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1 /*
2  * Copyright (C) 2013 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_COMPILER_UTILS_GROWABLE_ARRAY_H_
18 #define ART_COMPILER_UTILS_GROWABLE_ARRAY_H_
19 
20 #include <stdint.h>
21 #include <stddef.h>
22 #include "arena_allocator.h"
23 
24 namespace art {
25 
26 // Type of growable list for memory tuning.
27 enum OatListKind {
28   kGrowableArrayMisc = 0,
29   kGrowableArrayBlockList,
30   kGrowableArraySSAtoDalvikMap,
31   kGrowableArrayDfsOrder,
32   kGrowableArrayDfsPostOrder,
33   kGrowableArrayDomPostOrderTraversal,
34   kGrowableArraySwitchTables,
35   kGrowableArrayFillArrayData,
36   kGrowableArraySuccessorBlocks,
37   kGrowableArrayPredecessors,
38   kGrowableArraySlowPaths,
39   kGNumListKinds
40 };
41 
42 template<typename T>
43 class GrowableArray {
44   public:
45     class Iterator {
46       public:
Iterator(GrowableArray * g_list)47         explicit Iterator(GrowableArray* g_list)
48           : idx_(0),
49             g_list_(g_list) {}
50 
Iterator()51         explicit Iterator()
52           : idx_(0),
53             g_list_(nullptr) {}
54 
55         // NOTE: returns 0/NULL when no next.
56         // TODO: redo to make usage consistent with other iterators.
Next()57         T Next() {
58           DCHECK(g_list_ != nullptr);
59           if (idx_ >= g_list_->Size()) {
60             return 0;
61           } else {
62             return g_list_->Get(idx_++);
63           }
64         }
65 
Reset()66         void Reset() {
67           idx_ = 0;
68         }
69 
Reset(GrowableArray * g_list)70         void Reset(GrowableArray* g_list) {
71           idx_ = 0;
72           g_list_ = g_list;
73         }
74 
GetIndex()75         size_t GetIndex() const {
76           return idx_;
77         }
78 
79       private:
80         size_t idx_;
81         GrowableArray* g_list_;
82     };
83 
84     GrowableArray(ArenaAllocator* arena, size_t init_length, OatListKind kind = kGrowableArrayMisc)
arena_(arena)85       : arena_(arena),
86         num_allocated_(init_length),
87         num_used_(0),
88         kind_(kind) {
89       elem_list_ = static_cast<T*>(arena_->Alloc(sizeof(T) * init_length,
90                                                  kArenaAllocGrowableArray));
91     };
92 
93 
94     // Expand the list size to at least new length.
Resize(size_t new_length)95     void Resize(size_t new_length) {
96       if (new_length <= num_allocated_) return;
97       // If it's a small list double the size, else grow 1.5x.
98       size_t target_length =
99           (num_allocated_ < 128) ? num_allocated_ << 1 : num_allocated_ + (num_allocated_ >> 1);
100       if (new_length > target_length) {
101          target_length = new_length;
102       }
103       T* new_array = static_cast<T*>(arena_->Alloc(sizeof(T) * target_length,
104                                                    kArenaAllocGrowableArray));
105       memcpy(new_array, elem_list_, sizeof(T) * num_allocated_);
106       num_allocated_ = target_length;
107       elem_list_ = new_array;
108     };
109 
110     // NOTE: does not return storage, just resets use count.
Reset()111     void Reset() {
112       num_used_ = 0;
113     }
114 
115     // Insert an element to the end of a list, resizing if necessary.
Insert(T elem)116     void Insert(T elem) {
117       if (num_used_ == num_allocated_) {
118         Resize(num_used_ + 1);
119       }
120       elem_list_[num_used_++] = elem;
121     }
122 
InsertAt(size_t index,T elem)123     void InsertAt(size_t index, T elem) {
124       DCHECK(index <= Size());
125       Insert(elem);
126       for (size_t i = Size() - 1; i > index; --i) {
127         elem_list_[i] = elem_list_[i - 1];
128       }
129       elem_list_[index] = elem;
130     }
131 
Add(T elem)132     void Add(T elem) {
133       Insert(elem);
134     }
135 
Get(size_t index)136     T Get(size_t index) const {
137       DCHECK_LT(index, num_used_);
138       return elem_list_[index];
139     };
140 
141     // Overwrite existing element at position index.  List must be large enough.
Put(size_t index,T elem)142     void Put(size_t index, T elem) {
143       DCHECK_LT(index, num_used_);
144       elem_list_[index] = elem;
145     }
146 
Increment(size_t index)147     void Increment(size_t index) {
148       DCHECK_LT(index, num_used_);
149       elem_list_[index]++;
150     }
151 
152     /*
153      * Remove an existing element from list.  If there are more than one copy
154      * of the element, only the first one encountered will be deleted.
155      */
156     // TODO: consider renaming this.
Delete(T element)157     void Delete(T element) {
158       bool found = false;
159       for (size_t i = 0; i < num_used_ - 1; i++) {
160         if (!found && elem_list_[i] == element) {
161           found = true;
162         }
163         if (found) {
164           elem_list_[i] = elem_list_[i+1];
165         }
166       }
167       // We should either have found the element, or it was the last (unscanned) element.
168       DCHECK(found || (element == elem_list_[num_used_ - 1]));
169       num_used_--;
170     };
171 
DeleteAt(size_t index)172     void DeleteAt(size_t index) {
173       for (size_t i = index; i < num_used_ - 1; i++) {
174         elem_list_[i] = elem_list_[i + 1];
175       }
176       num_used_--;
177     };
178 
GetNumAllocated()179     size_t GetNumAllocated() const { return num_allocated_; }
180 
Size()181     size_t Size() const { return num_used_; }
182 
IsEmpty()183     bool IsEmpty() const { return num_used_ == 0; }
184 
Pop()185     T Pop() {
186       DCHECK_GE(num_used_, (size_t)0);
187       return elem_list_[--num_used_];
188     }
189 
Peek()190     T Peek() const {
191       DCHECK_GE(num_used_, (size_t)0);
192       return elem_list_[num_used_ - 1];
193     }
194 
SetSize(size_t new_size)195     void SetSize(size_t new_size) {
196       Resize(new_size);
197       num_used_ = new_size;
198     }
199 
GetRawStorage()200     T* GetRawStorage() const { return elem_list_; }
201 
new(size_t size,ArenaAllocator * arena)202     static void* operator new(size_t size, ArenaAllocator* arena) {
203       return arena->Alloc(sizeof(GrowableArray<T>), kArenaAllocGrowableArray);
204     };
delete(void * p)205     static void operator delete(void* p) {}  // Nop.
206 
207   private:
208     ArenaAllocator* const arena_;
209     size_t num_allocated_;
210     size_t num_used_;
211     OatListKind kind_;
212     T* elem_list_;
213 };
214 
215 }  // namespace art
216 
217 #endif  // ART_COMPILER_UTILS_GROWABLE_ARRAY_H_
218