Commit Graph

17 Commits

Author SHA1 Message Date
Peter Collingbourne c336557f02 hwasan: Compatibility fixes for short granules.
We can't use short granules with stack instrumentation when targeting older
API levels because the rest of the system won't understand the short granule
tags stored in shadow memory.

Moreover, we need to be able to let old binaries (which won't understand
short granule tags) run on a new system that supports short granule
tags. Such binaries will call the __hwasan_tag_mismatch function when their
outlined checks fail. We can compensate for the binary's lack of support
for short granules by implementing the short granule part of the check in
the __hwasan_tag_mismatch function. Unfortunately we can't do anything about
inline checks, but I don't believe that we can generate these by default on
aarch64, nor did we do so when the ABI was fixed.

A new function, __hwasan_tag_mismatch_v2, is introduced that lets code
targeting the new runtime avoid redoing the short granule check. Because tag
mismatches are rare this isn't important from a performance perspective; the
main benefit is that it introduces a symbol dependency that prevents binaries
targeting the new runtime from running on older (i.e. incompatible) runtimes.

Differential Revision: https://reviews.llvm.org/D68059

llvm-svn: 373035
2019-09-27 01:02:10 +00:00
Peter Collingbourne 3b82b92c6b hwasan: Initialize the pass only once.
This will let us instrument globals during initialization. This required
making the new PM pass a module pass, which should still provide access to
analyses via the ModuleAnalysisManager.

Differential Revision: https://reviews.llvm.org/D64843

llvm-svn: 366379
2019-07-17 21:45:19 +00:00
Peter Collingbourne 1366262b74 hwasan: Improve precision of checks using short granule tags.
A short granule is a granule of size between 1 and `TG-1` bytes. The size
of a short granule is stored at the location in shadow memory where the
granule's tag is normally stored, while the granule's actual tag is stored
in the last byte of the granule. This means that in order to verify that a
pointer tag matches a memory tag, HWASAN must check for two possibilities:

* the pointer tag is equal to the memory tag in shadow memory, or
* the shadow memory tag is actually a short granule size, the value being loaded
  is in bounds of the granule and the pointer tag is equal to the last byte of
  the granule.

Pointer tags between 1 to `TG-1` are possible and are as likely as any other
tag. This means that these tags in memory have two interpretations: the full
tag interpretation (where the pointer tag is between 1 and `TG-1` and the
last byte of the granule is ordinary data) and the short tag interpretation
(where the pointer tag is stored in the granule).

When HWASAN detects an error near a memory tag between 1 and `TG-1`, it
will show both the memory tag and the last byte of the granule. Currently,
it is up to the user to disambiguate the two possibilities.

Because this functionality obsoletes the right aligned heap feature of
the HWASAN memory allocator (and because we can no longer easily test
it), the feature is removed.

Also update the documentation to cover both short granule tags and
outlined checks.

Differential Revision: https://reviews.llvm.org/D63908

llvm-svn: 365551
2019-07-09 20:22:36 +00:00
Peter Collingbourne 7108df964a hwasan: Remove the old frame descriptor mechanism.
Differential Revision: https://reviews.llvm.org/D63470

llvm-svn: 364665
2019-06-28 17:53:26 +00:00
Leonard Chan 0cdd3b1d81 [NewPM] Port HWASan and Kernel HWASan
Port hardware assisted address sanitizer to new PM following the same guidelines as msan and tsan.

Changes:
- Separate HWAddressSanitizer into a pass class and a sanitizer class.
- Create new PM wrapper pass for the sanitizer class.
- Use the getOrINsert pattern for some module level initialization declarations.
- Also enable kernel-kwasan in new PM
- Update llvm tests and add clang test.

Differential Revision: https://reviews.llvm.org/D61709

llvm-svn: 360707
2019-05-14 21:17:21 +00:00
Peter Collingbourne 73078ecd38 hwasan: Move memory access checks into small outlined functions on aarch64.
Each hwasan check requires emitting a small piece of code like this:
https://clang.llvm.org/docs/HardwareAssistedAddressSanitizerDesign.html#memory-accesses

The problem with this is that these code blocks typically bloat code
size significantly.

An obvious solution is to outline these blocks of code. In fact, this
has already been implemented under the -hwasan-instrument-with-calls
flag. However, as currently implemented this has a number of problems:
- The functions use the same calling convention as regular C functions.
  This means that the backend must spill all temporary registers as
  required by the platform's C calling convention, even though the
  check only needs two registers on the hot path.
- The functions take the address to be checked in a fixed register,
  which increases register pressure.
Both of these factors can diminish the code size effect and increase
the performance hit of -hwasan-instrument-with-calls.

The solution that this patch implements is to involve the aarch64
backend in outlining the checks. An intrinsic and pseudo-instruction
are created to represent a hwasan check. The pseudo-instruction
is register allocated like any other instruction, and we allow the
register allocator to select almost any register for the address to
check. A particular combination of (register selection, type of check)
triggers the creation in the backend of a function to handle the check
for specifically that pair. The resulting functions are deduplicated by
the linker. The pseudo-instruction (really the function) is specified
to preserve all registers except for the registers that the AAPCS
specifies may be clobbered by a call.

To measure the code size and performance effect of this change, I
took a number of measurements using Chromium for Android on aarch64,
comparing a browser with inlined checks (the baseline) against a
browser with outlined checks.

Code size: Size of .text decreases from 243897420 to 171619972 bytes,
or a 30% decrease.

Performance: Using Chromium's blink_perf.layout microbenchmarks I
measured a median performance regression of 6.24%.

The fact that a perf/size tradeoff is evident here suggests that
we might want to make the new behaviour conditional on -Os/-Oz.
But for now I've enabled it unconditionally, my reasoning being that
hwasan users typically expect a relatively large perf hit, and ~6%
isn't really adding much. We may want to revisit this decision in
the future, though.

I also tried experimenting with varying the number of registers
selectable by the hwasan check pseudo-instruction (which would result
in fewer variants being created), on the hypothesis that creating
fewer variants of the function would expose another perf/size tradeoff
by reducing icache pressure from the check functions at the cost of
register pressure. Although I did observe a code size increase with
fewer registers, I did not observe a strong correlation between the
number of registers and the performance of the resulting browser on the
microbenchmarks, so I conclude that we might as well use ~all registers
to get the maximum code size improvement. My results are below:

Regs | .text size | Perf hit
-----+------------+---------
~all | 171619972  | 6.24%
  16 | 171765192  | 7.03%
   8 | 172917788  | 5.82%
   4 | 177054016  | 6.89%

Differential Revision: https://reviews.llvm.org/D56954

llvm-svn: 351920
2019-01-23 02:20:10 +00:00
Peter Collingbourne d3a3e4b46d hwasan: Move ctor into a comdat.
Differential Revision: https://reviews.llvm.org/D55733

llvm-svn: 349413
2018-12-17 22:56:34 +00:00
Kostya Serebryany af95597c3c [hwasan] add stack frame descriptions.
Summary:
At compile-time, create an array of {PC,HumanReadableStackFrameDescription}
for every function that has an instrumented frame, and pass this array
to the run-time at the module-init time.
Similar to how we handle pc-table in SanitizerCoverage.
The run-time is dummy, will add the actual logic in later commits.

Reviewers: morehouse, eugenis

Reviewed By: eugenis

Subscribers: srhines, llvm-commits, kubamracek

Differential Revision: https://reviews.llvm.org/D53227

llvm-svn: 344985
2018-10-23 00:50:40 +00:00
Evgeniy Stepanov 090f0f9504 [hwasan] Record and display stack history in stack-based reports.
Summary:
Display a list of recent stack frames (not a stack trace!) when
tag-mismatch is detected on a stack address.

The implementation uses alignment tricks to get both the address of
the history buffer, and the base address of the shadow with a single
8-byte load. See the comment in hwasan_thread_list.h for more
details.

Developed in collaboration with Kostya Serebryany.

Reviewers: kcc

Subscribers: srhines, kubamracek, mgorny, hiraditya, jfb, llvm-commits

Differential Revision: https://reviews.llvm.org/D52249

llvm-svn: 342923
2018-09-24 23:03:34 +00:00
Evgeniy Stepanov 20c4999e8b Revert "[hwasan] Record and display stack history in stack-based reports."
This reverts commit r342921: test failures on clang-cmake-arm* bots.

llvm-svn: 342922
2018-09-24 22:50:32 +00:00
Evgeniy Stepanov 9043e17edd [hwasan] Record and display stack history in stack-based reports.
Summary:
Display a list of recent stack frames (not a stack trace!) when
tag-mismatch is detected on a stack address.

The implementation uses alignment tricks to get both the address of
the history buffer, and the base address of the shadow with a single
8-byte load. See the comment in hwasan_thread_list.h for more
details.

Developed in collaboration with Kostya Serebryany.

Reviewers: kcc

Subscribers: srhines, kubamracek, mgorny, hiraditya, jfb, llvm-commits

Differential Revision: https://reviews.llvm.org/D52249

llvm-svn: 342921
2018-09-24 21:38:42 +00:00
Alex Shlyapnikov 99cf54baa6 [HWASan] Introduce non-zero based and dynamic shadow memory (LLVM).
Summary:
Support the dynamic shadow memory offset (the default case for user
space now) and static non-zero shadow memory offset
(-hwasan-mapping-offset option). Keeping the the latter case around
for functionality and performance comparison tests (and mostly for
-hwasan-mapping-offset=0 case).

The implementation is stripped down ASan one, picking only the relevant
parts in the following assumptions: shadow scale is fixed, the shadow
memory is dynamic, it is accessed via ifunc global, shadow memory address
rematerialization is suppressed.

Keep zero-based shadow memory for kernel (-hwasan-kernel option) and
calls instreumented case (-hwasan-instrument-with-calls option), which
essentially means that the generated code is not changed in these cases.

Reviewers: eugenis

Subscribers: srhines, llvm-commits

Differential Revision: https://reviews.llvm.org/D45840

llvm-svn: 330475
2018-04-20 20:04:04 +00:00
Evgeniy Stepanov 43271b1803 [hwasan] Fix inline instrumentation.
This patch changes hwasan inline instrumentation:

Fixes address untagging for shadow address calculation (use 0xFF instead of 0x00 for the top byte).
Emits brk instruction instead of hlt for the kernel and user space.
Use 0x900 instead of 0x100 for brk immediate (0x100 - 0x800 are unavailable in the kernel).
Fixes and adds appropriate tests.

Patch by Andrey Konovalov.

Differential Revision: https://reviews.llvm.org/D43135

llvm-svn: 325711
2018-02-21 19:52:23 +00:00
Evgeniy Stepanov c07e0bd533 [hwasan] Rename sized load/store callbacks to be consistent with ASan.
Summary: __hwasan_load is now __hwasan_loadN.

Reviewers: kcc

Subscribers: hiraditya, llvm-commits

Differential Revision: https://reviews.llvm.org/D42138

llvm-svn: 322601
2018-01-16 23:15:08 +00:00
Evgeniy Stepanov 3fd1b1a764 [hwasan] Implement -fsanitize-recover=hwaddress.
Summary: Very similar to AddressSanitizer, with the exception of the error type encoding.

Reviewers: kcc, alekseyshl

Subscribers: cfe-commits, kubamracek, llvm-commits, hiraditya

Differential Revision: https://reviews.llvm.org/D41417

llvm-svn: 321203
2017-12-20 19:05:44 +00:00
Evgeniy Stepanov ecb48e523e [hwasan] Inline instrumentation & fixed shadow.
Summary: This brings CPU overhead on bzip2 down from 5.5x to 2x.

Reviewers: kcc, alekseyshl

Subscribers: kubamracek, hiraditya, llvm-commits

Differential Revision: https://reviews.llvm.org/D41137

llvm-svn: 320538
2017-12-13 01:16:34 +00:00
Evgeniy Stepanov c667c1f47a Hardware-assisted AddressSanitizer (llvm part).
Summary:
This is LLVM instrumentation for the new HWASan tool. It is basically
a stripped down copy of ASan at this point, w/o stack or global
support. Instrumenation adds a global constructor + runtime callbacks
for every load and store.

HWASan comes with its own IR attribute.

A brief design document can be found in
clang/docs/HardwareAssistedAddressSanitizerDesign.rst (submitted earlier).

Reviewers: kcc, pcc, alekseyshl

Subscribers: srhines, mehdi_amini, mgorny, javed.absar, eraman, llvm-commits, hiraditya

Differential Revision: https://reviews.llvm.org/D40932

llvm-svn: 320217
2017-12-09 00:21:41 +00:00