// Copyright (c) 2011 The LevelDB Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. See the AUTHORS file for names of contributors. #include "db/log_reader.h" #include "db/log_writer.h" #include "leveldb/env.h" #include "util/coding.h" #include "util/crc32c.h" #include "util/random.h" #include "util/testharness.h" namespace leveldb { namespace log { // Construct a string of the specified length made out of the supplied // partial string. static std::string BigString(const std::string& partial_string, size_t n) { std::string result; while (result.size() < n) { result.append(partial_string); } result.resize(n); return result; } // Construct a string from a number static std::string NumberString(int n) { char buf[50]; snprintf(buf, sizeof(buf), "%d.", n); return std::string(buf); } // Return a skewed potentially long string static std::string RandomSkewedString(int i, Random* rnd) { return BigString(NumberString(i), rnd->Skewed(17)); } class LogTest { private: class StringDest : public WritableFile { public: std::string contents_; virtual Status Close() { return Status::OK(); } virtual Status Flush() { return Status::OK(); } virtual Status Sync() { return Status::OK(); } virtual Status Append(const Slice& slice) { contents_.append(slice.data(), slice.size()); return Status::OK(); } }; class StringSource : public SequentialFile { public: Slice contents_; bool force_error_; bool returned_partial_; StringSource() : force_error_(false), returned_partial_(false) { } virtual Status Read(size_t n, Slice* result, char* scratch) { ASSERT_TRUE(!returned_partial_) << "must not Read() after eof/error"; if (force_error_) { force_error_ = false; returned_partial_ = true; return Status::Corruption("read error"); } if (contents_.size() < n) { n = contents_.size(); returned_partial_ = true; } *result = Slice(contents_.data(), n); contents_.remove_prefix(n); return Status::OK(); } virtual Status Skip(uint64_t n) { if (n > contents_.size()) { contents_.clear(); return Status::NotFound("in-memory file skipepd past end"); } contents_.remove_prefix(n); return Status::OK(); } }; class ReportCollector : public Reader::Reporter { public: size_t dropped_bytes_; std::string message_; ReportCollector() : dropped_bytes_(0) { } virtual void Corruption(size_t bytes, const Status& status) { dropped_bytes_ += bytes; message_.append(status.ToString()); } }; StringDest dest_; StringSource source_; ReportCollector report_; bool reading_; Writer writer_; Reader reader_; // Record metadata for testing initial offset functionality static size_t initial_offset_record_sizes_[]; static uint64_t initial_offset_last_record_offsets_[]; public: LogTest() : reading_(false), writer_(&dest_), reader_(&source_, &report_, true/*checksum*/, 0/*initial_offset*/) { } void Write(const std::string& msg) { ASSERT_TRUE(!reading_) << "Write() after starting to read"; writer_.AddRecord(Slice(msg)); } size_t WrittenBytes() const { return dest_.contents_.size(); } std::string Read() { if (!reading_) { reading_ = true; source_.contents_ = Slice(dest_.contents_); } std::string scratch; Slice record; if (reader_.ReadRecord(&record, &scratch)) { return record.ToString(); } else { return "EOF"; } } void IncrementByte(int offset, int delta) { dest_.contents_[offset] += delta; } void SetByte(int offset, char new_byte) { dest_.contents_[offset] = new_byte; } void ShrinkSize(int bytes) { dest_.contents_.resize(dest_.contents_.size() - bytes); } void FixChecksum(int header_offset, int len) { // Compute crc of type/len/data uint32_t crc = crc32c::Value(&dest_.contents_[header_offset+6], 1 + len); crc = crc32c::Mask(crc); EncodeFixed32(&dest_.contents_[header_offset], crc); } void ForceError() { source_.force_error_ = true; } size_t DroppedBytes() const { return report_.dropped_bytes_; } std::string ReportMessage() const { return report_.message_; } // Returns OK iff recorded error message contains "msg" std::string MatchError(const std::string& msg) const { if (report_.message_.find(msg) == std::string::npos) { return report_.message_; } else { return "OK"; } } void WriteInitialOffsetLog() { for (int i = 0; i < 4; i++) { std::string record(initial_offset_record_sizes_[i], static_cast('a' + i)); Write(record); } } void CheckOffsetPastEndReturnsNoRecords(uint64_t offset_past_end) { WriteInitialOffsetLog(); reading_ = true; source_.contents_ = Slice(dest_.contents_); Reader* offset_reader = new Reader(&source_, &report_, true/*checksum*/, WrittenBytes() + offset_past_end); Slice record; std::string scratch; ASSERT_TRUE(!offset_reader->ReadRecord(&record, &scratch)); delete offset_reader; } void CheckInitialOffsetRecord(uint64_t initial_offset, int expected_record_offset) { WriteInitialOffsetLog(); reading_ = true; source_.contents_ = Slice(dest_.contents_); Reader* offset_reader = new Reader(&source_, &report_, true/*checksum*/, initial_offset); Slice record; std::string scratch; ASSERT_TRUE(offset_reader->ReadRecord(&record, &scratch)); ASSERT_EQ(initial_offset_record_sizes_[expected_record_offset], record.size()); ASSERT_EQ(initial_offset_last_record_offsets_[expected_record_offset], offset_reader->LastRecordOffset()); ASSERT_EQ((char)('a' + expected_record_offset), record.data()[0]); delete offset_reader; } }; size_t LogTest::initial_offset_record_sizes_[] = {10000, // Two sizable records in first block 10000, 2 * log::kBlockSize - 1000, // Span three blocks 1}; uint64_t LogTest::initial_offset_last_record_offsets_[] = {0, kHeaderSize + 10000, 2 * (kHeaderSize + 10000), 2 * (kHeaderSize + 10000) + (2 * log::kBlockSize - 1000) + 3 * kHeaderSize}; TEST(LogTest, Empty) { ASSERT_EQ("EOF", Read()); } TEST(LogTest, ReadWrite) { Write("foo"); Write("bar"); Write(""); Write("xxxx"); ASSERT_EQ("foo", Read()); ASSERT_EQ("bar", Read()); ASSERT_EQ("", Read()); ASSERT_EQ("xxxx", Read()); ASSERT_EQ("EOF", Read()); ASSERT_EQ("EOF", Read()); // Make sure reads at eof work } TEST(LogTest, ManyBlocks) { for (int i = 0; i < 100000; i++) { Write(NumberString(i)); } for (int i = 0; i < 100000; i++) { ASSERT_EQ(NumberString(i), Read()); } ASSERT_EQ("EOF", Read()); } TEST(LogTest, Fragmentation) { Write("small"); Write(BigString("medium", 50000)); Write(BigString("large", 100000)); ASSERT_EQ("small", Read()); ASSERT_EQ(BigString("medium", 50000), Read()); ASSERT_EQ(BigString("large", 100000), Read()); ASSERT_EQ("EOF", Read()); } TEST(LogTest, MarginalTrailer) { // Make a trailer that is exactly the same length as an empty record. const int n = kBlockSize - 2*kHeaderSize; Write(BigString("foo", n)); ASSERT_EQ(kBlockSize - kHeaderSize, WrittenBytes()); Write(""); Write("bar"); ASSERT_EQ(BigString("foo", n), Read()); ASSERT_EQ("", Read()); ASSERT_EQ("bar", Read()); ASSERT_EQ("EOF", Read()); } TEST(LogTest, MarginalTrailer2) { // Make a trailer that is exactly the same length as an empty record. const int n = kBlockSize - 2*kHeaderSize; Write(BigString("foo", n)); ASSERT_EQ(kBlockSize - kHeaderSize, WrittenBytes()); Write("bar"); ASSERT_EQ(BigString("foo", n), Read()); ASSERT_EQ("bar", Read()); ASSERT_EQ("EOF", Read()); ASSERT_EQ(0, DroppedBytes()); ASSERT_EQ("", ReportMessage()); } TEST(LogTest, ShortTrailer) { const int n = kBlockSize - 2*kHeaderSize + 4; Write(BigString("foo", n)); ASSERT_EQ(kBlockSize - kHeaderSize + 4, WrittenBytes()); Write(""); Write("bar"); ASSERT_EQ(BigString("foo", n), Read()); ASSERT_EQ("", Read()); ASSERT_EQ("bar", Read()); ASSERT_EQ("EOF", Read()); } TEST(LogTest, AlignedEof) { const int n = kBlockSize - 2*kHeaderSize + 4; Write(BigString("foo", n)); ASSERT_EQ(kBlockSize - kHeaderSize + 4, WrittenBytes()); ASSERT_EQ(BigString("foo", n), Read()); ASSERT_EQ("EOF", Read()); } TEST(LogTest, RandomRead) { const int N = 500; Random write_rnd(301); for (int i = 0; i < N; i++) { Write(RandomSkewedString(i, &write_rnd)); } Random read_rnd(301); for (int i = 0; i < N; i++) { ASSERT_EQ(RandomSkewedString(i, &read_rnd), Read()); } ASSERT_EQ("EOF", Read()); } // Tests of all the error paths in log_reader.cc follow: TEST(LogTest, ReadError) { Write("foo"); ForceError(); ASSERT_EQ("EOF", Read()); ASSERT_EQ(kBlockSize, DroppedBytes()); ASSERT_EQ("OK", MatchError("read error")); } TEST(LogTest, BadRecordType) { Write("foo"); // Type is stored in header[6] IncrementByte(6, 100); FixChecksum(0, 3); ASSERT_EQ("EOF", Read()); ASSERT_EQ(3, DroppedBytes()); ASSERT_EQ("OK", MatchError("unknown record type")); } TEST(LogTest, TruncatedTrailingRecord) { Write("foo"); ShrinkSize(4); // Drop all payload as well as a header byte ASSERT_EQ("EOF", Read()); ASSERT_EQ(kHeaderSize - 1, DroppedBytes()); ASSERT_EQ("OK", MatchError("truncated record at end of file")); } TEST(LogTest, BadLength) { Write("foo"); ShrinkSize(1); ASSERT_EQ("EOF", Read()); ASSERT_EQ(kHeaderSize + 2, DroppedBytes()); ASSERT_EQ("OK", MatchError("bad record length")); } TEST(LogTest, ChecksumMismatch) { Write("foo"); IncrementByte(0, 10); ASSERT_EQ("EOF", Read()); ASSERT_EQ(10, DroppedBytes()); ASSERT_EQ("OK", MatchError("checksum mismatch")); } TEST(LogTest, UnexpectedMiddleType) { Write("foo"); SetByte(6, kMiddleType); FixChecksum(0, 3); ASSERT_EQ("EOF", Read()); ASSERT_EQ(3, DroppedBytes()); ASSERT_EQ("OK", MatchError("missing start")); } TEST(LogTest, UnexpectedLastType) { Write("foo"); SetByte(6, kLastType); FixChecksum(0, 3); ASSERT_EQ("EOF", Read()); ASSERT_EQ(3, DroppedBytes()); ASSERT_EQ("OK", MatchError("missing start")); } TEST(LogTest, UnexpectedFullType) { Write("foo"); Write("bar"); SetByte(6, kFirstType); FixChecksum(0, 3); ASSERT_EQ("bar", Read()); ASSERT_EQ("EOF", Read()); ASSERT_EQ(3, DroppedBytes()); ASSERT_EQ("OK", MatchError("partial record without end")); } TEST(LogTest, UnexpectedFirstType) { Write("foo"); Write(BigString("bar", 100000)); SetByte(6, kFirstType); FixChecksum(0, 3); ASSERT_EQ(BigString("bar", 100000), Read()); ASSERT_EQ("EOF", Read()); ASSERT_EQ(3, DroppedBytes()); ASSERT_EQ("OK", MatchError("partial record without end")); } TEST(LogTest, ErrorJoinsRecords) { // Consider two fragmented records: // first(R1) last(R1) first(R2) last(R2) // where the middle two fragments disappear. We do not want // first(R1),last(R2) to get joined and returned as a valid record. // Write records that span two blocks Write(BigString("foo", kBlockSize)); Write(BigString("bar", kBlockSize)); Write("correct"); // Wipe the middle block for (int offset = kBlockSize; offset < 2*kBlockSize; offset++) { SetByte(offset, 'x'); } ASSERT_EQ("correct", Read()); ASSERT_EQ("EOF", Read()); const int dropped = DroppedBytes(); ASSERT_LE(dropped, 2*kBlockSize + 100); ASSERT_GE(dropped, 2*kBlockSize); } TEST(LogTest, ReadStart) { CheckInitialOffsetRecord(0, 0); } TEST(LogTest, ReadSecondOneOff) { CheckInitialOffsetRecord(1, 1); } TEST(LogTest, ReadSecondTenThousand) { CheckInitialOffsetRecord(10000, 1); } TEST(LogTest, ReadSecondStart) { CheckInitialOffsetRecord(10007, 1); } TEST(LogTest, ReadThirdOneOff) { CheckInitialOffsetRecord(10008, 2); } TEST(LogTest, ReadThirdStart) { CheckInitialOffsetRecord(20014, 2); } TEST(LogTest, ReadFourthOneOff) { CheckInitialOffsetRecord(20015, 3); } TEST(LogTest, ReadFourthFirstBlockTrailer) { CheckInitialOffsetRecord(log::kBlockSize - 4, 3); } TEST(LogTest, ReadFourthMiddleBlock) { CheckInitialOffsetRecord(log::kBlockSize + 1, 3); } TEST(LogTest, ReadFourthLastBlock) { CheckInitialOffsetRecord(2 * log::kBlockSize + 1, 3); } TEST(LogTest, ReadFourthStart) { CheckInitialOffsetRecord( 2 * (kHeaderSize + 1000) + (2 * log::kBlockSize - 1000) + 3 * kHeaderSize, 3); } TEST(LogTest, ReadEnd) { CheckOffsetPastEndReturnsNoRecords(0); } TEST(LogTest, ReadPastEnd) { CheckOffsetPastEndReturnsNoRecords(5); } } // namespace log } // namespace leveldb int main(int argc, char** argv) { return leveldb::test::RunAllTests(); }