Files
runc/vendor/cyphar.com/go-pathrs/internal/libpathrs/libpathrs_linux.go
T
Aleksa Sarai b58e342758 deps: update to cyphar.com/go-pathrs@v0.2.4
This includes a few fixes for 32-bit builds.

Signed-off-by: Aleksa Sarai <cyphar@cyphar.com>
2026-03-12 17:58:10 +09:00

338 lines
11 KiB
Go

//go:build linux
// SPDX-License-Identifier: MPL-2.0
/*
* libpathrs: safe path resolution on Linux
* Copyright (C) 2019-2025 SUSE LLC
* Copyright (C) 2026 Aleksa Sarai <cyphar@cyphar.com>
*
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at https://mozilla.org/MPL/2.0/.
*/
// Package libpathrs is an internal thin wrapper around the libpathrs C API.
package libpathrs
import (
"fmt"
"syscall"
"unsafe"
)
/*
// TODO: Figure out if we need to add support for linking against libpathrs
// statically even if in dynamically linked builds in order to make
// packaging a bit easier (using "-Wl,-Bstatic -lpathrs -Wl,-Bdynamic" or
// "-l:pathrs.a").
#cgo pkg-config: pathrs
#include <pathrs.h>
// This is a workaround for unsafe.Pointer() not working for non-void pointers.
char *cast_ptr(void *ptr) { return ptr; }
*/
import "C"
func fetchError(errID C.int) error {
if errID >= C.__PATHRS_MAX_ERR_VALUE {
return nil
}
cErr := C.pathrs_errorinfo(errID)
defer C.pathrs_errorinfo_free(cErr)
var err error
if cErr != nil {
err = &Error{
errno: syscall.Errno(cErr.saved_errno),
description: C.GoString(cErr.description),
}
}
return err
}
// OpenRoot wraps pathrs_open_root.
func OpenRoot(path string) (uintptr, error) {
cPath := C.CString(path)
defer C.free(unsafe.Pointer(cPath))
fd := C.pathrs_open_root(cPath)
return uintptr(fd), fetchError(fd)
}
// Reopen wraps pathrs_reopen.
func Reopen(fd uintptr, flags int) (uintptr, error) {
newFd := C.pathrs_reopen(C.int(fd), C.int(flags))
return uintptr(newFd), fetchError(newFd)
}
// InRootResolve wraps pathrs_inroot_resolve.
func InRootResolve(rootFd uintptr, path string) (uintptr, error) {
cPath := C.CString(path)
defer C.free(unsafe.Pointer(cPath))
fd := C.pathrs_inroot_resolve(C.int(rootFd), cPath)
return uintptr(fd), fetchError(fd)
}
// InRootResolveNoFollow wraps pathrs_inroot_resolve_nofollow.
func InRootResolveNoFollow(rootFd uintptr, path string) (uintptr, error) {
cPath := C.CString(path)
defer C.free(unsafe.Pointer(cPath))
fd := C.pathrs_inroot_resolve_nofollow(C.int(rootFd), cPath)
return uintptr(fd), fetchError(fd)
}
// InRootOpen wraps pathrs_inroot_open.
func InRootOpen(rootFd uintptr, path string, flags int) (uintptr, error) {
cPath := C.CString(path)
defer C.free(unsafe.Pointer(cPath))
fd := C.pathrs_inroot_open(C.int(rootFd), cPath, C.int(flags))
return uintptr(fd), fetchError(fd)
}
// InRootReadlink wraps pathrs_inroot_readlink.
func InRootReadlink(rootFd uintptr, path string) (string, error) {
cPath := C.CString(path)
defer C.free(unsafe.Pointer(cPath))
size := 128
for {
linkBuf := make([]byte, size)
n := C.pathrs_inroot_readlink(C.int(rootFd), cPath, C.cast_ptr(unsafe.Pointer(&linkBuf[0])), C.size_t(len(linkBuf)))
switch {
case int(n) < C.__PATHRS_MAX_ERR_VALUE:
return "", fetchError(n)
case int(n) <= len(linkBuf):
return string(linkBuf[:int(n)]), nil
default:
// The contents were truncated. Unlike readlinkat, pathrs returns
// the size of the link when it checked. So use the returned size
// as a basis for the reallocated size (but in order to avoid a DoS
// where a magic-link is growing by a single byte each iteration,
// make sure we are a fair bit larger).
size += int(n)
}
}
}
// InRootRmdir wraps pathrs_inroot_rmdir.
func InRootRmdir(rootFd uintptr, path string) error {
cPath := C.CString(path)
defer C.free(unsafe.Pointer(cPath))
err := C.pathrs_inroot_rmdir(C.int(rootFd), cPath)
return fetchError(err)
}
// InRootUnlink wraps pathrs_inroot_unlink.
func InRootUnlink(rootFd uintptr, path string) error {
cPath := C.CString(path)
defer C.free(unsafe.Pointer(cPath))
err := C.pathrs_inroot_unlink(C.int(rootFd), cPath)
return fetchError(err)
}
// InRootRemoveAll wraps pathrs_inroot_remove_all.
func InRootRemoveAll(rootFd uintptr, path string) error {
cPath := C.CString(path)
defer C.free(unsafe.Pointer(cPath))
err := C.pathrs_inroot_remove_all(C.int(rootFd), cPath)
return fetchError(err)
}
// InRootCreat wraps pathrs_inroot_creat.
func InRootCreat(rootFd uintptr, path string, flags int, mode uint32) (uintptr, error) {
cPath := C.CString(path)
defer C.free(unsafe.Pointer(cPath))
fd := C.pathrs_inroot_creat(C.int(rootFd), cPath, C.int(flags), C.uint(mode))
return uintptr(fd), fetchError(fd)
}
// InRootRename wraps pathrs_inroot_rename.
func InRootRename(rootFd uintptr, src, dst string, flags uint) error {
cSrc := C.CString(src)
defer C.free(unsafe.Pointer(cSrc))
cDst := C.CString(dst)
defer C.free(unsafe.Pointer(cDst))
err := C.pathrs_inroot_rename(C.int(rootFd), cSrc, cDst, C.uint(flags))
return fetchError(err)
}
// InRootMkdir wraps pathrs_inroot_mkdir.
func InRootMkdir(rootFd uintptr, path string, mode uint32) error {
cPath := C.CString(path)
defer C.free(unsafe.Pointer(cPath))
err := C.pathrs_inroot_mkdir(C.int(rootFd), cPath, C.uint(mode))
return fetchError(err)
}
// InRootMkdirAll wraps pathrs_inroot_mkdir_all.
func InRootMkdirAll(rootFd uintptr, path string, mode uint32) (uintptr, error) {
cPath := C.CString(path)
defer C.free(unsafe.Pointer(cPath))
fd := C.pathrs_inroot_mkdir_all(C.int(rootFd), cPath, C.uint(mode))
return uintptr(fd), fetchError(fd)
}
// InRootMknod wraps pathrs_inroot_mknod.
func InRootMknod(rootFd uintptr, path string, mode uint32, dev uint64) error {
cPath := C.CString(path)
defer C.free(unsafe.Pointer(cPath))
err := C.pathrs_inroot_mknod(C.int(rootFd), cPath, C.uint(mode), C.dev_t(dev))
return fetchError(err)
}
// InRootSymlink wraps pathrs_inroot_symlink.
func InRootSymlink(rootFd uintptr, path, target string) error {
cPath := C.CString(path)
defer C.free(unsafe.Pointer(cPath))
cTarget := C.CString(target)
defer C.free(unsafe.Pointer(cTarget))
err := C.pathrs_inroot_symlink(C.int(rootFd), cPath, cTarget)
return fetchError(err)
}
// InRootHardlink wraps pathrs_inroot_hardlink.
func InRootHardlink(rootFd uintptr, path, target string) error {
cPath := C.CString(path)
defer C.free(unsafe.Pointer(cPath))
cTarget := C.CString(target)
defer C.free(unsafe.Pointer(cTarget))
err := C.pathrs_inroot_hardlink(C.int(rootFd), cPath, cTarget)
return fetchError(err)
}
// ProcBase is pathrs_proc_base_t (uint64_t).
type ProcBase C.pathrs_proc_base_t
// FIXME: We need to open-code the constants because CGo unfortunately will
// implicitly convert any non-literal constants (i.e. those resolved using gcc)
// to signed integers. See <https://github.com/golang/go/issues/39136> for some
// more information on the underlying issue (though.
const (
// ProcRoot is PATHRS_PROC_ROOT.
ProcRoot ProcBase = 0xFFFF_FFFE_7072_6F63 // C.PATHRS_PROC_ROOT
// ProcSelf is PATHRS_PROC_SELF.
ProcSelf ProcBase = 0xFFFF_FFFE_091D_5E1F // C.PATHRS_PROC_SELF
// ProcThreadSelf is PATHRS_PROC_THREAD_SELF.
ProcThreadSelf ProcBase = 0xFFFF_FFFE_3EAD_5E1F // C.PATHRS_PROC_THREAD_SELF
// ProcBaseTypeMask is __PATHRS_PROC_TYPE_MASK.
ProcBaseTypeMask ProcBase = 0xFFFF_FFFF_0000_0000 // C.__PATHRS_PROC_TYPE_MASK
// ProcBaseTypePid is __PATHRS_PROC_TYPE_PID.
ProcBaseTypePid ProcBase = 0x8000_0000_0000_0000 // C.__PATHRS_PROC_TYPE_PID
// ProcDefaultRootFd is PATHRS_PROC_DEFAULT_ROOTFD.
ProcDefaultRootFd = -int(syscall.EBADF) // C.PATHRS_PROC_DEFAULT_ROOTFD
)
func assertEqual[T comparable](a, b T, msg string) {
if a != b {
panic(fmt.Sprintf("%s ((%T) %#v != (%T) %#v)", msg, a, a, b, b))
}
}
// Verify that the values above match the actual C values. Unfortunately, Go
// only allows us to forcefully cast int64 to uint64 if you use a temporary
// variable, which means we cannot do it in a const context and thus need to do
// it at runtime (even though it is a check that fundamentally could be done at
// compile-time)...
func init() {
var (
actualProcRoot int64 = C.PATHRS_PROC_ROOT
actualProcSelf int64 = C.PATHRS_PROC_SELF
actualProcThreadSelf int64 = C.PATHRS_PROC_THREAD_SELF
)
assertEqual(ProcRoot, ProcBase(actualProcRoot), "PATHRS_PROC_ROOT")
assertEqual(ProcSelf, ProcBase(actualProcSelf), "PATHRS_PROC_SELF")
assertEqual(ProcThreadSelf, ProcBase(actualProcThreadSelf), "PATHRS_PROC_THREAD_SELF")
var (
actualProcBaseTypeMask uint64 = C.__PATHRS_PROC_TYPE_MASK
actualProcBaseTypePid uint64 = C.__PATHRS_PROC_TYPE_PID
)
assertEqual(ProcBaseTypeMask, ProcBase(actualProcBaseTypeMask), "__PATHRS_PROC_TYPE_MASK")
assertEqual(ProcBaseTypePid, ProcBase(actualProcBaseTypePid), "__PATHRS_PROC_TYPE_PID")
assertEqual(ProcDefaultRootFd, int(C.PATHRS_PROC_DEFAULT_ROOTFD), "PATHRS_PROC_DEFAULT_ROOTFD")
}
// ProcPid reimplements the PROC_PID(x) conversion.
func ProcPid(pid uint32) ProcBase { return ProcBaseTypePid | ProcBase(pid) }
// ProcOpenat wraps pathrs_proc_openat.
func ProcOpenat(procRootFd int, base ProcBase, path string, flags int) (uintptr, error) {
cBase := C.pathrs_proc_base_t(base)
cPath := C.CString(path)
defer C.free(unsafe.Pointer(cPath))
fd := C.pathrs_proc_openat(C.int(procRootFd), cBase, cPath, C.int(flags))
return uintptr(fd), fetchError(fd)
}
// ProcReadlinkat wraps pathrs_proc_readlinkat.
func ProcReadlinkat(procRootFd int, base ProcBase, path string) (string, error) {
// TODO: See if we can unify this code with InRootReadlink.
cBase := C.pathrs_proc_base_t(base)
cPath := C.CString(path)
defer C.free(unsafe.Pointer(cPath))
size := 128
for {
linkBuf := make([]byte, size)
n := C.pathrs_proc_readlinkat(
C.int(procRootFd), cBase, cPath,
C.cast_ptr(unsafe.Pointer(&linkBuf[0])), C.size_t(len(linkBuf)))
switch {
case int(n) < C.__PATHRS_MAX_ERR_VALUE:
return "", fetchError(n)
case int(n) <= len(linkBuf):
return string(linkBuf[:int(n)]), nil
default:
// The contents were truncated. Unlike readlinkat, pathrs returns
// the size of the link when it checked. So use the returned size
// as a basis for the reallocated size (but in order to avoid a DoS
// where a magic-link is growing by a single byte each iteration,
// make sure we are a fair bit larger).
size += int(n)
}
}
}
// ProcfsOpenHow is pathrs_procfs_open_how (struct).
type ProcfsOpenHow C.pathrs_procfs_open_how
const (
// ProcfsNewUnmasked is PATHRS_PROCFS_NEW_UNMASKED.
ProcfsNewUnmasked = C.PATHRS_PROCFS_NEW_UNMASKED
)
// Flags returns a pointer to the internal flags field to allow other packages
// to modify structure fields that are internal due to Go's visibility model.
func (how *ProcfsOpenHow) Flags() *C.uint64_t { return &how.flags }
// ProcfsOpen is pathrs_procfs_open (sizeof(*how) is passed automatically).
func ProcfsOpen(how *ProcfsOpenHow) (uintptr, error) {
fd := C.pathrs_procfs_open((*C.pathrs_procfs_open_how)(how), C.size_t(unsafe.Sizeof(*how)))
return uintptr(fd), fetchError(fd)
}