1 /*
2  * Copyright (C) 2015 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_LIBARTBASE_BASE_VARIANT_MAP_H_
18 #define ART_LIBARTBASE_BASE_VARIANT_MAP_H_
19 
20 #include <memory.h>
21 #include <map>
22 #include <type_traits>
23 #include <utility>
24 
25 #include "android-base/logging.h"
26 #include "stl_util_identity.h"
27 
28 namespace art {
29 
30 //
31 // A variant map is a heterogenous, type safe key->value map. It allows
32 // for multiple different value types to be stored dynamically in the same map.
33 //
34 // It provides the following interface in a nutshell:
35 //
36 // struct VariantMap {
37 //   template <typename TValue>
38 //   TValue* Get(Key<T> key);  // null if the value was never set, otherwise the value.
39 //
40 //   template <typename TValue>
41 //   void Set(Key<T> key, TValue value);
42 // };
43 //
44 // Since the key is strongly typed at compile-time, it is impossible to accidentally
45 // read/write a value with a different type than the key at either compile-time or run-time.
46 //
47 // Do not use VariantMap/VariantMapKey directly. Instead subclass each of them and use
48 // the subclass, for example:
49 //
50 // template <typename TValue>
51 // struct FruitMapKey : VariantMapKey<TValue> {
52 //   FruitMapKey() {}
53 // };
54 //
55 // struct FruitMap : VariantMap<FruitMap, FruitMapKey> {
56 //   // This 'using' line is necessary to inherit the variadic constructor.
57 //   using VariantMap<FruitMap, FruitMapKey>::VariantMap;
58 //
59 //   // Make the next '4' usages of Key slightly shorter to type.
60 //   template <typename TValue>
61 //   using Key = FruitMapKey<TValue>;
62 //
63 //   static const Key<int> Apple;
64 //   static const Key<double> Orange;
65 //   static const Key<std::string> Banana;
66 // };
67 //
68 // const FruitMap::Key<int> FruitMap::Apple;
69 // const FruitMap::Key<double> FruitMap::Orange;
70 // const FruitMap::Key<std::string> Banana;
71 //
72 // See variant_map_test.cc for more examples.
73 //
74 
75 // Implementation details for VariantMap.
76 namespace detail {
77 // Allocate a unique counter value each time it's called.
78 struct VariantMapKeyCounterAllocator {
AllocateCounterVariantMapKeyCounterAllocator79   static size_t AllocateCounter() {
80     static size_t counter = 0;
81     counter++;
82 
83     return counter;
84   }
85 };
86 
87 // Type-erased version of VariantMapKey<T>
88 struct VariantMapKeyRaw {
89   // TODO: this may need to call a virtual function to support string comparisons
90   bool operator<(const VariantMapKeyRaw& other) const {
91     return key_counter_ < other.key_counter_;
92   }
93 
94   // The following functions need to be virtual since we don't know the compile-time type anymore:
95 
96   // Clone the key, creating a copy of the contents.
97   virtual VariantMapKeyRaw* Clone() const = 0;
98 
99   // Delete a value whose runtime type is that of the non-erased key's TValue.
100   virtual void ValueDelete(void* value) const = 0;
101 
102   // Clone a value whose runtime type is that of the non-erased key's TValue.
103   virtual void* ValueClone(void* value) const = 0;
104 
105   // Compare one key to another (same as operator<).
CompareVariantMapKeyRaw106   virtual bool Compare(const VariantMapKeyRaw* other) const {
107     if (other == nullptr) {
108       return false;
109     }
110     return key_counter_ < other->key_counter_;
111   }
112 
~VariantMapKeyRawVariantMapKeyRaw113   virtual ~VariantMapKeyRaw() {}
114 
115  protected:
VariantMapKeyRawVariantMapKeyRaw116   VariantMapKeyRaw()
117       : key_counter_(VariantMapKeyCounterAllocator::AllocateCounter()) {}
118   // explicit VariantMapKeyRaw(size_t counter)
119   //     : key_counter_(counter) {}
120 
GetCounterVariantMapKeyRaw121   size_t GetCounter() const {
122     return key_counter_;
123   }
124 
125  protected:
126   // Avoid the object slicing problem; use Clone() instead.
127   VariantMapKeyRaw(const VariantMapKeyRaw&) = default;
128   VariantMapKeyRaw(VariantMapKeyRaw&&) = default;
129 
130  private:
131   size_t key_counter_;  // Runtime type ID. Unique each time a new type is reified.
132 };
133 }  // namespace detail
134 
135 // The base type for keys used by the VariantMap. Users must subclass this type.
136 template <typename TValue>
137 struct VariantMapKey : detail::VariantMapKeyRaw {
138   // Instantiate a default value for this key. If an explicit default value was provided
139   // then that is used. Otherwise, the default value for the type TValue{} is returned.
CreateDefaultValueVariantMapKey140   TValue CreateDefaultValue() const {
141     if (default_value_ == nullptr) {
142       return TValue{};
143     } else {
144       return TValue(*default_value_);
145     }
146   }
147 
148  protected:
149   // explicit VariantMapKey(size_t counter) : detail::VariantMapKeyRaw(counter) {}
VariantMapKeyVariantMapKey150   explicit VariantMapKey(const TValue& default_value)
151     : default_value_(std::make_shared<TValue>(default_value)) {}
VariantMapKeyVariantMapKey152   explicit VariantMapKey(TValue&& default_value)
153     : default_value_(std::make_shared<TValue>(default_value)) {}
VariantMapKeyVariantMapKey154   VariantMapKey() {}
~VariantMapKeyVariantMapKey155   virtual ~VariantMapKey() {}
156 
157  private:
CloneVariantMapKey158   virtual VariantMapKeyRaw* Clone() const {
159     return new VariantMapKey<TValue>(*this);
160   }
161 
ValueCloneVariantMapKey162   virtual void* ValueClone(void* value) const {
163     if (value == nullptr) {
164       return nullptr;
165     }
166 
167     TValue* strong_value = reinterpret_cast<TValue*>(value);
168     return new TValue(*strong_value);
169   }
170 
ValueDeleteVariantMapKey171   virtual void ValueDelete(void* value) const {
172     if (value == nullptr) {
173       return;
174     }
175 
176     // Smartly invoke the proper delete/delete[]/etc
177     const std::default_delete<TValue> deleter = std::default_delete<TValue>();
178     deleter(reinterpret_cast<TValue*>(value));
179   }
180 
181   VariantMapKey(const VariantMapKey&) = default;
182   VariantMapKey(VariantMapKey&&) = default;
183 
184   template <typename Base, template <typename TV> class TKey> friend struct VariantMap;
185 
186   // Store a prototype of the key's default value, for usage with VariantMap::GetOrDefault
187   std::shared_ptr<TValue> default_value_;
188 };
189 
190 // Implementation details for a stringified VariantMapStringKey.
191 namespace detail {
192 struct VariantMapStringKeyRegistry {
193   // TODO
194 };
195 }  // namespace detail
196 
197 // Alternative base type for all keys used by VariantMap, supports runtime strings as the name.
198 template <typename TValue>
199 struct VariantMapStringKey : VariantMapKey<TValue> {
VariantMapStringKeyVariantMapStringKey200   explicit VariantMapStringKey(const char* name)
201       :   // VariantMapKey(/*std::hash<std::string>()(name)*/),
202         name_(name) {
203   }
204 
205  private:
206   const char* name_;
207 };
208 
209 // A variant map allows type-safe heteregeneous key->value mappings.
210 // All possible key types must be specified at compile-time. Values may be added/removed
211 // at runtime.
212 template <typename Base, template <typename TV> class TKey>
213 struct VariantMap {
214   // Allow users of this static interface to use the key type.
215   template <typename TValue>
216   using Key = TKey<TValue>;
217 
218   // Look up the value from the key. The pointer becomes invalid if this key is overwritten/removed.
219   // A null value is returned only when the key does not exist in this map.
220   template <typename TValue>
GetVariantMap221   const TValue* Get(const TKey<TValue>& key) const {
222     return GetValuePtr(key);
223   }
224 
225   // Look up the value from the key. The pointer becomes invalid if this key is overwritten/removed.
226   // A null value is returned only when the key does not exist in this map.
227   template <typename TValue>
GetVariantMap228   TValue* Get(const TKey<TValue>& key) {
229     return GetValuePtr(key);
230   }
231 
232   // Lookup the value from the key. If it was not set in the map, return the default value.
233   // The default value is either the key's default, or TValue{} if the key doesn't have a default.
234   template <typename TValue>
GetOrDefaultVariantMap235   TValue GetOrDefault(const TKey<TValue>& key) const {
236     auto* ptr = Get(key);
237     return (ptr == nullptr) ? key.CreateDefaultValue() : *ptr;
238   }
239 
240   template <typename T, typename U>
AssignIfExistsVariantMap241   void AssignIfExists(const TKey<T>& key, U* out) {
242     DCHECK(out != nullptr);
243     if (Exists(key)) {
244       *out = std::move(*Get(key));
245     }
246   }
247 
248  private:
249   // TODO: move to detail, or make it more generic like a ScopeGuard(function)
250   template <typename TValue>
251   struct ScopedRemove {
ScopedRemoveVariantMap::ScopedRemove252     ScopedRemove(VariantMap& map, const TKey<TValue>& key) : map_(map), key_(key) {}
~ScopedRemoveVariantMap::ScopedRemove253     ~ScopedRemove() {
254       map_.Remove(key_);
255     }
256 
257     VariantMap& map_;
258     const TKey<TValue>& key_;
259   };
260 
261  public:
262   // Release the value from the key. If it was not set in the map, returns the default value.
263   // If the key was set, it is removed as a side effect.
264   template <typename TValue>
ReleaseOrDefaultVariantMap265   TValue ReleaseOrDefault(const TKey<TValue>& key) {
266     ScopedRemove<TValue> remove_on_return(*this, key);
267 
268     TValue* ptr = Get(key);
269     if (ptr != nullptr) {
270       return std::move(*ptr);
271     } else {
272       return key.CreateDefaultValue();
273     }
274   }
275 
276   // See if a value is stored for this key.
277   template <typename TValue>
ExistsVariantMap278   bool Exists(const TKey<TValue>& key) const {
279     return GetKeyValueIterator(key) != storage_map_.end();
280   }
281 
282   // Set a value for a given key, overwriting the previous value if any.
283   // Note: Omit the `value` from TValue type deduction, deduce only from the `key` argument.
284   template <typename TValue>
SetVariantMap285   void Set(const TKey<TValue>& key, const typename Identity<TValue>::type& value) {
286     // Clone the value first, to protect against &value == GetValuePtr(key).
287     auto* new_value = new TValue(value);
288 
289     Remove(key);
290     bool inserted = storage_map_.insert({key.Clone(), new_value}).second;
291     DCHECK(inserted);  // ensure key.Clone() does not leak memory.
292   }
293 
294   // Set a value for a given key, only if there was no previous value before.
295   // Returns true if the value was set, false if a previous value existed.
296   // Note: Omit the `value` from TValue type deduction, deduce only from the `key` argument.
297   template <typename TValue>
SetIfMissingVariantMap298   bool SetIfMissing(const TKey<TValue>& key, const typename Identity<TValue>::type& value) {
299     TValue* ptr = Get(key);
300     if (ptr == nullptr) {
301       Set(key, value);
302       return true;
303     }
304     return false;
305   }
306 
307   // Remove the value for a given key, or a no-op if there was no previously set value.
308   template <typename TValue>
RemoveVariantMap309   void Remove(const TKey<TValue>& key) {
310     StaticAssertKeyType<TValue>();
311 
312     auto&& it = GetKeyValueIterator(key);
313     if (it != storage_map_.end()) {
314       key.ValueDelete(it->second);
315       delete it->first;
316       storage_map_.erase(it);
317     }
318   }
319 
320   // Remove all key/value pairs.
ClearVariantMap321   void Clear() {
322     DeleteStoredValues();
323     storage_map_.clear();
324   }
325 
326   // How many key/value pairs are stored in this map.
SizeVariantMap327   size_t Size() const {
328     return storage_map_.size();
329   }
330 
331   // Construct an empty map.
VariantMapVariantMap332   VariantMap() {}
333 
334   template <typename ... TKeyValue>
VariantMapVariantMap335   explicit VariantMap(const TKeyValue& ... key_value_list) {
336     static_assert(sizeof...(TKeyValue) % 2 == 0, "Must be an even number of key/value elements");
337     InitializeParameters(key_value_list...);
338   }
339 
340   // Create a new map from an existing map, copying all the key/value pairs.
VariantMapVariantMap341   VariantMap(const VariantMap& other) {
342     operator=(other);
343   }
344 
345   // Copy the key/value pairs from the other map into this one. Existing key/values are cleared.
346   VariantMap& operator=(const VariantMap& other) {
347     if (this == &other) {
348       return *this;
349     }
350 
351     Clear();
352 
353     for (auto&& kv_pair : other.storage_map_) {
354       const detail::VariantMapKeyRaw* raw_key_other = kv_pair.first;
355       void* value = kv_pair.second;
356 
357       detail::VariantMapKeyRaw* cloned_raw_key = raw_key_other->Clone();
358       void* cloned_value = raw_key_other->ValueClone(value);
359 
360       storage_map_.insert({{ cloned_raw_key, cloned_value }});
361     }
362 
363     return *this;
364   }
365 
366   // Create a new map by moving an existing map into this one. The other map becomes empty.
VariantMapVariantMap367   VariantMap(VariantMap&& other) {
368     operator=(std::forward<VariantMap>(other));
369   }
370 
371   // Move the existing map's key/value pairs into this one. The other map becomes empty.
372   VariantMap& operator=(VariantMap&& other) {
373     if (this != &other) {
374       Clear();
375       storage_map_.swap(other.storage_map_);
376       other.storage_map_.clear();
377     }
378     return *this;
379   }
380 
~VariantMapVariantMap381   ~VariantMap() {
382     DeleteStoredValues();
383   }
384 
385  private:
InitializeParametersVariantMap386   void InitializeParameters() {}
387 
388   template <typename TK, typename TValue, typename ... Rest>
InitializeParametersVariantMap389   void InitializeParameters(const TK& key, const TValue& value, const Rest& ... rest) {
390     static_assert(
391         std::is_same<TK, TKey<TValue>>::value, "The 0th/2nd/4th/etc parameters must be a key");
392 
393     const TKey<TValue>& key_refined = key;
394 
395     Set(key_refined, value);
396     InitializeParameters(rest...);
397   }
398 
399   // Custom key comparator for std::map, needed since we are storing raw pointers as the keys.
400   struct KeyComparator {
operatorVariantMap::KeyComparator401     bool operator()(const detail::VariantMapKeyRaw* lhs,
402                     const detail::VariantMapKeyRaw* rhs) const {
403       if (lhs == nullptr) {
404         return lhs != rhs;
405       }
406 
407       return lhs->Compare(rhs);
408     }
409   };
410 
411   // Map of key pointers to value pointers. Pointers are never null.
412   using StorageMap = std::map<const detail::VariantMapKeyRaw*, void*, KeyComparator>;
413 
414   template <typename TValue>
GetKeyValueIteratorVariantMap415   typename StorageMap::iterator GetKeyValueIterator(const TKey<TValue>& key) {
416     StaticAssertKeyType<TValue>();
417 
418     const TKey<TValue>* key_ptr = &key;
419     const detail::VariantMapKeyRaw* raw_ptr = key_ptr;
420     return storage_map_.find(raw_ptr);
421   }
422 
423   template <typename TValue>
GetKeyValueIteratorVariantMap424   typename StorageMap::const_iterator GetKeyValueIterator(const TKey<TValue>& key) const {
425     StaticAssertKeyType<TValue>();
426 
427     const TKey<TValue>* key_ptr = &key;
428     const detail::VariantMapKeyRaw* raw_ptr = key_ptr;
429     return storage_map_.find(raw_ptr);
430   }
431 
432   template <typename TValue>
GetValuePtrVariantMap433   TValue* GetValuePtr(const TKey<TValue>& key) {
434     return const_cast<TValue*>(GetValueConstPtr(key));
435   }
436 
437   template <typename TValue>
GetValuePtrVariantMap438   const TValue* GetValuePtr(const TKey<TValue>& key) const {
439     return GetValueConstPtr(key);
440   }
441 
442   template <typename TValue>
GetValueConstPtrVariantMap443   const TValue* GetValueConstPtr(const TKey<TValue>& key) const {
444     auto&& it = GetKeyValueIterator(key);
445     if (it == storage_map_.end()) {
446       return nullptr;
447     }
448 
449     return reinterpret_cast<const TValue*>(it->second);
450   }
451 
452   template <typename TValue>
StaticAssertKeyTypeVariantMap453   static void StaticAssertKeyType() {
454     static_assert(std::is_base_of<VariantMapKey<TValue>, TKey<TValue>>::value,
455                   "The provided key type (TKey) must be a subclass of VariantMapKey");
456   }
457 
DeleteStoredValuesVariantMap458   void DeleteStoredValues() {
459     for (auto&& kv_pair : storage_map_) {
460       kv_pair.first->ValueDelete(kv_pair.second);
461       delete kv_pair.first;
462     }
463   }
464 
465   StorageMap storage_map_;
466 };
467 
468 }  // namespace art
469 
470 #endif  // ART_LIBARTBASE_BASE_VARIANT_MAP_H_
471