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52 KiB
Markdown
# Speculative Load Hardening
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### A Spectre Variant #1 Mitigation Technique
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Author: Chandler Carruth - [chandlerc@google.com](mailto:chandlerc@google.com)
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## Problem Statement
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Recently, Google Project Zero and other researchers have found information leak
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vulnerabilities by exploiting speculative execution in modern CPUs. These
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exploits are currently broken down into three variants:
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* GPZ Variant #1 (a.k.a. Spectre Variant #1): Bounds check (or predicate) bypass
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* GPZ Variant #2 (a.k.a. Spectre Variant #2): Branch target injection
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* GPZ Variant #3 (a.k.a. Meltdown): Rogue data cache load
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For more details, see the Google Project Zero blog post and the Spectre research
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paper:
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* https://googleprojectzero.blogspot.com/2018/01/reading-privileged-memory-with-side.html
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* https://spectreattack.com/spectre.pdf
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The core problem of GPZ Variant #1 is that speculative execution uses branch
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prediction to select the path of instructions speculatively executed. This path
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is speculatively executed with the available data, and may load from memory and
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leak the loaded values through various side channels that survive even when the
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speculative execution is unwound due to being incorrect. Mispredicted paths can
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cause code to be executed with data inputs that never occur in correct
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executions, making checks against malicious inputs ineffective and allowing
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attackers to use malicious data inputs to leak secret data. Here is an example,
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extracted and simplified from the Project Zero paper:
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```
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struct array {
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unsigned long length;
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unsigned char data[];
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};
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struct array *arr1 = ...; // small array
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struct array *arr2 = ...; // array of size 0x400
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unsigned long untrusted_offset_from_caller = ...;
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if (untrusted_offset_from_caller < arr1->length) {
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unsigned char value = arr1->data[untrusted_offset_from_caller];
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unsigned long index2 = ((value&1)*0x100)+0x200;
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unsigned char value2 = arr2->data[index2];
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}
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```
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The key of the attack is to call this with `untrusted_offset_from_caller` that
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is far outside of the bounds when the branch predictor will predict that it
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will be in-bounds. In that case, the body of the `if` will be executed
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speculatively, and may read secret data into `value` and leak it via a
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cache-timing side channel when a dependent access is made to populate `value2`.
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## High Level Mitigation Approach
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While several approaches are being actively pursued to mitigate specific
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branches and/or loads inside especially risky software (most notably various OS
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kernels), these approaches require manual and/or static analysis aided auditing
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of code and explicit source changes to apply the mitigation. They are unlikely
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to scale well to large applications. We are proposing a comprehensive
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mitigation approach that would apply automatically across an entire program
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rather than through manual changes to the code. While this is likely to have a
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high performance cost, some applications may be in a good position to take this
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performance / security tradeoff.
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The specific technique we propose is to cause loads to be checked using
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branchless code to ensure that they are executing along a valid control flow
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path. Consider the following C-pseudo-code representing the core idea of a
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predicate guarding potentially invalid loads:
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```
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void leak(int data);
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void example(int* pointer1, int* pointer2) {
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if (condition) {
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// ... lots of code ...
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leak(*pointer1);
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} else {
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// ... more code ...
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leak(*pointer2);
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}
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}
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```
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This would get transformed into something resembling the following:
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```
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uintptr_t all_ones_mask = std::numerical_limits<uintptr_t>::max();
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uintptr_t all_zeros_mask = 0;
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void leak(int data);
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void example(int* pointer1, int* pointer2) {
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uintptr_t predicate_state = all_ones_mask;
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if (condition) {
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// Assuming ?: is implemented using branchless logic...
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predicate_state = !condition ? all_zeros_mask : predicate_state;
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// ... lots of code ...
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//
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// Harden the pointer so it can't be loaded
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pointer1 &= predicate_state;
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leak(*pointer1);
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} else {
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predicate_state = condition ? all_zeros_mask : predicate_state;
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// ... more code ...
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//
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// Alternative: Harden the loaded value
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int value2 = *pointer2 & predicate_state;
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leak(value2);
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}
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}
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```
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The result should be that if the `if (condition) {` branch is mis-predicted,
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there is a *data* dependency on the condition used to zero out any pointers
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prior to loading through them or to zero out all of the loaded bits. Even
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though this code pattern may still execute speculatively, *invalid* speculative
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executions are prevented from leaking secret data from memory (but note that
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this data might still be loaded in safe ways, and some regions of memory are
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required to not hold secrets, see below for detailed limitations). This
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approach only requires the underlying hardware have a way to implement a
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branchless and unpredicted conditional update of a register's value. All modern
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architectures have support for this, and in fact such support is necessary to
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correctly implement constant time cryptographic primitives.
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Crucial properties of this approach:
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* It is not preventing any particular side-channel from working. This is
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important as there are an unknown number of potential side channels and we
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expect to continue discovering more. Instead, it prevents the observation of
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secret data in the first place.
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* It accumulates the predicate state, protecting even in the face of nested
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*correctly* predicted control flows.
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* It passes this predicate state across function boundaries to provide
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[interprocedural protection](#interprocedural-checking).
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* When hardening the address of a load, it uses a *destructive* or
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*non-reversible* modification of the address to prevent an attacker from
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reversing the check using attacker-controlled inputs.
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* It does not completely block speculative execution, and merely prevents
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*mis*-speculated paths from leaking secrets from memory (and stalls
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speculation until this can be determined).
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* It is completely general and makes no fundamental assumptions about the
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underlying architecture other than the ability to do branchless conditional
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data updates and a lack of value prediction.
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* It does not require programmers to identify all possible secret data using
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static source code annotations or code vulnerable to a variant #1 style
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attack.
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Limitations of this approach:
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* It requires re-compiling source code to insert hardening instruction
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sequences. Only software compiled in this mode is protected.
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* The performance is heavily dependent on a particular architecture's
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implementation strategy. We outline a potential x86 implementation below and
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characterize its performance.
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* It does not defend against secret data already loaded from memory and
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residing in registers or leaked through other side-channels in
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non-speculative execution. Code dealing with this, e.g cryptographic
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routines, already uses constant-time algorithms and code to prevent
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side-channels. Such code should also scrub registers of secret data following
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[these
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guidelines](https://github.com/HACS-workshop/spectre-mitigations/blob/master/crypto_guidelines.md).
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* To achieve reasonable performance, many loads may not be checked, such as
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those with compile-time fixed addresses. This primarily consists of accesses
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at compile-time constant offsets of global and local variables. Code which
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needs this protection and intentionally stores secret data must ensure the
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memory regions used for secret data are necessarily dynamic mappings or heap
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allocations. This is an area which can be tuned to provide more comprehensive
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protection at the cost of performance.
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* [Hardened loads](#hardening-the-address-of-the-load) may still load data from
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_valid_ addresses if not _attacker-controlled_ addresses. To prevent these
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from reading secret data, the low 2gb of the address space and 2gb above and
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below any executable pages should be protected.
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Credit:
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* The core idea of tracing misspeculation through data and marking pointers to
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block misspeculated loads was developed as part of a HACS 2018 discussion
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between Chandler Carruth, Paul Kocher, Thomas Pornin, and several other
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individuals.
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* Core idea of masking out loaded bits was part of the original mitigation
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suggested by Jann Horn when these attacks were reported.
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### Indirect Branches, Calls, and Returns
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It is possible to attack control flow other than conditional branches with
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variant #1 style mispredictions.
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* A prediction towards a hot call target of a virtual method can lead to it
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being speculatively executed when an expected type is used (often called
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"type confusion").
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* A hot case may be speculatively executed due to prediction instead of the
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correct case for a switch statement implemented as a jump table.
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* A hot common return address may be predicted incorrectly when returning from
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a function.
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These code patterns are also vulnerable to Spectre variant #2, and as such are
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best mitigated with a
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[retpoline](https://support.google.com/faqs/answer/7625886) on x86 platforms.
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When a mitigation technique like retpoline is used, speculation simply cannot
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proceed through an indirect control flow edge (or it cannot be mispredicted in
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the case of a filled RSB) and so it is also protected from variant #1 style
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attacks. However, some architectures, micro-architectures, or vendors do not
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employ the retpoline mitigation, and on future x86 hardware (both Intel and
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AMD) it is expected to become unnecessary due to hardware-based mitigation.
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When not using a retpoline, these edges will need independent protection from
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variant #1 style attacks. The analogous approach to that used for conditional
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control flow should work:
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```
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uintptr_t all_ones_mask = std::numerical_limits<uintptr_t>::max();
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uintptr_t all_zeros_mask = 0;
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void leak(int data);
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void example(int* pointer1, int* pointer2) {
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uintptr_t predicate_state = all_ones_mask;
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switch (condition) {
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case 0:
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// Assuming ?: is implemented using branchless logic...
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predicate_state = (condition != 0) ? all_zeros_mask : predicate_state;
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// ... lots of code ...
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//
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// Harden the pointer so it can't be loaded
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pointer1 &= predicate_state;
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leak(*pointer1);
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break;
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case 1:
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predicate_state = (condition != 1) ? all_zeros_mask : predicate_state;
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// ... more code ...
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//
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// Alternative: Harden the loaded value
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int value2 = *pointer2 & predicate_state;
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leak(value2);
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break;
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// ...
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}
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}
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```
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The core idea remains the same: validate the control flow using data-flow and
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use that validation to check that loads cannot leak information along
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misspeculated paths. Typically this involves passing the desired target of such
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control flow across the edge and checking that it is correct afterwards. Note
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that while it is tempting to think that this mitigates variant #2 attacks, it
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does not. Those attacks go to arbitrary gadgets that don't include the checks.
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### Variant #1.1 and #1.2 attacks: "Bounds Check Bypass Store"
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Beyond the core variant #1 attack, there are techniques to extend this attack.
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The primary technique is known as "Bounds Check Bypass Store" and is discussed
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in this research paper: https://people.csail.mit.edu/vlk/spectre11.pdf
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We will analyze these two variants independently. First, variant #1.1 works by
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speculatively storing over the return address after a bounds check bypass. This
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speculative store then ends up being used by the CPU during speculative
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execution of the return, potentially directing speculative execution to
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arbitrary gadgets in the binary. Let's look at an example.
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```
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unsigned char local_buffer[4];
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unsigned char *untrusted_data_from_caller = ...;
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unsigned long untrusted_size_from_caller = ...;
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if (untrusted_size_from_caller < sizeof(local_buffer)) {
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// Speculative execution enters here with a too-large size.
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memcpy(local_buffer, untrusted_data_from_caller,
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untrusted_size_from_caller);
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// The stack has now been smashed, writing an attacker-controlled
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// address over the return address.
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minor_processing(local_buffer);
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return;
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// Control will speculate to the attacker-written address.
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}
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```
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However, this can be mitigated by hardening the load of the return address just
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like any other load. This is sometimes complicated because x86 for example
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*implicitly* loads the return address off the stack. However, the
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implementation technique below is specifically designed to mitigate this
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implicit load by using the stack pointer to communicate misspeculation between
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functions. This additionally causes a misspeculation to have an invalid stack
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pointer and never be able to read the speculatively stored return address. See
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the detailed discussion below.
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For variant #1.2, the attacker speculatively stores into the vtable or jump
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table used to implement an indirect call or indirect jump. Because this is
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speculative, this will often be possible even when these are stored in
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read-only pages. For example:
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```
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class FancyObject : public BaseObject {
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public:
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void DoSomething() override;
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};
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void f(unsigned long attacker_offset, unsigned long attacker_data) {
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FancyObject object = getMyObject();
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unsigned long *arr[4] = getFourDataPointers();
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if (attacker_offset < 4) {
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// We have bypassed the bounds check speculatively.
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unsigned long *data = arr[attacker_offset];
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// Now we have computed a pointer inside of `object`, the vptr.
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*data = attacker_data;
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// The vptr points to the virtual table and we speculatively clobber that.
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g(object); // Hand the object to some other routine.
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}
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}
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// In another file, we call a method on the object.
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void g(BaseObject &object) {
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object.DoSomething();
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// This speculatively calls the address stored over the vtable.
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}
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```
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Mitigating this requires hardening loads from these locations, or mitigating
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the indirect call or indirect jump. Any of these are sufficient to block the
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call or jump from using a speculatively stored value that has been read back.
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For both of these, using retpolines would be equally sufficient. One possible
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hybrid approach is to use retpolines for indirect call and jump, while relying
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on SLH to mitigate returns.
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Another approach that is sufficient for both of these is to harden all of the
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speculative stores. However, as most stores aren't interesting and don't
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inherently leak data, this is expected to be prohibitively expensive given the
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attack it is defending against.
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## Implementation Details
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There are a number of complex details impacting the implementation of this
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technique, both on a particular architecture and within a particular compiler.
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We discuss proposed implementation techniques for the x86 architecture and the
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LLVM compiler. These are primarily to serve as an example, as other
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implementation techniques are very possible.
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### x86 Implementation Details
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On the x86 platform we break down the implementation into three core
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components: accumulating the predicate state through the control flow graph,
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checking the loads, and checking control transfers between procedures.
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#### Accumulating Predicate State
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Consider baseline x86 instructions like the following, which test three
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conditions and if all pass, loads data from memory and potentially leaks it
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through some side channel:
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```
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# %bb.0: # %entry
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pushq %rax
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testl %edi, %edi
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jne .LBB0_4
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# %bb.1: # %then1
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testl %esi, %esi
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jne .LBB0_4
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# %bb.2: # %then2
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testl %edx, %edx
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je .LBB0_3
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.LBB0_4: # %exit
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popq %rax
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retq
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.LBB0_3: # %danger
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movl (%rcx), %edi
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callq leak
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popq %rax
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retq
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```
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When we go to speculatively execute the load, we want to know whether any of
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the dynamically executed predicates have been misspeculated. To track that,
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along each conditional edge, we need to track the data which would allow that
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edge to be taken. On x86, this data is stored in the flags register used by the
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conditional jump instruction. Along both edges after this fork in control flow,
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the flags register remains alive and contains data that we can use to build up
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our accumulated predicate state. We accumulate it using the x86 conditional
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move instruction which also reads the flag registers where the state resides.
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These conditional move instructions are known to not be predicted on any x86
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processors, making them immune to misprediction that could reintroduce the
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vulnerability. When we insert the conditional moves, the code ends up looking
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like the following:
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```
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# %bb.0: # %entry
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pushq %rax
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xorl %eax, %eax # Zero out initial predicate state.
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movq $-1, %r8 # Put all-ones mask into a register.
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testl %edi, %edi
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jne .LBB0_1
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# %bb.2: # %then1
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cmovneq %r8, %rax # Conditionally update predicate state.
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testl %esi, %esi
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jne .LBB0_1
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# %bb.3: # %then2
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cmovneq %r8, %rax # Conditionally update predicate state.
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testl %edx, %edx
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je .LBB0_4
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.LBB0_1:
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cmoveq %r8, %rax # Conditionally update predicate state.
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popq %rax
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retq
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.LBB0_4: # %danger
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cmovneq %r8, %rax # Conditionally update predicate state.
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...
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```
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Here we create the "empty" or "correct execution" predicate state by zeroing
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`%rax`, and we create a constant "incorrect execution" predicate value by
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putting `-1` into `%r8`. Then, along each edge coming out of a conditional
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branch we do a conditional move that in a correct execution will be a no-op,
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but if misspeculated, will replace the `%rax` with the value of `%r8`.
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Misspeculating any one of the three predicates will cause `%rax` to hold the
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"incorrect execution" value from `%r8` as we preserve incoming values when
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execution is correct rather than overwriting it.
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We now have a value in `%rax` in each basic block that indicates if at some
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point previously a predicate was mispredicted. And we have arranged for that
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value to be particularly effective when used below to harden loads.
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##### Indirect Call, Branch, and Return Predicates
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There is no analogous flag to use when tracing indirect calls, branches, and
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returns. The predicate state must be accumulated through some other means.
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Fundamentally, this is the reverse of the problem posed in CFI: we need to
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check where we came from rather than where we are going. For function-local
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jump tables, this is easily arranged by testing the input to the jump table
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within each destination (not yet implemented, use retpolines):
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```
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pushq %rax
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xorl %eax, %eax # Zero out initial predicate state.
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movq $-1, %r8 # Put all-ones mask into a register.
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jmpq *.LJTI0_0(,%rdi,8) # Indirect jump through table.
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.LBB0_2: # %sw.bb
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testq $0, %rdi # Validate index used for jump table.
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cmovneq %r8, %rax # Conditionally update predicate state.
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...
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jmp _Z4leaki # TAILCALL
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.LBB0_3: # %sw.bb1
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testq $1, %rdi # Validate index used for jump table.
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cmovneq %r8, %rax # Conditionally update predicate state.
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...
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jmp _Z4leaki # TAILCALL
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.LBB0_5: # %sw.bb10
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testq $2, %rdi # Validate index used for jump table.
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cmovneq %r8, %rax # Conditionally update predicate state.
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...
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jmp _Z4leaki # TAILCALL
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...
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.section .rodata,"a",@progbits
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.p2align 3
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.LJTI0_0:
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.quad .LBB0_2
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.quad .LBB0_3
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.quad .LBB0_5
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...
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```
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Returns have a simple mitigation technique on x86-64 (or other ABIs which have
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what is called a "red zone" region beyond the end of the stack). This region is
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guaranteed to be preserved across interrupts and context switches, making the
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return address used in returning to the current code remain on the stack and
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valid to read. We can emit code in the caller to verify that a return edge was
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not mispredicted:
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```
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callq other_function
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return_addr:
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testq -8(%rsp), return_addr # Validate return address.
|
|
cmovneq %r8, %rax # Update predicate state.
|
|
```
|
|
|
|
For an ABI without a "red zone" (and thus unable to read the return address
|
|
from the stack), we can compute the expected return address prior to the call
|
|
into a register preserved across the call and use that similarly to the above.
|
|
|
|
Indirect calls (and returns in the absence of a red zone ABI) pose the most
|
|
significant challenge to propagate. The simplest technique would be to define a
|
|
new ABI such that the intended call target is passed into the called function
|
|
and checked in the entry. Unfortunately, new ABIs are quite expensive to deploy
|
|
in C and C++. While the target function could be passed in TLS, we would still
|
|
require complex logic to handle a mixture of functions compiled with and
|
|
without this extra logic (essentially, making the ABI backwards compatible).
|
|
Currently, we suggest using retpolines here and will continue to investigate
|
|
ways of mitigating this.
|
|
|
|
|
|
##### Optimizations, Alternatives, and Tradeoffs
|
|
|
|
Merely accumulating predicate state involves significant cost. There are
|
|
several key optimizations we employ to minimize this and various alternatives
|
|
that present different tradeoffs in the generated code.
|
|
|
|
First, we work to reduce the number of instructions used to track the state:
|
|
* Rather than inserting a `cmovCC` instruction along every conditional edge in
|
|
the original program, we track each set of condition flags we need to capture
|
|
prior to entering each basic block and reuse a common `cmovCC` sequence for
|
|
those.
|
|
* We could further reuse suffixes when there are multiple `cmovCC`
|
|
instructions required to capture the set of flags. Currently this is
|
|
believed to not be worth the cost as paired flags are relatively rare and
|
|
suffixes of them are exceedingly rare.
|
|
* A common pattern in x86 is to have multiple conditional jump instructions
|
|
that use the same flags but handle different conditions. Naively, we could
|
|
consider each fallthrough between them an "edge" but this causes a much more
|
|
complex control flow graph. Instead, we accumulate the set of conditions
|
|
necessary for fallthrough and use a sequence of `cmovCC` instructions in a
|
|
single fallthrough edge to track it.
|
|
|
|
Second, we trade register pressure for simpler `cmovCC` instructions by
|
|
allocating a register for the "bad" state. We could read that value from memory
|
|
as part of the conditional move instruction, however, this creates more
|
|
micro-ops and requires the load-store unit to be involved. Currently, we place
|
|
the value into a virtual register and allow the register allocator to decide
|
|
when the register pressure is sufficient to make it worth spilling to memory
|
|
and reloading.
|
|
|
|
|
|
#### Hardening Loads
|
|
|
|
Once we have the predicate accumulated into a special value for correct vs.
|
|
misspeculated, we need to apply this to loads in a way that ensures they do not
|
|
leak secret data. There are two primary techniques for this: we can either
|
|
harden the loaded value to prevent observation, or we can harden the address
|
|
itself to prevent the load from occurring. These have significantly different
|
|
performance tradeoffs.
|
|
|
|
|
|
##### Hardening loaded values
|
|
|
|
The most appealing way to harden loads is to mask out all of the bits loaded.
|
|
The key requirement is that for each bit loaded, along the misspeculated path
|
|
that bit is always fixed at either 0 or 1 regardless of the value of the bit
|
|
loaded. The most obvious implementation uses either an `and` instruction with
|
|
an all-zero mask along misspeculated paths and an all-one mask along correct
|
|
paths, or an `or` instruction with an all-one mask along misspeculated paths
|
|
and an all-zero mask along correct paths. Other options become less appealing
|
|
such as multiplying by zero, or multiple shift instructions. For reasons we
|
|
elaborate on below, we end up suggesting you use `or` with an all-ones mask,
|
|
making the x86 instruction sequence look like the following:
|
|
```
|
|
...
|
|
|
|
.LBB0_4: # %danger
|
|
cmovneq %r8, %rax # Conditionally update predicate state.
|
|
movl (%rsi), %edi # Load potentially secret data from %rsi.
|
|
orl %eax, %edi
|
|
```
|
|
|
|
Other useful patterns may be to fold the load into the `or` instruction itself
|
|
at the cost of a register-to-register copy.
|
|
|
|
There are some challenges with deploying this approach:
|
|
1. Many loads on x86 are folded into other instructions. Separating them would
|
|
add very significant and costly register pressure with prohibitive
|
|
performance cost.
|
|
1. Loads may not target a general purpose register requiring extra instructions
|
|
to map the state value into the correct register class, and potentially more
|
|
expensive instructions to mask the value in some way.
|
|
1. The flags registers on x86 are very likely to be live, and challenging to
|
|
preserve cheaply.
|
|
1. There are many more values loaded than pointers & indices used for loads. As
|
|
a consequence, hardening the result of a load requires substantially more
|
|
instructions than hardening the address of the load (see below).
|
|
|
|
Despite these challenges, hardening the result of the load critically allows
|
|
the load to proceed and thus has dramatically less impact on the total
|
|
speculative / out-of-order potential of the execution. There are also several
|
|
interesting techniques to try and mitigate these challenges and make hardening
|
|
the results of loads viable in at least some cases. However, we generally
|
|
expect to fall back when unprofitable from hardening the loaded value to the
|
|
next approach of hardening the address itself.
|
|
|
|
|
|
###### Loads folded into data-invariant operations can be hardened after the operation
|
|
|
|
The first key to making this feasible is to recognize that many operations on
|
|
x86 are "data-invariant". That is, they have no (known) observable behavior
|
|
differences due to the particular input data. These instructions are often used
|
|
when implementing cryptographic primitives dealing with private key data
|
|
because they are not believed to provide any side-channels. Similarly, we can
|
|
defer hardening until after them as they will not in-and-of-themselves
|
|
introduce a speculative execution side-channel. This results in code sequences
|
|
that look like:
|
|
```
|
|
...
|
|
|
|
.LBB0_4: # %danger
|
|
cmovneq %r8, %rax # Conditionally update predicate state.
|
|
addl (%rsi), %edi # Load and accumulate without leaking.
|
|
orl %eax, %edi
|
|
```
|
|
|
|
While an addition happens to the loaded (potentially secret) value, that
|
|
doesn't leak any data and we then immediately harden it.
|
|
|
|
|
|
###### Hardening of loaded values deferred down the data-invariant expression graph
|
|
|
|
We can generalize the previous idea and sink the hardening down the expression
|
|
graph across as many data-invariant operations as desirable. This can use very
|
|
conservative rules for whether something is data-invariant. The primary goal
|
|
should be to handle multiple loads with a single hardening instruction:
|
|
```
|
|
...
|
|
|
|
.LBB0_4: # %danger
|
|
cmovneq %r8, %rax # Conditionally update predicate state.
|
|
addl (%rsi), %edi # Load and accumulate without leaking.
|
|
addl 4(%rsi), %edi # Continue without leaking.
|
|
addl 8(%rsi), %edi
|
|
orl %eax, %edi # Mask out bits from all three loads.
|
|
```
|
|
|
|
|
|
###### Preserving the flags while hardening loaded values on Haswell, Zen, and newer processors
|
|
|
|
Sadly, there are no useful instructions on x86 that apply a mask to all 64 bits
|
|
without touching the flag registers. However, we can harden loaded values that
|
|
are narrower than a word (fewer than 32-bits on 32-bit systems and fewer than
|
|
64-bits on 64-bit systems) by zero-extending the value to the full word size
|
|
and then shifting right by at least the number of original bits using the BMI2
|
|
`shrx` instruction:
|
|
```
|
|
...
|
|
|
|
.LBB0_4: # %danger
|
|
cmovneq %r8, %rax # Conditionally update predicate state.
|
|
addl (%rsi), %edi # Load and accumulate 32 bits of data.
|
|
shrxq %rax, %rdi, %rdi # Shift out all 32 bits loaded.
|
|
```
|
|
|
|
Because on x86 the zero-extend is free, this can efficiently harden the loaded
|
|
value.
|
|
|
|
|
|
##### Hardening the address of the load
|
|
|
|
When hardening the loaded value is inapplicable, most often because the
|
|
instruction directly leaks information (like `cmp` or `jmpq`), we switch to
|
|
hardening the _address_ of the load instead of the loaded value. This avoids
|
|
increasing register pressure by unfolding the load or paying some other high
|
|
cost.
|
|
|
|
To understand how this works in practice, we need to examine the exact
|
|
semantics of the x86 addressing modes which, in its fully general form, looks
|
|
like `(%base,%index,scale)offset`. Here `%base` and `%index` are 64-bit
|
|
registers that can potentially be any value, and may be attacker controlled,
|
|
and `scale` and `offset` are fixed immediate values. `scale` must be `1`, `2`,
|
|
`4`, or `8`, and `offset` can be any 32-bit sign extended value. The exact
|
|
computation performed to find the address is then: `%base + (scale * %index) +
|
|
offset` under 64-bit 2's complement modular arithmetic.
|
|
|
|
One issue with this approach is that, after hardening, the `%base + (scale *
|
|
%index)` subexpression will compute a value near zero (`-1 + (scale * -1)`) and
|
|
then a large, positive `offset` will index into memory within the first two
|
|
gigabytes of address space. While these offsets are not attacker controlled,
|
|
the attacker could chose to attack a load which happens to have the desired
|
|
offset and then successfully read memory in that region. This significantly
|
|
raises the burden on the attacker and limits the scope of attack but does not
|
|
eliminate it. To fully close the attack we must work with the operating system
|
|
to preclude mapping memory in the low two gigabytes of address space.
|
|
|
|
|
|
###### 64-bit load checking instructions
|
|
|
|
We can use the following instruction sequences to check loads. We set up `%r8`
|
|
in these examples to hold the special value of `-1` which will be `cmov`ed over
|
|
`%rax` in misspeculated paths.
|
|
|
|
Single register addressing mode:
|
|
```
|
|
...
|
|
|
|
.LBB0_4: # %danger
|
|
cmovneq %r8, %rax # Conditionally update predicate state.
|
|
orq %rax, %rsi # Mask the pointer if misspeculating.
|
|
movl (%rsi), %edi
|
|
```
|
|
|
|
Two register addressing mode:
|
|
```
|
|
...
|
|
|
|
.LBB0_4: # %danger
|
|
cmovneq %r8, %rax # Conditionally update predicate state.
|
|
orq %rax, %rsi # Mask the pointer if misspeculating.
|
|
orq %rax, %rcx # Mask the index if misspeculating.
|
|
movl (%rsi,%rcx), %edi
|
|
```
|
|
|
|
This will result in a negative address near zero or in `offset` wrapping the
|
|
address space back to a small positive address. Small, negative addresses will
|
|
fault in user-mode for most operating systems, but targets which need the high
|
|
address space to be user accessible may need to adjust the exact sequence used
|
|
above. Additionally, the low addresses will need to be marked unreadable by the
|
|
OS to fully harden the load.
|
|
|
|
|
|
###### RIP-relative addressing is even easier to break
|
|
|
|
There is a common addressing mode idiom that is substantially harder to check:
|
|
addressing relative to the instruction pointer. We cannot change the value of
|
|
the instruction pointer register and so we have the harder problem of forcing
|
|
`%base + scale * %index + offset` to be an invalid address, by *only* changing
|
|
`%index`. The only advantage we have is that the attacker also cannot modify
|
|
`%base`. If we use the fast instruction sequence above, but only apply it to
|
|
the index, we will always access `%rip + (scale * -1) + offset`. If the
|
|
attacker can find a load which with this address happens to point to secret
|
|
data, then they can reach it. However, the loader and base libraries can also
|
|
simply refuse to map the heap, data segments, or stack within 2gb of any of the
|
|
text in the program, much like it can reserve the low 2gb of address space.
|
|
|
|
|
|
###### The flag registers again make everything hard
|
|
|
|
Unfortunately, the technique of using `orq`-instructions has a serious flaw on
|
|
x86. The very thing that makes it easy to accumulate state, the flag registers
|
|
containing predicates, causes serious problems here because they may be alive
|
|
and used by the loading instruction or subsequent instructions. On x86, the
|
|
`orq` instruction **sets** the flags and will override anything already there.
|
|
This makes inserting them into the instruction stream very hazardous.
|
|
Unfortunately, unlike when hardening the loaded value, we have no fallback here
|
|
and so we must have a fully general approach available.
|
|
|
|
The first thing we must do when generating these sequences is try to analyze
|
|
the surrounding code to prove that the flags are not in fact alive or being
|
|
used. Typically, it has been set by some other instruction which just happens
|
|
to set the flags register (much like ours!) with no actual dependency. In those
|
|
cases, it is safe to directly insert these instructions. Alternatively we may
|
|
be able to move them earlier to avoid clobbering the used value.
|
|
|
|
However, this may ultimately be impossible. In that case, we need to preserve
|
|
the flags around these instructions:
|
|
```
|
|
...
|
|
|
|
.LBB0_4: # %danger
|
|
cmovneq %r8, %rax # Conditionally update predicate state.
|
|
pushfq
|
|
orq %rax, %rcx # Mask the pointer if misspeculating.
|
|
orq %rax, %rdx # Mask the index if misspeculating.
|
|
popfq
|
|
movl (%rcx,%rdx), %edi
|
|
```
|
|
|
|
Using the `pushf` and `popf` instructions saves the flags register around our
|
|
inserted code, but comes at a high cost. First, we must store the flags to the
|
|
stack and reload them. Second, this causes the stack pointer to be adjusted
|
|
dynamically, requiring a frame pointer be used for referring to temporaries
|
|
spilled to the stack, etc.
|
|
|
|
On newer x86 processors we can use the `lahf` and `sahf` instructions to save
|
|
all of the flags besides the overflow flag in a register rather than on the
|
|
stack. We can then use `seto` and `add` to save and restore the overflow flag
|
|
in a register. Combined, this will save and restore flags in the same manner as
|
|
above but using two registers rather than the stack. That is still very
|
|
expensive if slightly less expensive than `pushf` and `popf` in most cases.
|
|
|
|
|
|
###### A flag-less alternative on Haswell, Zen and newer processors
|
|
|
|
Starting with the BMI2 x86 instruction set extensions available on Haswell and
|
|
Zen processors, there is an instruction for shifting that does not set any
|
|
flags: `shrx`. We can use this and the `lea` instruction to implement analogous
|
|
code sequences to the above ones. However, these are still very marginally
|
|
slower, as there are fewer ports able to dispatch shift instructions in most
|
|
modern x86 processors than there are for `or` instructions.
|
|
|
|
Fast, single register addressing mode:
|
|
```
|
|
...
|
|
|
|
.LBB0_4: # %danger
|
|
cmovneq %r8, %rax # Conditionally update predicate state.
|
|
shrxq %rax, %rsi, %rsi # Shift away bits if misspeculating.
|
|
movl (%rsi), %edi
|
|
```
|
|
|
|
This will collapse the register to zero or one, and everything but the offset
|
|
in the addressing mode to be less than or equal to 9. This means the full
|
|
address can only be guaranteed to be less than `(1 << 31) + 9`. The OS may wish
|
|
to protect an extra page of the low address space to account for this
|
|
|
|
|
|
##### Optimizations
|
|
|
|
A very large portion of the cost for this approach comes from checking loads in
|
|
this way, so it is important to work to optimize this. However, beyond making
|
|
the instruction sequences to *apply* the checks efficient (for example by
|
|
avoiding `pushfq` and `popfq` sequences), the only significant optimization is
|
|
to check fewer loads without introducing a vulnerability. We apply several
|
|
techniques to accomplish that.
|
|
|
|
|
|
###### Don't check loads from compile-time constant stack offsets
|
|
|
|
We implement this optimization on x86 by skipping the checking of loads which
|
|
use a fixed frame pointer offset.
|
|
|
|
The result of this optimization is that patterns like reloading a spilled
|
|
register or accessing a global field don't get checked. This is a very
|
|
significant performance win.
|
|
|
|
|
|
###### Don't check dependent loads
|
|
|
|
A core part of why this mitigation strategy works is that it establishes a
|
|
data-flow check on the loaded address. However, this means that if the address
|
|
itself was already loaded using a checked load, there is no need to check a
|
|
dependent load provided it is within the same basic block as the checked load,
|
|
and therefore has no additional predicates guarding it. Consider code like the
|
|
following:
|
|
```
|
|
...
|
|
|
|
.LBB0_4: # %danger
|
|
movq (%rcx), %rdi
|
|
movl (%rdi), %edx
|
|
```
|
|
|
|
This will get transformed into:
|
|
```
|
|
...
|
|
|
|
.LBB0_4: # %danger
|
|
cmovneq %r8, %rax # Conditionally update predicate state.
|
|
orq %rax, %rcx # Mask the pointer if misspeculating.
|
|
movq (%rcx), %rdi # Hardened load.
|
|
movl (%rdi), %edx # Unhardened load due to dependent addr.
|
|
```
|
|
|
|
This doesn't check the load through `%rdi` as that pointer is dependent on a
|
|
checked load already.
|
|
|
|
|
|
###### Protect large, load-heavy blocks with a single lfence
|
|
|
|
It may be worth using a single `lfence` instruction at the start of a block
|
|
which begins with a (very) large number of loads that require independent
|
|
protection *and* which require hardening the address of the load. However, this
|
|
is unlikely to be profitable in practice. The latency hit of the hardening
|
|
would need to exceed that of an `lfence` when *correctly* speculatively
|
|
executed. But in that case, the `lfence` cost is a complete loss of speculative
|
|
execution (at a minimum). So far, the evidence we have of the performance cost
|
|
of using `lfence` indicates few if any hot code patterns where this trade off
|
|
would make sense.
|
|
|
|
|
|
###### Tempting optimizations that break the security model
|
|
|
|
Several optimizations were considered which didn't pan out due to failure to
|
|
uphold the security model. One in particular is worth discussing as many others
|
|
will reduce to it.
|
|
|
|
We wondered whether only the *first* load in a basic block could be checked. If
|
|
the check works as intended, it forms an invalid pointer that doesn't even
|
|
virtual-address translate in the hardware. It should fault very early on in its
|
|
processing. Maybe that would stop things in time for the misspeculated path to
|
|
fail to leak any secrets. This doesn't end up working because the processor is
|
|
fundamentally out-of-order, even in its speculative domain. As a consequence,
|
|
the attacker could cause the initial address computation itself to stall and
|
|
allow an arbitrary number of unrelated loads (including attacked loads of
|
|
secret data) to pass through.
|
|
|
|
|
|
#### Interprocedural Checking
|
|
|
|
Modern x86 processors may speculate into called functions and out of functions
|
|
to their return address. As a consequence, we need a way to check loads that
|
|
occur after a misspeculated predicate but where the load and the misspeculated
|
|
predicate are in different functions. In essence, we need some interprocedural
|
|
generalization of the predicate state tracking. A primary challenge to passing
|
|
the predicate state between functions is that we would like to not require a
|
|
change to the ABI or calling convention in order to make this mitigation more
|
|
deployable, and further would like code mitigated in this way to be easily
|
|
mixed with code not mitigated in this way and without completely losing the
|
|
value of the mitigation.
|
|
|
|
|
|
##### Embed the predicate state into the high bit(s) of the stack pointer
|
|
|
|
We can use the same technique that allows hardening pointers to pass the
|
|
predicate state into and out of functions. The stack pointer is trivially
|
|
passed between functions and we can test for it having the high bits set to
|
|
detect when it has been marked due to misspeculation. The callsite instruction
|
|
sequence looks like (assuming a misspeculated state value of `-1`):
|
|
```
|
|
...
|
|
|
|
.LBB0_4: # %danger
|
|
cmovneq %r8, %rax # Conditionally update predicate state.
|
|
shlq $47, %rax
|
|
orq %rax, %rsp
|
|
callq other_function
|
|
movq %rsp, %rax
|
|
sarq 63, %rax # Sign extend the high bit to all bits.
|
|
```
|
|
|
|
This first puts the predicate state into the high bits of `%rsp` before calling
|
|
the function and then reads it back out of high bits of `%rsp` afterward. When
|
|
correctly executing (speculatively or not), these are all no-ops. When
|
|
misspeculating, the stack pointer will end up negative. We arrange for it to
|
|
remain a canonical address, but otherwise leave the low bits alone to allow
|
|
stack adjustments to proceed normally without disrupting this. Within the
|
|
called function, we can extract this predicate state and then reset it on
|
|
return:
|
|
```
|
|
other_function:
|
|
# prolog
|
|
callq other_function
|
|
movq %rsp, %rax
|
|
sarq 63, %rax # Sign extend the high bit to all bits.
|
|
# ...
|
|
|
|
.LBB0_N:
|
|
cmovneq %r8, %rax # Conditionally update predicate state.
|
|
shlq $47, %rax
|
|
orq %rax, %rsp
|
|
retq
|
|
```
|
|
|
|
This approach is effective when all code is mitigated in this fashion, and can
|
|
even survive very limited reaches into unmitigated code (the state will
|
|
round-trip in and back out of an unmitigated function, it just won't be
|
|
updated). But it does have some limitations. There is a cost to merging the
|
|
state into `%rsp` and it doesn't insulate mitigated code from misspeculation in
|
|
an unmitigated caller.
|
|
|
|
There is also an advantage to using this form of interprocedural mitigation: by
|
|
forming these invalid stack pointer addresses we can prevent speculative
|
|
returns from successfully reading speculatively written values to the actual
|
|
stack. This works first by forming a data-dependency between computing the
|
|
address of the return address on the stack and our predicate state. And even
|
|
when satisfied, if a misprediction causes the state to be poisoned the
|
|
resulting stack pointer will be invalid.
|
|
|
|
|
|
##### Rewrite API of internal functions to directly propagate predicate state
|
|
|
|
(Not yet implemented.)
|
|
|
|
We have the option with internal functions to directly adjust their API to
|
|
accept the predicate as an argument and return it. This is likely to be
|
|
marginally cheaper than embedding into `%rsp` for entering functions.
|
|
|
|
|
|
##### Use `lfence` to guard function transitions
|
|
|
|
An `lfence` instruction can be used to prevent subsequent loads from
|
|
speculatively executing until all prior mispredicted predicates have resolved.
|
|
We can use this broader barrier to speculative loads executing between
|
|
functions. We emit it in the entry block to handle calls, and prior to each
|
|
return. This approach also has the advantage of providing the strongest degree
|
|
of mitigation when mixed with unmitigated code by halting all misspeculation
|
|
entering a function which is mitigated, regardless of what occurred in the
|
|
caller. However, such a mixture is inherently more risky. Whether this kind of
|
|
mixture is a sufficient mitigation requires careful analysis.
|
|
|
|
Unfortunately, experimental results indicate that the performance overhead of
|
|
this approach is very high for certain patterns of code. A classic example is
|
|
any form of recursive evaluation engine. The hot, rapid call and return
|
|
sequences exhibit dramatic performance loss when mitigated with `lfence`. This
|
|
component alone can regress performance by 2x or more, making it an unpleasant
|
|
tradeoff even when only used in a mixture of code.
|
|
|
|
|
|
##### Use an internal TLS location to pass predicate state
|
|
|
|
We can define a special thread-local value to hold the predicate state between
|
|
functions. This avoids direct ABI implications by using a side channel between
|
|
callers and callees to communicate the predicate state. It also allows implicit
|
|
zero-initialization of the state, which allows non-checked code to be the first
|
|
code executed.
|
|
|
|
However, this requires a load from TLS in the entry block, a store to TLS
|
|
before every call and every ret, and a load from TLS after every call. As a
|
|
consequence it is expected to be substantially more expensive even than using
|
|
`%rsp` and potentially `lfence` within the function entry block.
|
|
|
|
|
|
##### Define a new ABI and/or calling convention
|
|
|
|
We could define a new ABI and/or calling convention to explicitly pass the
|
|
predicate state in and out of functions. This may be interesting if none of the
|
|
alternatives have adequate performance, but it makes deployment and adoption
|
|
dramatically more complex, and potentially infeasible.
|
|
|
|
|
|
## High-Level Alternative Mitigation Strategies
|
|
|
|
There are completely different alternative approaches to mitigating variant 1
|
|
attacks. [Most](https://lwn.net/Articles/743265/)
|
|
[discussion](https://lwn.net/Articles/744287/) so far focuses on mitigating
|
|
specific known attackable components in the Linux kernel (or other kernels) by
|
|
manually rewriting the code to contain an instruction sequence that is not
|
|
vulnerable. For x86 systems this is done by either injecting an `lfence`
|
|
instruction along the code path which would leak data if executed speculatively
|
|
or by rewriting memory accesses to have branch-less masking to a known safe
|
|
region. On Intel systems, `lfence` [will prevent the speculative load of secret
|
|
data](https://newsroom.intel.com/wp-content/uploads/sites/11/2018/01/Intel-Analysis-of-Speculative-Execution-Side-Channels.pdf).
|
|
On AMD systems `lfence` is currently a no-op, but can be made
|
|
dispatch-serializing by setting an MSR, and thus preclude misspeculation of the
|
|
code path ([mitigation G-2 +
|
|
V1-1](https://developer.amd.com/wp-content/resources/Managing-Speculation-on-AMD-Processors.pdf)).
|
|
|
|
However, this relies on finding and enumerating all possible points in code
|
|
which could be attacked to leak information. While in some cases static
|
|
analysis is effective at doing this at scale, in many cases it still relies on
|
|
human judgement to evaluate whether code might be vulnerable. Especially for
|
|
software systems which receive less detailed scrutiny but remain sensitive to
|
|
these attacks, this seems like an impractical security model. We need an
|
|
automatic and systematic mitigation strategy.
|
|
|
|
|
|
### Automatic `lfence` on Conditional Edges
|
|
|
|
A natural way to scale up the existing hand-coded mitigations is simply to
|
|
inject an `lfence` instruction into both the target and fallthrough
|
|
destinations of every conditional branch. This ensures that no predicate or
|
|
bounds check can be bypassed speculatively. However, the performance overhead
|
|
of this approach is, simply put, catastrophic. Yet it remains the only truly
|
|
"secure by default" approach known prior to this effort and serves as the
|
|
baseline for performance.
|
|
|
|
One attempt to address the performance overhead of this and make it more
|
|
realistic to deploy is [MSVC's /Qspectre
|
|
switch](https://blogs.msdn.microsoft.com/vcblog/2018/01/15/spectre-mitigations-in-msvc/).
|
|
Their technique is to use static analysis within the compiler to only insert
|
|
`lfence` instructions into conditional edges at risk of attack. However,
|
|
[initial](https://arstechnica.com/gadgets/2018/02/microsofts-compiler-level-spectre-fix-shows-how-hard-this-problem-will-be-to-solve/)
|
|
[analysis](https://www.paulkocher.com/doc/MicrosoftCompilerSpectreMitigation.html)
|
|
has shown that this approach is incomplete and only catches a small and limited
|
|
subset of attackable patterns which happen to resemble very closely the initial
|
|
proofs of concept. As such, while its performance is acceptable, it does not
|
|
appear to be an adequate systematic mitigation.
|
|
|
|
|
|
## Performance Overhead
|
|
|
|
The performance overhead of this style of comprehensive mitigation is very
|
|
high. However, it compares very favorably with previously recommended
|
|
approaches such as the `lfence` instruction. Just as users can restrict the
|
|
scope of `lfence` to control its performance impact, this mitigation technique
|
|
could be restricted in scope as well.
|
|
|
|
However, it is important to understand what it would cost to get a fully
|
|
mitigated baseline. Here we assume targeting a Haswell (or newer) processor and
|
|
using all of the tricks to improve performance (so leaves the low 2gb
|
|
unprotected and +/- 2gb surrounding any PC in the program). We ran both
|
|
Google's microbenchmark suite and a large highly-tuned server built using
|
|
ThinLTO and PGO. All were built with `-march=haswell` to give access to BMI2
|
|
instructions, and benchmarks were run on large Haswell servers. We collected
|
|
data both with an `lfence`-based mitigation and load hardening as presented
|
|
here. The summary is that mitigating with load hardening is 1.77x faster than
|
|
mitigating with `lfence`, and the overhead of load hardening compared to a
|
|
normal program is likely between a 10% overhead and a 50% overhead with most
|
|
large applications seeing a 30% overhead or less.
|
|
|
|
| Benchmark | `lfence` | Load Hardening | Mitigated Speedup |
|
|
| -------------------------------------- | -------: | -------------: | ----------------: |
|
|
| Google microbenchmark suite | -74.8% | -36.4% | **2.5x** |
|
|
| Large server QPS (using ThinLTO & PGO) | -62% | -29% | **1.8x** |
|
|
|
|
Below is a visualization of the microbenchmark suite results which helps show
|
|
the distribution of results that is somewhat lost in the summary. The y-axis is
|
|
a log-scale speedup ratio of load hardening relative to `lfence` (up -> faster
|
|
-> better). Each box-and-whiskers represents one microbenchmark which may have
|
|
many different metrics measured. The red line marks the median, the box marks
|
|
the first and third quartiles, and the whiskers mark the min and max.
|
|
|
|
![Microbenchmark result visualization](speculative_load_hardening_microbenchmarks.png)
|
|
|
|
We don't yet have benchmark data on SPEC or the LLVM test suite, but we can
|
|
work on getting that. Still, the above should give a pretty clear
|
|
characterization of the performance, and specific benchmarks are unlikely to
|
|
reveal especially interesting properties.
|
|
|
|
|
|
### Future Work: Fine Grained Control and API-Integration
|
|
|
|
The performance overhead of this technique is likely to be very significant and
|
|
something users wish to control or reduce. There are interesting options here
|
|
that impact the implementation strategy used.
|
|
|
|
One particularly appealing option is to allow both opt-in and opt-out of this
|
|
mitigation at reasonably fine granularity such as on a per-function basis,
|
|
including intelligent handling of inlining decisions -- protected code can be
|
|
prevented from inlining into unprotected code, and unprotected code will become
|
|
protected when inlined into protected code. For systems where only a limited
|
|
set of code is reachable by externally controlled inputs, it may be possible to
|
|
limit the scope of mitigation through such mechanisms without compromising the
|
|
application's overall security. The performance impact may also be focused in a
|
|
few key functions that can be hand-mitigated in ways that have lower
|
|
performance overhead while the remainder of the application receives automatic
|
|
protection.
|
|
|
|
For both limiting the scope of mitigation or manually mitigating hot functions,
|
|
there needs to be some support for mixing mitigated and unmitigated code
|
|
without completely defeating the mitigation. For the first use case, it would
|
|
be particularly desirable that mitigated code remains safe when being called
|
|
during misspeculation from unmitigated code.
|
|
|
|
For the second use case, it may be important to connect the automatic
|
|
mitigation technique to explicit mitigation APIs such as what is described in
|
|
http://wg21.link/p0928 (or any other eventual API) so that there is a clean way
|
|
to switch from automatic to manual mitigation without immediately exposing a
|
|
hole. However, the design for how to do this is hard to come up with until the
|
|
APIs are better established. We will revisit this as those APIs mature.
|