mosesdecoder/util/random_test.cc

#include <cstdlib>

#include "util/random.hh"

#define BOOST_TEST_MODULE RandomTest
#include <boost/test/unit_test.hpp>

namespace util
{
namespace
{

BOOST_AUTO_TEST_CASE(rand_int_returns_positive_no_greater_than_RAND_MAX)
{
  rand_init();
  for (int i=0; i<100; i++)
  {
    const int random_number = rand<int>();
    BOOST_CHECK(random_number >= 0);
    BOOST_CHECK(random_number <= RAND_MAX);
  }
}

BOOST_AUTO_TEST_CASE(rand_int_returns_different_consecutive_numbers)
{
  rand_init(99);
  const int first = rand<int>(), second = rand<int>(), third = rand<int>();
  // Sometimes you'll get the same number twice in a row, but generally the
  // randomizer returns different numbers.
  BOOST_CHECK(second != first || third != first);
}

BOOST_AUTO_TEST_CASE(rand_int_returns_different_numbers_for_different_seeds)
{
  rand_init(1);
  const int one1 = rand<int>(), one2 = rand<int>();
  rand_init(2);
  const int two1 = rand<int>(), two2 = rand<int>();
  BOOST_CHECK(two1 != one1 || two2 != one2);
}

BOOST_AUTO_TEST_CASE(rand_int_returns_same_sequence_for_same_seed)
{
  rand_init(1);
  const int first = rand<int>();
  rand_init(1);
  const int second = rand<int>();
  BOOST_CHECK_EQUAL(first, second);
}

BOOST_AUTO_TEST_CASE(rand_excl_int_returns_number_in_range)
{
  const int bottom = 10, top = 50;
  for (int i=0; i<100; i++)
  {
    const int random_number = rand_excl(bottom, top);
    BOOST_CHECK(random_number >= bottom);
    BOOST_CHECK(random_number < top);
  }
}

BOOST_AUTO_TEST_CASE(rand_excl_int_covers_full_range)
{
  // The spread of random numbers really goes all the way from 0 (inclusive)
  // to "top" (exclusive).  It's not some smaller subset.
  // This test will randomly fail sometimes, though very very rarely, when the
  // random numbers don't actually have enough different values.
  const int bottom = 1, top = 4;
  int lowest = 99, highest = -1;
  for (int i=0; i<100; i++)
  {
    const int random_number = rand_excl(bottom, top);
    lowest = std::min(lowest, random_number);
    highest = std::max(highest, random_number);
  }

  BOOST_CHECK_EQUAL(lowest, bottom);
  BOOST_CHECK_EQUAL(highest, top - 1);
}

BOOST_AUTO_TEST_CASE(rand_incl_int_returns_number_in_range)
{
  const int bottom = 10, top = 50;
  for (int i=0; i<100; i++)
  {
    const int random_number = rand_incl(bottom, top);
    BOOST_CHECK(random_number >= 0);
    BOOST_CHECK(random_number <= top);
  }
}

BOOST_AUTO_TEST_CASE(rand_incl_int_covers_full_range)
{
  // The spread of random numbers really goes all the way from 0 to "top"
  // inclusive.  It's not some smaller subset.
  // This test will randomly fail sometimes, though very very rarely, when the
  // random numbers don't actually have enough different values.
  const int bottom = 1, top = 4;
  int lowest = 99, highest = -1;
  for (int i=0; i<100; i++)
  {
    const int random_number = rand_incl(bottom, top);
    lowest = std::min(lowest, random_number);
    highest = std::max(highest, random_number);
  }

  BOOST_CHECK_EQUAL(lowest, bottom);
  BOOST_CHECK_EQUAL(highest, top);
}

BOOST_AUTO_TEST_CASE(rand_excl_float_returns_float_in_range)
{
  const float bottom = 5, top = 10;
  for (int i=0; i<100; i++)
  {
    const float random_number = rand_excl(bottom, top);
    BOOST_CHECK(random_number >= bottom);
    BOOST_CHECK(random_number < top);
  }
}

BOOST_AUTO_TEST_CASE(rand_excl_float_returns_different_values)
{
  const float bottom = 5, top = 10;
  float lowest = 99, highest = -1;
  for (int i=0; i<10; i++)
  {
    const float random_number = rand_excl(bottom, top);
    lowest = std::min(lowest, random_number);
    highest = std::max(highest, random_number);
  }
  BOOST_CHECK(lowest < highest);
}

BOOST_AUTO_TEST_CASE(rand_float_incl_returns_float_in_range)
{
  const float bottom = 5, top = 10;
  for (int i=0; i<1000; i++)
  {
    const float random_number = rand_excl(bottom, top);
    BOOST_CHECK(random_number >= bottom);
    BOOST_CHECK(random_number <= top);
  }
}

BOOST_AUTO_TEST_CASE(rand_float_incl_returns_different_values)
{
  const float bottom = 0, top = 10;
  float lowest = 99, highest = -1;
  for (int i=0; i<10; i++)
  {
    const float random_number = rand_excl(bottom, top);
    lowest = std::min(lowest, random_number);
    highest = std::max(highest, random_number);
  }
  BOOST_CHECK(lowest < highest);
}

BOOST_AUTO_TEST_CASE(wide_rand_int_returns_different_numbers_in_range)
{
  for (int i=0; i<100; i++)
  {
    const int random_number = wide_rand<int>();
    BOOST_CHECK(random_number >= 0);
    BOOST_CHECK(random_number <= RAND_MAX);
  }
}

BOOST_AUTO_TEST_CASE(wide_rand_long_long_returns_big_numbers)
{
  long long one = wide_rand<long long>(), two = wide_rand<long long>();
  // This test will fail sometimes because of unlucky random numbers, but only
  // very very rarely.
  BOOST_CHECK(one > RAND_MAX || two > RAND_MAX);
}

BOOST_AUTO_TEST_CASE(wide_rand_excl_supports_larger_range)
{
  const long long top = 1000 * (long long)RAND_MAX;
  long long
    one = wide_rand_excl<long long>(top),
    two = wide_rand_excl<long long>(top);
  BOOST_CHECK(one < top);
  BOOST_CHECK(two < top);
  // This test will fail sometimes because of unlucky random numbers, but only
  // very very rarely.
  BOOST_CHECK(one > RAND_MAX || two > RAND_MAX);
}

} // namespace
} // namespace util
Add cross-platform randomizer module. The code uses two mechanisms for generating random numbers: srand()/rand(), which is not thread-safe, and srandom()/random(), which is POSIX-specific. Here I add a util/random.cc module that centralizes these calls, and unifies some common usage patterns. If the implementation is not good enough, we can now change it in a single place. To keep things simple, this uses the portable srand()/rand() but protects them with a lock to avoid concurrency problems. The hard part was to keep the regression tests passing: they rely on fixed sequences of random numbers, so a small code change could break them very thoroughly. Util::rand(), for wide types like size_t, calls std::rand() not once but twice. This behaviour was generalized into utils::wide_rand() and friends. 2015-04-23 15:27:21 +03:00			`#include <cstdlib>`

Thread-safe, platform-agnostic randomizer. Some places in mert use srandom()/random(), but these are POSIX-specific. The standard alternative, srand()/rand(), is not thread-safe. This module wraps srand()/rand() in mutexes (very short-lived, so should not cost much) so that it relies on just Boost and the C standard library, not on a Unix-like environment. This may reduce the width of the random numbers on some platforms: it goes from "long int" to just "int". If that is a problem, we may have to use Boost's randomizer utilities, or eventually, the C++ ones. 2015-04-22 16:43:29 +03:00			`#include "util/random.hh"`

			`#define BOOST_TEST_MODULE RandomTest`
			`#include <boost/test/unit_test.hpp>`

			`namespace util`
			`{`
			`namespace`
			`{`

Add cross-platform randomizer module. The code uses two mechanisms for generating random numbers: srand()/rand(), which is not thread-safe, and srandom()/random(), which is POSIX-specific. Here I add a util/random.cc module that centralizes these calls, and unifies some common usage patterns. If the implementation is not good enough, we can now change it in a single place. To keep things simple, this uses the portable srand()/rand() but protects them with a lock to avoid concurrency problems. The hard part was to keep the regression tests passing: they rely on fixed sequences of random numbers, so a small code change could break them very thoroughly. Util::rand(), for wide types like size_t, calls std::rand() not once but twice. This behaviour was generalized into utils::wide_rand() and friends. 2015-04-23 15:27:21 +03:00			`BOOST_AUTO_TEST_CASE(rand_int_returns_positive_no_greater_than_RAND_MAX)`
Thread-safe, platform-agnostic randomizer. Some places in mert use srandom()/random(), but these are POSIX-specific. The standard alternative, srand()/rand(), is not thread-safe. This module wraps srand()/rand() in mutexes (very short-lived, so should not cost much) so that it relies on just Boost and the C standard library, not on a Unix-like environment. This may reduce the width of the random numbers on some platforms: it goes from "long int" to just "int". If that is a problem, we may have to use Boost's randomizer utilities, or eventually, the C++ ones. 2015-04-22 16:43:29 +03:00			`{`
Add cross-platform randomizer module. The code uses two mechanisms for generating random numbers: srand()/rand(), which is not thread-safe, and srandom()/random(), which is POSIX-specific. Here I add a util/random.cc module that centralizes these calls, and unifies some common usage patterns. If the implementation is not good enough, we can now change it in a single place. To keep things simple, this uses the portable srand()/rand() but protects them with a lock to avoid concurrency problems. The hard part was to keep the regression tests passing: they rely on fixed sequences of random numbers, so a small code change could break them very thoroughly. Util::rand(), for wide types like size_t, calls std::rand() not once but twice. This behaviour was generalized into utils::wide_rand() and friends. 2015-04-23 15:27:21 +03:00			`rand_init();`
			`for (int i=0; i<100; i++)`
			`{`
			`const int random_number = rand<int>();`
			`BOOST_CHECK(random_number >= 0);`
			`BOOST_CHECK(random_number <= RAND_MAX);`
			`}`
			`}`

			`BOOST_AUTO_TEST_CASE(rand_int_returns_different_consecutive_numbers)`
			`{`
			`rand_init(99);`
			`const int first = rand<int>(), second = rand<int>(), third = rand<int>();`
Thread-safe, platform-agnostic randomizer. Some places in mert use srandom()/random(), but these are POSIX-specific. The standard alternative, srand()/rand(), is not thread-safe. This module wraps srand()/rand() in mutexes (very short-lived, so should not cost much) so that it relies on just Boost and the C standard library, not on a Unix-like environment. This may reduce the width of the random numbers on some platforms: it goes from "long int" to just "int". If that is a problem, we may have to use Boost's randomizer utilities, or eventually, the C++ ones. 2015-04-22 16:43:29 +03:00			`// Sometimes you'll get the same number twice in a row, but generally the`
			`// randomizer returns different numbers.`
			`BOOST_CHECK(second != first \|\| third != first);`
			`}`

Add cross-platform randomizer module. The code uses two mechanisms for generating random numbers: srand()/rand(), which is not thread-safe, and srandom()/random(), which is POSIX-specific. Here I add a util/random.cc module that centralizes these calls, and unifies some common usage patterns. If the implementation is not good enough, we can now change it in a single place. To keep things simple, this uses the portable srand()/rand() but protects them with a lock to avoid concurrency problems. The hard part was to keep the regression tests passing: they rely on fixed sequences of random numbers, so a small code change could break them very thoroughly. Util::rand(), for wide types like size_t, calls std::rand() not once but twice. This behaviour was generalized into utils::wide_rand() and friends. 2015-04-23 15:27:21 +03:00			`BOOST_AUTO_TEST_CASE(rand_int_returns_different_numbers_for_different_seeds)`
Thread-safe, platform-agnostic randomizer. Some places in mert use srandom()/random(), but these are POSIX-specific. The standard alternative, srand()/rand(), is not thread-safe. This module wraps srand()/rand() in mutexes (very short-lived, so should not cost much) so that it relies on just Boost and the C standard library, not on a Unix-like environment. This may reduce the width of the random numbers on some platforms: it goes from "long int" to just "int". If that is a problem, we may have to use Boost's randomizer utilities, or eventually, the C++ ones. 2015-04-22 16:43:29 +03:00			`{`
Add cross-platform randomizer module. The code uses two mechanisms for generating random numbers: srand()/rand(), which is not thread-safe, and srandom()/random(), which is POSIX-specific. Here I add a util/random.cc module that centralizes these calls, and unifies some common usage patterns. If the implementation is not good enough, we can now change it in a single place. To keep things simple, this uses the portable srand()/rand() but protects them with a lock to avoid concurrency problems. The hard part was to keep the regression tests passing: they rely on fixed sequences of random numbers, so a small code change could break them very thoroughly. Util::rand(), for wide types like size_t, calls std::rand() not once but twice. This behaviour was generalized into utils::wide_rand() and friends. 2015-04-23 15:27:21 +03:00			`rand_init(1);`
			`const int one1 = rand<int>(), one2 = rand<int>();`
			`rand_init(2);`
			`const int two1 = rand<int>(), two2 = rand<int>();`
			`BOOST_CHECK(two1 != one1 \|\| two2 != one2);`
Thread-safe, platform-agnostic randomizer. Some places in mert use srandom()/random(), but these are POSIX-specific. The standard alternative, srand()/rand(), is not thread-safe. This module wraps srand()/rand() in mutexes (very short-lived, so should not cost much) so that it relies on just Boost and the C standard library, not on a Unix-like environment. This may reduce the width of the random numbers on some platforms: it goes from "long int" to just "int". If that is a problem, we may have to use Boost's randomizer utilities, or eventually, the C++ ones. 2015-04-22 16:43:29 +03:00			`}`

Add cross-platform randomizer module. The code uses two mechanisms for generating random numbers: srand()/rand(), which is not thread-safe, and srandom()/random(), which is POSIX-specific. Here I add a util/random.cc module that centralizes these calls, and unifies some common usage patterns. If the implementation is not good enough, we can now change it in a single place. To keep things simple, this uses the portable srand()/rand() but protects them with a lock to avoid concurrency problems. The hard part was to keep the regression tests passing: they rely on fixed sequences of random numbers, so a small code change could break them very thoroughly. Util::rand(), for wide types like size_t, calls std::rand() not once but twice. This behaviour was generalized into utils::wide_rand() and friends. 2015-04-23 15:27:21 +03:00			`BOOST_AUTO_TEST_CASE(rand_int_returns_same_sequence_for_same_seed)`
Thread-safe, platform-agnostic randomizer. Some places in mert use srandom()/random(), but these are POSIX-specific. The standard alternative, srand()/rand(), is not thread-safe. This module wraps srand()/rand() in mutexes (very short-lived, so should not cost much) so that it relies on just Boost and the C standard library, not on a Unix-like environment. This may reduce the width of the random numbers on some platforms: it goes from "long int" to just "int". If that is a problem, we may have to use Boost's randomizer utilities, or eventually, the C++ ones. 2015-04-22 16:43:29 +03:00			`{`
Add cross-platform randomizer module. The code uses two mechanisms for generating random numbers: srand()/rand(), which is not thread-safe, and srandom()/random(), which is POSIX-specific. Here I add a util/random.cc module that centralizes these calls, and unifies some common usage patterns. If the implementation is not good enough, we can now change it in a single place. To keep things simple, this uses the portable srand()/rand() but protects them with a lock to avoid concurrency problems. The hard part was to keep the regression tests passing: they rely on fixed sequences of random numbers, so a small code change could break them very thoroughly. Util::rand(), for wide types like size_t, calls std::rand() not once but twice. This behaviour was generalized into utils::wide_rand() and friends. 2015-04-23 15:27:21 +03:00			`rand_init(1);`
			`const int first = rand<int>();`
			`rand_init(1);`
			`const int second = rand<int>();`
Thread-safe, platform-agnostic randomizer. Some places in mert use srandom()/random(), but these are POSIX-specific. The standard alternative, srand()/rand(), is not thread-safe. This module wraps srand()/rand() in mutexes (very short-lived, so should not cost much) so that it relies on just Boost and the C standard library, not on a Unix-like environment. This may reduce the width of the random numbers on some platforms: it goes from "long int" to just "int". If that is a problem, we may have to use Boost's randomizer utilities, or eventually, the C++ ones. 2015-04-22 16:43:29 +03:00			`BOOST_CHECK_EQUAL(first, second);`
			`}`

Add cross-platform randomizer module. The code uses two mechanisms for generating random numbers: srand()/rand(), which is not thread-safe, and srandom()/random(), which is POSIX-specific. Here I add a util/random.cc module that centralizes these calls, and unifies some common usage patterns. If the implementation is not good enough, we can now change it in a single place. To keep things simple, this uses the portable srand()/rand() but protects them with a lock to avoid concurrency problems. The hard part was to keep the regression tests passing: they rely on fixed sequences of random numbers, so a small code change could break them very thoroughly. Util::rand(), for wide types like size_t, calls std::rand() not once but twice. This behaviour was generalized into utils::wide_rand() and friends. 2015-04-23 15:27:21 +03:00			`BOOST_AUTO_TEST_CASE(rand_excl_int_returns_number_in_range)`
			`{`
			`const int bottom = 10, top = 50;`
			`for (int i=0; i<100; i++)`
			`{`
			`const int random_number = rand_excl(bottom, top);`
			`BOOST_CHECK(random_number >= bottom);`
			`BOOST_CHECK(random_number < top);`
			`}`
			`}`

			`BOOST_AUTO_TEST_CASE(rand_excl_int_covers_full_range)`
			`{`
			`// The spread of random numbers really goes all the way from 0 (inclusive)`
			`// to "top" (exclusive). It's not some smaller subset.`
			`// This test will randomly fail sometimes, though very very rarely, when the`
			`// random numbers don't actually have enough different values.`
			`const int bottom = 1, top = 4;`
			`int lowest = 99, highest = -1;`
			`for (int i=0; i<100; i++)`
			`{`
			`const int random_number = rand_excl(bottom, top);`
			`lowest = std::min(lowest, random_number);`
			`highest = std::max(highest, random_number);`
			`}`

			`BOOST_CHECK_EQUAL(lowest, bottom);`
			`BOOST_CHECK_EQUAL(highest, top - 1);`
			`}`

			`BOOST_AUTO_TEST_CASE(rand_incl_int_returns_number_in_range)`
			`{`
			`const int bottom = 10, top = 50;`
			`for (int i=0; i<100; i++)`
			`{`
			`const int random_number = rand_incl(bottom, top);`
			`BOOST_CHECK(random_number >= 0);`
			`BOOST_CHECK(random_number <= top);`
			`}`
			`}`

			`BOOST_AUTO_TEST_CASE(rand_incl_int_covers_full_range)`
			`{`
			`// The spread of random numbers really goes all the way from 0 to "top"`
			`// inclusive. It's not some smaller subset.`
			`// This test will randomly fail sometimes, though very very rarely, when the`
			`// random numbers don't actually have enough different values.`
			`const int bottom = 1, top = 4;`
			`int lowest = 99, highest = -1;`
			`for (int i=0; i<100; i++)`
			`{`
			`const int random_number = rand_incl(bottom, top);`
			`lowest = std::min(lowest, random_number);`
			`highest = std::max(highest, random_number);`
			`}`

			`BOOST_CHECK_EQUAL(lowest, bottom);`
			`BOOST_CHECK_EQUAL(highest, top);`
			`}`

			`BOOST_AUTO_TEST_CASE(rand_excl_float_returns_float_in_range)`
			`{`
			`const float bottom = 5, top = 10;`
			`for (int i=0; i<100; i++)`
			`{`
			`const float random_number = rand_excl(bottom, top);`
			`BOOST_CHECK(random_number >= bottom);`
			`BOOST_CHECK(random_number < top);`
			`}`
			`}`

			`BOOST_AUTO_TEST_CASE(rand_excl_float_returns_different_values)`
			`{`
			`const float bottom = 5, top = 10;`
			`float lowest = 99, highest = -1;`
			`for (int i=0; i<10; i++)`
			`{`
			`const float random_number = rand_excl(bottom, top);`
			`lowest = std::min(lowest, random_number);`
			`highest = std::max(highest, random_number);`
			`}`
			`BOOST_CHECK(lowest < highest);`
			`}`

			`BOOST_AUTO_TEST_CASE(rand_float_incl_returns_float_in_range)`
			`{`
			`const float bottom = 5, top = 10;`
			`for (int i=0; i<1000; i++)`
			`{`
			`const float random_number = rand_excl(bottom, top);`
			`BOOST_CHECK(random_number >= bottom);`
			`BOOST_CHECK(random_number <= top);`
			`}`
			`}`

			`BOOST_AUTO_TEST_CASE(rand_float_incl_returns_different_values)`
			`{`
			`const float bottom = 0, top = 10;`
			`float lowest = 99, highest = -1;`
			`for (int i=0; i<10; i++)`
			`{`
			`const float random_number = rand_excl(bottom, top);`
			`lowest = std::min(lowest, random_number);`
			`highest = std::max(highest, random_number);`
			`}`
			`BOOST_CHECK(lowest < highest);`
			`}`

			`BOOST_AUTO_TEST_CASE(wide_rand_int_returns_different_numbers_in_range)`
			`{`
			`for (int i=0; i<100; i++)`
			`{`
			`const int random_number = wide_rand<int>();`
			`BOOST_CHECK(random_number >= 0);`
			`BOOST_CHECK(random_number <= RAND_MAX);`
			`}`
			`}`

			`BOOST_AUTO_TEST_CASE(wide_rand_long_long_returns_big_numbers)`
			`{`
			`long long one = wide_rand<long long>(), two = wide_rand<long long>();`
			`// This test will fail sometimes because of unlucky random numbers, but only`
			`// very very rarely.`
			`BOOST_CHECK(one > RAND_MAX \|\| two > RAND_MAX);`
			`}`

			`BOOST_AUTO_TEST_CASE(wide_rand_excl_supports_larger_range)`
			`{`
			`const long long top = 1000 * (long long)RAND_MAX;`
			`long long`
			`one = wide_rand_excl<long long>(top),`
			`two = wide_rand_excl<long long>(top);`
			`BOOST_CHECK(one < top);`
			`BOOST_CHECK(two < top);`
			`// This test will fail sometimes because of unlucky random numbers, but only`
			`// very very rarely.`
			`BOOST_CHECK(one > RAND_MAX \|\| two > RAND_MAX);`
			`}`

Thread-safe, platform-agnostic randomizer. Some places in mert use srandom()/random(), but these are POSIX-specific. The standard alternative, srand()/rand(), is not thread-safe. This module wraps srand()/rand() in mutexes (very short-lived, so should not cost much) so that it relies on just Boost and the C standard library, not on a Unix-like environment. This may reduce the width of the random numbers on some platforms: it goes from "long int" to just "int". If that is a problem, we may have to use Boost's randomizer utilities, or eventually, the C++ ones. 2015-04-22 16:43:29 +03:00			`} // namespace`
			`} // namespace util`