1 /*
2 ** Copyright 2011, 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 //#define LOG_NDEBUG 0
18
19 #include "BlobCache.h"
20
21 #include <errno.h>
22 #include <inttypes.h>
23
24 #include <cutils/properties.h>
25 #include <log/log.h>
26 #include <chrono>
27
28 namespace android {
29
30 // BlobCache::Header::mMagicNumber value
31 static const uint32_t blobCacheMagic = ('_' << 24) + ('B' << 16) + ('b' << 8) + '$';
32
33 // BlobCache::Header::mBlobCacheVersion value
34 static const uint32_t blobCacheVersion = 3;
35
36 // BlobCache::Header::mDeviceVersion value
37 static const uint32_t blobCacheDeviceVersion = 1;
38
BlobCache(size_t maxKeySize,size_t maxValueSize,size_t maxTotalSize)39 BlobCache::BlobCache(size_t maxKeySize, size_t maxValueSize, size_t maxTotalSize):
40 mMaxTotalSize(maxTotalSize),
41 mMaxKeySize(maxKeySize),
42 mMaxValueSize(maxValueSize),
43 mTotalSize(0) {
44 int64_t now = std::chrono::steady_clock::now().time_since_epoch().count();
45 #ifdef _WIN32
46 srand(now);
47 #else
48 mRandState[0] = (now >> 0) & 0xFFFF;
49 mRandState[1] = (now >> 16) & 0xFFFF;
50 mRandState[2] = (now >> 32) & 0xFFFF;
51 #endif
52 ALOGV("initializing random seed using %lld", (unsigned long long)now);
53 }
54
set(const void * key,size_t keySize,const void * value,size_t valueSize)55 void BlobCache::set(const void* key, size_t keySize, const void* value,
56 size_t valueSize) {
57 if (mMaxKeySize < keySize) {
58 ALOGV("set: not caching because the key is too large: %zu (limit: %zu)",
59 keySize, mMaxKeySize);
60 return;
61 }
62 if (mMaxValueSize < valueSize) {
63 ALOGV("set: not caching because the value is too large: %zu (limit: %zu)",
64 valueSize, mMaxValueSize);
65 return;
66 }
67 if (mMaxTotalSize < keySize + valueSize) {
68 ALOGV("set: not caching because the combined key/value size is too "
69 "large: %zu (limit: %zu)", keySize + valueSize, mMaxTotalSize);
70 return;
71 }
72 if (keySize == 0) {
73 ALOGW("set: not caching because keySize is 0");
74 return;
75 }
76 if (valueSize <= 0) {
77 ALOGW("set: not caching because valueSize is 0");
78 return;
79 }
80
81 std::shared_ptr<Blob> dummyKey(new Blob(key, keySize, false));
82 CacheEntry dummyEntry(dummyKey, NULL);
83
84 while (true) {
85 auto index = std::lower_bound(mCacheEntries.begin(), mCacheEntries.end(), dummyEntry);
86 if (index == mCacheEntries.end() || dummyEntry < *index) {
87 // Create a new cache entry.
88 std::shared_ptr<Blob> keyBlob(new Blob(key, keySize, true));
89 std::shared_ptr<Blob> valueBlob(new Blob(value, valueSize, true));
90 size_t newTotalSize = mTotalSize + keySize + valueSize;
91 if (mMaxTotalSize < newTotalSize) {
92 if (isCleanable()) {
93 // Clean the cache and try again.
94 clean();
95 continue;
96 } else {
97 ALOGV("set: not caching new key/value pair because the "
98 "total cache size limit would be exceeded: %zu "
99 "(limit: %zu)",
100 keySize + valueSize, mMaxTotalSize);
101 break;
102 }
103 }
104 mCacheEntries.insert(index, CacheEntry(keyBlob, valueBlob));
105 mTotalSize = newTotalSize;
106 ALOGV("set: created new cache entry with %zu byte key and %zu byte value",
107 keySize, valueSize);
108 } else {
109 // Update the existing cache entry.
110 std::shared_ptr<Blob> valueBlob(new Blob(value, valueSize, true));
111 std::shared_ptr<Blob> oldValueBlob(index->getValue());
112 size_t newTotalSize = mTotalSize + valueSize - oldValueBlob->getSize();
113 if (mMaxTotalSize < newTotalSize) {
114 if (isCleanable()) {
115 // Clean the cache and try again.
116 clean();
117 continue;
118 } else {
119 ALOGV("set: not caching new value because the total cache "
120 "size limit would be exceeded: %zu (limit: %zu)",
121 keySize + valueSize, mMaxTotalSize);
122 break;
123 }
124 }
125 index->setValue(valueBlob);
126 mTotalSize = newTotalSize;
127 ALOGV("set: updated existing cache entry with %zu byte key and %zu byte "
128 "value", keySize, valueSize);
129 }
130 break;
131 }
132 }
133
get(const void * key,size_t keySize,void * value,size_t valueSize)134 size_t BlobCache::get(const void* key, size_t keySize, void* value,
135 size_t valueSize) {
136 if (mMaxKeySize < keySize) {
137 ALOGV("get: not searching because the key is too large: %zu (limit %zu)",
138 keySize, mMaxKeySize);
139 return 0;
140 }
141 std::shared_ptr<Blob> dummyKey(new Blob(key, keySize, false));
142 CacheEntry dummyEntry(dummyKey, NULL);
143 auto index = std::lower_bound(mCacheEntries.begin(), mCacheEntries.end(), dummyEntry);
144 if (index == mCacheEntries.end() || dummyEntry < *index) {
145 ALOGV("get: no cache entry found for key of size %zu", keySize);
146 return 0;
147 }
148
149 // The key was found. Return the value if the caller's buffer is large
150 // enough.
151 std::shared_ptr<Blob> valueBlob(index->getValue());
152 size_t valueBlobSize = valueBlob->getSize();
153 if (valueBlobSize <= valueSize) {
154 ALOGV("get: copying %zu bytes to caller's buffer", valueBlobSize);
155 memcpy(value, valueBlob->getData(), valueBlobSize);
156 } else {
157 ALOGV("get: caller's buffer is too small for value: %zu (needs %zu)",
158 valueSize, valueBlobSize);
159 }
160 return valueBlobSize;
161 }
162
align4(size_t size)163 static inline size_t align4(size_t size) {
164 return (size + 3) & ~3;
165 }
166
getFlattenedSize() const167 size_t BlobCache::getFlattenedSize() const {
168 size_t size = align4(sizeof(Header) + PROPERTY_VALUE_MAX);
169 for (const CacheEntry& e : mCacheEntries) {
170 std::shared_ptr<Blob> const& keyBlob = e.getKey();
171 std::shared_ptr<Blob> const& valueBlob = e.getValue();
172 size += align4(sizeof(EntryHeader) + keyBlob->getSize() + valueBlob->getSize());
173 }
174 return size;
175 }
176
flatten(void * buffer,size_t size) const177 int BlobCache::flatten(void* buffer, size_t size) const {
178 // Write the cache header
179 if (size < sizeof(Header)) {
180 ALOGE("flatten: not enough room for cache header");
181 return 0;
182 }
183 Header* header = reinterpret_cast<Header*>(buffer);
184 header->mMagicNumber = blobCacheMagic;
185 header->mBlobCacheVersion = blobCacheVersion;
186 header->mDeviceVersion = blobCacheDeviceVersion;
187 header->mNumEntries = mCacheEntries.size();
188 char buildId[PROPERTY_VALUE_MAX];
189 header->mBuildIdLength = property_get("ro.build.id", buildId, "");
190 memcpy(header->mBuildId, buildId, header->mBuildIdLength);
191
192 // Write cache entries
193 uint8_t* byteBuffer = reinterpret_cast<uint8_t*>(buffer);
194 off_t byteOffset = align4(sizeof(Header) + header->mBuildIdLength);
195 for (const CacheEntry& e : mCacheEntries) {
196 std::shared_ptr<Blob> const& keyBlob = e.getKey();
197 std::shared_ptr<Blob> const& valueBlob = e.getValue();
198 size_t keySize = keyBlob->getSize();
199 size_t valueSize = valueBlob->getSize();
200
201 size_t entrySize = sizeof(EntryHeader) + keySize + valueSize;
202 size_t totalSize = align4(entrySize);
203 if (byteOffset + totalSize > size) {
204 ALOGE("flatten: not enough room for cache entries");
205 return -EINVAL;
206 }
207
208 EntryHeader* eheader = reinterpret_cast<EntryHeader*>(&byteBuffer[byteOffset]);
209 eheader->mKeySize = keySize;
210 eheader->mValueSize = valueSize;
211
212 memcpy(eheader->mData, keyBlob->getData(), keySize);
213 memcpy(eheader->mData + keySize, valueBlob->getData(), valueSize);
214
215 if (totalSize > entrySize) {
216 // We have padding bytes. Those will get written to storage, and contribute to the CRC,
217 // so make sure we zero-them to have reproducible results.
218 memset(eheader->mData + keySize + valueSize, 0, totalSize - entrySize);
219 }
220
221 byteOffset += totalSize;
222 }
223
224 return 0;
225 }
226
unflatten(void const * buffer,size_t size)227 int BlobCache::unflatten(void const* buffer, size_t size) {
228 // All errors should result in the BlobCache being in an empty state.
229 mCacheEntries.clear();
230
231 // Read the cache header
232 if (size < sizeof(Header)) {
233 ALOGE("unflatten: not enough room for cache header");
234 return -EINVAL;
235 }
236 const Header* header = reinterpret_cast<const Header*>(buffer);
237 if (header->mMagicNumber != blobCacheMagic) {
238 ALOGE("unflatten: bad magic number: %" PRIu32, header->mMagicNumber);
239 return -EINVAL;
240 }
241 char buildId[PROPERTY_VALUE_MAX];
242 int len = property_get("ro.build.id", buildId, "");
243 if (header->mBlobCacheVersion != blobCacheVersion ||
244 header->mDeviceVersion != blobCacheDeviceVersion ||
245 len != header->mBuildIdLength ||
246 strncmp(buildId, header->mBuildId, len)) {
247 // We treat version mismatches as an empty cache.
248 return 0;
249 }
250
251 // Read cache entries
252 const uint8_t* byteBuffer = reinterpret_cast<const uint8_t*>(buffer);
253 off_t byteOffset = align4(sizeof(Header) + header->mBuildIdLength);
254 size_t numEntries = header->mNumEntries;
255 for (size_t i = 0; i < numEntries; i++) {
256 if (byteOffset + sizeof(EntryHeader) > size) {
257 mCacheEntries.clear();
258 ALOGE("unflatten: not enough room for cache entry headers");
259 return -EINVAL;
260 }
261
262 const EntryHeader* eheader = reinterpret_cast<const EntryHeader*>(
263 &byteBuffer[byteOffset]);
264 size_t keySize = eheader->mKeySize;
265 size_t valueSize = eheader->mValueSize;
266 size_t entrySize = sizeof(EntryHeader) + keySize + valueSize;
267
268 size_t totalSize = align4(entrySize);
269 if (byteOffset + totalSize > size) {
270 mCacheEntries.clear();
271 ALOGE("unflatten: not enough room for cache entry headers");
272 return -EINVAL;
273 }
274
275 const uint8_t* data = eheader->mData;
276 set(data, keySize, data + keySize, valueSize);
277
278 byteOffset += totalSize;
279 }
280
281 return 0;
282 }
283
blob_random()284 long int BlobCache::blob_random() {
285 #ifdef _WIN32
286 return rand();
287 #else
288 return nrand48(mRandState);
289 #endif
290 }
291
clean()292 void BlobCache::clean() {
293 // Remove a random cache entry until the total cache size gets below half
294 // the maximum total cache size.
295 while (mTotalSize > mMaxTotalSize / 2) {
296 size_t i = size_t(blob_random() % (mCacheEntries.size()));
297 const CacheEntry& entry(mCacheEntries[i]);
298 mTotalSize -= entry.getKey()->getSize() + entry.getValue()->getSize();
299 mCacheEntries.erase(mCacheEntries.begin() + i);
300 }
301 }
302
isCleanable() const303 bool BlobCache::isCleanable() const {
304 return mTotalSize > mMaxTotalSize / 2;
305 }
306
Blob(const void * data,size_t size,bool copyData)307 BlobCache::Blob::Blob(const void* data, size_t size, bool copyData) :
308 mData(copyData ? malloc(size) : data),
309 mSize(size),
310 mOwnsData(copyData) {
311 if (data != NULL && copyData) {
312 memcpy(const_cast<void*>(mData), data, size);
313 }
314 }
315
~Blob()316 BlobCache::Blob::~Blob() {
317 if (mOwnsData) {
318 free(const_cast<void*>(mData));
319 }
320 }
321
operator <(const Blob & rhs) const322 bool BlobCache::Blob::operator<(const Blob& rhs) const {
323 if (mSize == rhs.mSize) {
324 return memcmp(mData, rhs.mData, mSize) < 0;
325 } else {
326 return mSize < rhs.mSize;
327 }
328 }
329
getData() const330 const void* BlobCache::Blob::getData() const {
331 return mData;
332 }
333
getSize() const334 size_t BlobCache::Blob::getSize() const {
335 return mSize;
336 }
337
CacheEntry()338 BlobCache::CacheEntry::CacheEntry() {
339 }
340
CacheEntry(const std::shared_ptr<Blob> & key,const std::shared_ptr<Blob> & value)341 BlobCache::CacheEntry::CacheEntry(
342 const std::shared_ptr<Blob>& key, const std::shared_ptr<Blob>& value):
343 mKey(key),
344 mValue(value) {
345 }
346
CacheEntry(const CacheEntry & ce)347 BlobCache::CacheEntry::CacheEntry(const CacheEntry& ce):
348 mKey(ce.mKey),
349 mValue(ce.mValue) {
350 }
351
operator <(const CacheEntry & rhs) const352 bool BlobCache::CacheEntry::operator<(const CacheEntry& rhs) const {
353 return *mKey < *rhs.mKey;
354 }
355
operator =(const CacheEntry & rhs)356 const BlobCache::CacheEntry& BlobCache::CacheEntry::operator=(const CacheEntry& rhs) {
357 mKey = rhs.mKey;
358 mValue = rhs.mValue;
359 return *this;
360 }
361
getKey() const362 std::shared_ptr<BlobCache::Blob> BlobCache::CacheEntry::getKey() const {
363 return mKey;
364 }
365
getValue() const366 std::shared_ptr<BlobCache::Blob> BlobCache::CacheEntry::getValue() const {
367 return mValue;
368 }
369
setValue(const std::shared_ptr<Blob> & value)370 void BlobCache::CacheEntry::setValue(const std::shared_ptr<Blob>& value) {
371 mValue = value;
372 }
373
374 } // namespace android
375