// Copyright 2014 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // All data that is passed through a WebSocket with type "Text" needs to be // validated as UTF8. Since this is done on the IO thread, it needs to be // reasonably fast. // We are only interested in the performance on valid UTF8. Invalid UTF8 will // result in a connection failure, so is unlikely to become a source of // performance issues. #include "base/i18n/streaming_utf8_validator.h" #include #include #include "base/bind.h" #include "base/callback.h" #include "base/macros.h" #include "base/strings/string_util.h" #include "base/strings/stringprintf.h" #include "base/test/perf_time_logger.h" #include "testing/gtest/include/gtest/gtest.h" namespace base { namespace { // We want to test ranges of valid UTF-8 sequences. These ranges are inclusive. // They are intended to be large enough that the validator needs to do // meaningful work while being in some sense "realistic" (eg. control characters // are not included). const char kOneByteSeqRangeStart[] = " "; // U+0020 const char kOneByteSeqRangeEnd[] = "~"; // U+007E const char kTwoByteSeqRangeStart[] = "\xc2\xa0"; // U+00A0 non-breaking space const char kTwoByteSeqRangeEnd[] = "\xc9\x8f"; // U+024F small y with stroke const char kThreeByteSeqRangeStart[] = "\xe3\x81\x82"; // U+3042 Hiragana "a" const char kThreeByteSeqRangeEnd[] = "\xe9\xbf\x83"; // U+9FC3 "to blink" const char kFourByteSeqRangeStart[] = "\xf0\xa0\x80\x8b"; // U+2000B const char kFourByteSeqRangeEnd[] = "\xf0\xaa\x9a\xb2"; // U+2A6B2 // The different lengths of strings to test. const size_t kTestLengths[] = {1, 32, 256, 32768, 1 << 20}; // Simplest possible byte-at-a-time validator, to provide a baseline // for comparison. This is only tried on 1-byte UTF-8 sequences, as // the results will not be meaningful with sequences containing // top-bit-set bytes. bool IsString7Bit(const std::string& s) { for (std::string::const_iterator it = s.begin(); it != s.end(); ++it) { if (*it & 0x80) return false; } return true; } // Assumes that |previous| is a valid UTF-8 sequence, and attempts to return // the next one. Is just barely smart enough to iterate through the ranges // defined about. std::string NextUtf8Sequence(const std::string& previous) { DCHECK(StreamingUtf8Validator::Validate(previous)); std::string next = previous; for (int i = static_cast(previous.length() - 1); i >= 0; --i) { // All bytes in a UTF-8 sequence except the first one are // constrained to the range 0x80 to 0xbf, inclusive. When we // increment past 0xbf, we carry into the previous byte. if (i > 0 && next[i] == '\xbf') { next[i] = '\x80'; continue; // carry } ++next[i]; break; // no carry } DCHECK(StreamingUtf8Validator::Validate(next)) << "Result \"" << next << "\" failed validation"; return next; } typedef bool (*TestTargetType)(const std::string&); // Run fuction |target| over |test_string| |times| times, and report the results // using |description|. bool RunTest(const std::string& description, TestTargetType target, const std::string& test_string, int times) { base::PerfTimeLogger timer(description.c_str()); bool result = true; for (int i = 0; i < times; ++i) { result = target(test_string) && result; } timer.Done(); return result; } // Construct a string by repeating |input| enough times to equal or exceed // |length|. std::string ConstructRepeatedTestString(const std::string& input, size_t length) { std::string output = input; while (output.length() * 2 < length) { output += output; } if (output.length() < length) { output += ConstructRepeatedTestString(input, length - output.length()); } return output; } // Construct a string by expanding the range of UTF-8 sequences // between |input_start| and |input_end|, inclusive, and then // repeating the resulting string until it equals or exceeds |length| // bytes. |input_start| and |input_end| must be valid UTF-8 // sequences. std::string ConstructRangedTestString(const std::string& input_start, const std::string& input_end, size_t length) { std::string output = input_start; std::string input = input_start; while (output.length() < length && input != input_end) { input = NextUtf8Sequence(input); output += input; } if (output.length() < length) { output = ConstructRepeatedTestString(output, length); } return output; } struct TestFunctionDescription { TestTargetType function; const char* function_name; }; bool IsStringUTF8(const std::string& str) { return base::IsStringUTF8(base::StringPiece(str)); } // IsString7Bit is intentionally placed last so it can be excluded easily. const TestFunctionDescription kTestFunctions[] = { {&StreamingUtf8Validator::Validate, "StreamingUtf8Validator"}, {&IsStringUTF8, "IsStringUTF8"}, {&IsString7Bit, "IsString7Bit"}}; // Construct a test string from |construct_test_string| for each of the lengths // in |kTestLengths| in turn. For each string, run each test in |test_functions| // for a number of iterations such that the total number of bytes validated // is around 16MB. void RunSomeTests( const char format[], base::Callback construct_test_string, const TestFunctionDescription* test_functions, size_t test_count) { for (size_t i = 0; i < arraysize(kTestLengths); ++i) { const size_t length = kTestLengths[i]; const std::string test_string = construct_test_string.Run(length); const int real_length = static_cast(test_string.length()); const int times = (1 << 24) / real_length; for (size_t test_index = 0; test_index < test_count; ++test_index) { EXPECT_TRUE(RunTest(StringPrintf(format, test_functions[test_index].function_name, real_length, times), test_functions[test_index].function, test_string, times)); } } } TEST(StreamingUtf8ValidatorPerfTest, OneByteRepeated) { RunSomeTests("%s: bytes=1 repeated length=%d repeat=%d", base::Bind(ConstructRepeatedTestString, kOneByteSeqRangeStart), kTestFunctions, 3); } TEST(StreamingUtf8ValidatorPerfTest, OneByteRange) { RunSomeTests("%s: bytes=1 ranged length=%d repeat=%d", base::Bind(ConstructRangedTestString, kOneByteSeqRangeStart, kOneByteSeqRangeEnd), kTestFunctions, 3); } TEST(StreamingUtf8ValidatorPerfTest, TwoByteRepeated) { RunSomeTests("%s: bytes=2 repeated length=%d repeat=%d", base::Bind(ConstructRepeatedTestString, kTwoByteSeqRangeStart), kTestFunctions, 2); } TEST(StreamingUtf8ValidatorPerfTest, TwoByteRange) { RunSomeTests("%s: bytes=2 ranged length=%d repeat=%d", base::Bind(ConstructRangedTestString, kTwoByteSeqRangeStart, kTwoByteSeqRangeEnd), kTestFunctions, 2); } TEST(StreamingUtf8ValidatorPerfTest, ThreeByteRepeated) { RunSomeTests( "%s: bytes=3 repeated length=%d repeat=%d", base::Bind(ConstructRepeatedTestString, kThreeByteSeqRangeStart), kTestFunctions, 2); } TEST(StreamingUtf8ValidatorPerfTest, ThreeByteRange) { RunSomeTests("%s: bytes=3 ranged length=%d repeat=%d", base::Bind(ConstructRangedTestString, kThreeByteSeqRangeStart, kThreeByteSeqRangeEnd), kTestFunctions, 2); } TEST(StreamingUtf8ValidatorPerfTest, FourByteRepeated) { RunSomeTests("%s: bytes=4 repeated length=%d repeat=%d", base::Bind(ConstructRepeatedTestString, kFourByteSeqRangeStart), kTestFunctions, 2); } TEST(StreamingUtf8ValidatorPerfTest, FourByteRange) { RunSomeTests("%s: bytes=4 ranged length=%d repeat=%d", base::Bind(ConstructRangedTestString, kFourByteSeqRangeStart, kFourByteSeqRangeEnd), kTestFunctions, 2); } } // namespace } // namespace base