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// Copyright (c) 2008, Google Inc.
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
#include "breakpad_googletest_includes.h"
#include "common/simple_string_dictionary.h"
namespace google_breakpad {
TEST(NonAllocatingMapTest, Entry) {
typedef NonAllocatingMap<5, 9, 15> TestMap;
TestMap map;
const TestMap::Entry* entry = TestMap::Iterator(map).Next();
EXPECT_FALSE(entry);
// Try setting a key/value and then verify.
map.SetKeyValue("key1", "value1");
entry = TestMap::Iterator(map).Next();
ASSERT_TRUE(entry);
EXPECT_STREQ(entry->key, "key1");
EXPECT_STREQ(entry->value, "value1");
// Try setting a new value.
map.SetKeyValue("key1", "value3");
EXPECT_STREQ(entry->value, "value3");
// Make sure the key didn't change.
EXPECT_STREQ(entry->key, "key1");
// Clear the entry and verify the key and value are empty strings.
map.RemoveKey("key1");
EXPECT_FALSE(entry->is_active());
EXPECT_EQ(strlen(entry->key), 0u);
EXPECT_EQ(strlen(entry->value), 0u);
}
TEST(NonAllocatingMapTest, SimpleStringDictionary) {
// Make a new dictionary
SimpleStringDictionary dict;
// Set three distinct values on three keys
dict.SetKeyValue("key1", "value1");
dict.SetKeyValue("key2", "value2");
dict.SetKeyValue("key3", "value3");
EXPECT_NE(dict.GetValueForKey("key1"), "value1");
EXPECT_NE(dict.GetValueForKey("key2"), "value2");
EXPECT_NE(dict.GetValueForKey("key3"), "value3");
EXPECT_EQ(dict.GetCount(), 3u);
// try an unknown key
EXPECT_FALSE(dict.GetValueForKey("key4"));
// Remove a key
dict.RemoveKey("key3");
// Now make sure it's not there anymore
EXPECT_FALSE(dict.GetValueForKey("key3"));
// Remove by setting value to NULL
dict.SetKeyValue("key2", NULL);
// Now make sure it's not there anymore
EXPECT_FALSE(dict.GetValueForKey("key2"));
}
TEST(NonAllocatingMapTest, CopyAndAssign) {
NonAllocatingMap<10, 10, 10> map;
map.SetKeyValue("one", "a");
map.SetKeyValue("two", "b");
map.SetKeyValue("three", "c");
map.RemoveKey("two");
EXPECT_EQ(2u, map.GetCount());
// Test copy.
NonAllocatingMap<10, 10, 10> map_copy(map);
EXPECT_EQ(2u, map_copy.GetCount());
EXPECT_STREQ("a", map_copy.GetValueForKey("one"));
EXPECT_STREQ("c", map_copy.GetValueForKey("three"));
map_copy.SetKeyValue("four", "d");
EXPECT_STREQ("d", map_copy.GetValueForKey("four"));
EXPECT_FALSE(map.GetValueForKey("four"));
// Test assign.
NonAllocatingMap<10, 10, 10> map_assign;
map_assign = map;
EXPECT_EQ(2u, map_assign.GetCount());
EXPECT_STREQ("a", map_assign.GetValueForKey("one"));
EXPECT_STREQ("c", map_assign.GetValueForKey("three"));
map_assign.SetKeyValue("four", "d");
EXPECT_STREQ("d", map_assign.GetValueForKey("four"));
EXPECT_FALSE(map.GetValueForKey("four"));
map.RemoveKey("one");
EXPECT_FALSE(map.GetValueForKey("one"));
EXPECT_STREQ("a", map_copy.GetValueForKey("one"));
EXPECT_STREQ("a", map_assign.GetValueForKey("one"));
}
// Add a bunch of values to the dictionary, remove some entries in the middle,
// and then add more.
TEST(NonAllocatingMapTest, Iterator) {
SimpleStringDictionary* dict = new SimpleStringDictionary();
ASSERT_TRUE(dict);
char key[SimpleStringDictionary::key_size];
char value[SimpleStringDictionary::value_size];
const int kDictionaryCapacity = SimpleStringDictionary::num_entries;
const int kPartitionIndex = kDictionaryCapacity - 5;
// We assume at least this size in the tests below
ASSERT_GE(kDictionaryCapacity, 64);
// We'll keep track of the number of key/value pairs we think should
// be in the dictionary
int expectedDictionarySize = 0;
// Set a bunch of key/value pairs like key0/value0, key1/value1, ...
for (int i = 0; i < kPartitionIndex; ++i) {
sprintf(key, "key%d", i);
sprintf(value, "value%d", i);
dict->SetKeyValue(key, value);
}
expectedDictionarySize = kPartitionIndex;
// set a couple of the keys twice (with the same value) - should be nop
dict->SetKeyValue("key2", "value2");
dict->SetKeyValue("key4", "value4");
dict->SetKeyValue("key15", "value15");
// Remove some random elements in the middle
dict->RemoveKey("key7");
dict->RemoveKey("key18");
dict->RemoveKey("key23");
dict->RemoveKey("key31");
expectedDictionarySize -= 4; // we just removed four key/value pairs
// Set some more key/value pairs like key59/value59, key60/value60, ...
for (int i = kPartitionIndex; i < kDictionaryCapacity; ++i) {
sprintf(key, "key%d", i);
sprintf(value, "value%d", i);
dict->SetKeyValue(key, value);
}
expectedDictionarySize += kDictionaryCapacity - kPartitionIndex;
// Now create an iterator on the dictionary
SimpleStringDictionary::Iterator iter(*dict);
// We then verify that it iterates through exactly the number of
// key/value pairs we expect, and that they match one-for-one with what we
// would expect. The ordering of the iteration does not matter...
// used to keep track of number of occurrences found for key/value pairs
int count[kDictionaryCapacity];
memset(count, 0, sizeof(count));
int totalCount = 0;
const SimpleStringDictionary::Entry* entry;
while ((entry = iter.Next())) {
totalCount++;
// Extract keyNumber from a string of the form key<keyNumber>
int keyNumber;
sscanf(entry->key, "key%d", &keyNumber);
// Extract valueNumber from a string of the form value<valueNumber>
int valueNumber;
sscanf(entry->value, "value%d", &valueNumber);
// The value number should equal the key number since that's how we set them
EXPECT_EQ(keyNumber, valueNumber);
// Key and value numbers should be in proper range:
// 0 <= keyNumber < kDictionaryCapacity
bool isKeyInGoodRange =
(keyNumber >= 0 && keyNumber < kDictionaryCapacity);
bool isValueInGoodRange =
(valueNumber >= 0 && valueNumber < kDictionaryCapacity);
EXPECT_TRUE(isKeyInGoodRange);
EXPECT_TRUE(isValueInGoodRange);
if (isKeyInGoodRange && isValueInGoodRange) {
++count[keyNumber];
}
}
// Make sure each of the key/value pairs showed up exactly one time, except
// for the ones which we removed.
for (size_t i = 0; i < kDictionaryCapacity; ++i) {
// Skip over key7, key18, key23, and key31, since we removed them
if (!(i == 7 || i == 18 || i == 23 || i == 31)) {
EXPECT_EQ(count[i], 1);
}
}
// Make sure the number of iterations matches the expected dictionary size.
EXPECT_EQ(totalCount, expectedDictionarySize);
}
TEST(NonAllocatingMapTest, AddRemove) {
NonAllocatingMap<5, 7, 6> map;
map.SetKeyValue("rob", "ert");
map.SetKeyValue("mike", "pink");
map.SetKeyValue("mark", "allays");
EXPECT_EQ(3u, map.GetCount());
EXPECT_STREQ("ert", map.GetValueForKey("rob"));
EXPECT_STREQ("pink", map.GetValueForKey("mike"));
EXPECT_STREQ("allays", map.GetValueForKey("mark"));
map.RemoveKey("mike");
EXPECT_EQ(2u, map.GetCount());
EXPECT_FALSE(map.GetValueForKey("mike"));
map.SetKeyValue("mark", "mal");
EXPECT_EQ(2u, map.GetCount());
EXPECT_STREQ("mal", map.GetValueForKey("mark"));
map.RemoveKey("mark");
EXPECT_EQ(1u, map.GetCount());
EXPECT_FALSE(map.GetValueForKey("mark"));
}
TEST(NonAllocatingMapTest, Serialize) {
typedef NonAllocatingMap<4, 5, 7> TestMap;
TestMap map;
map.SetKeyValue("one", "abc");
map.SetKeyValue("two", "def");
map.SetKeyValue("tre", "hig");
EXPECT_STREQ("abc", map.GetValueForKey("one"));
EXPECT_STREQ("def", map.GetValueForKey("two"));
EXPECT_STREQ("hig", map.GetValueForKey("tre"));
const SerializedNonAllocatingMap* serialized;
size_t size = map.Serialize(&serialized);
SerializedNonAllocatingMap* serialized_copy =
reinterpret_cast<SerializedNonAllocatingMap*>(malloc(size));
ASSERT_TRUE(serialized_copy);
memcpy(serialized_copy, serialized, size);
TestMap deserialized(serialized_copy, size);
free(serialized_copy);
EXPECT_EQ(3u, deserialized.GetCount());
EXPECT_STREQ("abc", deserialized.GetValueForKey("one"));
EXPECT_STREQ("def", deserialized.GetValueForKey("two"));
EXPECT_STREQ("hig", deserialized.GetValueForKey("tre"));
}
// Running out of space shouldn't crash.
TEST(NonAllocatingMapTest, OutOfSpace) {
NonAllocatingMap<3, 2, 2> map;
map.SetKeyValue("a", "1");
map.SetKeyValue("b", "2");
map.SetKeyValue("c", "3");
EXPECT_EQ(2u, map.GetCount());
EXPECT_FALSE(map.GetValueForKey("c"));
}
TEST(NonAllocatingMapTest, ByIndex) {
NonAllocatingMap<10, 10, 3> map;
size_t index1 = map.SetKeyValue("test", "one");
EXPECT_TRUE(index1 >= 0 && index1 <= map.num_entries);
size_t index2 = map.SetKeyValue("moo", "foo");
EXPECT_TRUE(index2 >= 0 && index2 <= map.num_entries);
EXPECT_NE(index1, index2);
size_t index3 = map.SetKeyValue("blob", "kebab");
EXPECT_TRUE(index3 >= 0 && index3 <= map.num_entries);
EXPECT_NE(index2, index3);
size_t index4 = map.SetKeyValue("nogo", "full");
EXPECT_TRUE(index4 == map.num_entries);
EXPECT_STREQ("one", map.GetValueForKey("test"));
EXPECT_STREQ("foo", map.GetValueForKey("moo"));
EXPECT_STREQ("kebab", map.GetValueForKey("blob"));
map.SetValueAtIndex(index2, "booo");
EXPECT_STREQ("booo", map.GetValueForKey("moo"));
EXPECT_TRUE(map.RemoveAtIndex(index1));
EXPECT_FALSE(map.GetValueForKey("test"));
EXPECT_FALSE(map.RemoveAtIndex(map.num_entries));
EXPECT_FALSE(map.RemoveAtIndex(9999));
}
#ifndef NDEBUG
TEST(NonAllocatingMapTest, NullKey) {
NonAllocatingMap<4, 6, 6> map;
ASSERT_DEATH(map.SetKeyValue(NULL, "hello"), "");
map.SetKeyValue("hi", "there");
ASSERT_DEATH(map.GetValueForKey(NULL), "");
EXPECT_STREQ("there", map.GetValueForKey("hi"));
ASSERT_DEATH(map.GetValueForKey(NULL), "");
map.RemoveKey("hi");
EXPECT_EQ(0u, map.GetCount());
}
#endif // !NDEBUG
} // namespace google_breakpad
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