The Android team has been working on introducing the Rust programming language into the Android Open Source Project (AOSP) since 2019 as a memory-safe alternative for platform native code development. As with any large project, introducing a new language requires careful consideration. For Android, one important area was assessing how to best fit Rust into Android’s build system. Currently this means the Soong build system (where the Rust support resides), but these design decisions and considerations are equally applicable for Bazel when AOSP migrates to that build system. This post discusses some of the key design considerations and resulting decisions we made in integrating Rust support into Android’s build system.
A RustConf 2019 meeting on Rust usage within large organizations highlighted several challenges, such as the risk that eschewing Cargo in favor of using the Rust Compiler, rustc, directly (see next section) may remove organizations from the wider Rust community. We share this same concern. When changes to imported third-party crates might be beneficial to the wider community, our goal is to upstream those changes. Likewise when crates developed for Android could benefit the wider Rust community, we hope to release them as independent crates. We believe that the success of Rust within Android is dependent on minimizing any divergence between Android and the Rust community at large, and hope that the Rust community will benefit from Android’s involvement.
rustc,
Rust provides Cargo as the default build system and package manager, collecting dependencies and invoking rustc (the Rust compiler) to build the target crate (Rust package). Soong takes this role instead in Android and calls rustc directly for several reasons:
rustc
Cargo.toml
build.rs
Using the Rust compiler directly allows us to avoid these issues and is consistent with how we compile all other code in AOSP. It provides the most control over the build process and eases integration into Android’s existing build system. Unfortunately, avoiding it introduces several challenges and influences many other build system decisions because Cargo usage is so deeply ingrained in the Rust crate ecosystem.
A build.rs script compiles to a Rust binary which Cargo builds and executes during a build to handle pre-build tasks, commonly setting up the build environment, or building libraries in other languages (for example C/C++). This is analogous to configure scripts used for other languages.
Avoiding build.rs scripts somewhat flows naturally from not relying on Cargo since supporting these would require replicating Cargo behavior and assumptions. Beyond this however, there are good reasons for AOSP to avoid build scripts as well:
/usr/lib
Android.bp
For instances in third-party code where a build script is used only to compile C dependencies, we either use existing cc_library Soong definitions (such as boringssl for quiche) or create new definitions for crate-specific code.
cc_library
When the build.rs is used to generate source, we try to replicate the core functionality in a Soong rust_binary module for use as a custom source generator. In other cases where Soong can provide the information without source generation, we may carry a small patch that leverages this information.
Why do we support proc_macros, which are compiler plug-ins that execute code on the host within the compiler context, but not build.rs scripts?
proc_macros
While build.rs code is written as one-off code to handle building a single crate, proc_macros define reusable functionality within the compiler which can become widely relied upon across the Rust community. As a result popular proc_macros are generally better maintained and more scrutinized upstream, which makes the code review process more manageable. They are also more readily sandboxed as part of the build process since they are less likely to have dependencies external to the compiler.
proc_macros are also a language feature rather than a method for building code. These are relied upon by source code, are unavoidable for third-party dependencies, and are useful enough to define and use within our platform code. While we can avoid build.rs by leveraging our build system, the same can’t be said of proc_macros.
There is also precedence for compiler plugin support within the Android build system. For example see Soong’s java_plugin modules.
Unlike C/C++ compilers, rustc only accepts a single source file representing an entry point to a binary or library. It expects that the source tree is structured such that all required source files can be automatically discovered. This means that generated source either needs to be placed in the source tree or provided through an include directive in source:
include!("/path/to/hello.rs");
The Rust community depends on build.rs scripts alongside assumptions about the Cargo build environment to get around this limitation. When building, the cargo command sets an OUT_DIR environment variable which build.rs scripts are expected to place generated source code in. This source can then be included via:
cargo
include!(concat!(env!("OUT_DIR"), "/hello.rs"));
This presents a challenge for Soong as outputs for each module are placed in their own out/ directory2; there is no single OUT_DIR where dependencies output their generated source.
out/
OUT_DIR
For platform code, we prefer to package generated source into a crate that can be imported. There are a few reasons to favor this approach:
As a result, all of Android’s Rust source generation module types produce code that can be compiled and used as a crate.
We still support third-party crates without modification by copying all the generated source dependencies for a module into a single per-module directory similar to Cargo. Soong then sets the OUT_DIR environment variable to that directory when compiling the module so the generated source can be found. However we discourage use of this mechanism in platform code unless absolutely necessary for the reasons described above.
By default, the Rust ecosystem assumes that crates will be statically linked into binaries. The usual benefits of dynamic libraries are upgrades (whether for security or functionality) and decreased memory usage. Rust’s lack of a stable binary interface and usage of cross-crate information flow prevents upgrading libraries without upgrading all dependent code. Even when the same crate is used by two different programs on the system, it is unlikely to be provided by the same shared object4 due to the precision with which Rust identifies its crates. This makes Rust binaries more portable but also results in larger disk and memory footprints.
This is problematic for Android devices where resources like memory and disk usage must be carefully managed because statically linking all crates into Rust binaries would result in excessive code duplication (especially in the standard library). However, our situation is also different from the standard host environment: we build Android using global decisions about dependencies. This means that nearly every crate is shareable between all users of that crate. Thus, we opt to link crates dynamically by default for device targets. This reduces the overall memory footprint of Rust in Android by allowing crates to be reused across multiple binaries which depend on them.
Since this is unusual in the Rust community, not all third-party crates support dynamic compilation. Sometimes we must carry small patches while we work with upstream maintainers to add support.
We support building all output types supported by rustc (rlibs, dylibs, proc_macros, cdylibs, staticlibs, and executables). Rust modules can automatically request the appropriate crate linkage for a given dependency (rlib vs dylib). C and C++ modules can depend on Rust cdylib or staticlib producing modules the same way as they would for a C or C++ library.
rlib
dylib
proc_macro
cdylib
staticlib
In addition to being able to build Rust code, Android’s build system also provides support for protobuf and gRPC and AIDL generated crates. First-class bindgen support makes interfacing with existing C code simple and we have support modules using cxx for tighter integration with C++ code.
The Rust community produces great tooling for developers, such as the language server rust-analyzer. We have integrated support for rust-analyzer into the build system so that any IDE which supports it can provide code completion and goto definitions for Android modules.
Source-based code coverage builds are supported to provide platform developers high level signals on how well their code is covered by tests. Benchmarks are supported as their own module type, leveraging the criterion crate to provide performance metrics. In order to maintain a consistent style and level of code quality, a default set of clippy lints and rustc lints are enabled by default. Additionally, HWASAN/ASAN fuzzers are supported, with the HWASAN rustc support added to upstream.
clippy
In the near future, we plan to add documentation to source.android.com on how to define and use Rust modules in Soong. We expect Android’s support for Rust to continue evolving alongside the Rust ecosystem and hope to continue to participate in discussions around how Rust can be integrated into existing build systems.
Thank you to Matthew Maurer, Jeff Vander Stoep, Joel Galenson, Manish Goregaokar, and Tyler Mandry for their contributions to this post.
This can be mitigated to some extent with workspaces, but requires a very specific directory arrangement that AOSP does not conform to. ↩
This presents no problem for C/C++ and similar languages as the path to the generated source is provided directly to the compiler. ↩
Since include! works by textual inclusion, it may reference values from the enclosing namespace, modify the namespace, or use constructs like #![foo]. These implicit interactions can be difficult to maintain. Macros should be preferred if interaction with the rest of the crate is truly required. ↩
While libstd would usually be shareable for the same compiler revision, most other libraries would end up with several copies for Cargo-built Rust binaries, since each build would attempt to use a minimum feature set and may select different dependency versions for the library in question. Since information propagates across crate boundaries, you cannot simply produce a “most general” instance of that library. ↩
Chrome 90 for Windows adopts Hardware-enforced Stack Protection, a mitigation technology to make the exploitation of security bugs more difficult for attackers. This is supported by Windows 20H1 (December Update) or later, running on processors with Control-flow Enforcement Technology (CET) such as Intel 11th Gen or AMD Zen 3 CPUs. With this mitigation the processor maintains a new, protected, stack of valid return addresses (a shadow stack). This improves security by making exploits more difficult to write. However, it may affect stability if software that loads itself into Chrome is not compatible with the mitigation. Below we describe some exploitation techniques that are mitigated by stack protection, discuss its limitations and what we will do next to approach them. Finally, we provide some quick tips for other software authors as they enable /cetcompat for their Windows applications.
Imagine a simple use-after-free (UAF) bug where an attacker can induce a program to call a pointer of their choosing. Here the attacker controls an object which occupies space formerly used by another object, which the program erroneously continues to use. The attacker sets a field in this region that is used as a function call to the address of code the attacker would like to execute. Years ago an attacker could simply write their shellcode to a known location, then, in their overwrite, set the instruction pointer to this shellcode. In time, Data Execution Prevention was added to prevent stacks or heaps from being executable.
In response, attackers invented Return Oriented Programming (ROP). Here, attackers take advantage of the process’s own code, as that must be executable. With control of the stack (either to write values there, or by changing the stack pointer) and control of the instruction pointer, an attacker can use the `ret` instruction to jump to a different, useful, piece of code.
During an exploit attempt, the instruction pointer is changed so that instead of its normal destination, a small fragment of code, called an ROP gadget, is invoked instead. These gadgets are selected so that they do something useful (such as prepare a register for a function call) then call return.
These tiny fragments need not be a complete function in the normal program, and could even be found part-way through a legitimate instruction. By lining up the right set of “return” addresses, a chain of these gadgets can be called, with each gadget’s `ret` switching to the next gadget. With some patience, or the right tooling, an attacker can piece together the arguments to a function call, then really call the function.
Chrome has a multi-process architecture -- a main browser process acts as the logged-in user, and spawns restricted renderer and utility processes to host website code. This isolation reduces the severity of a bug in a renderer as its process cannot do much by itself. Attackers will then attempt to use another sandbox escape bug to run code in the browser, which lets them act as the logged-in user. As libraries are mapped at the same address in different processes by Windows, any bug that allows an attacker to read memory is enough for them to examine Chrome’s binary and any loaded libraries for ROP gadgets. This makes preventing ROP chains in the browser process especially useful as a mitigation.
Enter stack-protection. Along with the existing stack, the cpu maintains a shadow stack. This stack cannot be directly manipulated by normal program code and only stores return addresses. The CALL instruction is modified to push a return address (the instruction after the CALL) to both the normal stack, and the shadow stack. The RET (return) instruction still takes its return address from the normal stack, but now verifies that it is the same as the one stored in the shadow stack region. If it is, then the program is left alone and it continues to work as it always did. If the addresses do not match then an exception is raised which is intercepted by the operating system (not by Chrome). The operating system has an opportunity to modify the shadow region and allow the program to continue, but in most cases an address mismatch is the result of a program error so the program is immediately terminated.
In our example above, the attacker will be able to make their initial jump into a ROP gadget, but on trying to return to their next gadget they will be stopped.
Some software may be incompatible with this mechanism, especially some older security software that injects into a process and hooks operating system functions by overwriting the prelude with `rax = &hook; push rax; ret`.
Chrome does not yet support every direction of control flow enforcement. Stack protection enforces the reverse-edge of the call graph but does not constrain the forward-edge. It will still be possible to make indirect jumps around existing code as stack protection is only validated when a return instruction is encountered, and call targets are not validated. On Windows a technology called Control Flow Guard (CFG) can be used to verify the target of an indirect function call before it is attempted. This prevents calling into the middle of a function, significantly reducing the scope of useful instructions for attackers to use. Another approach is provided by Intel’s CET which includes an ENDBRANCH instruction to prevent jumps into arbitrary code locations. Memory tagging tools such as MTE can be used to make it more difficult to modify pointers to valid code sequences (and makes UAFs more difficult in general). We are working to introduce CFG to Chrome for Windows, and will add other techniques over time.
By itself, stack protection can be bypassed in some contexts. For instance, stack protection does not prevent an attacker tricking a program into calling an existing function by entirely replacing an object containing a function pointer. This approach does not involve ROP as the function call happens instead of the expected call, and returns to the address it was originally called from, so must be allowed. However, the called function must be useful to an attacker, and most functions will not be. An example of an attack using this method is to craft a call to add the `--no-sandbox` argument to Chrome’s command line. This results in future renderers being launched without normal protections. Over time we will identify and remove such useful tools.
In the renderer, for performance reasons, our javascript and wasm engines may use memory that is both writable and executable at the same time. This allows an attacker to modify code that v8 is already going to execute, saving them the trouble of constructing a ROP chain. This explains why it was not our first priority to make v8 CET compatible, and why stack-protection is not yet enabled in the renderer.
Finally, stack protection doesn’t stop the bugs in the first place. Everything we have discussed above is a mitigation that makes it more difficult to execute arbitrary code. If a programming error allows arbitrary writes then it is very unlikely that we can prevent this being used to run arbitrary code. Attackers will adapt and find new ways to turn memory safety errors into code execution.
You can see if Hardware-enforced Stack Protection is enabled for a process using the Windows Task Manager. Open task manager, open the Details Tab, Right Click on a heading, Select Columns & Check the Hardware-enforced Stack Protection box. The process display will then indicate if a process is opted-in to this mitigation. ‘Compatible Modules Only’ indicates that any dll marked as /cetcompat at build time will raise an exception if a return address is invalid.
You can see which Chrome processes are opted-out of CET by consulting the Mitigations field of chrome://sandbox and clicking ‘+’. All processes are included unless the mitigation CET_USER_SHADOW_STACKS_ALWAYS_OFF is present in the expanded details view.
If you are developing software, or debugging a problem in Chrome the shadow stack can be helpful as it includes only return addresses, and these cannot be corrupted by rogue writes elsewhere in the process. To see these registers use the `r` command in windbg with the mask option:
0:159> rM 8002
rax=00000000c000060a rbx=000000fa5bbfeff0 rcx=0000000000000030
rdx=0000000000000000 rsi=00007ffba4118924 rdi=000000fa5bbff1a0
rip=00007ffc1847b4a1 rsp=000000fa5bbfc0a0 rbp=000000fa5bbfc0a0
r8=000000fa5bbfc098 r9=0000000000000000 r10=0000000000000000
r11=0000000000000246 r12=000000fa5bbfe230 r13=000002c3450b5830
r14=000002c3450b7850 r15=000000fa5bbfc260
iopl=0 nv up ei pl zr na po nc
ssp=000000fa5c3fef10 cetumsr=0000000000000001
`ssp` points to the shadow stack region, `cetumsr` indicates if cet is enabled for the process.
You can then see the call stack within the shadow region using `dps @ssp`. Values are not overwritten so you can also see where you came from by looking a bit deeper: `dps @ssp-20`.
If a process is not compatible with Hardware-enforced Stack Protection, the system event log (Application Log) will include brief error reports (Id:1001). You can filter those related to cetcompat using the following powershell snippet:-
Get-WinEvent -MaxEvents 128 -FilterHashtable @{ LogName='Application'; Id='1001' } `
| Where-Object {$_.Message -match 'chrome.exe'} `
| Select-Object -First 8 `
| fl
These will include the following parameters:-
P1: application.exe
P2: application version
P3: application build ts
P4: faulting module .dll
P5: faulting module version
P6: faulting module build ts
P7: faulting offset in P4 from base_address
P8: exception code (c0000409)
P9: subcode (00...000030)
If Chrome is misbehaving and you think it might be because of cetcompat, it is possible to disable it using Image File Execution Options - we do not recommend this except for a limited period of testing. If you find you have to do this, please raise an issue on https://crbug.com so that we can investigate the failure.
/cetcompat is enabled for most processes for Chrome M90 on Windows. Enabling Hardware-enforced Stack Protection will layer with existing and future measures to make exploitation more difficult and so more expensive for an attacker, ultimately protecting the people who use Chrome every day.
Providing safe experiences to billions of users and millions of Android developers has been one of the highest priorities for Google Play for many years. Last year we introduced new policies, improved our systems, and further optimized our processes to better protect our users, assist good developers and strengthen our guard against bad apps and developers. Additionally, in 2020, Google Play Protect scanned over 100B installed apps each day for malware across billions of devices.
Users come to Google Play to find helpful, reliable apps on everything from COVID-19 vaccine information to new forms of entertainment, grocery delivery, communication and more.
As such, we introduced a series of policies and new developer support to continue to elevate information quality on the platform and reduce the risk of user harm from misinformation.
Our core efforts around identifying and mitigating bad apps and developers continued to evolve to address new adversarial behaviors and forms of abuse. Our machine-learning detection capabilities and enhanced app review processes prevented over 962k policy-violating app submissions from getting published to Google Play. We also banned 119k malicious and spammy developer accounts. Additionally, we significantly increased our focus on SDK enforcement, as we've found these violations have an outsized impact on security and user data privacy.
Last year, we continued to reduce developer access to sensitive permissions. In February, we announced a new background location policy to ensure that apps requesting this permission need the data in order to provide clear user benefit. As a result of the new policy, developers now have to demonstrate that benefit and prominently tell users about it or face possible removal from Google Play. We've begun enforcement on apps not meeting new policy guidelines and will provide an update on the usage of this permission in a future blog post.
We've also continued to invest in protecting kids and helping parents find great content. In 2020 we launched a new kids tab filled with “Teacher approved” apps. To evaluate apps, we teamed with academic experts and teachers across the country, including our lead advisors, Joe Blatt (Harvard Graduate School of Education) and Dr. Sandra Calvert (Georgetown University).
As we continue to invest in protecting people from apps with harmful content, malicious behaviors, or threats to user privacy, we are also equally motivated to provide trusted experiences to Play developers. For example, we’ve improved our process for providing relevant information about enforcement actions we’ve taken, resulting in significant reduction in appeals and increased developer satisfaction. We will continue to enhance the speed and quality of our communications to developers, and continue listening to feedback about how we can further engage and elevate trusted developers. Android developers can expect to see more on this front in the coming year.
Our global teams of product managers, engineers, policy experts, and operations leaders are more excited than ever to advance the safety of the platform and forge a sustaining trust with our users. We look forward to building an even better Google Play experience.
With all of the challenges from this past year, users have become increasingly dependent on their mobile devices to create fitness routines, stay connected with loved ones, work remotely, and order things like groceries with ease. According to eMarketer, in 2020 users spent over three and a half hours per day using mobile apps. With so much time spent on mobile devices, ensuring the safety of mobile apps is more important than ever. Despite the importance of digital security, there isn’t a consistent industry standard for assessing mobile apps. Existing guidelines tend to be either too lightweight or too onerous for the average developer, and lack a compliance arm. That’s why we're excited to share ioXt’s announcement of a new Mobile Application Profile which provides a set of security and privacy requirements with defined acceptance criteria which developers can certify their apps against.
Over 20 industry stakeholders, including Google, Amazon, and a number of certified labs such as NCC Group and Dekra, as well as automated mobile app security testing vendors like NowSecure collaborated to develop this new security standard for mobile apps. We’ve seen early interest from Internet of Things (IoT) and virtual private network (VPN) developers, however the standard is appropriate for any cloud connected service such as social, messaging, fitness, or productivity apps.
The Internet of Secure Things Alliance (ioXt) manages a security compliance assessment program for connected devices. ioXt has over 300 members across various industries, including Google, Amazon, Facebook, T-Mobile, Comcast, Zigbee Alliance, Z-Wave Alliance, Legrand, Resideo, Schneider Electric, and many others. With so many companies involved, ioXt covers a wide range of device types, including smart lighting, smart speakers, and webcams, and since most smart devices are managed through apps, they have expanded coverage to include mobile apps with the launch of this profile.
The ioXt Mobile Application Profile provides a minimum set of commercial best practices for all cloud connected apps running on mobile devices. This security baseline helps mitigate against common threats and reduces the probability of significant vulnerabilities. The profile leverages existing standards and principles set forth by OWASP MASVS and the VPN Trust Initiative, and allows developers to differentiate security capabilities around cryptography, authentication, network security, and vulnerability disclosure program quality. The profile also provides a framework to evaluate app category specific requirements which may be applied based on the features contained in the app. For example, an IoT app only needs to certify under the Mobile Application profile, whereas a VPN app must comply with the Mobile Application profile, plus the VPN extension.
Certification allows developers to demonstrate product safety and we’re excited about the opportunity for this standard to push the industry forward. We observed that app developers were very quick to resolve any issues that were identified during their blackbox evaluations against this new standard, oftentimes with turnarounds in a matter of days. At launch, the following apps have been certified: Comcast, ExpressVPN, GreenMAX, Hubspace, McAfee Innovations, NordVPN, OpenVPN for Android, Private Internet Access, VPN Private, as well as the Google One app, including VPN by Google One.
We look forward to seeing adoption of the standard grow over time and for those app developers that are already investing in security best practices to be able to highlight their efforts. The standard also serves as a guiding light to inspire more developers to invest in mobile app security. If you are interested in learning more about the ioXt Alliance and how to get your app certified, visit https://compliance.ioxtalliance.org/sign-up and check out Android’s guidelines for building secure apps here.
In our previous post, we announced that Android now supports the Rust programming language for developing the OS itself. Related to this, we are also participating in the effort to evaluate the use of Rust as a supported language for developing the Linux kernel. In this post, we discuss some technical aspects of this work using a few simple examples.
C has been the language of choice for writing kernels for almost half a century because it offers the level of control and predictable performance required by such a critical component. Density of memory safety bugs in the Linux kernel is generally quite low due to high code quality, high standards of code review, and carefully implemented safeguards. However, memory safety bugs do still regularly occur. On Android, vulnerabilities in the kernel are generally considered high-severity because they can result in a security model bypass due to the privileged mode that the kernel runs in.
We feel that Rust is now ready to join C as a practical language for implementing the kernel. It can help us reduce the number of potential bugs and security vulnerabilities in privileged code while playing nicely with the core kernel and preserving its performance characteristics.
We developed an initial prototype of the Binder driver to allow us to make meaningful comparisons between the safety and performance characteristics of the existing C version and its Rust counterpart. The Linux kernel has over 30 million lines of code, so naturally our goal is not to convert it all to Rust but rather to allow new code to be written in Rust. We believe this incremental approach allows us to benefit from the kernel’s existing high-performance implementation while providing kernel developers with new tools to improve memory safety and maintain performance going forward.
We joined the Rust for Linux organization, where the community had already done and continues to do great work toward adding Rust support to the Linux kernel build system. We also need designs that allow code in the two languages to interact with each other: we're particularly interested in safe, zero-cost abstractions that allow Rust code to use kernel functionality written in C, and how to implement functionality in idiomatic Rust that can be called seamlessly from the C portions of the kernel.
Since Rust is a new language for the kernel, we also have the opportunity to enforce best practices in terms of documentation and uniformity. For example, we have specific machine-checked requirements around the usage of unsafe code: for every unsafe function, the developer must document the requirements that need to be satisfied by callers to ensure that its usage is safe; additionally, for every call to unsafe functions (or usage of unsafe constructs like dereferencing a raw pointer), the developer must document the justification for why it is safe to do so.
Just as important as safety, Rust support needs to be convenient and helpful for developers to use. Let’s get into a few examples of how Rust can assist kernel developers in writing drivers that are safe and correct.
We'll use an implementation of a semaphore character device. Each device has a current value; writes of n bytes result in the device value being incremented by n; reads decrement the value by 1 unless the value is 0, in which case they will block until they can decrement the count without going below 0.
Suppose semaphore is a file representing our device. We can interact with it from the shell as follows:
> cat semaphore
When semaphore is a newly initialized device, the command above will block because the device's current value is 0. It will be unblocked if we run the following command from another shell because it increments the value by 1, which allows the original read to complete:
> echo -n a > semaphore
We could also increment the count by more than 1 if we write more data, for example:
> echo -n abc > semaphore
increments the count by 3, so the next 3 reads won't block.
To allow us to show a few more aspects of Rust, we'll add the following features to our driver: remember what the maximum value was throughout the lifetime of a device, and remember how many reads each file issued on the device.
We'll now show how such a driver would be implemented in Rust, contrasting it with a C implementation. We note, however, we are still early on so this is all subject to change in the future. How Rust can assist the developer is the aspect that we'd like to emphasize. For example, at compile time it allows us to eliminate or greatly reduce the chances of introducing classes of bugs, while at the same time remaining flexible and having minimal overhead.
A developer needs to do the following to implement a driver for a new character device in Rust:
The following outlines how the first two steps of our example compare in Rust and C:
impl FileOpener<Arc<Semaphore>> for FileState { fn open( shared: &Arc<Semaphore> ) -> KernelResult<Box<Self>> { [...] } } impl FileOperations for FileState { type Wrapper = Box<Self>; fn read( &self, _: &File, data: &mut UserSlicePtrWriter, offset: u64 ) -> KernelResult<usize> { [...] } fn write( &self, data: &mut UserSlicePtrReader, _offset: u64 ) -> KernelResult<usize> { [...] } fn ioctl( &self, file: &File, cmd: &mut IoctlCommand ) -> KernelResult<i32> { [...] } fn release(_obj: Box<Self>, _file: &File) { [...] } declare_file_operations!(read, write, ioctl); }
static int semaphore_open(struct inode *nodp, struct file *filp) { struct semaphore_state *shared = container_of(filp->private_data, struct semaphore_state, miscdev); [...] } static ssize_t semaphore_write(struct file *filp, const char __user *buffer, size_t count, loff_t *ppos) { struct file_state *state = filp->private_data; [...] } static ssize_t semaphore_read(struct file *filp, char __user *buffer, size_t count, loff_t *ppos) { struct file_state *state = filp->private_data; [...] } static long semaphore_ioctl(struct file *filp, unsigned int cmd, unsigned long arg) { struct file_state *state = filp->private_data; [...] } static int semaphore_release(struct inode *nodp, struct file *filp) { struct file_state *state = filp->private_data; [...] } static const struct file_operations semaphore_fops = { .owner = THIS_MODULE, .open = semaphore_open, .read = semaphore_read, .write = semaphore_write, .compat_ioctl = semaphore_ioctl, .release = semaphore_release, };
Character devices in Rust benefit from a number of safety features:
For a driver to provide a custom ioctl handler, it needs to implement the ioctl function that is part of the FileOperations trait, as exemplified in the table below.
fn ioctl( &self, file: &File, cmd: &mut IoctlCommand ) -> KernelResult<i32> { cmd.dispatch(self, file) } impl IoctlHandler for FileState { fn read( &self, _file: &File, cmd: u32, writer: &mut UserSlicePtrWriter ) -> KernelResult<i32> { match cmd { IOCTL_GET_READ_COUNT => { writer.write( &self .read_count .load(Ordering::Relaxed))?; Ok(0) } _ => Err(Error::EINVAL), } } fn write( &self, _file: &File, cmd: u32, reader: &mut UserSlicePtrReader ) -> KernelResult<i32> { match cmd { IOCTL_SET_READ_COUNT => { self .read_count .store(reader.read()?, Ordering::Relaxed); Ok(0) } _ => Err(Error::EINVAL), } } }
#define IOCTL_GET_READ_COUNT _IOR('c', 1, u64) #define IOCTL_SET_READ_COUNT _IOW('c', 1, u64) static long semaphore_ioctl(struct file *filp, unsigned int cmd, unsigned long arg) { struct file_state *state = filp->private_data; void __user *buffer = (void __user *)arg; u64 value; switch (cmd) { case IOCTL_GET_READ_COUNT: value = atomic64_read(&state->read_count); if (copy_to_user(buffer, &value, sizeof(value))) return -EFAULT; return 0; case IOCTL_SET_READ_COUNT: if (copy_from_user(&value, buffer, sizeof(value))) return -EFAULT; atomic64_set(&state->read_count, value); return 0; default: return -EINVAL; } }
Ioctl commands are standardized such that, given a command, we know whether a user buffer is provided, its intended use (read, write, both, none), and its size. In Rust, we provide a dispatcher (accessible by calling cmd.dispatch) that uses this information to automatically create user memory access helpers and pass them to the caller.
A driver is not required to use this though. If, for example, it doesn't use the standard ioctl encoding, Rust offers the flexibility of simply calling cmd.raw to extract the raw arguments and using them to handle the ioctl (potentially with unsafe code, which will need to be justified).
However, if a driver implementation does use the standard dispatcher, it will benefit from not having to implement any unsafe code, and:
All of the above could potentially also be done in C, but it's very easy for developers to (likely unintentionally) break contracts that lead to unsafety; Rust requires unsafe blocks for this, which should only be used in rare cases and brings additional scrutiny. Additionally, Rust offers the following:
We allow developers to use mutexes and spinlocks to provide interior mutability. In our example, we use a mutex to protect mutable data; in the tables below we show the data structures we use in C and Rust, and how we implement a wait until the count is nonzero so that we can satisfy a read:
struct SemaphoreInner { count: usize, max_seen: usize, } struct Semaphore { changed: CondVar, inner: Mutex<SemaphoreInner>, } struct FileState { read_count: AtomicU64, shared: Arc<Semaphore>, }
struct semaphore_state { struct kref ref; struct miscdevice miscdev; wait_queue_head_t changed; struct mutex mutex; size_t count; size_t max_seen; }; struct file_state { atomic64_t read_count; struct semaphore_state *shared; };
fn consume(&self) -> KernelResult { let mut inner = self.shared.inner.lock(); while inner.count == 0 { if self.shared.changed.wait(&mut inner) { return Err(Error::EINTR); } } inner.count -= 1; Ok(()) }
static int semaphore_consume( struct semaphore_state *state) { DEFINE_WAIT(wait); mutex_lock(&state->mutex); while (state->count == 0) { prepare_to_wait(&state->changed, &wait, TASK_INTERRUPTIBLE); mutex_unlock(&state->mutex); schedule(); finish_wait(&state->changed, &wait); if (signal_pending(current)) return -EINTR; mutex_lock(&state->mutex); } state->count--; mutex_unlock(&state->mutex); return 0; }
We note that such waits are not uncommon in the existing C code, for example, a pipe waiting for a "partner" to write, a unix-domain socket waiting for data, an inode search waiting for completion of a delete, or a user-mode helper waiting for state change.
The following are benefits from the Rust implementation:
In the tables below, we show how open, read, and write are implemented in our example driver:
fn read( &self, _: &File, data: &mut UserSlicePtrWriter, offset: u64 ) -> KernelResult<usize> { if data.is_empty() || offset > 0 { return Ok(0); } self.consume()?; data.write_slice(&[0u8; 1])?; self.read_count.fetch_add(1, Ordering::Relaxed); Ok(1) }
static ssize_t semaphore_read(struct file *filp, char __user *buffer, size_t count, loff_t *ppos) { struct file_state *state = filp->private_data; char c = 0; int ret; if (count == 0 || *ppos > 0) return 0; ret = semaphore_consume(state->shared); if (ret) return ret; if (copy_to_user(buffer, &c, sizeof(c))) return -EFAULT; atomic64_add(1, &state->read_count); *ppos += 1; return 1; }
fn write( &self, data: &mut UserSlicePtrReader, _offset: u64 ) -> KernelResult<usize> { { let mut inner = self.shared.inner.lock(); inner.count = inner.count.saturating_add(data.len()); if inner.count > inner.max_seen { inner.max_seen = inner.count; } } self.shared.changed.notify_all(); Ok(data.len()) }
static ssize_t semaphore_write(struct file *filp, const char __user *buffer, size_t count, loff_t *ppos) { struct file_state *state = filp->private_data; struct semaphore_state *shared = state->shared; mutex_lock(&shared->mutex); shared->count += count; if (shared->count < count) shared->count = SIZE_MAX; if (shared->count > shared->max_seen) shared->max_seen = shared->count; mutex_unlock(&shared->mutex); wake_up_all(&shared->changed); return count; }
fn open( shared: &Arc<Semaphore> ) -> KernelResult<Box<Self>> { Ok(Box::try_new(Self { read_count: AtomicU64::new(0), shared: shared.clone(), })?) }
static int semaphore_open(struct inode *nodp, struct file *filp) { struct semaphore_state *shared = container_of(filp->private_data, struct semaphore_state, miscdev); struct file_state *state; state = kzalloc(sizeof(*state), GFP_KERNEL); if (!state) return -ENOMEM; kref_get(&shared->ref); state->shared = shared; atomic64_set(&state->read_count, 0); filp->private_data = state; return 0; }
They illustrate other benefits brought by Rust:
The examples above are only a small part of the whole project. We hope it gives readers a glimpse of the kinds of benefits that Rust brings. At the moment we have nearly all generic kernel functionality needed by Binder neatly wrapped in safe Rust abstractions, so we are in the process of gathering feedback from the broader Linux kernel community with the intent of upstreaming the existing Rust support.
We also continue to make progress on our Binder prototype, implement additional abstractions, and smooth out some rough edges. This is an exciting time and a rare opportunity to potentially influence how the Linux kernel is developed, as well as inform the evolution of the Rust language. We invite those interested to join us in Rust for Linux and attend our planned talk at Linux Plumbers Conference 2021!
Thanks Nick Desaulniers, Kees Cook, and Adrian Taylor for contributions to this post. Special thanks to Jeff Vander Stoep for contributions and editing, and to Greg Kroah-Hartman for reviewing and contributing to the code examples.
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