minio/vendor/github.com/inconshreveable/go-update/apply.go

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package update
import (
"bytes"
"crypto"
"crypto/x509"
"encoding/pem"
"errors"
"fmt"
"io"
"io/ioutil"
"os"
"path/filepath"
"github.com/inconshreveable/go-update/internal/osext"
)
var (
openFile = os.OpenFile
)
// Apply performs an update of the current executable (or opts.TargetFile, if set) with the contents of the given io.Reader.
//
// Apply performs the following actions to ensure a safe cross-platform update:
//
// 1. If configured, applies the contents of the update io.Reader as a binary patch.
//
// 2. If configured, computes the checksum of the new executable and verifies it matches.
//
// 3. If configured, verifies the signature with a public key.
//
// 4. Creates a new file, /path/to/.target.new with the TargetMode with the contents of the updated file
//
// 5. Renames /path/to/target to /path/to/.target.old
//
// 6. Renames /path/to/.target.new to /path/to/target
//
// 7. If the final rename is successful, deletes /path/to/.target.old, returns no error. On Windows,
// the removal of /path/to/target.old always fails, so instead Apply hides the old file instead.
//
// 8. If the final rename fails, attempts to roll back by renaming /path/to/.target.old
// back to /path/to/target.
//
// If the roll back operation fails, the file system is left in an inconsistent state (betweet steps 5 and 6) where
// there is no new executable file and the old executable file could not be be moved to its original location. In this
// case you should notify the user of the bad news and ask them to recover manually. Applications can determine whether
// the rollback failed by calling RollbackError, see the documentation on that function for additional detail.
func Apply(update io.Reader, opts Options) error {
// validate
verify := false
switch {
case opts.Signature != nil && opts.PublicKey != nil:
// okay
verify = true
case opts.Signature != nil:
return errors.New("no public key to verify signature with")
case opts.PublicKey != nil:
return errors.New("No signature to verify with")
}
// set defaults
if opts.Hash == 0 {
opts.Hash = crypto.SHA256
}
if opts.Verifier == nil {
opts.Verifier = NewECDSAVerifier()
}
if opts.TargetMode == 0 {
opts.TargetMode = 0755
}
// get target path
var err error
opts.TargetPath, err = opts.getPath()
if err != nil {
return err
}
var newBytes []byte
if opts.Patcher != nil {
if newBytes, err = opts.applyPatch(update); err != nil {
return err
}
} else {
// no patch to apply, go on through
if newBytes, err = ioutil.ReadAll(update); err != nil {
return err
}
}
// verify checksum if requested
if opts.Checksum != nil {
if err = opts.verifyChecksum(newBytes); err != nil {
return err
}
}
if verify {
if err = opts.verifySignature(newBytes); err != nil {
return err
}
}
// get the directory the executable exists in
updateDir := filepath.Dir(opts.TargetPath)
filename := filepath.Base(opts.TargetPath)
// Copy the contents of newbinary to a new executable file
newPath := filepath.Join(updateDir, fmt.Sprintf(".%s.new", filename))
fp, err := openFile(newPath, os.O_CREATE|os.O_WRONLY|os.O_TRUNC, opts.TargetMode)
if err != nil {
return err
}
defer fp.Close()
_, err = io.Copy(fp, bytes.NewReader(newBytes))
if err != nil {
return err
}
// if we don't call fp.Close(), windows won't let us move the new executable
// because the file will still be "in use"
fp.Close()
// this is where we'll move the executable to so that we can swap in the updated replacement
oldPath := opts.OldSavePath
removeOld := opts.OldSavePath == ""
if removeOld {
oldPath = filepath.Join(updateDir, fmt.Sprintf(".%s.old", filename))
}
// delete any existing old exec file - this is necessary on Windows for two reasons:
// 1. after a successful update, Windows can't remove the .old file because the process is still running
// 2. windows rename operations fail if the destination file already exists
_ = os.Remove(oldPath)
// move the existing executable to a new file in the same directory
err = os.Rename(opts.TargetPath, oldPath)
if err != nil {
return err
}
// move the new exectuable in to become the new program
err = os.Rename(newPath, opts.TargetPath)
if err != nil {
// move unsuccessful
//
// The filesystem is now in a bad state. We have successfully
// moved the existing binary to a new location, but we couldn't move the new
// binary to take its place. That means there is no file where the current executable binary
// used to be!
// Try to rollback by restoring the old binary to its original path.
rerr := os.Rename(oldPath, opts.TargetPath)
if rerr != nil {
return &rollbackErr{err, rerr}
}
return err
}
// move successful, remove the old binary if needed
if removeOld {
errRemove := os.Remove(oldPath)
// windows has trouble with removing old binaries, so hide it instead
if errRemove != nil {
_ = hideFile(oldPath)
}
}
return nil
}
// RollbackError takes an error value returned by Apply and returns the error, if any,
// that occurred when attempting to roll back from a failed update. Applications should
// always call this function on any non-nil errors returned by Apply.
//
// If no rollback was needed or if the rollback was successful, RollbackError returns nil,
// otherwise it returns the error encountered when trying to roll back.
func RollbackError(err error) error {
if err == nil {
return nil
}
if rerr, ok := err.(*rollbackErr); ok {
return rerr.rollbackErr
}
return nil
}
type rollbackErr struct {
error // original error
rollbackErr error // error encountered while rolling back
}
type Options struct {
// TargetPath defines the path to the file to update.
// The emptry string means 'the executable file of the running program'.
TargetPath string
// Create TargetPath replacement with this file mode. If zero, defaults to 0755.
TargetMode os.FileMode
// Checksum of the new binary to verify against. If nil, no checksum or signature verification is done.
Checksum []byte
// Public key to use for signature verification. If nil, no signature verification is done.
PublicKey crypto.PublicKey
// Signature to verify the updated file. If nil, no signature verification is done.
Signature []byte
// Pluggable signature verification algorithm. If nil, ECDSA is used.
Verifier Verifier
// Use this hash function to generate the checksum. If not set, SHA256 is used.
Hash crypto.Hash
// If nil, treat the update as a complete replacement for the contents of the file at TargetPath.
// If non-nil, treat the update contents as a patch and use this object to apply the patch.
Patcher Patcher
// Store the old executable file at this path after a successful update.
// The empty string means the old executable file will be removed after the update.
OldSavePath string
}
// CheckPermissions determines whether the process has the correct permissions to
// perform the requested update. If the update can proceed, it returns nil, otherwise
// it returns the error that would occur if an update were attempted.
func (o *Options) CheckPermissions() error {
// get the directory the file exists in
path, err := o.getPath()
if err != nil {
return err
}
fileDir := filepath.Dir(path)
fileName := filepath.Base(path)
// attempt to open a file in the file's directory
newPath := filepath.Join(fileDir, fmt.Sprintf(".%s.new", fileName))
fp, err := openFile(newPath, os.O_CREATE|os.O_WRONLY|os.O_TRUNC, o.TargetMode)
if err != nil {
return err
}
fp.Close()
_ = os.Remove(newPath)
return nil
}
// SetPublicKeyPEM is a convenience method to set the PublicKey property
// used for checking a completed update's signature by parsing a
// Public Key formatted as PEM data.
func (o *Options) SetPublicKeyPEM(pembytes []byte) error {
block, _ := pem.Decode(pembytes)
if block == nil {
return errors.New("couldn't parse PEM data")
}
pub, err := x509.ParsePKIXPublicKey(block.Bytes)
if err != nil {
return err
}
o.PublicKey = pub
return nil
}
func (o *Options) getPath() (string, error) {
if o.TargetPath == "" {
return osext.Executable()
} else {
return o.TargetPath, nil
}
}
func (o *Options) applyPatch(patch io.Reader) ([]byte, error) {
// open the file to patch
old, err := os.Open(o.TargetPath)
if err != nil {
return nil, err
}
defer old.Close()
// apply the patch
var applied bytes.Buffer
if err = o.Patcher.Patch(old, &applied, patch); err != nil {
return nil, err
}
return applied.Bytes(), nil
}
func (o *Options) verifyChecksum(updated []byte) error {
checksum, err := checksumFor(o.Hash, updated)
if err != nil {
return err
}
if !bytes.Equal(o.Checksum, checksum) {
return fmt.Errorf("Updated file has wrong checksum. Expected: %x, got: %x", o.Checksum, checksum)
}
return nil
}
func (o *Options) verifySignature(updated []byte) error {
checksum, err := checksumFor(o.Hash, updated)
if err != nil {
return err
}
return o.Verifier.VerifySignature(checksum, o.Signature, o.Hash, o.PublicKey)
}
func checksumFor(h crypto.Hash, payload []byte) ([]byte, error) {
if !h.Available() {
return nil, errors.New("requested hash function not available")
}
hash := h.New()
hash.Write(payload) // guaranteed not to error
return hash.Sum([]byte{}), nil
}