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1Runtime locking correctness validator
2=====================================
3
4started by Ingo Molnar <mingo@redhat.com>
5additions by Arjan van de Ven <arjan@linux.intel.com>
6
7Lock-class
8----------
9
10The basic object the validator operates upon is a 'class' of locks.
11
12A class of locks is a group of locks that are logically the same with
13respect to locking rules, even if the locks may have multiple (possibly
14tens of thousands of) instantiations. For example a lock in the inode
15struct is one class, while each inode has its own instantiation of that
16lock class.
17
18The validator tracks the 'state' of lock-classes, and it tracks
19dependencies between different lock-classes. The validator maintains a
20rolling proof that the state and the dependencies are correct.
21
22Unlike an lock instantiation, the lock-class itself never goes away: when
23a lock-class is used for the first time after bootup it gets registered,
24and all subsequent uses of that lock-class will be attached to this
25lock-class.
26
27State
28-----
29
30The validator tracks lock-class usage history into 5 separate state bits:
31
32- 'ever held in hardirq context' [ == hardirq-safe ]
33- 'ever held in softirq context' [ == softirq-safe ]
34- 'ever held with hardirqs enabled' [ == hardirq-unsafe ]
35- 'ever held with softirqs and hardirqs enabled' [ == softirq-unsafe ]
36
37- 'ever used' [ == !unused ]
38
39Single-lock state rules:
40------------------------
41
42A softirq-unsafe lock-class is automatically hardirq-unsafe as well. The
43following states are exclusive, and only one of them is allowed to be
44set for any lock-class:
45
46 <hardirq-safe> and <hardirq-unsafe>
47 <softirq-safe> and <softirq-unsafe>
48
49The validator detects and reports lock usage that violate these
50single-lock state rules.
51
52Multi-lock dependency rules:
53----------------------------
54
55The same lock-class must not be acquired twice, because this could lead
56to lock recursion deadlocks.
57
58Furthermore, two locks may not be taken in different order:
59
60 <L1> -> <L2>
61 <L2> -> <L1>
62
63because this could lead to lock inversion deadlocks. (The validator
64finds such dependencies in arbitrary complexity, i.e. there can be any
65other locking sequence between the acquire-lock operations, the
66validator will still track all dependencies between locks.)
67
68Furthermore, the following usage based lock dependencies are not allowed
69between any two lock-classes:
70
71 <hardirq-safe> -> <hardirq-unsafe>
72 <softirq-safe> -> <softirq-unsafe>
73
74The first rule comes from the fact the a hardirq-safe lock could be
75taken by a hardirq context, interrupting a hardirq-unsafe lock - and
76thus could result in a lock inversion deadlock. Likewise, a softirq-safe
77lock could be taken by an softirq context, interrupting a softirq-unsafe
78lock.
79
80The above rules are enforced for any locking sequence that occurs in the
81kernel: when acquiring a new lock, the validator checks whether there is
82any rule violation between the new lock and any of the held locks.
83
84When a lock-class changes its state, the following aspects of the above
85dependency rules are enforced:
86
87- if a new hardirq-safe lock is discovered, we check whether it
88 took any hardirq-unsafe lock in the past.
89
90- if a new softirq-safe lock is discovered, we check whether it took
91 any softirq-unsafe lock in the past.
92
93- if a new hardirq-unsafe lock is discovered, we check whether any
94 hardirq-safe lock took it in the past.
95
96- if a new softirq-unsafe lock is discovered, we check whether any
97 softirq-safe lock took it in the past.
98
99(Again, we do these checks too on the basis that an interrupt context
100could interrupt _any_ of the irq-unsafe or hardirq-unsafe locks, which
101could lead to a lock inversion deadlock - even if that lock scenario did
102not trigger in practice yet.)
103
104Exception: Nested data dependencies leading to nested locking
105-------------------------------------------------------------
106
107There are a few cases where the Linux kernel acquires more than one
108instance of the same lock-class. Such cases typically happen when there
109is some sort of hierarchy within objects of the same type. In these
110cases there is an inherent "natural" ordering between the two objects
111(defined by the properties of the hierarchy), and the kernel grabs the
112locks in this fixed order on each of the objects.
113
114An example of such an object hieararchy that results in "nested locking"
115is that of a "whole disk" block-dev object and a "partition" block-dev
116object; the partition is "part of" the whole device and as long as one
117always takes the whole disk lock as a higher lock than the partition
118lock, the lock ordering is fully correct. The validator does not
119automatically detect this natural ordering, as the locking rule behind
120the ordering is not static.
121
122In order to teach the validator about this correct usage model, new
123versions of the various locking primitives were added that allow you to
124specify a "nesting level". An example call, for the block device mutex,
125looks like this:
126
127enum bdev_bd_mutex_lock_class
128{
129 BD_MUTEX_NORMAL,
130 BD_MUTEX_WHOLE,
131 BD_MUTEX_PARTITION
132};
133
134 mutex_lock_nested(&bdev->bd_contains->bd_mutex, BD_MUTEX_PARTITION);
135
136In this case the locking is done on a bdev object that is known to be a
137partition.
138
139The validator treats a lock that is taken in such a nested fasion as a
140separate (sub)class for the purposes of validation.
141
142Note: When changing code to use the _nested() primitives, be careful and
143check really thoroughly that the hiearchy is correctly mapped; otherwise
144you can get false positives or false negatives.
145
146Proof of 100% correctness:
147--------------------------
148
149The validator achieves perfect, mathematical 'closure' (proof of locking
150correctness) in the sense that for every simple, standalone single-task
151locking sequence that occured at least once during the lifetime of the
152kernel, the validator proves it with a 100% certainty that no
153combination and timing of these locking sequences can cause any class of
154lock related deadlock. [*]
155
156I.e. complex multi-CPU and multi-task locking scenarios do not have to
157occur in practice to prove a deadlock: only the simple 'component'
158locking chains have to occur at least once (anytime, in any
159task/context) for the validator to be able to prove correctness. (For
160example, complex deadlocks that would normally need more than 3 CPUs and
161a very unlikely constellation of tasks, irq-contexts and timings to
162occur, can be detected on a plain, lightly loaded single-CPU system as
163well!)
164
165This radically decreases the complexity of locking related QA of the
166kernel: what has to be done during QA is to trigger as many "simple"
167single-task locking dependencies in the kernel as possible, at least
168once, to prove locking correctness - instead of having to trigger every
169possible combination of locking interaction between CPUs, combined with
170every possible hardirq and softirq nesting scenario (which is impossible
171to do in practice).
172
173[*] assuming that the validator itself is 100% correct, and no other
174 part of the system corrupts the state of the validator in any way.
175 We also assume that all NMI/SMM paths [which could interrupt
176 even hardirq-disabled codepaths] are correct and do not interfere
177 with the validator. We also assume that the 64-bit 'chain hash'
178 value is unique for every lock-chain in the system. Also, lock
179 recursion must not be higher than 20.
180
181Performance:
182------------
183
184The above rules require _massive_ amounts of runtime checking. If we did
185that for every lock taken and for every irqs-enable event, it would
186render the system practically unusably slow. The complexity of checking
187is O(N^2), so even with just a few hundred lock-classes we'd have to do
188tens of thousands of checks for every event.
189
190This problem is solved by checking any given 'locking scenario' (unique
191sequence of locks taken after each other) only once. A simple stack of
192held locks is maintained, and a lightweight 64-bit hash value is
193calculated, which hash is unique for every lock chain. The hash value,
194when the chain is validated for the first time, is then put into a hash
195table, which hash-table can be checked in a lockfree manner. If the
196locking chain occurs again later on, the hash table tells us that we
197dont have to validate the chain again.