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229 lines
9.1 KiB
Go
229 lines
9.1 KiB
Go
//go:build linux
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// Copyright (C) 2024 SUSE LLC. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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package securejoin
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import (
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"errors"
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"fmt"
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"io"
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"os"
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"path/filepath"
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"slices"
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"strings"
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"golang.org/x/sys/unix"
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)
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var (
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errInvalidMode = errors.New("invalid permission mode")
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errPossibleAttack = errors.New("possible attack detected")
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)
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// MkdirAllHandle is equivalent to MkdirAll, except that it is safer to use in
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// two respects:
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//
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// - The caller provides the root directory as an *os.File (preferably O_PATH)
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// handle. This means that the caller can be sure which root directory is
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// being used. Note that this can be emulated by using /proc/self/fd/... as
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// the root path with MkdirAll.
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//
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// - Once all of the directories have been created, an *os.File (O_PATH) handle
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// to the directory at unsafePath is returned to the caller. This is done in
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// an effectively-race-free way (an attacker would only be able to swap the
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// final directory component), which is not possible to emulate with
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// MkdirAll.
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//
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// In addition, the returned handle is obtained far more efficiently than doing
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// a brand new lookup of unsafePath (such as with SecureJoin or openat2) after
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// doing MkdirAll. If you intend to open the directory after creating it, you
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// should use MkdirAllHandle.
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func MkdirAllHandle(root *os.File, unsafePath string, mode int) (_ *os.File, Err error) {
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// Make sure there are no os.FileMode bits set.
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if mode&^0o7777 != 0 {
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return nil, fmt.Errorf("%w for mkdir 0o%.3o", errInvalidMode, mode)
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}
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// Try to open as much of the path as possible.
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currentDir, remainingPath, err := partialLookupInRoot(root, unsafePath)
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if err != nil {
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return nil, fmt.Errorf("find existing subpath of %q: %w", unsafePath, err)
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}
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defer func() {
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if Err != nil {
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_ = currentDir.Close()
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}
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}()
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// If there is an attacker deleting directories as we walk into them,
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// detect this proactively. Note this is guaranteed to detect if the
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// attacker deleted any part of the tree up to currentDir.
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//
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// Once we walk into a dead directory, partialLookupInRoot would not be
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// able to walk further down the tree (directories must be empty before
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// they are deleted), and if the attacker has removed the entire tree we
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// can be sure that anything that was originally inside a dead directory
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// must also be deleted and thus is a dead directory in its own right.
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//
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// This is mostly a quality-of-life check, because mkdir will simply fail
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// later if the attacker deletes the tree after this check.
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if err := isDeadInode(currentDir); err != nil {
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return nil, fmt.Errorf("finding existing subpath of %q: %w", unsafePath, err)
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}
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// Re-open the path to match the O_DIRECTORY reopen loop later (so that we
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// always return a non-O_PATH handle). We also check that we actually got a
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// directory.
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if reopenDir, err := Reopen(currentDir, unix.O_DIRECTORY|unix.O_CLOEXEC); errors.Is(err, unix.ENOTDIR) {
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return nil, fmt.Errorf("cannot create subdirectories in %q: %w", currentDir.Name(), unix.ENOTDIR)
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} else if err != nil {
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return nil, fmt.Errorf("re-opening handle to %q: %w", currentDir.Name(), err)
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} else {
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currentDir = reopenDir
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}
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remainingParts := strings.Split(remainingPath, string(filepath.Separator))
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if slices.Contains(remainingParts, "..") {
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// The path contained ".." components after the end of the "real"
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// components. We could try to safely resolve ".." here but that would
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// add a bunch of extra logic for something that it's not clear even
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// needs to be supported. So just return an error.
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//
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// If we do filepath.Clean(remainingPath) then we end up with the
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// problem that ".." can erase a trailing dangling symlink and produce
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// a path that doesn't quite match what the user asked for.
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return nil, fmt.Errorf("%w: yet-to-be-created path %q contains '..' components", unix.ENOENT, remainingPath)
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}
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// Make sure the mode doesn't have any type bits.
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mode &^= unix.S_IFMT
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// What properties do we expect any newly created directories to have?
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var (
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// While umask(2) is a per-thread property, and thus this value could
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// vary between threads, a functioning Go program would LockOSThread
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// threads with different umasks and so we don't need to LockOSThread
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// for this entire mkdirat loop (if we are in the locked thread with a
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// different umask, we are already locked and there's nothing for us to
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// do -- and if not then it doesn't matter which thread we run on and
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// there's nothing for us to do).
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expectedMode = uint32(unix.S_IFDIR | (mode &^ getUmask()))
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// We would want to get the fs[ug]id here, but we can't access those
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// from userspace. In practice, nobody uses setfs[ug]id() anymore, so
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// just use the effective [ug]id (which is equivalent to the fs[ug]id
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// for programs that don't use setfs[ug]id).
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expectedUid = uint32(unix.Geteuid())
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expectedGid = uint32(unix.Getegid())
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)
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// Create the remaining components.
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for _, part := range remainingParts {
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switch part {
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case "", ".":
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// Skip over no-op paths.
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continue
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}
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// NOTE: mkdir(2) will not follow trailing symlinks, so we can safely
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// create the finaly component without worrying about symlink-exchange
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// attacks.
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if err := unix.Mkdirat(int(currentDir.Fd()), part, uint32(mode)); err != nil {
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err = &os.PathError{Op: "mkdirat", Path: currentDir.Name() + "/" + part, Err: err}
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// Make the error a bit nicer if the directory is dead.
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if err2 := isDeadInode(currentDir); err2 != nil {
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err = fmt.Errorf("%w (%w)", err, err2)
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}
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return nil, err
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}
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// Get a handle to the next component. O_DIRECTORY means we don't need
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// to use O_PATH.
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var nextDir *os.File
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if hasOpenat2() {
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nextDir, err = openat2File(currentDir, part, &unix.OpenHow{
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Flags: unix.O_NOFOLLOW | unix.O_DIRECTORY | unix.O_CLOEXEC,
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Resolve: unix.RESOLVE_BENEATH | unix.RESOLVE_NO_SYMLINKS | unix.RESOLVE_NO_XDEV,
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})
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} else {
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nextDir, err = openatFile(currentDir, part, unix.O_NOFOLLOW|unix.O_DIRECTORY|unix.O_CLOEXEC, 0)
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}
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if err != nil {
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return nil, err
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}
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_ = currentDir.Close()
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currentDir = nextDir
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// Make sure that the directory matches what we expect. An attacker
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// could have swapped the directory between us making it and opening
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// it. There's no way for us to be sure that the directory is
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// _precisely_ the same as the directory we created, but if we are in
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// an empty directory with the same owner and mode as the one we
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// created then there is nothing the attacker could do with this new
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// directory that they couldn't do with the old one.
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if stat, err := fstat(currentDir); err != nil {
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return nil, fmt.Errorf("check newly created directory: %w", err)
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} else {
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if stat.Mode != expectedMode {
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return nil, fmt.Errorf("%w: newly created directory %q has incorrect mode 0o%.3o (expected 0o%.3o)", errPossibleAttack, currentDir.Name(), stat.Mode, expectedMode)
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}
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if stat.Uid != expectedUid || stat.Gid != expectedGid {
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return nil, fmt.Errorf("%w: newly created directory %q has incorrect owner %d:%d (expected %d:%d)", errPossibleAttack, currentDir.Name(), stat.Uid, stat.Gid, expectedUid, expectedGid)
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}
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// Check that the directory is empty. We only need to check for
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// a single entry, and we should get EOF if the directory is
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// empty.
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_, err := currentDir.Readdirnames(1)
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if !errors.Is(err, io.EOF) {
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if err == nil {
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err = fmt.Errorf("%w: newly created directory %q is non-empty", errPossibleAttack, currentDir.Name())
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}
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return nil, fmt.Errorf("check if newly created directory %q is empty: %w", currentDir.Name(), err)
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}
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// Reset the offset.
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_, _ = currentDir.Seek(0, unix.SEEK_SET)
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}
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}
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return currentDir, nil
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}
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// MkdirAll is a race-safe alternative to the Go stdlib's os.MkdirAll function,
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// where the new directory is guaranteed to be within the root directory (if an
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// attacker can move directories from inside the root to outside the root, the
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// created directory tree might be outside of the root but the key constraint
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// is that at no point will we walk outside of the directory tree we are
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// creating).
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//
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// Effectively, MkdirAll(root, unsafePath, mode) is equivalent to
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//
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// path, _ := securejoin.SecureJoin(root, unsafePath)
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// err := os.MkdirAll(path, mode)
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//
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// But is much safer. The above implementation is unsafe because if an attacker
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// can modify the filesystem tree between SecureJoin and MkdirAll, it is
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// possible for MkdirAll to resolve unsafe symlink components and create
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// directories outside of the root.
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//
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// If you plan to open the directory after you have created it or want to use
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// an open directory handle as the root, you should use MkdirAllHandle instead.
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// This function is a wrapper around MkdirAllHandle.
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//
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// NOTE: The mode argument must be set the unix mode bits (unix.S_I...), not
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// the Go generic mode bits (os.Mode...).
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func MkdirAll(root, unsafePath string, mode int) error {
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rootDir, err := os.OpenFile(root, unix.O_PATH|unix.O_DIRECTORY|unix.O_CLOEXEC, 0)
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if err != nil {
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return err
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}
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defer rootDir.Close()
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f, err := MkdirAllHandle(rootDir, unsafePath, mode)
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if err != nil {
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return err
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}
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_ = f.Close()
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return nil
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}
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