blob: 70dd56f1037e349ec7c980bb2fbd3f0909f19d3f [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 sumdb
import (
"bytes"
"errors"
"fmt"
"path"
"strings"
"sync"
"sync/atomic"
"golang.org/x/mod/module"
"golang.org/x/mod/sumdb/note"
"golang.org/x/mod/sumdb/tlog"
)
// A ClientOps provides the external operations
// (file caching, HTTP fetches, and so on) needed by the Client.
// The methods must be safe for concurrent use by multiple goroutines.
type ClientOps interface {
// ReadRemote reads and returns the content served at the given path
// on the remote database server. The path begins with "/lookup" or "/tile/",
// and there is no need to parse the path in any way.
// It is the implementation's responsibility to turn that path into a full URL
// and make the HTTP request. ReadRemote should return an error for
// any non-200 HTTP response status.
ReadRemote(path string) ([]byte, error)
// ReadConfig reads and returns the content of the named configuration file.
// There are only a fixed set of configuration files.
//
// "key" returns a file containing the verifier key for the server.
//
// serverName + "/latest" returns a file containing the latest known
// signed tree from the server.
// To signal that the client wishes to start with an "empty" signed tree,
// ReadConfig can return a successful empty result (0 bytes of data).
ReadConfig(file string) ([]byte, error)
// WriteConfig updates the content of the named configuration file,
// changing it from the old []byte to the new []byte.
// If the old []byte does not match the stored configuration,
// WriteConfig must return ErrWriteConflict.
// Otherwise, WriteConfig should atomically replace old with new.
// The "key" configuration file is never written using WriteConfig.
WriteConfig(file string, old, new []byte) error
// ReadCache reads and returns the content of the named cache file.
// Any returned error will be treated as equivalent to the file not existing.
// There can be arbitrarily many cache files, such as:
// serverName/lookup/pkg@version
// serverName/tile/8/1/x123/456
ReadCache(file string) ([]byte, error)
// WriteCache writes the named cache file.
WriteCache(file string, data []byte)
// Log prints the given log message (such as with log.Print)
Log(msg string)
// SecurityError prints the given security error log message.
// The Client returns ErrSecurity from any operation that invokes SecurityError,
// but the return value is mainly for testing. In a real program,
// SecurityError should typically print the message and call log.Fatal or os.Exit.
SecurityError(msg string)
}
// ErrWriteConflict signals a write conflict during Client.WriteConfig.
var ErrWriteConflict = errors.New("write conflict")
// ErrSecurity is returned by Client operations that invoke Client.SecurityError.
var ErrSecurity = errors.New("security error: misbehaving server")
// A Client is a client connection to a checksum database.
// All the methods are safe for simultaneous use by multiple goroutines.
type Client struct {
ops ClientOps // access to operations in the external world
didLookup uint32
// one-time initialized data
initOnce sync.Once
initErr error // init error, if any
name string // name of accepted verifier
verifiers note.Verifiers // accepted verifiers (just one, but Verifiers for note.Open)
tileReader tileReader
tileHeight int
nosumdb string
record parCache // cache of record lookup, keyed by path@vers
tileCache parCache // cache of c.readTile, keyed by tile
latestMu sync.Mutex
latest tlog.Tree // latest known tree head
latestMsg []byte // encoded signed note for latest
tileSavedMu sync.Mutex
tileSaved map[tlog.Tile]bool // which tiles have been saved using c.ops.WriteCache already
}
// NewClient returns a new Client using the given Client.
func NewClient(ops ClientOps) *Client {
return &Client{
ops: ops,
}
}
// init initiailzes the client (if not already initialized)
// and returns any initialization error.
func (c *Client) init() error {
c.initOnce.Do(c.initWork)
return c.initErr
}
// initWork does the actual initialization work.
func (c *Client) initWork() {
defer func() {
if c.initErr != nil {
c.initErr = fmt.Errorf("initializing sumdb.Client: %v", c.initErr)
}
}()
c.tileReader.c = c
if c.tileHeight == 0 {
c.tileHeight = 8
}
c.tileSaved = make(map[tlog.Tile]bool)
vkey, err := c.ops.ReadConfig("key")
if err != nil {
c.initErr = err
return
}
verifier, err := note.NewVerifier(strings.TrimSpace(string(vkey)))
if err != nil {
c.initErr = err
return
}
c.verifiers = note.VerifierList(verifier)
c.name = verifier.Name()
data, err := c.ops.ReadConfig(c.name + "/latest")
if err != nil {
c.initErr = err
return
}
if err := c.mergeLatest(data); err != nil {
c.initErr = err
return
}
}
// SetTileHeight sets the tile height for the Client.
// Any call to SetTileHeight must happen before the first call to Lookup.
// If SetTileHeight is not called, the Client defaults to tile height 8.
// SetTileHeight can be called at most once,
// and if so it must be called before the first call to Lookup.
func (c *Client) SetTileHeight(height int) {
if atomic.LoadUint32(&c.didLookup) != 0 {
panic("SetTileHeight used after Lookup")
}
if height <= 0 {
panic("invalid call to SetTileHeight")
}
if c.tileHeight != 0 {
panic("multiple calls to SetTileHeight")
}
c.tileHeight = height
}
// SetGONOSUMDB sets the list of comma-separated GONOSUMDB patterns for the Client.
// For any module path matching one of the patterns,
// Lookup will return ErrGONOSUMDB.
// SetGONOSUMDB can be called at most once,
// and if so it must be called before the first call to Lookup.
func (c *Client) SetGONOSUMDB(list string) {
if atomic.LoadUint32(&c.didLookup) != 0 {
panic("SetGONOSUMDB used after Lookup")
}
if c.nosumdb != "" {
panic("multiple calls to SetGONOSUMDB")
}
c.nosumdb = list
}
// ErrGONOSUMDB is returned by Lookup for paths that match
// a pattern listed in the GONOSUMDB list (set by SetGONOSUMDB,
// usually from the environment variable).
var ErrGONOSUMDB = errors.New("skipped (listed in GONOSUMDB)")
func (c *Client) skip(target string) bool {
return globsMatchPath(c.nosumdb, target)
}
// globsMatchPath reports whether any path prefix of target
// matches one of the glob patterns (as defined by path.Match)
// in the comma-separated globs list.
// It ignores any empty or malformed patterns in the list.
func globsMatchPath(globs, target string) bool {
for globs != "" {
// Extract next non-empty glob in comma-separated list.
var glob string
if i := strings.Index(globs, ","); i >= 0 {
glob, globs = globs[:i], globs[i+1:]
} else {
glob, globs = globs, ""
}
if glob == "" {
continue
}
// A glob with N+1 path elements (N slashes) needs to be matched
// against the first N+1 path elements of target,
// which end just before the N+1'th slash.
n := strings.Count(glob, "/")
prefix := target
// Walk target, counting slashes, truncating at the N+1'th slash.
for i := 0; i < len(target); i++ {
if target[i] == '/' {
if n == 0 {
prefix = target[:i]
break
}
n--
}
}
if n > 0 {
// Not enough prefix elements.
continue
}
matched, _ := path.Match(glob, prefix)
if matched {
return true
}
}
return false
}
// Lookup returns the go.sum lines for the given module path and version.
// The version may end in a /go.mod suffix, in which case Lookup returns
// the go.sum lines for the module's go.mod-only hash.
func (c *Client) Lookup(path, vers string) (lines []string, err error) {
atomic.StoreUint32(&c.didLookup, 1)
if c.skip(path) {
return nil, ErrGONOSUMDB
}
defer func() {
if err != nil {
err = fmt.Errorf("%s@%s: %v", path, vers, err)
}
}()
if err := c.init(); err != nil {
return nil, err
}
// Prepare encoded cache filename / URL.
epath, err := module.EscapePath(path)
if err != nil {
return nil, err
}
evers, err := module.EscapeVersion(strings.TrimSuffix(vers, "/go.mod"))
if err != nil {
return nil, err
}
remotePath := "/lookup/" + epath + "@" + evers
file := c.name + remotePath
// Fetch the data.
// The lookupCache avoids redundant ReadCache/GetURL operations
// (especially since go.sum lines tend to come in pairs for a given
// path and version) and also avoids having multiple of the same
// request in flight at once.
type cached struct {
data []byte
err error
}
result := c.record.Do(file, func() interface{} {
// Try the on-disk cache, or else get from web.
writeCache := false
data, err := c.ops.ReadCache(file)
if err != nil {
data, err = c.ops.ReadRemote(remotePath)
if err != nil {
return cached{nil, err}
}
writeCache = true
}
// Validate the record before using it for anything.
id, text, treeMsg, err := tlog.ParseRecord(data)
if err != nil {
return cached{nil, err}
}
if err := c.mergeLatest(treeMsg); err != nil {
return cached{nil, err}
}
if err := c.checkRecord(id, text); err != nil {
return cached{nil, err}
}
// Now that we've validated the record,
// save it to the on-disk cache (unless that's where it came from).
if writeCache {
c.ops.WriteCache(file, data)
}
return cached{data, nil}
}).(cached)
if result.err != nil {
return nil, result.err
}
// Extract the lines for the specific version we want
// (with or without /go.mod).
prefix := path + " " + vers + " "
var hashes []string
for _, line := range strings.Split(string(result.data), "\n") {
if strings.HasPrefix(line, prefix) {
hashes = append(hashes, line)
}
}
return hashes, nil
}
// mergeLatest merges the tree head in msg
// with the Client's current latest tree head,
// ensuring the result is a consistent timeline.
// If the result is inconsistent, mergeLatest calls c.ops.SecurityError
// with a detailed security error message and then
// (only if c.ops.SecurityError does not exit the program) returns ErrSecurity.
// If the Client's current latest tree head moves forward,
// mergeLatest updates the underlying configuration file as well,
// taking care to merge any independent updates to that configuration.
func (c *Client) mergeLatest(msg []byte) error {
// Merge msg into our in-memory copy of the latest tree head.
when, err := c.mergeLatestMem(msg)
if err != nil {
return err
}
if when != msgFuture {
// msg matched our present or was in the past.
// No change to our present, so no update of config file.
return nil
}
// Flush our extended timeline back out to the configuration file.
// If the configuration file has been updated in the interim,
// we need to merge any updates made there as well.
// Note that writeConfig is an atomic compare-and-swap.
for {
msg, err := c.ops.ReadConfig(c.name + "/latest")
if err != nil {
return err
}
when, err := c.mergeLatestMem(msg)
if err != nil {
return err
}
if when != msgPast {
// msg matched our present or was from the future,
// and now our in-memory copy matches.
return nil
}
// msg (== config) is in the past, so we need to update it.
c.latestMu.Lock()
latestMsg := c.latestMsg
c.latestMu.Unlock()
if err := c.ops.WriteConfig(c.name+"/latest", msg, latestMsg); err != ErrWriteConflict {
// Success or a non-write-conflict error.
return err
}
}
}
const (
msgPast = 1 + iota
msgNow
msgFuture
)
// mergeLatestMem is like mergeLatest but is only concerned with
// updating the in-memory copy of the latest tree head (c.latest)
// not the configuration file.
// The when result explains when msg happened relative to our
// previous idea of c.latest:
// msgPast means msg was from before c.latest,
// msgNow means msg was exactly c.latest, and
// msgFuture means msg was from after c.latest, which has now been updated.
func (c *Client) mergeLatestMem(msg []byte) (when int, err error) {
if len(msg) == 0 {
// Accept empty msg as the unsigned, empty timeline.
c.latestMu.Lock()
latest := c.latest
c.latestMu.Unlock()
if latest.N == 0 {
return msgNow, nil
}
return msgPast, nil
}
note, err := note.Open(msg, c.verifiers)
if err != nil {
return 0, fmt.Errorf("reading tree note: %v\nnote:\n%s", err, msg)
}
tree, err := tlog.ParseTree([]byte(note.Text))
if err != nil {
return 0, fmt.Errorf("reading tree: %v\ntree:\n%s", err, note.Text)
}
// Other lookups may be calling mergeLatest with other heads,
// so c.latest is changing underfoot. We don't want to hold the
// c.mu lock during tile fetches, so loop trying to update c.latest.
c.latestMu.Lock()
latest := c.latest
latestMsg := c.latestMsg
c.latestMu.Unlock()
for {
// If the tree head looks old, check that it is on our timeline.
if tree.N <= latest.N {
if err := c.checkTrees(tree, msg, latest, latestMsg); err != nil {
return 0, err
}
if tree.N < latest.N {
return msgPast, nil
}
return msgNow, nil
}
// The tree head looks new. Check that we are on its timeline and try to move our timeline forward.
if err := c.checkTrees(latest, latestMsg, tree, msg); err != nil {
return 0, err
}
// Install our msg if possible.
// Otherwise we will go around again.
c.latestMu.Lock()
installed := false
if c.latest == latest {
installed = true
c.latest = tree
c.latestMsg = msg
} else {
latest = c.latest
latestMsg = c.latestMsg
}
c.latestMu.Unlock()
if installed {
return msgFuture, nil
}
}
}
// checkTrees checks that older (from olderNote) is contained in newer (from newerNote).
// If an error occurs, such as malformed data or a network problem, checkTrees returns that error.
// If on the other hand checkTrees finds evidence of misbehavior, it prepares a detailed
// message and calls log.Fatal.
func (c *Client) checkTrees(older tlog.Tree, olderNote []byte, newer tlog.Tree, newerNote []byte) error {
thr := tlog.TileHashReader(newer, &c.tileReader)
h, err := tlog.TreeHash(older.N, thr)
if err != nil {
if older.N == newer.N {
return fmt.Errorf("checking tree#%d: %v", older.N, err)
}
return fmt.Errorf("checking tree#%d against tree#%d: %v", older.N, newer.N, err)
}
if h == older.Hash {
return nil
}
// Detected a fork in the tree timeline.
// Start by reporting the inconsistent signed tree notes.
var buf bytes.Buffer
fmt.Fprintf(&buf, "SECURITY ERROR\n")
fmt.Fprintf(&buf, "go.sum database server misbehavior detected!\n\n")
indent := func(b []byte) []byte {
return bytes.Replace(b, []byte("\n"), []byte("\n\t"), -1)
}
fmt.Fprintf(&buf, "old database:\n\t%s\n", indent(olderNote))
fmt.Fprintf(&buf, "new database:\n\t%s\n", indent(newerNote))
// The notes alone are not enough to prove the inconsistency.
// We also need to show that the newer note's tree hash for older.N
// does not match older.Hash. The consumer of this report could
// of course consult the server to try to verify the inconsistency,
// but we are holding all the bits we need to prove it right now,
// so we might as well print them and make the report not depend
// on the continued availability of the misbehaving server.
// Preparing this data only reuses the tiled hashes needed for
// tlog.TreeHash(older.N, thr) above, so assuming thr is caching tiles,
// there are no new access to the server here, and these operations cannot fail.
fmt.Fprintf(&buf, "proof of misbehavior:\n\t%v", h)
if p, err := tlog.ProveTree(newer.N, older.N, thr); err != nil {
fmt.Fprintf(&buf, "\tinternal error: %v\n", err)
} else if err := tlog.CheckTree(p, newer.N, newer.Hash, older.N, h); err != nil {
fmt.Fprintf(&buf, "\tinternal error: generated inconsistent proof\n")
} else {
for _, h := range p {
fmt.Fprintf(&buf, "\n\t%v", h)
}
}
c.ops.SecurityError(buf.String())
return ErrSecurity
}
// checkRecord checks that record #id's hash matches data.
func (c *Client) checkRecord(id int64, data []byte) error {
c.latestMu.Lock()
latest := c.latest
c.latestMu.Unlock()
if id >= latest.N {
return fmt.Errorf("cannot validate record %d in tree of size %d", id, latest.N)
}
hashes, err := tlog.TileHashReader(latest, &c.tileReader).ReadHashes([]int64{tlog.StoredHashIndex(0, id)})
if err != nil {
return err
}
if hashes[0] == tlog.RecordHash(data) {
return nil
}
return fmt.Errorf("cannot authenticate record data in server response")
}
// tileReader is a *Client wrapper that implements tlog.TileReader.
// The separate type avoids exposing the ReadTiles and SaveTiles
// methods on Client itself.
type tileReader struct {
c *Client
}
func (r *tileReader) Height() int {
return r.c.tileHeight
}
// ReadTiles reads and returns the requested tiles,
// either from the on-disk cache or the server.
func (r *tileReader) ReadTiles(tiles []tlog.Tile) ([][]byte, error) {
// Read all the tiles in parallel.
data := make([][]byte, len(tiles))
errs := make([]error, len(tiles))
var wg sync.WaitGroup
for i, tile := range tiles {
wg.Add(1)
go func(i int, tile tlog.Tile) {
defer wg.Done()
data[i], errs[i] = r.c.readTile(tile)
}(i, tile)
}
wg.Wait()
for _, err := range errs {
if err != nil {
return nil, err
}
}
return data, nil
}
// tileCacheKey returns the cache key for the tile.
func (c *Client) tileCacheKey(tile tlog.Tile) string {
return c.name + "/" + tile.Path()
}
// tileRemotePath returns the remote path for the tile.
func (c *Client) tileRemotePath(tile tlog.Tile) string {
return "/" + tile.Path()
}
// readTile reads a single tile, either from the on-disk cache or the server.
func (c *Client) readTile(tile tlog.Tile) ([]byte, error) {
type cached struct {
data []byte
err error
}
result := c.tileCache.Do(tile, func() interface{} {
// Try the requested tile in on-disk cache.
data, err := c.ops.ReadCache(c.tileCacheKey(tile))
if err == nil {
c.markTileSaved(tile)
return cached{data, nil}
}
// Try the full tile in on-disk cache (if requested tile not already full).
// We only save authenticated tiles to the on-disk cache,
// so the recreated prefix is equally authenticated.
full := tile
full.W = 1 << uint(tile.H)
if tile != full {
data, err := c.ops.ReadCache(c.tileCacheKey(full))
if err == nil {
c.markTileSaved(tile) // don't save tile later; we already have full
return cached{data[:len(data)/full.W*tile.W], nil}
}
}
// Try requested tile from server.
data, err = c.ops.ReadRemote(c.tileRemotePath(tile))
if err == nil {
return cached{data, nil}
}
// Try full tile on server.
// If the partial tile does not exist, it should be because
// the tile has been completed and only the complete one
// is available.
if tile != full {
data, err := c.ops.ReadRemote(c.tileRemotePath(full))
if err == nil {
// Note: We could save the full tile in the on-disk cache here,
// but we don't know if it is valid yet, and we will only find out
// about the partial data, not the full data. So let SaveTiles
// save the partial tile, and we'll just refetch the full tile later
// once we can validate more (or all) of it.
return cached{data[:len(data)/full.W*tile.W], nil}
}
}
// Nothing worked.
// Return the error from the server fetch for the requested (not full) tile.
return cached{nil, err}
}).(cached)
return result.data, result.err
}
// markTileSaved records that tile is already present in the on-disk cache,
// so that a future SaveTiles for that tile can be ignored.
func (c *Client) markTileSaved(tile tlog.Tile) {
c.tileSavedMu.Lock()
c.tileSaved[tile] = true
c.tileSavedMu.Unlock()
}
// SaveTiles saves the now validated tiles.
func (r *tileReader) SaveTiles(tiles []tlog.Tile, data [][]byte) {
c := r.c
// Determine which tiles need saving.
// (Tiles that came from the cache need not be saved back.)
save := make([]bool, len(tiles))
c.tileSavedMu.Lock()
for i, tile := range tiles {
if !c.tileSaved[tile] {
save[i] = true
c.tileSaved[tile] = true
}
}
c.tileSavedMu.Unlock()
for i, tile := range tiles {
if save[i] {
// If WriteCache fails here (out of disk space? i/o error?),
// c.tileSaved[tile] is still true and we will not try to write it again.
// Next time we run maybe we'll redownload it again and be
// more successful.
c.ops.WriteCache(c.name+"/"+tile.Path(), data[i])
}
}
}