1 /*
2  * Copyright (C) 2017 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *      http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 
17 #ifndef ART_RUNTIME_SUBTYPE_CHECK_H_
18 #define ART_RUNTIME_SUBTYPE_CHECK_H_
19 
20 #include "subtype_check_bits_and_status.h"
21 #include "subtype_check_info.h"
22 
23 #include "base/locks.h"
24 #include "mirror/class.h"
25 #include "runtime.h"
26 
27 // Build flag for the bitstring subtype check runtime hooks.
28 constexpr bool kBitstringSubtypeCheckEnabled = false;
29 
30 /**
31  * Any node in a tree can have its path (from the root to the node) represented as a string by
32  * concatenating the path of the parent to that of the current node.
33  *
34  * We can annotate each node with a `sibling-label` which is some value unique amongst all of the
35  * node's siblings. As a special case, the root is empty.
36  *
37  *           (none)
38  *        /    |     \
39  *       A     B      C
40  *     /   \
41  *    A’    B’
42  *          |
43  *          A’’
44  *          |
45  *          A’’’
46  *          |
47  *          A’’’’
48  *
49  * Given these sibling-labels, we can now encode the path from any node to the root by starting at
50  * the node and going up to the root, marking each node with this `path-label`. The special
51  * character $ means "end of path".
52  *
53  *             $
54  *        /    |      \
55  *       A$    B$     C$
56  *     /    \
57  *   A’A$   B’A$
58  *           |
59  *           A’’B’A$
60  *           |
61  *           A’’’A’’B’A$
62  *           |
63  *           A’’’’A’’B’A$
64  *
65  * Given the above `path-label` we can express if any two nodes are an offspring of the other
66  * through a O(1) expression:
67  *
68  *    x <: y :=
69  *      suffix(x, y) == y
70  *
71  * In the above example suffix(x,y) means the suffix of x that is as long as y (right-padded with
72  * $s if x is shorter than y) :
73  *
74  *    suffix(x,y) := x(x.length - y.length .. 0]
75  *                     + repeat($, max(y.length - x.length, 0))
76  *
77  * A few generalities here to elaborate:
78  *
79  * - There can be at most D levels in the tree.
80  * - Each level L has an alphabet A, and the maximum number of
81  *   nodes is determined by |A|
82  * - The alphabet A can be a subset, superset, equal, or unique with respect to the other alphabets
83  *   without loss of generality. (In practice it would almost always be a subset of the previous
84  *   level’s alphabet as we assume most classes have less children the deeper they are.)
85  * - The `sibling-label` doesn’t need to be stored as an explicit value. It can a temporary when
86  *   visiting every immediate child of a node. Only the `path-label` needs to be actually stored for
87  *   every node.
88  *
89  * The path can also be reversed, and use a prefix instead of a suffix to define the subchild
90  * relation.
91  *
92  *             $
93  *        /    |      \    \
94  *       A$    B$     C$    D$
95  *     /    \
96  *   AA’$   AB’$
97  *            |
98  *            AB’A’’$
99  *            |
100  *            AB’A’’A’’’$
101  *            |
102  *            AB’A’’A’’’A’’’’$
103  *
104  *    x <: y :=
105  *      prefix(x, y) == y
106  *
107  *    prefix(x,y) := x[0 .. y.length)
108  *                     + repeat($, max(y.length - x.length, 0))
109  *
110  * In a dynamic tree, new nodes can be inserted at any time. This means if a minimal alphabet is
111  * selected to contain the initial tree hierarchy, later node insertions will be illegal because
112  * there is no more room to encode the path.
113  *
114  * In this simple example with an alphabet A,B,C and max level 1:
115  *
116  *     Level
117  *     0:               $
118  *              /     |     \     \
119  *     1:      A$     B$     C$    D$   (illegal)
120  *              |
121  *     2:      AA$  (illegal)
122  *
123  * Attempting to insert the sibling “D” at Level 1 would be illegal because the Alphabet(1) is
124  * {A,B,C} and inserting an extra node would mean the `sibling-label` is no longer unique.
125  * Attempting to insert “AA$” is illegal because the level 2 is more than the max level 1.
126  *
127  * One solution to this would be to revisit the entire graph, select a larger alphabet to that
128  * every `sibling-label` is unique, pick a larger max level count, and then store the updated
129  * `path-label` accordingly.
130  *
131  * The more common approach would instead be to select a set of alphabets and max levels statically,
132  * with large enough sizes, for example:
133  *
134  *     Alphabets = {{A,B,C,D}, {A,B,C}, {A,B}, {A}}
135  *     Max Levels = |Alphabets|
136  *
137  * Which would allow up to 4 levels with each successive level having 1 less max siblings.
138  *
139  * Attempting to insert a new node into the graph which does not fit into that level’s alphabet
140  * would be represented by re-using the `path-label` of the parent. Such a `path_label` would be
141  * considered truncated (because it would only have a prefix of the full path from the root to the
142  * node).
143  *
144  *    Level
145  *    0:             $
146  *             /     |     \     \
147  *    1:      A$     B$     C$    $   (same as parent)
148  *             |
149  *    2:      A$ (same as parent)
150  *
151  * The updated relation for offspring is then:
152  *
153  *    x <: y :=
154  *      if !truncated_path(y):
155  *        return prefix(x, y) == y               // O(1)
156  *      else:
157  *        return slow_check_is_offspring(x, y)   // worse than O(1)
158  *
159  * (Example definition of truncated_path -- any semantically equivalent way to check that the
160  *  sibling's `sibling-label` is not unique will do)
161  *
162  *    truncated_path(y) :=
163  *      return y == parent(y)
164  *
165  * (Example definition. Any slower-than-O(1) definition will do here. This is the traversing
166  * superclass hierarchy solution)
167  *
168  *    slow_check_is_offspring(x, y) :=
169  *      if not x: return false
170  *      else: return x == y || recursive_is_offspring(parent(x), y)
171  *
172  * In which case slow_check_is_offspring is some non-O(1) way to check if x and is an offspring of y.
173  *
174  * In addition, note that it doesn’t matter if the "x" from above is a unique sibling or not; the
175  * relation will still be correct.
176  *
177  * ------------------------------------------------------------------------------------------------
178  *
179  * Leveraging truncated paths to minimize path lengths.
180  *
181  * As observed above, for any x <: y, it is sufficient to have a full path only for y,
182  * and x can be truncated (to its nearest ancestor's full path).
183  *
184  * We call a node that stores a full path "Assigned", and a node that stores a truncated path
185  * either "Initialized" or "Overflowed."
186  *
187  * "Initialized" means it is still possible to assign a full path to the node, and "Overflowed"
188  * means there is insufficient characters in the alphabet left.
189  *
190  * In this example, assume that we attempt to "Assign" all non-leafs if possible. Leafs
191  * always get truncated (as either Initialized or Overflowed).
192  *
193  *     Alphabets = {{A,B,C,D}, {A,B}}
194  *     Max Levels = |Alphabets|
195  *
196  *    Level
197  *    0:             $
198  *             /     |     \     \     \
199  *    1:      A$     B$     C$    D$    $ (Overflowed: Too wide)
200  *            |             |
201  *    2:     AA$            C$ (Initialized)
202  *            |
203  *    3:     AA$ (Overflowed: Too deep)
204  *
205  * (All un-annotated nodes are "Assigned").
206  * Above, the node at level 3 becomes overflowed because it exceeds the max levels. The
207  * right-most node at level 1 becomes overflowed because there's no characters in the alphabet
208  * left in that level.
209  *
210  * The "C$" node is Initialized at level 2, but it can still be promoted to "Assigned" later on
211  * if we wanted to.
212  *
213  * In particular, this is the strategy we use in our implementation
214  * (SubtypeCheck::EnsureInitialized, SubtypeCheck::EnsureAssigned).
215  *
216  * Since the # of characters in our alphabet (BitString) is very limited, we want to avoid
217  * allocating a character to a node until its absolutely necessary.
218  *
219  * All node targets (in `src <: target`) get Assigned, and any parent of an Initialized
220  * node also gets Assigned.
221  */
222 namespace art {
223 
224 struct MockSubtypeCheck;  // Forward declaration for testing.
225 
226 // This class is using a template parameter to enable testability without losing performance.
227 // ClassPtr is almost always `mirror::Class*` or `ObjPtr<mirror::Class>`.
228 template <typename ClassPtr /* Pointer-like type to Class */>
229 struct SubtypeCheck {
230   // Force this class's SubtypeCheckInfo state into at least Initialized.
231   // As a side-effect, all parent classes also become Assigned|Overflowed.
232   //
233   // Cost: O(Depth(Class))
234   //
235   // Post-condition: State is >= Initialized.
236   // Returns: The precise SubtypeCheckInfo::State.
EnsureInitializedSubtypeCheck237   static SubtypeCheckInfo::State EnsureInitialized(ClassPtr klass)
238       REQUIRES(Locks::subtype_check_lock_)
239       REQUIRES_SHARED(Locks::mutator_lock_) {
240     return InitializeOrAssign(klass, /*assign=*/false).GetState();
241   }
242 
243   // Force this class's SubtypeCheckInfo state into Assigned|Overflowed.
244   // As a side-effect, all parent classes also become Assigned|Overflowed.
245   //
246   // Cost: O(Depth(Class))
247   //
248   // Post-condition: State is Assigned|Overflowed.
249   // Returns: The precise SubtypeCheckInfo::State.
EnsureAssignedSubtypeCheck250   static SubtypeCheckInfo::State EnsureAssigned(ClassPtr klass)
251       REQUIRES(Locks::subtype_check_lock_)
252       REQUIRES_SHARED(Locks::mutator_lock_) {
253     return InitializeOrAssign(klass, /*assign=*/true).GetState();
254   }
255 
256   // Resets the SubtypeCheckInfo into the Uninitialized state.
257   //
258   // Intended only for the AOT image writer.
259   // This is a static function to avoid calling klass.Depth(), which is unsupported
260   // in some portions of the image writer.
261   //
262   // Cost: O(1).
263   //
264   // Returns: A state that is always Uninitialized.
ForceUninitializeSubtypeCheck265   static SubtypeCheckInfo::State ForceUninitialize(ClassPtr klass)
266     REQUIRES(Locks::subtype_check_lock_)
267     REQUIRES_SHARED(Locks::mutator_lock_) {
268     // Trying to do this in a real runtime will break thread safety invariants
269     // of existing live objects in the class hierarchy.
270     // This is only safe as the last step when the classes are about to be
271     // written out as an image and IsSubClass is never used again.
272     DCHECK(Runtime::Current() == nullptr || Runtime::Current()->IsAotCompiler())
273       << "This only makes sense when compiling an app image.";
274 
275     // Directly read/write the class field here.
276     // As this method is used by image_writer on a copy,
277     // the Class* there is not a real class and using it for anything
278     // more complicated (e.g. ObjPtr or Depth call) will fail dchecks.
279 
280     // OK. zero-initializing subtype_check_info_ puts us into the kUninitialized state.
281     SubtypeCheckBits scb_uninitialized = SubtypeCheckBits{};
282     WriteSubtypeCheckBits(klass, scb_uninitialized);
283 
284     // Do not use "SubtypeCheckInfo" API here since that requires Depth()
285     // which would cause a dcheck failure.
286     return SubtypeCheckInfo::kUninitialized;
287   }
288 
289   // Retrieve the state of this class's SubtypeCheckInfo.
290   //
291   // Cost: O(Depth(Class)).
292   //
293   // Returns: The precise SubtypeCheckInfo::State.
GetStateSubtypeCheck294   static SubtypeCheckInfo::State GetState(ClassPtr klass)
295       REQUIRES(Locks::subtype_check_lock_)
296       REQUIRES_SHARED(Locks::mutator_lock_) {
297     return GetSubtypeCheckInfo(klass).GetState();
298   }
299 
300   // Retrieve the path to root bitstring as a plain uintN_t value that is amenable to
301   // be used by a fast check "encoded_src & mask_target == encoded_target".
302   //
303   // Cost: O(Depth(Class)).
304   //
305   // Returns the encoded_src value. Must be >= Initialized (EnsureInitialized).
GetEncodedPathToRootForSourceSubtypeCheck306   static BitString::StorageType GetEncodedPathToRootForSource(ClassPtr klass)
307       REQUIRES(Locks::subtype_check_lock_)
308       REQUIRES_SHARED(Locks::mutator_lock_) {
309     DCHECK_NE(SubtypeCheckInfo::kUninitialized, GetSubtypeCheckInfo(klass).GetState());
310     return GetSubtypeCheckInfo(klass).GetEncodedPathToRoot();
311   }
312 
313   // Retrieve the path to root bitstring as a plain uintN_t value that is amenable to
314   // be used by a fast check "encoded_src & mask_target == encoded_target".
315   //
316   // Cost: O(Depth(Class)).
317   //
318   // Returns the encoded_target value. Must be Assigned (EnsureAssigned).
GetEncodedPathToRootForTargetSubtypeCheck319   static BitString::StorageType GetEncodedPathToRootForTarget(ClassPtr klass)
320       REQUIRES(Locks::subtype_check_lock_)
321       REQUIRES_SHARED(Locks::mutator_lock_) {
322     SubtypeCheckInfo sci = GetSubtypeCheckInfo(klass);
323     DCHECK_EQ(SubtypeCheckInfo::kAssigned, sci.GetState());
324     return sci.GetEncodedPathToRoot();
325   }
326 
327   // Retrieve the path to root bitstring mask as a plain uintN_t value that is amenable to
328   // be used by a fast check "encoded_src & mask_target == encoded_target".
329   //
330   // Cost: O(Depth(Class)).
331   //
332   // Returns the mask_target value. Must be Assigned (EnsureAssigned).
GetEncodedPathToRootMaskSubtypeCheck333   static BitString::StorageType GetEncodedPathToRootMask(ClassPtr klass)
334       REQUIRES(Locks::subtype_check_lock_)
335       REQUIRES_SHARED(Locks::mutator_lock_) {
336     SubtypeCheckInfo sci = GetSubtypeCheckInfo(klass);
337     DCHECK_EQ(SubtypeCheckInfo::kAssigned, sci.GetState());
338     return sci.GetEncodedPathToRootMask();
339   }
340 
341   // Is the source class a subclass of the target?
342   //
343   // The source state must be at least Initialized, and the target state
344   // must be Assigned, otherwise the result will return kUnknownSubtypeOf.
345   //
346   // See EnsureInitialized and EnsureAssigned. Ideally,
347   // EnsureInitialized will be called previously on all possible sources,
348   // and EnsureAssigned will be called previously on all possible targets.
349   //
350   // Runtime cost: O(Depth(Class)), but would be O(1) if depth was known.
351   //
352   // If the result is known, return kSubtypeOf or kNotSubtypeOf.
IsSubtypeOfSubtypeCheck353   static SubtypeCheckInfo::Result IsSubtypeOf(ClassPtr source, ClassPtr target)
354       REQUIRES_SHARED(Locks::mutator_lock_) {
355     SubtypeCheckInfo sci = GetSubtypeCheckInfo(source);
356     SubtypeCheckInfo target_sci = GetSubtypeCheckInfo(target);
357 
358     return sci.IsSubtypeOf(target_sci);
359   }
360 
361   // Print SubtypeCheck bitstring and overflow to a stream (e.g. for oatdump).
DumpSubtypeCheck362   static std::ostream& Dump(ClassPtr klass, std::ostream& os)
363       REQUIRES_SHARED(Locks::mutator_lock_) {
364     return os << GetSubtypeCheckInfo(klass);
365   }
366 
WriteStatusSubtypeCheck367   static void WriteStatus(ClassPtr klass, ClassStatus status)
368       REQUIRES_SHARED(Locks::mutator_lock_) {
369     WriteStatusImpl(klass, status);
370   }
371 
372  private:
GetParentClassSubtypeCheck373   static ClassPtr GetParentClass(ClassPtr klass)
374       REQUIRES_SHARED(Locks::mutator_lock_) {
375     DCHECK(klass->HasSuperClass());
376     return ClassPtr(klass->GetSuperClass());
377   }
378 
InitializeOrAssignSubtypeCheck379   static SubtypeCheckInfo InitializeOrAssign(ClassPtr klass, bool assign)
380       REQUIRES(Locks::subtype_check_lock_)
381       REQUIRES_SHARED(Locks::mutator_lock_) {
382     if (UNLIKELY(!klass->HasSuperClass())) {
383       // Object root always goes directly from Uninitialized -> Assigned.
384 
385       const SubtypeCheckInfo root_sci = GetSubtypeCheckInfo(klass);
386       if (root_sci.GetState() != SubtypeCheckInfo::kUninitialized) {
387         return root_sci;  // No change needed.
388       }
389 
390       const SubtypeCheckInfo new_root_sci = root_sci.CreateRoot();
391       SetSubtypeCheckInfo(klass, new_root_sci);
392 
393       // The object root is always in the Uninitialized|Assigned state.
394       DCHECK_EQ(SubtypeCheckInfo::kAssigned, GetSubtypeCheckInfo(klass).GetState())
395           << "Invalid object root state, must be Assigned";
396       return new_root_sci;
397     }
398 
399     // Force all ancestors to Assigned | Overflowed.
400     ClassPtr parent_klass = GetParentClass(klass);
401     size_t parent_depth = InitializeOrAssign(parent_klass, /*assign=*/true).GetDepth();
402     if (kIsDebugBuild) {
403       SubtypeCheckInfo::State parent_state = GetSubtypeCheckInfo(parent_klass).GetState();
404       DCHECK(parent_state == SubtypeCheckInfo::kAssigned ||
405           parent_state == SubtypeCheckInfo::kOverflowed)
406           << "Expected parent Assigned|Overflowed, but was: " << parent_state;
407     }
408 
409     // Read.
410     SubtypeCheckInfo sci = GetSubtypeCheckInfo(klass, parent_depth + 1u);
411     SubtypeCheckInfo parent_sci = GetSubtypeCheckInfo(parent_klass, parent_depth);
412 
413     // Modify.
414     const SubtypeCheckInfo::State sci_state = sci.GetState();
415     // Skip doing any work if the state is already up-to-date.
416     //   - assign == false -> Initialized or higher.
417     //   - assign == true  -> Assigned or higher.
418     if (sci_state == SubtypeCheckInfo::kUninitialized ||
419         (sci_state == SubtypeCheckInfo::kInitialized && assign)) {
420       // Copy parent path into the child.
421       //
422       // If assign==true, this also appends Parent.Next value to the end.
423       // Then the Parent.Next value is incremented to avoid allocating
424       // the same value again to another node.
425       sci = parent_sci.CreateChild(assign);  // Note: Parent could be mutated.
426     } else {
427       // Nothing to do, already >= Initialized.
428       return sci;
429     }
430 
431     // Post-condition: EnsureAssigned -> Assigned|Overflowed.
432     // Post-condition: EnsureInitialized -> Not Uninitialized.
433     DCHECK_NE(sci.GetState(), SubtypeCheckInfo::kUninitialized);
434 
435     if (assign) {
436       DCHECK_NE(sci.GetState(), SubtypeCheckInfo::kInitialized);
437     }
438 
439     // Write.
440     SetSubtypeCheckInfo(klass, sci);                     // self
441     SetSubtypeCheckInfo(parent_klass, parent_sci);       // parent
442 
443     return sci;
444   }
445 
ReadFieldSubtypeCheck446   static SubtypeCheckBitsAndStatus ReadField(ClassPtr klass)
447       REQUIRES_SHARED(Locks::mutator_lock_) {
448     SubtypeCheckBitsAndStatus current_bits_and_status;
449 
450     int32_t int32_data = klass->GetField32Volatile(klass->StatusOffset());
451     current_bits_and_status.int32_alias_ = int32_data;
452 
453     if (kIsDebugBuild) {
454       SubtypeCheckBitsAndStatus tmp;
455       memcpy(&tmp, &int32_data, sizeof(tmp));
456       DCHECK_EQ(0, memcmp(&tmp, &current_bits_and_status, sizeof(tmp))) << int32_data;
457     }
458     return current_bits_and_status;
459   }
460 
WriteSubtypeCheckBitsSubtypeCheck461   static void WriteSubtypeCheckBits(ClassPtr klass, const SubtypeCheckBits& new_bits)
462       REQUIRES(Locks::subtype_check_lock_)
463       REQUIRES_SHARED(Locks::mutator_lock_) {
464     // Use a "CAS" to write the SubtypeCheckBits in the class.
465     // Although we have exclusive access to the bitstrings, because
466     // ClassStatus and SubtypeCheckBits share the same word, another thread could
467     // potentially overwrite that word still.
468 
469     SubtypeCheckBitsAndStatus new_value;
470     ClassStatus old_status;
471     SubtypeCheckBitsAndStatus full_old;
472     while (true) {
473       // TODO: Atomic compare-and-swap does not update the 'expected' parameter,
474       // so we have to read it as a separate step instead.
475       SubtypeCheckBitsAndStatus old_value = ReadField(klass);
476 
477       {
478         SubtypeCheckBits old_bits = old_value.subtype_check_info_;
479         if (memcmp(&old_bits, &new_bits, sizeof(old_bits)) == 0) {
480           // Avoid dirtying memory when the data hasn't changed.
481           return;
482         }
483       }
484 
485       full_old = old_value;
486       old_status = old_value.status_;
487 
488       new_value = old_value;
489       new_value.subtype_check_info_ = new_bits;
490 
491       if (kIsDebugBuild) {
492         int32_t int32_data = 0;
493         memcpy(&int32_data, &new_value, sizeof(int32_t));
494         DCHECK_EQ(int32_data, new_value.int32_alias_) << int32_data;
495 
496         DCHECK_EQ(old_status, new_value.status_)
497           << "full new: " << bit_cast<uint32_t>(new_value)
498           << ", full old: " << bit_cast<uint32_t>(full_old);
499       }
500 
501       if (CasFieldWeakSequentiallyConsistent32(klass,
502                                                klass->StatusOffset(),
503                                                old_value.int32_alias_,
504                                                new_value.int32_alias_)) {
505         break;
506       }
507     }
508   }
509 
WriteStatusImplSubtypeCheck510   static void WriteStatusImpl(ClassPtr klass, ClassStatus status)
511       REQUIRES_SHARED(Locks::mutator_lock_) {
512     // Despite not having a lock annotation, this is done with mutual exclusion.
513     // See Class::SetStatus for more details.
514     SubtypeCheckBitsAndStatus new_value;
515     ClassStatus old_status;
516     while (true) {
517       // TODO: Atomic compare-and-swap does not update the 'expected' parameter,
518       // so we have to read it as a separate step instead.
519       SubtypeCheckBitsAndStatus old_value = ReadField(klass);
520       old_status = old_value.status_;
521 
522       if (memcmp(&old_status, &status, sizeof(status)) == 0) {
523         // Avoid dirtying memory when the data hasn't changed.
524         return;
525       }
526 
527       new_value = old_value;
528       new_value.status_ = status;
529 
530       if (CasFieldWeakSequentiallyConsistent32(klass,
531                                                klass->StatusOffset(),
532                                                old_value.int32_alias_,
533                                                new_value.int32_alias_)) {
534         break;
535       }
536     }
537   }
538 
CasFieldWeakSequentiallyConsistent32SubtypeCheck539   static bool CasFieldWeakSequentiallyConsistent32(ClassPtr klass,
540                                                    MemberOffset offset,
541                                                    int32_t old_value,
542                                                    int32_t new_value)
543       REQUIRES_SHARED(Locks::mutator_lock_) {
544     if (Runtime::Current() != nullptr && Runtime::Current()->IsActiveTransaction()) {
545       return klass->template CasField32</*kTransactionActive=*/true>(offset,
546                                                                      old_value,
547                                                                      new_value,
548                                                                      CASMode::kWeak,
549                                                                      std::memory_order_seq_cst);
550     } else {
551       return klass->template CasField32</*kTransactionActive=*/false>(offset,
552                                                                       old_value,
553                                                                       new_value,
554                                                                       CASMode::kWeak,
555                                                                       std::memory_order_seq_cst);
556     }
557   }
558 
559   // Get the SubtypeCheckInfo for a klass. O(Depth(Class)) since
560   // it also requires calling klass->Depth.
561   //
562   // Anything calling this function will also be O(Depth(Class)).
GetSubtypeCheckInfoSubtypeCheck563   static SubtypeCheckInfo GetSubtypeCheckInfo(ClassPtr klass)
564         REQUIRES_SHARED(Locks::mutator_lock_) {
565     return GetSubtypeCheckInfo(klass, klass->Depth());
566   }
567 
568   // Get the SubtypeCheckInfo for a klass with known depth.
GetSubtypeCheckInfoSubtypeCheck569   static SubtypeCheckInfo GetSubtypeCheckInfo(ClassPtr klass, size_t depth)
570         REQUIRES_SHARED(Locks::mutator_lock_) {
571     DCHECK_EQ(depth, klass->Depth());
572     SubtypeCheckBitsAndStatus current_bits_and_status = ReadField(klass);
573 
574     const SubtypeCheckInfo current =
575         SubtypeCheckInfo::Create(current_bits_and_status.subtype_check_info_, depth);
576     return current;
577   }
578 
SetSubtypeCheckInfoSubtypeCheck579   static void SetSubtypeCheckInfo(ClassPtr klass, const SubtypeCheckInfo& new_sci)
580         REQUIRES(Locks::subtype_check_lock_)
581         REQUIRES_SHARED(Locks::mutator_lock_) {
582     SubtypeCheckBits new_bits = new_sci.GetSubtypeCheckBits();
583     WriteSubtypeCheckBits(klass, new_bits);
584   }
585 
586   // Tests can inherit this class. Normal code should use static methods.
587   SubtypeCheck() = default;
588   SubtypeCheck(const SubtypeCheck& other) = default;
589   SubtypeCheck(SubtypeCheck&& other) = default;
590   ~SubtypeCheck() = default;
591 
592   friend struct MockSubtypeCheck;
593 };
594 
595 }  // namespace art
596 
597 #endif  // ART_RUNTIME_SUBTYPE_CHECK_H_
598