are required. We only need to invalidate
// packages directly containing the affected file, and only if it changed in
// a relevant way.
metadataUpdates := make(map[PackageID]*source.Metadata)
for k, v := range s.meta.metadata {
invalidateMetadata := idsToInvalidate[k]
// For metadata that has been newly invalidated, capture package paths
// requiring reloading in the shouldLoad map.
if invalidateMetadata && !source.IsCommandLineArguments(v.ID) {
if result.shouldLoad == nil {
result.shouldLoad = make(map[PackageID][]PackagePath)
}
needsReload := []PackagePath{v.PkgPath}
if v.ForTest != "" && v.ForTest != v.PkgPath {
// When reloading test variants, always reload their ForTest package as
// well. Otherwise, we may miss test variants in the resulting load.
//
// TODO(rfindley): is this actually sufficient? Is it possible that
// other test variants may be invalidated? Either way, we should
// determine exactly what needs to be reloaded here.
needsReload = append(needsReload, v.ForTest)
}
result.shouldLoad[k] = needsReload
}
// Check whether the metadata should be deleted.
if skipID[k] || invalidateMetadata {
metadataUpdates[k] = nil
continue
}
}
// Update metadata, if necessary.
result.meta = s.meta.Clone(metadataUpdates)
// Update workspace and active packages, if necessary.
if result.meta != s.meta || anyFileOpenedOrClosed {
result.workspacePackages = computeWorkspacePackagesLocked(result, result.meta)
result.resetActivePackagesLocked()
} else {
result.workspacePackages = s.workspacePackages
}
// Don't bother copying the importedBy graph,
// as it changes each time we update metadata.
// TODO(rfindley): consolidate the this workspace mode detection with
// workspace invalidation.
workspaceModeChanged := s.workspaceMode() != result.workspaceMode()
// If the snapshot's workspace mode has changed, the packages loaded using
// the previous mode are no longer relevant, so clear them out.
if workspaceModeChanged {
result.workspacePackages = map[PackageID]PackagePath{}
}
return result, release
}
// deleteMostRelevantModFile deletes the mod file most likely to be the mod
// file for the changed URI, if it exists.
//
// Specifically, this is the longest mod file path in a directory containing
// changed. This might not be accurate if there is another mod file closer to
// changed that happens not to be present in the map, but that's OK: the goal
// of this function is to guarantee that IF the nearest mod file is present in
// the map, it is invalidated.
func deleteMostRelevantModFile(m *persistent.Map, changed span.URI) {
var mostRelevant span.URI
changedFile := changed.Filename()
m.Range(func(key, value interface{}) {
modURI := key.(span.URI)
if len(modURI) > len(mostRelevant) {
if source.InDir(filepath.Dir(modURI.Filename()), changedFile) {
mostRelevant = modURI
}
}
})
if mostRelevant != "" {
m.Delete(mostRelevant)
}
}
// invalidatedPackageIDs returns all packages invalidated by a change to uri.
// If we haven't seen this URI before, we guess based on files in the same
// directory. This is of course incorrect in build systems where packages are
// not organized by directory.
//
// If packageFileChanged is set, the file is either a new file, or has a new
// package name. In this case, all known packages in the directory will be
// invalidated.
func invalidatedPackageIDs(uri span.URI, known map[span.URI][]PackageID, packageFileChanged bool) map[PackageID]struct{} {
invalidated := make(map[PackageID]struct{})
// At a minimum, we invalidate packages known to contain uri.
for _, id := range known[uri] {
invalidated[id] = struct{}{}
}
// If the file didn't move to a new package, we should only invalidate the
// packages it is currently contained inside.
if !packageFileChanged && len(invalidated) > 0 {
return invalidated
}
// This is a file we don't yet know about, or which has moved packages. Guess
// relevant packages by considering files in the same directory.
// Cache of FileInfo to avoid unnecessary stats for multiple files in the
// same directory.
stats := make(map[string]struct {
os.FileInfo
error
})
getInfo := func(dir string) (os.FileInfo, error) {
if res, ok := stats[dir]; ok {
return res.FileInfo, res.error
}
fi, err := os.Stat(dir)
stats[dir] = struct {
os.FileInfo
error
}{fi, err}
return fi, err
}
dir := filepath.Dir(uri.Filename())
fi, err := getInfo(dir)
if err == nil {
// Aggregate all possibly relevant package IDs.
for knownURI, ids := range known {
knownDir := filepath.Dir(knownURI.Filename())
knownFI, err := getInfo(knownDir)
if err != nil {
continue
}
if os.SameFile(fi, knownFI) {
for _, id := range ids {
invalidated[id] = struct{}{}
}
}
}
}
return invalidated
}
// 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
}
// metadataChanges detects features of the change from oldFH->newFH that may
// affect package metadata.
//
// It uses lockedSnapshot to access cached parse information. lockedSnapshot
// must be locked.
//
// The result parameters have the following meaning:
// - invalidate means that package metadata for packages containing the file
// should be invalidated.
// - pkgFileChanged means that the file->package associates for the file have
// changed (possibly because the file is new, or because its package name has
// changed).
// - importDeleted means that an import has been deleted, or we can't
// determine if an import was deleted due to errors.
func metadataChanges(ctx context.Context, lockedSnapshot *snapshot, oldFH, newFH source.FileHandle) (invalidate, pkgFileChanged, importDeleted bool) {
if oldFH == nil || newFH == nil { // existential changes
changed := (oldFH == nil) != (newFH == nil)
return changed, changed, (newFH == nil) // we don't know if an import was deleted
}
// If the file hasn't changed, there's no need to reload.
if oldFH.FileIdentity() == newFH.FileIdentity() {
return false, false, false
}
fset := token.NewFileSet()
// Parse headers to compare package names and imports.
oldHeads, oldErr := lockedSnapshot.parseCache.parseFiles(ctx, fset, source.ParseHeader, oldFH)
newHeads, newErr := lockedSnapshot.parseCache.parseFiles(ctx, fset, source.ParseHeader, newFH)
if oldErr != nil || newErr != nil {
// TODO(rfindley): we can get here if newFH does not exist. There is
// asymmetry, in that newFH may be non-nil even if the underlying file does
// not exist.
//
// We should not produce a non-nil filehandle for a file that does not exist.
errChanged := (oldErr == nil) != (newErr == nil)
return errChanged, errChanged, (newErr != nil) // we don't know if an import was deleted
}
oldHead := oldHeads[0]
newHead := newHeads[0]
// `go list` fails completely if the file header cannot be parsed. If we go
// from a non-parsing state to a parsing state, we should reload.
if oldHead.ParseErr != nil && newHead.ParseErr == nil {
return true, true, true // We don't know what changed, so fall back on full invalidation.
}
// If a package name has changed, the set of package imports may have changed
// in ways we can't detect here. Assume an import has been deleted.
if oldHead.File.Name.Name != newHead.File.Name.Name {
return true, true, true
}
// Check whether package imports have changed. Only consider potentially
// valid imports paths.
oldImports := validImports(oldHead.File.Imports)
newImports := validImports(newHead.File.Imports)
for path := range newImports {
if _, ok := oldImports[path]; ok {
delete(oldImports, path)
} else {
invalidate = true // a new, potentially valid import was added
}
}
if len(oldImports) > 0 {
invalidate = true
importDeleted = true
}
// If the change does not otherwise invalidate metadata, get the full ASTs in
// order to check magic comments.
//
// Note: if this affects performance we can probably avoid parsing in the
// common case by first scanning the source for potential comments.
if !invalidate {
origFulls, oldErr := lockedSnapshot.parseCache.parseFiles(ctx, fset, source.ParseFull, oldFH)
newFulls, newErr := lockedSnapshot.parseCache.parseFiles(ctx, fset, source.ParseFull, newFH)
if oldErr == nil && newErr == nil {
invalidate = magicCommentsChanged(origFulls[0].File, newFulls[0].File)
} else {
// At this point, we shouldn't ever fail to produce a ParsedGoFile, as
// we're already past header parsing.
bug.Reportf("metadataChanges: unparseable file %v (old error: %v, new error: %v)", oldFH.URI(), oldErr, newErr)
}
}
return invalidate, pkgFileChanged, importDeleted
}
func magicCommentsChanged(original *ast.File, current *ast.File) bool {
oldComments := extractMagicComments(original)
newComments := extractMagicComments(current)
if len(oldComments) != len(newComments) {
return true
}
for i := range oldComments {
if oldComments[i] != newComments[i] {
return true
}
}
return false
}
// validImports extracts the set of valid import paths from imports.
func validImports(imports []*ast.ImportSpec) map[string]struct{} {
m := make(map[string]struct{})
for _, spec := range imports {
if path := spec.Path.Value; validImportPath(path) {
m[path] = struct{}{}
}
}
return m
}
func validImportPath(path string) bool {
path, err := strconv.Unquote(path)
if err != nil {
return false
}
if path == "" {
return false
}
if path[len(path)-1] == '/' {
return false
}
return true
}
var buildConstraintOrEmbedRe = regexp.MustCompile(`^//(go:embed|go:build|\s*\+build).*`)
// extractMagicComments finds magic comments that affect metadata in f.
func extractMagicComments(f *ast.File) []string {
var results []string
for _, cg := range f.Comments {
for _, c := range cg.List {
if buildConstraintOrEmbedRe.MatchString(c.Text) {
results = append(results, c.Text)
}
}
}
return results
}
func (s *snapshot) BuiltinFile(ctx context.Context) (*source.ParsedGoFile, error) {
s.AwaitInitialized(ctx)
s.mu.Lock()
builtin := s.builtin
s.mu.Unlock()
if builtin == "" {
return nil, fmt.Errorf("no builtin package for view %s", s.view.name)
}
fh, err := s.ReadFile(ctx, builtin)
if err != nil {
return nil, err
}
// For the builtin file only, we need syntactic object resolution
// (since we can't type check).
mode := source.ParseFull &^ source.SkipObjectResolution
pgfs, err := s.parseCache.parseFiles(ctx, token.NewFileSet(), mode, fh)
if err != nil {
return nil, err
}
return pgfs[0], nil
}
func (s *snapshot) IsBuiltin(uri span.URI) bool {
s.mu.Lock()
defer s.mu.Unlock()
// We should always get the builtin URI in a canonical form, so use simple
// string comparison here. span.CompareURI is too expensive.
return uri == s.builtin
}
func (s *snapshot) setBuiltin(path string) {
s.mu.Lock()
defer s.mu.Unlock()
s.builtin = span.URIFromPath(path)
}