lib/cpp/test/ZlibTest.cpp - thrift - Git at Google

 /*
  * Licensed to the Apache Software Foundation (ASF) under one
  * or more contributor license agreements. See the NOTICE file
  * distributed with this work for additional information
  * regarding copyright ownership. The ASF licenses this file
  * to you under the Apache License, Version 2.0 (the
  * "License"); you may not use this file except in compliance
  * with the License. You may obtain a copy of the License at
  *
  *   http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing,
  * software distributed under the License is distributed on an
  * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
  * KIND, either express or implied. See the License for the
  * specific language governing permissions and limitations
  * under the License.
  */

 #define __STDC_LIMIT_MACROS
 #define __STDC_FORMAT_MACROS

 #ifndef _GNU_SOURCE
 #define _GNU_SOURCE // needed for getopt_long
 #endif

 #include <stdint.h>
 #include <inttypes.h>
 #include <getopt.h>
 #include <cstddef>
 #include <fstream>
 #include <iostream>
 #include <tr1/functional>

 #include <boost/random.hpp>
 #include <boost/shared_array.hpp>
 #include <boost/test/unit_test.hpp>

 #include <transport/TBufferTransports.h>
 #include <transport/TZlibTransport.h>

 using namespace std;
 using namespace boost;
 using namespace apache::thrift::transport;

 boost::mt19937 rng;

 /*
  * Utility code
  */

 class SizeGenerator {
  public:
   virtual ~SizeGenerator() {}
   virtual unsigned int getSize() = 0;
 };

 class ConstantSizeGenerator : public SizeGenerator {
  public:
   ConstantSizeGenerator(unsigned int value) : value_(value) {}
   virtual unsigned int getSize() {
     return value_;
   }

  private:
   unsigned int value_;
 };

 class LogNormalSizeGenerator : public SizeGenerator {
  public:
   LogNormalSizeGenerator(double mean, double std_dev) :
       gen_(rng, lognormal_distribution<double>(mean, std_dev)) {}

   virtual unsigned int getSize() {
     // Loop until we get a size of 1 or more
     while (true) {
       unsigned int value = static_cast<unsigned int>(gen_());
       if (value >= 1) {
         return value;
       }
     }
   }

  private:
   variate_generator< mt19937, lognormal_distribution<double> > gen_;
 };

 uint8_t* gen_uniform_buffer(uint32_t buf_len, uint8_t c) {
   uint8_t* buf = new uint8_t[buf_len];
   memset(buf, c, buf_len);
   return buf;
 }

 uint8_t* gen_compressible_buffer(uint32_t buf_len) {
   uint8_t* buf = new uint8_t[buf_len];

   // Generate small runs of alternately increasing and decreasing bytes
   boost::uniform_smallint<uint32_t> run_length_distribution(1, 64);
   boost::uniform_smallint<uint8_t> byte_distribution(0, UINT8_MAX);
   boost::variate_generator< boost::mt19937, boost::uniform_smallint<uint8_t> >
     byte_generator(rng, byte_distribution);
   boost::variate_generator< boost::mt19937, boost::uniform_smallint<uint32_t> >
     run_len_generator(rng, run_length_distribution);

   uint32_t idx = 0;
   int8_t step = 1;
   while (idx < buf_len) {
     uint32_t run_length = run_len_generator();
     if (idx + run_length > buf_len) {
       run_length = buf_len - idx;
     }

     uint8_t byte = byte_generator();
     for (uint32_t n = 0; n < run_length; ++n) {
       buf[idx] = byte;
       ++idx;
       byte += step;
     }

     step *= -1;
   }

   return buf;
 }

 uint8_t* gen_random_buffer(uint32_t buf_len) {
   uint8_t* buf = new uint8_t[buf_len];

   boost::uniform_smallint<uint8_t> distribution(0, UINT8_MAX);
   boost::variate_generator< boost::mt19937, boost::uniform_smallint<uint8_t> >
     generator(rng, distribution);

   for (uint32_t n = 0; n < buf_len; ++n) {
     buf[n] = generator();
   }

   return buf;
 }

 /*
  * Test functions
  */

 void test_write_then_read(const uint8_t* buf, uint32_t buf_len) {
   shared_ptr<TMemoryBuffer> membuf(new TMemoryBuffer());
   shared_ptr<TZlibTransport> zlib_trans(new TZlibTransport(membuf));
   zlib_trans->write(buf, buf_len);
   zlib_trans->finish();

   boost::shared_array<uint8_t> mirror(new uint8_t[buf_len]);
   uint32_t got = zlib_trans->readAll(mirror.get(), buf_len);
   BOOST_REQUIRE_EQUAL(got, buf_len);
   BOOST_CHECK_EQUAL(memcmp(mirror.get(), buf, buf_len), 0);
   zlib_trans->verifyChecksum();
 }

 void test_separate_checksum(const uint8_t* buf, uint32_t buf_len) {
   // This one is tricky.  I separate the last byte of the stream out
   // into a separate crbuf_.  The last byte is part of the checksum,
   // so the entire read goes fine, but when I go to verify the checksum
   // it isn't there.  The original implementation complained that
   // the stream was not complete.  I'm about to go fix that.
   // It worked.  Awesome.
   shared_ptr<TMemoryBuffer> membuf(new TMemoryBuffer());
   shared_ptr<TZlibTransport> zlib_trans(new TZlibTransport(membuf));
   zlib_trans->write(buf, buf_len);
   zlib_trans->finish();
   string tmp_buf;
   membuf->appendBufferToString(tmp_buf);
   zlib_trans.reset(new TZlibTransport(membuf,
                                       TZlibTransport::DEFAULT_URBUF_SIZE,
                                       tmp_buf.length()-1));

   boost::shared_array<uint8_t> mirror(new uint8_t[buf_len]);
   uint32_t got = zlib_trans->readAll(mirror.get(), buf_len);
   BOOST_REQUIRE_EQUAL(got, buf_len);
   BOOST_CHECK_EQUAL(memcmp(mirror.get(), buf, buf_len), 0);
   zlib_trans->verifyChecksum();
 }

 void test_incomplete_checksum(const uint8_t* buf, uint32_t buf_len) {
   // Make sure we still get that "not complete" error if
   // it really isn't complete.
   shared_ptr<TMemoryBuffer> membuf(new TMemoryBuffer());
   shared_ptr<TZlibTransport> zlib_trans(new TZlibTransport(membuf));
   zlib_trans->write(buf, buf_len);
   zlib_trans->finish();
   string tmp_buf;
   membuf->appendBufferToString(tmp_buf);
   tmp_buf.erase(tmp_buf.length() - 1);
   membuf->resetBuffer(const_cast<uint8_t*>(
                         reinterpret_cast<const uint8_t*>(tmp_buf.data())),
                       tmp_buf.length());

   boost::shared_array<uint8_t> mirror(new uint8_t[buf_len]);
   uint32_t got = zlib_trans->readAll(mirror.get(), buf_len);
   BOOST_REQUIRE_EQUAL(got, buf_len);
   BOOST_CHECK_EQUAL(memcmp(mirror.get(), buf, buf_len), 0);
   try {
     zlib_trans->verifyChecksum();
     BOOST_ERROR("verifyChecksum() did not report an error");
   } catch (TTransportException& ex) {
     BOOST_CHECK_EQUAL(ex.getType(), TTransportException::CORRUPTED_DATA);
   }
 }

 void test_read_write_mix(const uint8_t* buf, uint32_t buf_len,
                          const shared_ptr<SizeGenerator>& write_gen,
                          const shared_ptr<SizeGenerator>& read_gen) {
   // Try it with a mix of read/write sizes.
   shared_ptr<TMemoryBuffer> membuf(new TMemoryBuffer());
   shared_ptr<TZlibTransport> zlib_trans(new TZlibTransport(membuf));
   unsigned int tot;

   tot = 0;
   while (tot < buf_len) {
     uint32_t write_len = write_gen->getSize();
     if (tot + write_len > buf_len) {
       write_len = buf_len - tot;
     }
     zlib_trans->write(buf + tot, write_len);
     tot += write_len;
   }

   zlib_trans->finish();

   tot = 0;
   boost::shared_array<uint8_t> mirror(new uint8_t[buf_len]);
   while (tot < buf_len) {
     uint32_t read_len = read_gen->getSize();
     uint32_t expected_read_len = read_len;
     if (tot + read_len > buf_len) {
       expected_read_len = buf_len - tot;
     }
     uint32_t got = zlib_trans->read(mirror.get() + tot, read_len);
     BOOST_REQUIRE_LE(got, expected_read_len);
     BOOST_REQUIRE_NE(got, (uint32_t) 0);
     tot += got;
   }

   BOOST_CHECK_EQUAL(memcmp(mirror.get(), buf, buf_len), 0);
   zlib_trans->verifyChecksum();
 }

 void test_invalid_checksum(const uint8_t* buf, uint32_t buf_len) {
   // Verify checksum checking.
   shared_ptr<TMemoryBuffer> membuf(new TMemoryBuffer());
   shared_ptr<TZlibTransport> zlib_trans(new TZlibTransport(membuf));
   zlib_trans->write(buf, buf_len);
   zlib_trans->finish();
   string tmp_buf;
   membuf->appendBufferToString(tmp_buf);
   // Modify a byte at the end of the buffer (part of the checksum).
   // On rare occasions, modifying a byte in the middle of the buffer
   // isn't caught by the checksum.
   //
   // (This happens especially often for the uniform buffer.  The
   // re-inflated data is correct, however.  I suspect in this case that
   // we're more likely to modify bytes that are part of zlib metadata
   // instead of the actual compressed data.)
   //
   // I've also seen some failure scenarios where a checksum failure isn't
   // reported, but zlib keeps trying to decode past the end of the data.
   // (When this occurs, verifyChecksum() throws an exception indicating
   // that the end of the data hasn't been reached.)  I haven't seen this
   // error when only modifying checksum bytes.
   int index = tmp_buf.size() - 1;
   tmp_buf[index]++;
   membuf->resetBuffer(const_cast<uint8_t*>(
                         reinterpret_cast<const uint8_t*>(tmp_buf.data())),
                       tmp_buf.length());

   boost::shared_array<uint8_t> mirror(new uint8_t[buf_len]);
   try {
     zlib_trans->readAll(mirror.get(), buf_len);
     zlib_trans->verifyChecksum();
     BOOST_ERROR("verifyChecksum() did not report an error");
   } catch (TZlibTransportException& ex) {
     BOOST_CHECK_EQUAL(ex.getType(), TTransportException::INTERNAL_ERROR);
   }
 }

 void test_write_after_flush(const uint8_t* buf, uint32_t buf_len) {
   // write some data
   shared_ptr<TMemoryBuffer> membuf(new TMemoryBuffer());
   shared_ptr<TZlibTransport> zlib_trans(new TZlibTransport(membuf));
   zlib_trans->write(buf, buf_len);

   // call finish()
   zlib_trans->finish();

   // make sure write() throws an error
   try {
     uint8_t write_buf[] = "a";
     zlib_trans->write(write_buf, 1);
     BOOST_ERROR("write() after finish() did not raise an exception");
   } catch (TTransportException& ex) {
     BOOST_CHECK_EQUAL(ex.getType(), TTransportException::BAD_ARGS);
   }

   // make sure flush() throws an error
   try {
     zlib_trans->flush();
     BOOST_ERROR("flush() after finish() did not raise an exception");
   } catch (TTransportException& ex) {
     BOOST_CHECK_EQUAL(ex.getType(), TTransportException::BAD_ARGS);
   }

   // make sure finish() throws an error
   try {
     zlib_trans->finish();
     BOOST_ERROR("finish() after finish() did not raise an exception");
   } catch (TTransportException& ex) {
     BOOST_CHECK_EQUAL(ex.getType(), TTransportException::BAD_ARGS);
   }
 }

 void test_no_write() {
   // Verify that no data is written to the underlying transport if we
   // never write data to the TZlibTransport.
   shared_ptr<TMemoryBuffer> membuf(new TMemoryBuffer());
   {
     // Create a TZlibTransport object, and immediately destroy it
     // when it goes out of scope.
     TZlibTransport w_zlib_trans(membuf);
   }

   BOOST_CHECK_EQUAL(membuf->available_read(), (uint32_t) 0);
 }

 /*
  * Initialization
  */

 #define ADD_TEST_CASE(suite, name, function, ...) \
   do { \
     ::std::ostringstream name_ss; \
     name_ss << name << "-" << BOOST_STRINGIZE(function); \
     ::boost::unit_test::test_case* tc = ::boost::unit_test::make_test_case( \
         ::std::tr1::bind(function, ## __VA_ARGS__), \
         name_ss.str()); \
     (suite)->add(tc); \
   } while (0)

 void add_tests(unit_test::test_suite* suite,
                const uint8_t* buf,
                uint32_t buf_len,
                const char* name) {
   ADD_TEST_CASE(suite, name, test_write_then_read, buf, buf_len);
   ADD_TEST_CASE(suite, name, test_separate_checksum, buf, buf_len);
   ADD_TEST_CASE(suite, name, test_incomplete_checksum, buf, buf_len);
   ADD_TEST_CASE(suite, name, test_invalid_checksum, buf, buf_len);
   ADD_TEST_CASE(suite, name, test_write_after_flush, buf, buf_len);

   shared_ptr<SizeGenerator> size_32k(new ConstantSizeGenerator(1<<15));
   shared_ptr<SizeGenerator> size_lognormal(new LogNormalSizeGenerator(20, 30));
   ADD_TEST_CASE(suite, name << "-constant",
                 test_read_write_mix, buf, buf_len,
                 size_32k, size_32k);
   ADD_TEST_CASE(suite, name << "-lognormal-write",
                 test_read_write_mix, buf, buf_len,
                 size_lognormal, size_32k);
   ADD_TEST_CASE(suite, name << "-lognormal-read",
                 test_read_write_mix, buf, buf_len,
                 size_32k, size_lognormal);
   ADD_TEST_CASE(suite, name << "-lognormal-both",
                 test_read_write_mix, buf, buf_len,
                 size_lognormal, size_lognormal);

   // Test with a random size distribution,
   // but use the exact same distribution for reading as for writing.
   //
   // Because the SizeGenerator makes a copy of the random number generator,
   // both SizeGenerators should return the exact same set of values, since they
   // both start with random number generators in the same state.
   shared_ptr<SizeGenerator> write_size_gen(new LogNormalSizeGenerator(20, 30));
   shared_ptr<SizeGenerator> read_size_gen(new LogNormalSizeGenerator(20, 30));
   ADD_TEST_CASE(suite, name << "-lognormal-same-distribution",
                 test_read_write_mix, buf, buf_len,
                 write_size_gen, read_size_gen);
 }

 void print_usage(FILE* f, const char* argv0) {
   fprintf(f, "Usage: %s [boost_options] [options]\n", argv0);
   fprintf(f, "Options:\n");
   fprintf(f, "  --seed=<N>, -s <N>\n");
   fprintf(f, "  --help\n");
 }

 void parse_args(int argc, char* argv[]) {
   uint32_t seed = 0;
   bool has_seed = false;

   struct option long_opts[] = {
     { "help", false, NULL, 'h' },
     { "seed", true, NULL, 's' },
     { NULL, 0, NULL, 0 }
   };

   while (true) {
     optopt = 1;
     int optchar = getopt_long(argc, argv, "hs:", long_opts, NULL);
     if (optchar == -1) {
       break;
     }

     switch (optchar) {
       case 's': {
         char *endptr;
         seed = strtol(optarg, &endptr, 0);
         if (endptr == optarg || *endptr != '\0') {
           fprintf(stderr, "invalid seed value \"%s\": must be a positive "
                   "integer\n", optarg);
           exit(1);
         }
         has_seed = true;
         break;
       }
       case 'h':
         print_usage(stdout, argv[0]);
         exit(0);
       case '?':
         exit(1);
       default:
         // Only happens if someone adds another option to the optarg string,
         // but doesn't update the switch statement to handle it.
         fprintf(stderr, "unknown option \"-%c\"\n", optchar);
         exit(1);
     }
   }

   if (!has_seed) {
     seed = time(NULL);
   }

   printf("seed: %" PRIu32 "\n", seed);
   rng.seed(seed);
 }

 unit_test::test_suite* init_unit_test_suite(int argc, char* argv[]) {
   parse_args(argc, argv);

   unit_test::test_suite* suite =
     &boost::unit_test::framework::master_test_suite();
   suite->p_name.value = "ZlibTest";

   uint32_t buf_len = 1024*32;
   add_tests(suite, gen_uniform_buffer(buf_len, 'a'), buf_len, "uniform");
   add_tests(suite, gen_compressible_buffer(buf_len), buf_len, "compressible");
   add_tests(suite, gen_random_buffer(buf_len), buf_len, "random");

   suite->add(BOOST_TEST_CASE(test_no_write));

   return NULL;
 }
	/*
	* Licensed to the Apache Software Foundation (ASF) under one
	* or more contributor license agreements. See the NOTICE file
	* distributed with this work for additional information
	* regarding copyright ownership. The ASF licenses this file
	* to you under the Apache License, Version 2.0 (the
	* "License"); you may not use this file except in compliance
	* with the License. You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing,
	* software distributed under the License is distributed on an
	* "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
	* KIND, either express or implied. See the License for the
	* specific language governing permissions and limitations
	* under the License.
	*/

	#define __STDC_LIMIT_MACROS
	#define __STDC_FORMAT_MACROS

	#ifndef _GNU_SOURCE
	#define _GNU_SOURCE // needed for getopt_long
	#endif

	#include <stdint.h>
	#include <inttypes.h>
	#include <getopt.h>
	#include <cstddef>
	#include <fstream>
	#include <iostream>
	#include <tr1/functional>

	#include <boost/random.hpp>
	#include <boost/shared_array.hpp>
	#include <boost/test/unit_test.hpp>

	#include <transport/TBufferTransports.h>
	#include <transport/TZlibTransport.h>

	using namespace std;
	using namespace boost;
	using namespace apache::thrift::transport;

	boost::mt19937 rng;

	/*
	* Utility code
	*/

	class SizeGenerator {
	public:
	virtual ~SizeGenerator() {}
	virtual unsigned int getSize() = 0;
	};

	class ConstantSizeGenerator : public SizeGenerator {
	public:
	ConstantSizeGenerator(unsigned int value) : value_(value) {}
	virtual unsigned int getSize() {
	return value_;
	}

	private:
	unsigned int value_;
	};

	class LogNormalSizeGenerator : public SizeGenerator {
	public:
	LogNormalSizeGenerator(double mean, double std_dev) :
	gen_(rng, lognormal_distribution<double>(mean, std_dev)) {}

	virtual unsigned int getSize() {
	// Loop until we get a size of 1 or more
	while (true) {
	unsigned int value = static_cast<unsigned int>(gen_());
	if (value >= 1) {
	return value;
	}
	}
	}

	private:
	variate_generator< mt19937, lognormal_distribution<double> > gen_;
	};

	uint8_t* gen_uniform_buffer(uint32_t buf_len, uint8_t c) {
	uint8_t* buf = new uint8_t[buf_len];
	memset(buf, c, buf_len);
	return buf;
	}

	uint8_t* gen_compressible_buffer(uint32_t buf_len) {
	uint8_t* buf = new uint8_t[buf_len];

	// Generate small runs of alternately increasing and decreasing bytes
	boost::uniform_smallint<uint32_t> run_length_distribution(1, 64);
	boost::uniform_smallint<uint8_t> byte_distribution(0, UINT8_MAX);
	boost::variate_generator< boost::mt19937, boost::uniform_smallint<uint8_t> >
	byte_generator(rng, byte_distribution);
	boost::variate_generator< boost::mt19937, boost::uniform_smallint<uint32_t> >
	run_len_generator(rng, run_length_distribution);

	uint32_t idx = 0;
	int8_t step = 1;
	while (idx < buf_len) {
	uint32_t run_length = run_len_generator();
	if (idx + run_length > buf_len) {
	run_length = buf_len - idx;
	}

	uint8_t byte = byte_generator();
	for (uint32_t n = 0; n < run_length; ++n) {
	buf[idx] = byte;
	++idx;
	byte += step;
	}

	step *= -1;
	}

	return buf;
	}

	uint8_t* gen_random_buffer(uint32_t buf_len) {
	uint8_t* buf = new uint8_t[buf_len];

	boost::uniform_smallint<uint8_t> distribution(0, UINT8_MAX);
	boost::variate_generator< boost::mt19937, boost::uniform_smallint<uint8_t> >
	generator(rng, distribution);

	for (uint32_t n = 0; n < buf_len; ++n) {
	buf[n] = generator();
	}

	return buf;
	}

	/*
	* Test functions
	*/

	void test_write_then_read(const uint8_t* buf, uint32_t buf_len) {
	shared_ptr<TMemoryBuffer> membuf(new TMemoryBuffer());
	shared_ptr<TZlibTransport> zlib_trans(new TZlibTransport(membuf));
	zlib_trans->write(buf, buf_len);
	zlib_trans->finish();

	boost::shared_array<uint8_t> mirror(new uint8_t[buf_len]);
	uint32_t got = zlib_trans->readAll(mirror.get(), buf_len);
	BOOST_REQUIRE_EQUAL(got, buf_len);
	BOOST_CHECK_EQUAL(memcmp(mirror.get(), buf, buf_len), 0);
	zlib_trans->verifyChecksum();
	}

	void test_separate_checksum(const uint8_t* buf, uint32_t buf_len) {
	// This one is tricky. I separate the last byte of the stream out
	// into a separate crbuf_. The last byte is part of the checksum,
	// so the entire read goes fine, but when I go to verify the checksum
	// it isn't there. The original implementation complained that
	// the stream was not complete. I'm about to go fix that.
	// It worked. Awesome.
	shared_ptr<TMemoryBuffer> membuf(new TMemoryBuffer());
	shared_ptr<TZlibTransport> zlib_trans(new TZlibTransport(membuf));
	zlib_trans->write(buf, buf_len);
	zlib_trans->finish();
	string tmp_buf;
	membuf->appendBufferToString(tmp_buf);
	zlib_trans.reset(new TZlibTransport(membuf,
	TZlibTransport::DEFAULT_URBUF_SIZE,
	tmp_buf.length()-1));

	boost::shared_array<uint8_t> mirror(new uint8_t[buf_len]);
	uint32_t got = zlib_trans->readAll(mirror.get(), buf_len);
	BOOST_REQUIRE_EQUAL(got, buf_len);
	BOOST_CHECK_EQUAL(memcmp(mirror.get(), buf, buf_len), 0);
	zlib_trans->verifyChecksum();
	}

	void test_incomplete_checksum(const uint8_t* buf, uint32_t buf_len) {
	// Make sure we still get that "not complete" error if
	// it really isn't complete.
	shared_ptr<TMemoryBuffer> membuf(new TMemoryBuffer());
	shared_ptr<TZlibTransport> zlib_trans(new TZlibTransport(membuf));
	zlib_trans->write(buf, buf_len);
	zlib_trans->finish();
	string tmp_buf;
	membuf->appendBufferToString(tmp_buf);
	tmp_buf.erase(tmp_buf.length() - 1);
	membuf->resetBuffer(const_cast<uint8_t*>(
	reinterpret_cast<const uint8_t*>(tmp_buf.data())),
	tmp_buf.length());

	boost::shared_array<uint8_t> mirror(new uint8_t[buf_len]);
	uint32_t got = zlib_trans->readAll(mirror.get(), buf_len);
	BOOST_REQUIRE_EQUAL(got, buf_len);
	BOOST_CHECK_EQUAL(memcmp(mirror.get(), buf, buf_len), 0);
	try {
	zlib_trans->verifyChecksum();
	BOOST_ERROR("verifyChecksum() did not report an error");
	} catch (TTransportException& ex) {
	BOOST_CHECK_EQUAL(ex.getType(), TTransportException::CORRUPTED_DATA);
	}
	}

	void test_read_write_mix(const uint8_t* buf, uint32_t buf_len,
	const shared_ptr<SizeGenerator>& write_gen,
	const shared_ptr<SizeGenerator>& read_gen) {
	// Try it with a mix of read/write sizes.
	shared_ptr<TMemoryBuffer> membuf(new TMemoryBuffer());
	shared_ptr<TZlibTransport> zlib_trans(new TZlibTransport(membuf));
	unsigned int tot;

	tot = 0;
	while (tot < buf_len) {
	uint32_t write_len = write_gen->getSize();
	if (tot + write_len > buf_len) {
	write_len = buf_len - tot;
	}
	zlib_trans->write(buf + tot, write_len);
	tot += write_len;
	}

	zlib_trans->finish();

	tot = 0;
	boost::shared_array<uint8_t> mirror(new uint8_t[buf_len]);
	while (tot < buf_len) {
	uint32_t read_len = read_gen->getSize();
	uint32_t expected_read_len = read_len;
	if (tot + read_len > buf_len) {
	expected_read_len = buf_len - tot;
	}
	uint32_t got = zlib_trans->read(mirror.get() + tot, read_len);
	BOOST_REQUIRE_LE(got, expected_read_len);
	BOOST_REQUIRE_NE(got, (uint32_t) 0);
	tot += got;
	}

	BOOST_CHECK_EQUAL(memcmp(mirror.get(), buf, buf_len), 0);
	zlib_trans->verifyChecksum();
	}

	void test_invalid_checksum(const uint8_t* buf, uint32_t buf_len) {
	// Verify checksum checking.
	shared_ptr<TMemoryBuffer> membuf(new TMemoryBuffer());
	shared_ptr<TZlibTransport> zlib_trans(new TZlibTransport(membuf));
	zlib_trans->write(buf, buf_len);
	zlib_trans->finish();
	string tmp_buf;
	membuf->appendBufferToString(tmp_buf);
	// Modify a byte at the end of the buffer (part of the checksum).
	// On rare occasions, modifying a byte in the middle of the buffer
	// isn't caught by the checksum.
	//
	// (This happens especially often for the uniform buffer. The
	// re-inflated data is correct, however. I suspect in this case that
	// we're more likely to modify bytes that are part of zlib metadata
	// instead of the actual compressed data.)
	//
	// I've also seen some failure scenarios where a checksum failure isn't
	// reported, but zlib keeps trying to decode past the end of the data.
	// (When this occurs, verifyChecksum() throws an exception indicating
	// that the end of the data hasn't been reached.) I haven't seen this
	// error when only modifying checksum bytes.
	int index = tmp_buf.size() - 1;
	tmp_buf[index]++;
	membuf->resetBuffer(const_cast<uint8_t*>(
	reinterpret_cast<const uint8_t*>(tmp_buf.data())),
	tmp_buf.length());

	boost::shared_array<uint8_t> mirror(new uint8_t[buf_len]);
	try {
	zlib_trans->readAll(mirror.get(), buf_len);
	zlib_trans->verifyChecksum();
	BOOST_ERROR("verifyChecksum() did not report an error");
	} catch (TZlibTransportException& ex) {
	BOOST_CHECK_EQUAL(ex.getType(), TTransportException::INTERNAL_ERROR);
	}
	}

	void test_write_after_flush(const uint8_t* buf, uint32_t buf_len) {
	// write some data
	shared_ptr<TMemoryBuffer> membuf(new TMemoryBuffer());
	shared_ptr<TZlibTransport> zlib_trans(new TZlibTransport(membuf));
	zlib_trans->write(buf, buf_len);

	// call finish()
	zlib_trans->finish();

	// make sure write() throws an error
	try {
	uint8_t write_buf[] = "a";
	zlib_trans->write(write_buf, 1);
	BOOST_ERROR("write() after finish() did not raise an exception");
	} catch (TTransportException& ex) {
	BOOST_CHECK_EQUAL(ex.getType(), TTransportException::BAD_ARGS);
	}

	// make sure flush() throws an error
	try {
	zlib_trans->flush();
	BOOST_ERROR("flush() after finish() did not raise an exception");
	} catch (TTransportException& ex) {
	BOOST_CHECK_EQUAL(ex.getType(), TTransportException::BAD_ARGS);
	}

	// make sure finish() throws an error
	try {
	zlib_trans->finish();
	BOOST_ERROR("finish() after finish() did not raise an exception");
	} catch (TTransportException& ex) {
	BOOST_CHECK_EQUAL(ex.getType(), TTransportException::BAD_ARGS);
	}
	}

	void test_no_write() {
	// Verify that no data is written to the underlying transport if we
	// never write data to the TZlibTransport.
	shared_ptr<TMemoryBuffer> membuf(new TMemoryBuffer());
	{
	// Create a TZlibTransport object, and immediately destroy it
	// when it goes out of scope.
	TZlibTransport w_zlib_trans(membuf);
	}

	BOOST_CHECK_EQUAL(membuf->available_read(), (uint32_t) 0);
	}

	/*
	* Initialization
	*/

	#define ADD_TEST_CASE(suite, name, function, ...) \
	do { \
	::std::ostringstream name_ss; \
	name_ss << name << "-" << BOOST_STRINGIZE(function); \
	::boost::unit_test::test_case* tc = ::boost::unit_test::make_test_case( \
	::std::tr1::bind(function, ## __VA_ARGS__), \
	name_ss.str()); \
	(suite)->add(tc); \
	} while (0)

	void add_tests(unit_test::test_suite* suite,
	const uint8_t* buf,
	uint32_t buf_len,
	const char* name) {
	ADD_TEST_CASE(suite, name, test_write_then_read, buf, buf_len);
	ADD_TEST_CASE(suite, name, test_separate_checksum, buf, buf_len);
	ADD_TEST_CASE(suite, name, test_incomplete_checksum, buf, buf_len);
	ADD_TEST_CASE(suite, name, test_invalid_checksum, buf, buf_len);
	ADD_TEST_CASE(suite, name, test_write_after_flush, buf, buf_len);

	shared_ptr<SizeGenerator> size_32k(new ConstantSizeGenerator(1<<15));
	shared_ptr<SizeGenerator> size_lognormal(new LogNormalSizeGenerator(20, 30));
	ADD_TEST_CASE(suite, name << "-constant",
	test_read_write_mix, buf, buf_len,
	size_32k, size_32k);
	ADD_TEST_CASE(suite, name << "-lognormal-write",
	test_read_write_mix, buf, buf_len,
	size_lognormal, size_32k);
	ADD_TEST_CASE(suite, name << "-lognormal-read",
	test_read_write_mix, buf, buf_len,
	size_32k, size_lognormal);
	ADD_TEST_CASE(suite, name << "-lognormal-both",
	test_read_write_mix, buf, buf_len,
	size_lognormal, size_lognormal);

	// Test with a random size distribution,
	// but use the exact same distribution for reading as for writing.
	//
	// Because the SizeGenerator makes a copy of the random number generator,
	// both SizeGenerators should return the exact same set of values, since they
	// both start with random number generators in the same state.
	shared_ptr<SizeGenerator> write_size_gen(new LogNormalSizeGenerator(20, 30));
	shared_ptr<SizeGenerator> read_size_gen(new LogNormalSizeGenerator(20, 30));
	ADD_TEST_CASE(suite, name << "-lognormal-same-distribution",
	test_read_write_mix, buf, buf_len,
	write_size_gen, read_size_gen);
	}

	void print_usage(FILE* f, const char* argv0) {
	fprintf(f, "Usage: %s [boost_options] [options]\n", argv0);
	fprintf(f, "Options:\n");
	fprintf(f, " --seed=<N>, -s <N>\n");
	fprintf(f, " --help\n");
	}

	void parse_args(int argc, char* argv[]) {
	uint32_t seed = 0;
	bool has_seed = false;

	struct option long_opts[] = {
	{ "help", false, NULL, 'h' },
	{ "seed", true, NULL, 's' },
	{ NULL, 0, NULL, 0 }
	};

	while (true) {
	optopt = 1;
	int optchar = getopt_long(argc, argv, "hs:", long_opts, NULL);
	if (optchar == -1) {
	break;
	}

	switch (optchar) {
	case 's': {
	char *endptr;
	seed = strtol(optarg, &endptr, 0);
	if (endptr == optarg \|\| *endptr != '\0') {
	fprintf(stderr, "invalid seed value \"%s\": must be a positive "
	"integer\n", optarg);
	exit(1);
	}
	has_seed = true;
	break;
	}
	case 'h':
	print_usage(stdout, argv[0]);
	exit(0);
	case '?':
	exit(1);
	default:
	// Only happens if someone adds another option to the optarg string,
	// but doesn't update the switch statement to handle it.
	fprintf(stderr, "unknown option \"-%c\"\n", optchar);
	exit(1);
	}
	}

	if (!has_seed) {
	seed = time(NULL);
	}

	printf("seed: %" PRIu32 "\n", seed);
	rng.seed(seed);
	}

	unit_test::test_suite* init_unit_test_suite(int argc, char* argv[]) {
	parse_args(argc, argv);

	unit_test::test_suite* suite =
	&boost::unit_test::framework::master_test_suite();
	suite->p_name.value = "ZlibTest";

	uint32_t buf_len = 1024*32;
	add_tests(suite, gen_uniform_buffer(buf_len, 'a'), buf_len, "uniform");
	add_tests(suite, gen_compressible_buffer(buf_len), buf_len, "compressible");
	add_tests(suite, gen_random_buffer(buf_len), buf_len, "random");

	suite->add(BOOST_TEST_CASE(test_no_write));

	return NULL;
	}