[PATCH v3 00/21] arm64: implement support for KASLR

Kees Cook keescook at chromium.org
Mon Jan 11 14:07:47 PST 2016


On Mon, Jan 11, 2016 at 5:18 AM, Ard Biesheuvel
<ard.biesheuvel at linaro.org> wrote:
> This series implements KASLR for arm64, by building the kernel as a PIE
> executable that can relocate itself at runtime, and moving it to a random
> offset in the vmalloc area. v2 and up also implement physical randomization,
> i.e., it allows the kernel to deal with being loaded at any physical offset
> (modulo the required alignment), and invokes the EFI_RNG_PROTOCOL from the
> UEFI stub to obtain random bits and perform the actual randomization of the
> physical load address.

I will continue cheering! :)

> Changes since v2:
> - Incorporated feedback from Marc Zyngier into the KVM patch (#5)
> - Dropped the pgdir section and the patch that memblock_reserve()'s the kernel
>   sections at a smaller granularity. This is no longer necessary with the pgdir
>   section gone. This also fixes an issue spotted by James Morse where the fixmap
>   page tables are not zeroed correctly; these have been moved back to the .bss
>   section.
> - Got rid of all ifdef'ery regarding the number of translation levels in the
>   changed .c files, by introducing new definitions in pgtable.h (#3, #6)
> - Fixed KAsan support, which was broken by all earlier versions.
> - Moved module region along with the virtually randomized kernel, so that module
>   addresses become unpredictable as well, and we only have to rely on veneers in
>   the PLTs when the module region is exhausted (which is somewhat more likely
>   since the module region is now shared with other uses of the vmalloc area)

Just to make sure I understand: this means that the offset between
kernel and modules remains static? It may still be useful to bump
modules as well, just so that leaking a module address doesn't
compromise the base kernel image address too. Don't block the series
for this, though. It's a minor nit. :)

-Kees

> - Added support for the 'nokaslr' command line option. This affects the
>   randomization performed by the stub, and results in a warning if passed while
>   the bootloader also presented a random seed for virtual KASLR in register x1.
> - The .text/.rodata sections of the kernel are no longer aliased in the linear
>   region with a writable mapping.
> - Added a separate image header flag for kernel images that may be loaded at any
>   2 MB aligned offset (+ TEXT_OFFSET)
> - The KASLR displacement is now corrected if it results in the kernel image
>   intersecting a PUD/PMD boundary (4k and 16k/64k granule kernels, respectively)
> - Split out UEFI stub random routines into separate patches.
> - Implemented a weight based EFI random allocation routine so that each suitable
>   offset in available memory is equally likely to be selected (as suggested by
>   Kees Cook)
> - Reused CONFIG_RELOCATABLE and CONFIG_RANDOMIZE_BASE instead of introducing
>   new Kconfig symbols to describe the same functionality.
> - Reimplemented mem= logic so memory is clipped from the top first.
>
> Changes since v1/RFC:
> - This series now implements fully independent virtual and physical address
>   randomization at load time. I have recycled some patches from this series:
>   http://thread.gmane.org/gmane.linux.ports.arm.kernel/455151, and updated the
>   final UEFI stub patch to randomize the physical address as well.
> - Added a patch to deal with the way KVM on arm64 makes assumptions about the
>   relation between kernel symbols and the linear mapping (on which the HYP
>   mapping is based), as these assumptions cease to be valid once we move the
>   kernel Image out of the linear mapping.
> - Updated the module PLT patch so it works on BE kernels as well.
> - Moved the constant Image header values to head.S, and updated the linker
>   script to provide the kernel size using R_AARCH64_ABS32 relocation rather
>   than a R_AARCH64_ABS64 relocation, since those are always resolved at build
>   time. This allows me to get rid of the post-build perl script to swab header
>   values on BE kernels.
> - Minor style tweaks.
>
> Notes:
> - These patches apply on top of Mark Rutland's pagetable rework series:
>   http://thread.gmane.org/gmane.linux.ports.arm.kernel/462438
> - The arm64 Image is uncompressed by default, and the Elf64_Rela format uses
>   24 bytes per relocation entry. This results in considerable bloat (i.e., a
>   couple of MBs worth of relocation data in an .init section). However, no
>   build time postprocessing is required, we rely fully on the toolchain to
>   produce the image
> - We have to rely on the bootloader to supply some randomness in register x1
>   upon kernel entry. Since we have no decompressor, it is simply not feasible
>   to collect randomness in the head.S code path before mapping the kernel and
>   enabling the MMU.
> - The EFI_RNG_PROTOCOL that is invoked in patch #13 to supply randomness on
>   UEFI systems is not universally available. A QEMU/KVM firmware image that
>   implements a pseudo-random version is available here:
>   http://people.linaro.org/~ard.biesheuvel/QEMU_EFI.fd.aarch64-rng.bz2
>   (requires access to PMCCNTR_EL0 and support for AES instructions)
>   See below for instructions how to run the pseudo-random version on real
>   hardware.
> - Only mildly tested. Help appreciated.
>
> Code can be found here:
> git://git.linaro.org/people/ard.biesheuvel/linux-arm.git arm64-kaslr-v3
> https://git.linaro.org/people/ard.biesheuvel/linux-arm.git/shortlog/refs/heads/arm64-kaslr-v3
>
> Patch #1 updates the OF code to allow the minimum memblock physical address to
> be overridden by the arch.
>
> Patch #2 introduces KIMAGE_VADDR as the base of the kernel virtual region.
>
> Patch #3 introduces dummy pud_index() and pmd_index() macros that are intended
> to be optimized away if the configured number of translation levels does not
> actually use them.
>
> Patch #4 rewrites early_fixmap_init() so it does not rely on the linear mapping
> (i.e., the use of phys_to_virt() is avoided)
>
> Patch #5 updates KVM on arm64 so it can deal with kernel symbols whose addresses
> are not covered by the linear mapping.
>
> Patch #6 introduces pte_offset_kimg(), pmd_offset_kimg() and pud_offset_kimg()
> that allow statically allocated page tables (i.e., by fixmap and kasan) to be
> traversed before the linear mapping is installed.
>
> Patch #7 moves the kernel virtual mapping to the vmalloc area, along with the
> module region which is kept right below it, as before.
>
> Patch #8 adds support for PLTs in modules so that relative branches can be
> resolved via a PLT if the target is out of range. This is required for KASLR,
> since modules may be loaded far away from the core kernel.
>
> Patch #9 and #10 move arm64 to the a new generic relative version of the extable
> implementation so that it no longer contains absolute addresses that require
> fixing up at relocation time, but uses relative offsets instead.
>
> Patch #11 reverts some changes to the Image header population code so we no
> longer depend on the linker to populate the header fields. This is necessary
> since the R_AARCH64_ABS64 relocations that are emitted for these fields are not
> resolved at build time for PIE executables.
>
> Patch #12 updates the code in head.S that needs to execute before relocation to
> avoid the use of values that are subject to dynamic relocation. These values
> will not be populated in PIE executables.
>
> Patch #13 allows the kernel Image to be loaded anywhere in physical memory, by
> decoupling PHYS_OFFSET from the base of the kernel image.
>
> Patch #14 redefines SWAPPER_TABLE_SHIFT in a way that allows it to be used from
> assembler code regardless of the number of configured translation levels.
>
> Patch #15 (from Mark Rutland) moves the ELF relocation type #defines to a
> separate file so we can use it from head.S later
>
> Patch #16 updates scripts/sortextable.c so it accepts ET_DYN (relocatable)
> executables as well as ET_EXEC (static) executables.
>
> Patch #17 implements the core KASLR, by taking randomness supplied in register
> x1 and using it to move the kernel inside the vmalloc area.
>
> Patch #18 implements efi_get_random_bytes() based on the EFI_RNG_PROTOCOL
>
> Patch #19 implements efi_random_alloc()
>
> Patch #20 moves the allocation for the converted command line (UTF-16 to ASCII)
> away from the base of memory. This is necessary since for parsing
>
> Patch #21 implements the actual KASLR, by randomizing the kernel physical
> address, and passing entropy in x1 so that the kernel proper can relocate itself
> virtually.
>
> Ard Biesheuvel (20):
>   of/fdt: make memblock minimum physical address arch configurable
>   arm64: introduce KIMAGE_VADDR as the virtual base of the kernel region
>   arm64: pgtable: add dummy pud_index() and pmd_index() definitions
>   arm64: decouple early fixmap init from linear mapping
>   arm64: kvm: deal with kernel symbols outside of linear mapping
>   arm64: pgtable: implement static [pte|pmd|pud]_offset variants
>   arm64: move kernel image to base of vmalloc area
>   arm64: add support for module PLTs
>   extable: add support for relative extables to search and sort routines
>   arm64: switch to relative exception tables
>   arm64: avoid R_AARCH64_ABS64 relocations for Image header fields
>   arm64: avoid dynamic relocations in early boot code
>   arm64: allow kernel Image to be loaded anywhere in physical memory
>   arm64: redefine SWAPPER_TABLE_SHIFT for use in asm code
>   scripts/sortextable: add support for ET_DYN binaries
>   arm64: add support for a relocatable kernel and KASLR
>   efi: stub: implement efi_get_random_bytes() based on EFI_RNG_PROTOCOL
>   efi: stub: add implementation of efi_random_alloc()
>   efi: stub: use high allocation for converted command line
>   arm64: efi: invoke EFI_RNG_PROTOCOL to supply KASLR randomness
>
> Mark Rutland (1):
>   arm64: split elf relocs into a separate header.
>
>  Documentation/arm64/booting.txt                |  34 ++++-
>  arch/arm/include/asm/kvm_asm.h                 |   2 +
>  arch/arm/include/asm/kvm_mmu.h                 |   2 +
>  arch/arm/kvm/arm.c                             |   5 +-
>  arch/arm/kvm/mmu.c                             |   8 +-
>  arch/arm64/Kconfig                             |  40 +++++
>  arch/arm64/Makefile                            |  10 +-
>  arch/arm64/include/asm/assembler.h             |  30 +++-
>  arch/arm64/include/asm/boot.h                  |   6 +
>  arch/arm64/include/asm/elf.h                   |  54 +------
>  arch/arm64/include/asm/elf_relocs.h            |  75 ++++++++++
>  arch/arm64/include/asm/futex.h                 |  12 +-
>  arch/arm64/include/asm/kasan.h                 |  20 +--
>  arch/arm64/include/asm/kernel-pgtable.h        |  20 ++-
>  arch/arm64/include/asm/kvm_asm.h               |  19 ++-
>  arch/arm64/include/asm/kvm_host.h              |   8 +-
>  arch/arm64/include/asm/kvm_mmu.h               |   2 +
>  arch/arm64/include/asm/memory.h                |  38 +++--
>  arch/arm64/include/asm/module.h                |  11 ++
>  arch/arm64/include/asm/pgtable.h               |  22 ++-
>  arch/arm64/include/asm/uaccess.h               |  30 ++--
>  arch/arm64/include/asm/virt.h                  |   4 -
>  arch/arm64/include/asm/word-at-a-time.h        |   7 +-
>  arch/arm64/kernel/Makefile                     |   1 +
>  arch/arm64/kernel/armv8_deprecated.c           |   7 +-
>  arch/arm64/kernel/efi-entry.S                  |   9 +-
>  arch/arm64/kernel/head.S                       | 155 +++++++++++++++++---
>  arch/arm64/kernel/image.h                      |  37 ++---
>  arch/arm64/kernel/module-plts.c                | 137 +++++++++++++++++
>  arch/arm64/kernel/module.c                     |  15 +-
>  arch/arm64/kernel/module.lds                   |   4 +
>  arch/arm64/kernel/setup.c                      |  44 +++++-
>  arch/arm64/kernel/vmlinux.lds.S                |  13 +-
>  arch/arm64/kvm/debug.c                         |   1 +
>  arch/arm64/kvm/hyp.S                           |   6 +-
>  arch/arm64/mm/dump.c                           |  12 +-
>  arch/arm64/mm/extable.c                        |   2 +-
>  arch/arm64/mm/init.c                           |  91 ++++++++++--
>  arch/arm64/mm/kasan_init.c                     |  21 ++-
>  arch/arm64/mm/mmu.c                            |  95 +++++++-----
>  arch/x86/include/asm/efi.h                     |   2 +
>  drivers/firmware/efi/libstub/Makefile          |   2 +-
>  drivers/firmware/efi/libstub/arm-stub.c        |  17 ++-
>  drivers/firmware/efi/libstub/arm64-stub.c      |  67 +++++++--
>  drivers/firmware/efi/libstub/efi-stub-helper.c |  24 ++-
>  drivers/firmware/efi/libstub/efistub.h         |   9 ++
>  drivers/firmware/efi/libstub/random.c          | 120 +++++++++++++++
>  drivers/of/fdt.c                               |   5 +-
>  include/linux/efi.h                            |   5 +-
>  lib/extable.c                                  |  50 +++++--
>  scripts/sortextable.c                          |  10 +-
>  51 files changed, 1111 insertions(+), 309 deletions(-)
>  create mode 100644 arch/arm64/include/asm/elf_relocs.h
>  create mode 100644 arch/arm64/kernel/module-plts.c
>  create mode 100644 arch/arm64/kernel/module.lds
>  create mode 100644 drivers/firmware/efi/libstub/random.c
>
> EFI_RNG_PROTOCOL on real hardware
> =================================
>
> To test whether your UEFI implements the EFI_RNG_PROTOCOL, download the
> following executable and run it from the UEFI Shell:
> http://people.linaro.org/~ard.biesheuvel/RngTest.efi
>
> FS0:\> rngtest
> UEFI RNG Protocol Testing :
> ----------------------------
>  -- Locate UEFI RNG Protocol : [Fail - Status = Not Found]
>
> If your UEFI does not implement the EFI_RNG_PROTOCOL, you can download and
> install the pseudo-random version that uses the generic timer and PMCCNTR_EL0
> values and permutes them using a couple of rounds of AES.
> http://people.linaro.org/~ard.biesheuvel/RngDxe.efi
>
> NOTE: not for production!! This is a quick and dirty hack to test the KASLR
> code, and is not suitable for anything else.
>
> FS0:\> rngdxe
> FS0:\> rngtest
> UEFI RNG Protocol Testing :
> ----------------------------
>  -- Locate UEFI RNG Protocol : [Pass]
>  -- Call RNG->GetInfo() interface :
>      >> Supported RNG Algorithm (Count = 2) :
>           0) 44F0DE6E-4D8C-4045-A8C7-4DD168856B9E
>           1) E43176D7-B6E8-4827-B784-7FFDC4B68561
>  -- Call RNG->GetRNG() interface :
>      >> RNG with default algorithm : [Pass]
>      >> RNG with SP800-90-HMAC-256 : [Fail - Status = Unsupported]
>      >> RNG with SP800-90-Hash-256 : [Fail - Status = Unsupported]
>      >> RNG with SP800-90-CTR-256 : [Pass]
>      >> RNG with X9.31-3DES : [Fail - Status = Unsupported]
>      >> RNG with X9.31-AES : [Fail - Status = Unsupported]
>      >> RNG with RAW Entropy : [Pass]
>  -- Random Number Generation Test with default RNG Algorithm (20 Rounds):
>           01) - 27
>           02) - 61E8
>           03) - 496FD8
>           04) - DDD793BF
>           05) - B6C37C8E23
>           06) - 4D183C604A96
>           07) - 9363311DB61298
>           08) - 5715A7294F4E436E
>           09) - F0D4D7BAA0DD52318E
>           10) - C88C6EBCF4C0474D87C3
>           11) - B5594602B482A643932172
>           12) - CA7573F704B2089B726B9CF1
>           13) - A93E9451CB533DCFBA87B97C33
>           14) - 45AA7B83DB6044F7BBAB031F0D24
>           15) - 3DD7A4D61F34ADCB400B5976730DCF
>           16) - 4DD168D21FAB8F59708330D6A9BEB021
>           17) - 4BBB225E61C465F174254159467E65939F
>           18) - 030A156C9616337A20070941E702827DA8E1
>           19) - AB0FC11C9A4E225011382A9D164D9D55CA2B64
>           20) - 72B9B4735DC445E5DA6AF88DE965B7E87CB9A23C



-- 
Kees Cook
Chrome OS & Brillo Security



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