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      1 // Copyright (c) 2010 The Chromium Authors. All rights reserved.
      2 // Use of this source code is governed by a BSD-style license that can be
      3 // found in the LICENSE file.
      4 
      5 #include <sstream>
      6 
      7 #include "chrome/renderer/net/predictor_queue.h"
      8 #include "testing/gtest/include/gtest/gtest.h"
      9 
     10 // Single threaded tests of DnsQueue functionality.
     11 
     12 namespace {
     13 
     14 class DnsQueueTest : public testing::Test {
     15 };
     16 
     17 // Define a helper class that does Push'es and Pop's of numbers.
     18 // This makes it easy to test a LOT of reads, and keep the expected Pop
     19 // value in sync with the Push value.
     20 class DnsQueueSequentialTester {
     21  public:
     22   DnsQueueSequentialTester(DnsQueue& buffer, int32 read_counter = 0,
     23                            int32 write_counter = 0);
     24 
     25   // Return of false means buffer was full, or would not take entry.
     26   bool Push(void);  // Push the string value of next number.
     27 
     28   // Return of false means buffer returned wrong value.
     29   bool Pop(void);  // Validate string value of next read.
     30 
     31  private:
     32   DnsQueue* buffer_;
     33   int32 read_counter_;  // expected value of next read string.
     34   int32 write_counter_;  // Numerical value to write next string.
     35   DISALLOW_COPY_AND_ASSIGN(DnsQueueSequentialTester);
     36 };
     37 
     38 
     39 DnsQueueSequentialTester::DnsQueueSequentialTester(
     40   DnsQueue& buffer, int32 read_counter, int32 write_counter)
     41     : buffer_(&buffer),
     42       read_counter_(read_counter),
     43       write_counter_(write_counter) {
     44 }
     45 
     46 bool DnsQueueSequentialTester::Push(void) {
     47   std::ostringstream value;
     48   value << write_counter_;
     49 
     50   // Exercise both write methods intermittently.
     51   DnsQueue::PushResult result = (write_counter_ % 2) ?
     52        buffer_->Push(value.str().c_str(), value.str().size()) :
     53        buffer_->Push(value.str());
     54   if (DnsQueue::SUCCESSFUL_PUSH == result)
     55     write_counter_++;
     56   return DnsQueue::OVERFLOW_PUSH != result;
     57 }
     58 
     59 bool DnsQueueSequentialTester::Pop(void) {
     60   std::string string;
     61   if (buffer_->Pop(&string)) {
     62     std::ostringstream expected_value;
     63     expected_value << read_counter_++;
     64     EXPECT_STREQ(expected_value.str().c_str(), string.c_str())
     65         << "Pop did not match write for value " << read_counter_;
     66     return true;
     67   }
     68   return false;
     69 }
     70 
     71 
     72 TEST(DnsQueueTest, BufferUseCheck) {
     73   // Use a small buffer so we can see that we can't write a string as soon as it
     74   // gets longer than one less than the buffer size.  The extra empty character
     75   // is used to keep read and write pointers from overlapping when buffer is
     76   // full.  This shows the buffer size can constrain writes (and we're not
     77   // scribbling all over memory).
     78   const int buffer_size = 3;  // Just room for 2 digts plus '\0' plus blank.
     79   std::string string;
     80   DnsQueue buffer(buffer_size);
     81   DnsQueueSequentialTester tester(buffer);
     82 
     83   EXPECT_FALSE(tester.Pop()) << "Pop from empty buffer succeeded";
     84 
     85   int i;
     86   for (i = 0; i < 102; i++) {
     87     if (!tester.Push())
     88       break;  // String was too large.
     89     EXPECT_TRUE(tester.Pop()) << "Unable to read back data " << i;
     90     EXPECT_FALSE(buffer.Pop(&string))
     91                 << "read from empty buffer not flagged";
     92   }
     93 
     94   EXPECT_GE(i, 100) << "Can't write 2 digit strings in 4 character buffer";
     95   EXPECT_LT(i, 101) << "We wrote 3 digit strings into a 4 character buffer";
     96 }
     97 
     98 TEST(DnsQueueTest, SubstringUseCheck) {
     99   // Verify that only substring is written/read.
    100   const int buffer_size = 100;
    101   const char big_string[] = "123456789";
    102   std::string string;
    103   DnsQueue buffer(buffer_size);
    104 
    105   EXPECT_FALSE(buffer.Pop(&string)) << "Initial buffer not empty";
    106 
    107   EXPECT_EQ(DnsQueue::SUCCESSFUL_PUSH, buffer.Push(big_string, 3))
    108       << "Can't write string";
    109   EXPECT_EQ(DnsQueue::SUCCESSFUL_PUSH, buffer.Push(big_string, 0))
    110       << "Can't write null string";
    111   EXPECT_EQ(DnsQueue::SUCCESSFUL_PUSH, buffer.Push(big_string, 5))
    112       << "Can't write string";
    113 
    114   EXPECT_TRUE(buffer.Pop(&string)) << "Filled buffer marked as empty";
    115   EXPECT_STREQ(string.c_str(), "123") << "Can't read actual data";
    116   EXPECT_TRUE(buffer.Pop(&string)) << "Filled buffer marked as empty";
    117   EXPECT_STREQ(string.c_str(), "") << "Can't read null string";
    118   EXPECT_TRUE(buffer.Pop(&string)) << "Filled buffer marked as empty";
    119   EXPECT_STREQ(string.c_str(), "12345") << "Can't read actual data";
    120 
    121   EXPECT_FALSE(buffer.Pop(&string))
    122               << "read from empty buffer not flagged";
    123 }
    124 
    125 TEST(DnsQueueTest, SizeCheck) {
    126   // Verify that size is correctly accounted for in buffer.
    127   const int buffer_size = 100;
    128   std::string input_string = "Hello";
    129   std::string string;
    130   DnsQueue buffer(buffer_size);
    131 
    132   EXPECT_EQ(0U, buffer.Size());
    133   EXPECT_FALSE(buffer.Pop(&string));
    134   EXPECT_EQ(DnsQueue::SUCCESSFUL_PUSH, buffer.Push(input_string));
    135   EXPECT_EQ(1U, buffer.Size());
    136   EXPECT_EQ(DnsQueue::SUCCESSFUL_PUSH, buffer.Push("Hi There"));
    137   EXPECT_EQ(2U, buffer.Size());
    138   EXPECT_TRUE(buffer.Pop(&string));
    139   EXPECT_EQ(1U, buffer.Size());
    140   EXPECT_TRUE(buffer.Pop(&string));
    141   EXPECT_EQ(0U, buffer.Size());
    142   EXPECT_EQ(DnsQueue::SUCCESSFUL_PUSH, buffer.Push(input_string));
    143   EXPECT_EQ(1U, buffer.Size());
    144 
    145   // Check to see that the first string, if repeated, is discarded.
    146   EXPECT_EQ(DnsQueue::REDUNDANT_PUSH, buffer.Push(input_string));
    147   EXPECT_EQ(1U, buffer.Size());
    148 }
    149 
    150 TEST(DnsQueueTest, FillThenEmptyCheck) {
    151   // Use a big buffer so we'll get a bunch of writes in.
    152   // This tests to be sure the buffer holds many strings.
    153   // We also make sure they all come out intact.
    154   const size_t buffer_size = 1000;
    155   size_t byte_usage_counter = 1;  // Separation character between pointer.
    156   DnsQueue buffer(buffer_size);
    157   DnsQueueSequentialTester tester(buffer);
    158 
    159   size_t write_success;
    160   for (write_success = 0; write_success < buffer_size; write_success++) {
    161     if (!tester.Push())
    162       break;
    163     EXPECT_EQ(buffer.Size(), write_success + 1);
    164     if (write_success > 99)
    165       byte_usage_counter += 4;  // 3 digit plus '\0'.
    166     else if (write_success > 9)
    167       byte_usage_counter += 3;  // 2 digits plus '\0'.
    168     else
    169       byte_usage_counter += 2;  // Digit plus '\0'.
    170   }
    171   EXPECT_LE(byte_usage_counter, buffer_size)
    172       << "Written data exceeded buffer size";
    173   EXPECT_GE(byte_usage_counter, buffer_size - 4)
    174       << "Buffer does not appear to have filled";
    175 
    176   EXPECT_GE(write_success, 10U) << "Couldn't even write 10 one digit strings "
    177       "in " << buffer_size << " byte buffer";
    178 
    179 
    180   while (1) {
    181     if (!tester.Pop())
    182       break;
    183     write_success--;
    184   }
    185   EXPECT_EQ(write_success, 0U) << "Push and Pop count were different";
    186 
    187   EXPECT_FALSE(tester.Pop()) << "Read from empty buffer succeeded";
    188 }
    189 
    190 TEST(DnsQueueTest, ClearCheck) {
    191   // Use a big buffer so we'll get a bunch of writes in.
    192   const size_t buffer_size = 1000;
    193   DnsQueue buffer(buffer_size);
    194   std::string string("ABC");
    195   DnsQueueSequentialTester tester(buffer);
    196 
    197   size_t write_success;
    198   for (write_success = 0; write_success < buffer_size; write_success++) {
    199     if (!tester.Push())
    200       break;
    201     EXPECT_EQ(buffer.Size(), write_success + 1);
    202   }
    203 
    204   buffer.Clear();
    205   EXPECT_EQ(buffer.Size(), 0U);
    206 
    207   size_t write_success2;
    208   for (write_success2 = 0; write_success2 < buffer_size; write_success2++) {
    209     if (!tester.Push())
    210       break;
    211     EXPECT_EQ(buffer.Size(), write_success2 + 1);
    212   }
    213 
    214   for (; write_success2 > 0; write_success2--) {
    215     EXPECT_EQ(buffer.Size(), write_success2);
    216     EXPECT_TRUE(buffer.Pop(&string));
    217   }
    218 
    219   EXPECT_EQ(buffer.Size(), 0U);
    220   buffer.Clear();
    221   EXPECT_EQ(buffer.Size(), 0U);
    222 }
    223 
    224 TEST(DnsQueueTest, WrapOnVariousSubstrings) {
    225   // Use a prime number for the allocated buffer size so that we tend
    226   // to exercise all possible edge conditions (in circular text buffer).
    227   // Once we're over 10 writes, all our strings are 2 digits long,
    228   // with a '\0' terminator added making 3 characters per write.
    229   // Since 3 is relatively prime to 23, we'll soon wrap (about
    230   // every 6 writes).  Hence after 18 writes, we'll have tested all
    231   // edge conditions.  We'll first do this where we empty the buffer
    232   // after each write, and then again where there are some strings
    233   // still in the buffer after each write.
    234   const int prime_number = 23;
    235   // Circular buffer needs an extra extra space to distinguish full from empty.
    236   const int buffer_size = prime_number - 1;
    237   DnsQueue buffer(buffer_size);
    238   DnsQueueSequentialTester tester(buffer);
    239 
    240   // First test empties between each write. Second loop
    241   // has writes for each pop.  Third has three pushes per pop.
    242   // Third has two items pending during each write.
    243   for (int j = 0; j < 3; j++) {
    244     // Each group does 30 tests, which is more than 10+18
    245     // which was needed to get into the thorough testing zone
    246     // mentioned above.
    247     for (int i = 0; i < 30; i++) {
    248       EXPECT_TRUE(tester.Push()) << "write failed with only " << j
    249                                     << " blocks in buffer";
    250       EXPECT_TRUE(tester.Pop()) << "Unable to read back data ";
    251     }
    252     EXPECT_TRUE(tester.Push());
    253   }
    254 
    255   // Read back the accumulated 3 extra blocks.
    256   EXPECT_TRUE(tester.Pop());
    257   EXPECT_TRUE(tester.Pop());
    258   EXPECT_TRUE(tester.Pop());
    259   EXPECT_FALSE(tester.Pop());
    260 }
    261 
    262 };  // namespace
    263