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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 #include <fcntl.h>
18 #include <stdio.h>
19 
20 #include <gtest/gtest.h>
21 
22 #include <utils/BlobCache.h>
23 #include <utils/Errors.h>
24 
25 namespace android {
26 
27 class BlobCacheTest : public ::testing::Test {
28 protected:
29     enum {
30         MAX_KEY_SIZE = 6,
31         MAX_VALUE_SIZE = 8,
32         MAX_TOTAL_SIZE = 13,
33     };
34 
SetUp()35     virtual void SetUp() {
36         mBC = new BlobCache(MAX_KEY_SIZE, MAX_VALUE_SIZE, MAX_TOTAL_SIZE);
37     }
38 
TearDown()39     virtual void TearDown() {
40         mBC.clear();
41     }
42 
43     sp<BlobCache> mBC;
44 };
45 
TEST_F(BlobCacheTest,CacheSingleValueSucceeds)46 TEST_F(BlobCacheTest, CacheSingleValueSucceeds) {
47     unsigned char buf[4] = { 0xee, 0xee, 0xee, 0xee };
48     mBC->set("abcd", 4, "efgh", 4);
49     ASSERT_EQ(size_t(4), mBC->get("abcd", 4, buf, 4));
50     ASSERT_EQ('e', buf[0]);
51     ASSERT_EQ('f', buf[1]);
52     ASSERT_EQ('g', buf[2]);
53     ASSERT_EQ('h', buf[3]);
54 }
55 
TEST_F(BlobCacheTest,CacheTwoValuesSucceeds)56 TEST_F(BlobCacheTest, CacheTwoValuesSucceeds) {
57     unsigned char buf[2] = { 0xee, 0xee };
58     mBC->set("ab", 2, "cd", 2);
59     mBC->set("ef", 2, "gh", 2);
60     ASSERT_EQ(size_t(2), mBC->get("ab", 2, buf, 2));
61     ASSERT_EQ('c', buf[0]);
62     ASSERT_EQ('d', buf[1]);
63     ASSERT_EQ(size_t(2), mBC->get("ef", 2, buf, 2));
64     ASSERT_EQ('g', buf[0]);
65     ASSERT_EQ('h', buf[1]);
66 }
67 
TEST_F(BlobCacheTest,GetOnlyWritesInsideBounds)68 TEST_F(BlobCacheTest, GetOnlyWritesInsideBounds) {
69     unsigned char buf[6] = { 0xee, 0xee, 0xee, 0xee, 0xee, 0xee };
70     mBC->set("abcd", 4, "efgh", 4);
71     ASSERT_EQ(size_t(4), mBC->get("abcd", 4, buf+1, 4));
72     ASSERT_EQ(0xee, buf[0]);
73     ASSERT_EQ('e', buf[1]);
74     ASSERT_EQ('f', buf[2]);
75     ASSERT_EQ('g', buf[3]);
76     ASSERT_EQ('h', buf[4]);
77     ASSERT_EQ(0xee, buf[5]);
78 }
79 
TEST_F(BlobCacheTest,GetOnlyWritesIfBufferIsLargeEnough)80 TEST_F(BlobCacheTest, GetOnlyWritesIfBufferIsLargeEnough) {
81     unsigned char buf[3] = { 0xee, 0xee, 0xee };
82     mBC->set("abcd", 4, "efgh", 4);
83     ASSERT_EQ(size_t(4), mBC->get("abcd", 4, buf, 3));
84     ASSERT_EQ(0xee, buf[0]);
85     ASSERT_EQ(0xee, buf[1]);
86     ASSERT_EQ(0xee, buf[2]);
87 }
88 
TEST_F(BlobCacheTest,GetDoesntAccessNullBuffer)89 TEST_F(BlobCacheTest, GetDoesntAccessNullBuffer) {
90     mBC->set("abcd", 4, "efgh", 4);
91     ASSERT_EQ(size_t(4), mBC->get("abcd", 4, NULL, 0));
92 }
93 
TEST_F(BlobCacheTest,MultipleSetsCacheLatestValue)94 TEST_F(BlobCacheTest, MultipleSetsCacheLatestValue) {
95     unsigned char buf[4] = { 0xee, 0xee, 0xee, 0xee };
96     mBC->set("abcd", 4, "efgh", 4);
97     mBC->set("abcd", 4, "ijkl", 4);
98     ASSERT_EQ(size_t(4), mBC->get("abcd", 4, buf, 4));
99     ASSERT_EQ('i', buf[0]);
100     ASSERT_EQ('j', buf[1]);
101     ASSERT_EQ('k', buf[2]);
102     ASSERT_EQ('l', buf[3]);
103 }
104 
TEST_F(BlobCacheTest,SecondSetKeepsFirstValueIfTooLarge)105 TEST_F(BlobCacheTest, SecondSetKeepsFirstValueIfTooLarge) {
106     unsigned char buf[MAX_VALUE_SIZE+1] = { 0xee, 0xee, 0xee, 0xee };
107     mBC->set("abcd", 4, "efgh", 4);
108     mBC->set("abcd", 4, buf, MAX_VALUE_SIZE+1);
109     ASSERT_EQ(size_t(4), mBC->get("abcd", 4, buf, 4));
110     ASSERT_EQ('e', buf[0]);
111     ASSERT_EQ('f', buf[1]);
112     ASSERT_EQ('g', buf[2]);
113     ASSERT_EQ('h', buf[3]);
114 }
115 
TEST_F(BlobCacheTest,DoesntCacheIfKeyIsTooBig)116 TEST_F(BlobCacheTest, DoesntCacheIfKeyIsTooBig) {
117     char key[MAX_KEY_SIZE+1];
118     unsigned char buf[4] = { 0xee, 0xee, 0xee, 0xee };
119     for (int i = 0; i < MAX_KEY_SIZE+1; i++) {
120         key[i] = 'a';
121     }
122     mBC->set(key, MAX_KEY_SIZE+1, "bbbb", 4);
123     ASSERT_EQ(size_t(0), mBC->get(key, MAX_KEY_SIZE+1, buf, 4));
124     ASSERT_EQ(0xee, buf[0]);
125     ASSERT_EQ(0xee, buf[1]);
126     ASSERT_EQ(0xee, buf[2]);
127     ASSERT_EQ(0xee, buf[3]);
128 }
129 
TEST_F(BlobCacheTest,DoesntCacheIfValueIsTooBig)130 TEST_F(BlobCacheTest, DoesntCacheIfValueIsTooBig) {
131     char buf[MAX_VALUE_SIZE+1];
132     for (int i = 0; i < MAX_VALUE_SIZE+1; i++) {
133         buf[i] = 'b';
134     }
135     mBC->set("abcd", 4, buf, MAX_VALUE_SIZE+1);
136     for (int i = 0; i < MAX_VALUE_SIZE+1; i++) {
137         buf[i] = 0xee;
138     }
139     ASSERT_EQ(size_t(0), mBC->get("abcd", 4, buf, MAX_VALUE_SIZE+1));
140     for (int i = 0; i < MAX_VALUE_SIZE+1; i++) {
141         SCOPED_TRACE(i);
142         ASSERT_EQ(0xee, buf[i]);
143     }
144 }
145 
TEST_F(BlobCacheTest,DoesntCacheIfKeyValuePairIsTooBig)146 TEST_F(BlobCacheTest, DoesntCacheIfKeyValuePairIsTooBig) {
147     // Check a testing assumptions
148     ASSERT_TRUE(MAX_TOTAL_SIZE < MAX_KEY_SIZE + MAX_VALUE_SIZE);
149     ASSERT_TRUE(MAX_KEY_SIZE < MAX_TOTAL_SIZE);
150 
151     enum { bufSize = MAX_TOTAL_SIZE - MAX_KEY_SIZE + 1 };
152 
153     char key[MAX_KEY_SIZE];
154     char buf[bufSize];
155     for (int i = 0; i < MAX_KEY_SIZE; i++) {
156         key[i] = 'a';
157     }
158     for (int i = 0; i < bufSize; i++) {
159         buf[i] = 'b';
160     }
161 
162     mBC->set(key, MAX_KEY_SIZE, buf, MAX_VALUE_SIZE);
163     ASSERT_EQ(size_t(0), mBC->get(key, MAX_KEY_SIZE, NULL, 0));
164 }
165 
TEST_F(BlobCacheTest,CacheMaxKeySizeSucceeds)166 TEST_F(BlobCacheTest, CacheMaxKeySizeSucceeds) {
167     char key[MAX_KEY_SIZE];
168     unsigned char buf[4] = { 0xee, 0xee, 0xee, 0xee };
169     for (int i = 0; i < MAX_KEY_SIZE; i++) {
170         key[i] = 'a';
171     }
172     mBC->set(key, MAX_KEY_SIZE, "wxyz", 4);
173     ASSERT_EQ(size_t(4), mBC->get(key, MAX_KEY_SIZE, buf, 4));
174     ASSERT_EQ('w', buf[0]);
175     ASSERT_EQ('x', buf[1]);
176     ASSERT_EQ('y', buf[2]);
177     ASSERT_EQ('z', buf[3]);
178 }
179 
TEST_F(BlobCacheTest,CacheMaxValueSizeSucceeds)180 TEST_F(BlobCacheTest, CacheMaxValueSizeSucceeds) {
181     char buf[MAX_VALUE_SIZE];
182     for (int i = 0; i < MAX_VALUE_SIZE; i++) {
183         buf[i] = 'b';
184     }
185     mBC->set("abcd", 4, buf, MAX_VALUE_SIZE);
186     for (int i = 0; i < MAX_VALUE_SIZE; i++) {
187         buf[i] = 0xee;
188     }
189     ASSERT_EQ(size_t(MAX_VALUE_SIZE), mBC->get("abcd", 4, buf,
190             MAX_VALUE_SIZE));
191     for (int i = 0; i < MAX_VALUE_SIZE; i++) {
192         SCOPED_TRACE(i);
193         ASSERT_EQ('b', buf[i]);
194     }
195 }
196 
TEST_F(BlobCacheTest,CacheMaxKeyValuePairSizeSucceeds)197 TEST_F(BlobCacheTest, CacheMaxKeyValuePairSizeSucceeds) {
198     // Check a testing assumption
199     ASSERT_TRUE(MAX_KEY_SIZE < MAX_TOTAL_SIZE);
200 
201     enum { bufSize = MAX_TOTAL_SIZE - MAX_KEY_SIZE };
202 
203     char key[MAX_KEY_SIZE];
204     char buf[bufSize];
205     for (int i = 0; i < MAX_KEY_SIZE; i++) {
206         key[i] = 'a';
207     }
208     for (int i = 0; i < bufSize; i++) {
209         buf[i] = 'b';
210     }
211 
212     mBC->set(key, MAX_KEY_SIZE, buf, bufSize);
213     ASSERT_EQ(size_t(bufSize), mBC->get(key, MAX_KEY_SIZE, NULL, 0));
214 }
215 
TEST_F(BlobCacheTest,CacheMinKeyAndValueSizeSucceeds)216 TEST_F(BlobCacheTest, CacheMinKeyAndValueSizeSucceeds) {
217     unsigned char buf[1] = { 0xee };
218     mBC->set("x", 1, "y", 1);
219     ASSERT_EQ(size_t(1), mBC->get("x", 1, buf, 1));
220     ASSERT_EQ('y', buf[0]);
221 }
222 
TEST_F(BlobCacheTest,CacheSizeDoesntExceedTotalLimit)223 TEST_F(BlobCacheTest, CacheSizeDoesntExceedTotalLimit) {
224     for (int i = 0; i < 256; i++) {
225         uint8_t k = i;
226         mBC->set(&k, 1, "x", 1);
227     }
228     int numCached = 0;
229     for (int i = 0; i < 256; i++) {
230         uint8_t k = i;
231         if (mBC->get(&k, 1, NULL, 0) == 1) {
232             numCached++;
233         }
234     }
235     ASSERT_GE(MAX_TOTAL_SIZE / 2, numCached);
236 }
237 
TEST_F(BlobCacheTest,ExceedingTotalLimitHalvesCacheSize)238 TEST_F(BlobCacheTest, ExceedingTotalLimitHalvesCacheSize) {
239     // Fill up the entire cache with 1 char key/value pairs.
240     const int maxEntries = MAX_TOTAL_SIZE / 2;
241     for (int i = 0; i < maxEntries; i++) {
242         uint8_t k = i;
243         mBC->set(&k, 1, "x", 1);
244     }
245     // Insert one more entry, causing a cache overflow.
246     {
247         uint8_t k = maxEntries;
248         mBC->set(&k, 1, "x", 1);
249     }
250     // Count the number of entries in the cache.
251     int numCached = 0;
252     for (int i = 0; i < maxEntries+1; i++) {
253         uint8_t k = i;
254         if (mBC->get(&k, 1, NULL, 0) == 1) {
255             numCached++;
256         }
257     }
258     ASSERT_EQ(maxEntries/2 + 1, numCached);
259 }
260 
261 class BlobCacheFlattenTest : public BlobCacheTest {
262 protected:
SetUp()263     virtual void SetUp() {
264         BlobCacheTest::SetUp();
265         mBC2 = new BlobCache(MAX_KEY_SIZE, MAX_VALUE_SIZE, MAX_TOTAL_SIZE);
266     }
267 
TearDown()268     virtual void TearDown() {
269         mBC2.clear();
270         BlobCacheTest::TearDown();
271     }
272 
roundTrip()273     void roundTrip() {
274         size_t size = mBC->getFlattenedSize();
275         uint8_t* flat = new uint8_t[size];
276         ASSERT_EQ(OK, mBC->flatten(flat, size));
277         ASSERT_EQ(OK, mBC2->unflatten(flat, size));
278         delete[] flat;
279     }
280 
281     sp<BlobCache> mBC2;
282 };
283 
TEST_F(BlobCacheFlattenTest,FlattenOneValue)284 TEST_F(BlobCacheFlattenTest, FlattenOneValue) {
285     unsigned char buf[4] = { 0xee, 0xee, 0xee, 0xee };
286     mBC->set("abcd", 4, "efgh", 4);
287     roundTrip();
288     ASSERT_EQ(size_t(4), mBC2->get("abcd", 4, buf, 4));
289     ASSERT_EQ('e', buf[0]);
290     ASSERT_EQ('f', buf[1]);
291     ASSERT_EQ('g', buf[2]);
292     ASSERT_EQ('h', buf[3]);
293 }
294 
TEST_F(BlobCacheFlattenTest,FlattenFullCache)295 TEST_F(BlobCacheFlattenTest, FlattenFullCache) {
296     // Fill up the entire cache with 1 char key/value pairs.
297     const int maxEntries = MAX_TOTAL_SIZE / 2;
298     for (int i = 0; i < maxEntries; i++) {
299         uint8_t k = i;
300         mBC->set(&k, 1, &k, 1);
301     }
302 
303     roundTrip();
304 
305     // Verify the deserialized cache
306     for (int i = 0; i < maxEntries; i++) {
307         uint8_t k = i;
308         uint8_t v = 0xee;
309         ASSERT_EQ(size_t(1), mBC2->get(&k, 1, &v, 1));
310         ASSERT_EQ(k, v);
311     }
312 }
313 
TEST_F(BlobCacheFlattenTest,FlattenDoesntChangeCache)314 TEST_F(BlobCacheFlattenTest, FlattenDoesntChangeCache) {
315     // Fill up the entire cache with 1 char key/value pairs.
316     const int maxEntries = MAX_TOTAL_SIZE / 2;
317     for (int i = 0; i < maxEntries; i++) {
318         uint8_t k = i;
319         mBC->set(&k, 1, &k, 1);
320     }
321 
322     size_t size = mBC->getFlattenedSize();
323     uint8_t* flat = new uint8_t[size];
324     ASSERT_EQ(OK, mBC->flatten(flat, size));
325     delete[] flat;
326 
327     // Verify the cache that we just serialized
328     for (int i = 0; i < maxEntries; i++) {
329         uint8_t k = i;
330         uint8_t v = 0xee;
331         ASSERT_EQ(size_t(1), mBC->get(&k, 1, &v, 1));
332         ASSERT_EQ(k, v);
333     }
334 }
335 
TEST_F(BlobCacheFlattenTest,FlattenCatchesBufferTooSmall)336 TEST_F(BlobCacheFlattenTest, FlattenCatchesBufferTooSmall) {
337     // Fill up the entire cache with 1 char key/value pairs.
338     const int maxEntries = MAX_TOTAL_SIZE / 2;
339     for (int i = 0; i < maxEntries; i++) {
340         uint8_t k = i;
341         mBC->set(&k, 1, &k, 1);
342     }
343 
344     size_t size = mBC->getFlattenedSize() - 1;
345     uint8_t* flat = new uint8_t[size];
346     ASSERT_EQ(BAD_VALUE, mBC->flatten(flat, size));
347     delete[] flat;
348 }
349 
TEST_F(BlobCacheFlattenTest,UnflattenCatchesBadMagic)350 TEST_F(BlobCacheFlattenTest, UnflattenCatchesBadMagic) {
351     unsigned char buf[4] = { 0xee, 0xee, 0xee, 0xee };
352     mBC->set("abcd", 4, "efgh", 4);
353 
354     size_t size = mBC->getFlattenedSize();
355     uint8_t* flat = new uint8_t[size];
356     ASSERT_EQ(OK, mBC->flatten(flat, size));
357     flat[1] = ~flat[1];
358 
359     // Bad magic should cause an error.
360     ASSERT_EQ(BAD_VALUE, mBC2->unflatten(flat, size));
361     delete[] flat;
362 
363     // The error should cause the unflatten to result in an empty cache
364     ASSERT_EQ(size_t(0), mBC2->get("abcd", 4, buf, 4));
365 }
366 
TEST_F(BlobCacheFlattenTest,UnflattenCatchesBadBlobCacheVersion)367 TEST_F(BlobCacheFlattenTest, UnflattenCatchesBadBlobCacheVersion) {
368     unsigned char buf[4] = { 0xee, 0xee, 0xee, 0xee };
369     mBC->set("abcd", 4, "efgh", 4);
370 
371     size_t size = mBC->getFlattenedSize();
372     uint8_t* flat = new uint8_t[size];
373     ASSERT_EQ(OK, mBC->flatten(flat, size));
374     flat[5] = ~flat[5];
375 
376     // Version mismatches shouldn't cause errors, but should not use the
377     // serialized entries
378     ASSERT_EQ(OK, mBC2->unflatten(flat, size));
379     delete[] flat;
380 
381     // The version mismatch should cause the unflatten to result in an empty
382     // cache
383     ASSERT_EQ(size_t(0), mBC2->get("abcd", 4, buf, 4));
384 }
385 
TEST_F(BlobCacheFlattenTest,UnflattenCatchesBadBlobCacheDeviceVersion)386 TEST_F(BlobCacheFlattenTest, UnflattenCatchesBadBlobCacheDeviceVersion) {
387     unsigned char buf[4] = { 0xee, 0xee, 0xee, 0xee };
388     mBC->set("abcd", 4, "efgh", 4);
389 
390     size_t size = mBC->getFlattenedSize();
391     uint8_t* flat = new uint8_t[size];
392     ASSERT_EQ(OK, mBC->flatten(flat, size));
393     flat[10] = ~flat[10];
394 
395     // Version mismatches shouldn't cause errors, but should not use the
396     // serialized entries
397     ASSERT_EQ(OK, mBC2->unflatten(flat, size));
398     delete[] flat;
399 
400     // The version mismatch should cause the unflatten to result in an empty
401     // cache
402     ASSERT_EQ(size_t(0), mBC2->get("abcd", 4, buf, 4));
403 }
404 
TEST_F(BlobCacheFlattenTest,UnflattenCatchesBufferTooSmall)405 TEST_F(BlobCacheFlattenTest, UnflattenCatchesBufferTooSmall) {
406     unsigned char buf[4] = { 0xee, 0xee, 0xee, 0xee };
407     mBC->set("abcd", 4, "efgh", 4);
408 
409     size_t size = mBC->getFlattenedSize();
410     uint8_t* flat = new uint8_t[size];
411     ASSERT_EQ(OK, mBC->flatten(flat, size));
412 
413     // A buffer truncation shouldt cause an error
414     ASSERT_EQ(BAD_VALUE, mBC2->unflatten(flat, size-1));
415     delete[] flat;
416 
417     // The error should cause the unflatten to result in an empty cache
418     ASSERT_EQ(size_t(0), mBC2->get("abcd", 4, buf, 4));
419 }
420 
421 } // namespace android
422