Runtime Lock Validation in Zircon

Introduction

Zircon integrates a runtime lock validator to diagnose inconsistent lock ordering that could lead to deadlocks. This document discusses how the validator is integrated, how to enable and tune the validator at build time, and what output the validator produces.

The theory of operation for the validator itself can be found in the design document.

Enabling the Lock Validator

Lock validation is disabled by default. When disabled the lock instrumentation is transparent, acting as a zero-overhead wrapper for the underlying locking primitives.

The validator is enabled at compile time by setting the GN build argument enable_lock_dep to true. As of this writing logic for this variable is handled by zircon/kernel/BUILD.gn.

You can set this variable in your GN invocation like this:

fx set <your build options> --args 'enable_lock_dep = true'

When the lock validator is enabled a set of global lock-free, wait-free data structures are generated to track the relationships between the instrumented locks. The acquire/release operations of the locks are augmented to update these data structures.

Lock Instrumentation

The current incarnation of the runtime lock validator requires manually instrumenting each lock in kernel with a wrapper type. The wrapper type provides the context the validator needs to properly identify the lock and generate a global tracking structure for locks with the same context or role.

The kernel defines utility macros for this purpose in kernel/spinlock.h and kernel/mutex.h.

Member Locks

A type with a lock member like this:

#include <kernel/mutex.h>

class MyType {
public:
    // ...
private:
    mutable fbl::Mutex lock_;
    // ...
};

May be instrumented like this:

#include <kernel/mutex.h>

class MyType {
public:
    // ...
private:
    mutable DECLARE_MUTEX(MyType) lock_;
    // ...
};

Note that the containing type is passed to the macro DECLARE_MUTEX(containing_type). This type provides the context the validator needs to distinguish locks that are members of MyType from locks that are members of other types.

The macro DECLARE_SPINLOCK(containing_type) provides similar support for instrumenting SpinLock members.

For those who are curious, the macro in the example above expands to this type expression: ::lockdep::LockDep<containing_type, fbl::Mutex, __LINE__>. This expression results in a unique instantiation of the lockdep::LockDep<> type, both across different containing types, and within a containing type where there is more than one mutex.

Global Locks

Global locks are instrumented using a singleton-type pattern. The kernel defines utility macros for this purpose in kernel/mutex.h and kernel/spinlock.h.

In Zircon global locks are typically defined either at global/namespace scope or within another type as a static member.

example.h:

#include <kernel/mutex.h>

extern fbl::Mutex a_global_lock;

class MyType {
public:
    // ...
private:
    static fbl::Mutex all_objects_lock_;
};

example.cpp:

#include "example.h"

fbl::Mutex a_global_lock;

fbl::Mutex MyType::all_objects_lock_;

The instrumentation simplifies declaring locks by declaring singleton types that may be used in either scope and handles ODR-use automatically.

example.h:

#include <kernel/mutex.h>

DECLARE_SINGLETON_MUTEX(AGlobalLock);

class MyType {
public:
    // ...
private:
    DECLARE_SINGLETON_MUTEX(AllObjectsLock);
};

These macro invocations declare new singleton types, AGlobalLock and MyType::AllObjectsLock respectively. These types have a static Get() method that returns the underlying global lock with all of the necessary instrumentation. Note that there is no need to separately define storage for the locks, this is handled automatically by the supporting template types.

The macro DECLARE_SINGLETON_SPINLOCK(name) provides similar support for declaring a global SpinLock.

Lock Guards

Instrumented locks are acquired and released using the scoped capability types Guard and GuardMultiple. In the kernel these types are defined in kernel/lockdep.h.

The operation of Guard for simple mutexes is similar to AutoLock:

#include <kernel/mutex.h>

class MyType {
public:
    // ...

    int GetData() const {
        Guard<fbl::Mutex> guard{&lock_};
        return data_;
    }

    int DoSomething() {
        Guard<fbl::Mutex> guard{&lock_};
        int data_copy = data_;
        guard.Release();

        return DoWorkUnlocked(data_copy);
    }

private:
    mutable DECLARE_MUTEX(MyType) lock_;
    int data_{0} TA_GUARDED(lock_);
};

SpinLock types require an additional template argument to Guard to select one of a few possible options when acquiring the lock: IrqSave, NoIrqSave, and TryLockNoIrqSave. Omitting one of these type tags results in a compile-time error.

#include <kernel/spinlock.h>

class MyType {
public:
    // ...

    int GetData() const {
        Guard<SpinLock, IrqSave> guard{&lock_};
        return data_;
    }

    void DoSomethingInIrqContext() {
        Guard<SpinLock, NoIrqSave> guard{&lock_};
        // ...
    }

    bool TryToDoSomethingInIrqContext() {
        if (Guard<SpinLock, TryLockNoIrqSave> guard{&lock_}) {
            // ...
            return true;
        }
        return false;
    }

private:
    mutable DECLARE_SPINLOCK(MyType) lock_;
    int data_{0} TA_GUARDED(lock_);
};

Instrumented global locks work similarly:

#include <kernel/mutex.h>
#include <fbl/intrusive_double_list.h>

class MyType : public fbl::DoublyLinkedListable<MyType> {
public:
    // ...

    void AddToList(MyType* object) {
        Guard<fbl::Mutex> guard{AllObjectsLock::Get()};
        all_objects_list_.push_back(*object);
    }

private:
    DECLARE_SINGLETON_MUTEX(AllObjectsLock);
    fbl::DoublyLinkedList<MyType> all_objects_list_ TA_GUARDED(AllObjectsLock::Get());
};

Note that instrumented locks do not have manual Acquire() and Release() methods; using a Guard is the only way to acquire the locks directly. There are two important reasons for this:

  1. Manual acquire/release operations are more error prone than guard, plus manual release when necessary.
  2. When lock validation is enabled the guard provides the storage that the validator uses to account for actively held locks. This approach permits temporary storage of validator state on the stack only for the duration the lock is held, which corresponds with the use patterns of guard objects. Without this approach the tracking data would either have to be stored with each lock instance, increasing memory use even when locks are not held, or stored in heap allocated memory. Neither of these alternatives is desirable.

In rare circumstances the underlying lock may be accessed using the lock() accessor of the instrumented lock. This should be done with care as manipulating the underlying lock directly may result inconsistency between the state of the lock and the state the lock validator; at best this may lead to missing a lock order warning and at worst may lead to a deadlock. You have been warned!

Clang Static Analysis and Instrumented Locks

The lock instrumentation is designed to interoperate with Clang static lock analysis. In general usage, an instrumented lock may be used as a "mutex" capability and specified in any of the static lock annotations.

There are two special cases that need some extra attention:

  1. Returning pointers or references to capabilities.
  2. Unlocking a guard passed by reference.

Pointers and References to Capabilities

When returning a lock by pointer or reference it may be convenient or necessary to use a uniform type. Recall from earlier that instrumented locks are wrapped in a type that captures the containing type, the underlying lock type, and the line number to disambiguate locks belonging to different types (::lockdep::LockDep<Class, Locktype, Index>). This can lead to difficulty when returning a lock from a uniform (virtual) interface (e.g. kernel Dispatcher::get_lock()).

Fortunately there is a straightforward solution: every instrumented lock is also a subclass of ::lockdep::Lock<LockType> (or simply Lock<LockType> in the kernel). This type only depends on the underlying LockType, not the context in which the instrumented lock is declared, making it convenient to use as a pointer or reference type to refer to an instrumented lock more generically. This type may be used in type annotations as well.

The following illustrates the pattern, which is similar to that employed by the kernel Dispatcher types.

#include <kernel/mutex.h>


struct LockableInterface {
    virtual ~LockableInterface() {}
    virtual Lock<fbl::Mutex>* get_lock() = 0;
    virtual void DoSomethingLocked() TA_REQ(get_lock()) = 0;
};

class A : public LockableInterface {
public:
    Lock<fbl::Mutex>* get_lock() override { return &lock_; }
    void DoSomethingLocked() override {
        data_++;
    }
    void DoSomething() {
        Guard<fbl::Mutex> guard{get_lock()};
        DoSomethingLocked();
        // ...
    }
private:
    mutable DECLARE_MUTEX(A) lock_;
    int data_ TA_GUARDED(get_lock());
};

class B : public LockableInterface {
public:
    Lock<fbl::Mutex>* get_lock() override { return &lock_; }
    void DoSomethingLocked() override {
        // ...
    }
    void DoSomething() {
        Guard<fbl::Mutex> guard{get_lock()};
        DoSomethingLocked();
        // ...
    }
private:
    mutable DECLARE_MUTEX(B) lock_;
    char data_[32] TA_GUARDED(get_lock());
};

Note that the type of A::lock_ is ::lockdep::LockDep<A, fbl::Mutex, __LINE__> and the type of B::lock_ is ::lockdep::LockDep<B, fbl::Mutex, __LINE__>. However, both of these types are subclasses of Lock<fbl::Mutex>, so we can treat them uniformly as this type in pointer and reference expressions.

While this is very convenient, a limitation in Clang static analysis prevents it from understanding that LockableInterface::get_lock() is equivalent to A::lock_ or B::lock_, even in their local contexts. For this reason is it necessary to use get_lock() in all of the lock annotations.

Unlocking a Guard Passed by Reference

In very rare circumstances it is useful to release a Guard instance held in a function from a callee of the function.

TODO(eieio): Complete documentation of this feature.

Lock Validation Errors

The lock validator detects and reports two broad classes of violations:

  1. Pair-wise violations reported at the point of acquisition.
  2. Multi-lock cycles reported asynchronously by a dedicated loop detection thread.

Violations Reported at Acquisition

When a violation is detected at the point of lock acquisition the validator produces a message like the following in the kernel log:

[00002.668] 01032:01039> ZIRCON KERNEL OOPS
[00002.668] 01032:01039> Lock validation failed for thread 0xffff000001e53598 pid 1032 tid 1039 (userboot:userboot):
[00002.668] 01032:01039> Reason: Out Of Order
[00002.668] 01032:01039> Bad lock: name=lockdep::LockClass<SoloDispatcher<ThreadDispatcher, 316111>, Mutex, 282, (lockdep::LockFlags)0> order=0
[00002.668] 01032:01039> Conflict: name=lockdep::LockClass<SoloDispatcher<ProcessDispatcher, 447439>, Mutex, 282, (lockdep::LockFlags)0> order=0
[00002.668] 01032:01039> {{{module:0:kernel:elf:0bf16acb54de1ceef7ffb6ee4449c6aafc0ab392}}}
[00002.668] 01032:01039> {{{mmap:0xffffffff10000000:0x1ae1f0:load:0:rx:0xffffffff00000000}}}
[00002.668] 01032:01039> {{{mmap:0xffffffff101af000:0x49000:load:0:r:0xffffffff001af000}}}
[00002.668] 01032:01039> {{{mmap:0xffffffff101f8000:0x1dc8:load:0:rw:0xffffffff001f8000}}}
[00002.668] 01032:01039> {{{mmap:0xffffffff10200000:0x76000:load:0:rw:0xffffffff00200000}}}
[00002.668] 01032:01039> {{{bt:0:0xffffffff10088574}}}
[00002.668] 01032:01039> {{{bt:1:0xffffffff1008f324}}}
[00002.668] 01032:01039> {{{bt:2:0xffffffff10162860}}}
[00002.668] 01032:01039> {{{bt:3:0xffffffff101711e0}}}
[00002.668] 01032:01039> {{{bt:4:0xffffffff100edae0}}}

The error is informational and non-fatal. The first line identifies the thread and process where the kernel lock violation occurred. The next line identifies the type of violation. The next two lines identify which locks were found to be inconsistent with previous observations: the "Bad lock" is the lock that is about to be acquired, while "Conflict" is a lock that is already held by the current context and is the point of inconsistency with the lock that is about to be acquired. All of the lines following this are part of the stack trace leading up to the bad lock.

Multi-Lock Cycles

Circular dependencies between three or more locks are detected with a dedicated loop detection thread. Because this detection happens in a separate context from the lock operations that caused the cycle a stack trace is not provided.

Reports from the loop detection thread look like this:

[00002.000] 00000.00000> ZIRCON KERNEL OOPS
[00002.000] 00000.00000> Circular lock dependency detected:
[00002.000] 00000.00000>   lockdep::LockClass<VmObject, fbl::Mutex, 249, (lockdep::LockFlags)0>
[00002.000] 00000.00000>   lockdep::LockClass<VmAspace, fbl::Mutex, 198, (lockdep::LockFlags)0>
[00002.000] 00000.00000>   lockdep::LockClass<SoloDispatcher<VmObjectDispatcher>, fbl::Mutex, 362, (lockdep::LockFlags)0>
[00002.000] 00000.00000>   lockdep::LockClass<SoloDispatcher<PortDispatcher>, fbl::Mutex, 362, (lockdep::LockFlags)0>

Each of the locks involved in the cycle are reported in a group. Frequently only two of the circularly-dependent locks are acquired by a single thread at any given time, making manual detection difficult or impossible. However, the potential for deadlock between three or more threads is real and should be addressed for long-term system stability.

Kernel Commands

When the lock validator is enabled the following kernel commands are available:

  • k lockdep dump - dumps the dependency graph and connected sets (loops) for all instrumented locks.
  • k lockdep loop - triggers a loop detection pass and reports any loops found to the kernel log.