osb/source/core/StarRandom.hpp

#ifndef STAR_RANDOM_HPP
#define STAR_RANDOM_HPP

#include "StarStaticRandom.hpp"
#include "StarByteArray.hpp"

namespace Star {

STAR_EXCEPTION(RandomException, StarException);

// Deterministic random number source.  Uses multiply-with-carry algorithm.
// Much higher quality than the predictable random number generators.  Not
// thread safe (won't crash or anything, but might return less than optimal
// values).
class RandomSource {
public:
  // Generates a RandomSource with a seed from Random::randu64()
  RandomSource();
  RandomSource(uint64_t seed);

  // Re-initializes the random number generator using the given seed.  It is
  // exactly equivalent to constructing a new RandomSource, just using the same
  // buffer.
  void init();
  void init(uint64_t seed);

  void addEntropy();
  void addEntropy(uint64_t seed);

  uint32_t randu32();
  uint64_t randu64();

  int32_t randi32();
  int64_t randi64();

  // Generates values in the range [0.0, 1.0]
  float randf();
  // Generates values in the range [0.0, 1.0]
  double randd();

  // Random integer from [0, max], max must be >= 0
  int64_t randInt(int64_t max);
  uint64_t randUInt(uint64_t max);

  // Random integer from [min, max]
  int64_t randInt(int64_t min, int64_t max);
  uint64_t randUInt(uint64_t min, uint64_t max);

  float randf(float min, float max);
  double randd(double min, double max);

  bool randb();

  // Generates values via normal distribution with box-muller algorithm
  float nrandf(float stddev = 1.0f, float mean = 0.0f);
  double nrandd(double stddev = 1.0, double mean = 0.0);

  // Round a fractional value statistically towards the floor or ceiling.  For
  // example, if a value is 5.2, 80% of the time it will round to 5, but 20% of
  // the time it will round to 6.
  int64_t stochasticRound(double val);

  void randBytes(char* buf, size_t len);
  ByteArray randBytes(size_t len);

  // Pick a random value out of a container
  template <typename Container>
  typename Container::value_type const& randFrom(Container const& container);
  template <typename Container>
  typename Container::value_type& randFrom(Container& container);
  template <typename Container>
  typename Container::value_type randValueFrom(Container const& container);
  template <typename Container>
  typename Container::value_type randValueFrom(Container const& container, typename Container::value_type const& defaultVal);

  template <typename Container>
  void shuffle(Container& container);

private:
  uint32_t gen32();

  uint32_t m_data[256];
  uint32_t m_carry;
  uint8_t m_index;
};

// Global static versions of the methods in RandomSource.  It is not necessary
// to initialize the global RandomSource manually, it will be automatically
// initialized with a random seed on first use if it is not already initialized.
namespace Random {
  void init();
  void init(uint64_t seed);

  void addEntropy();
  void addEntropy(uint64_t seed);

  uint32_t randu32();
  uint64_t randu64();
  int32_t randi32();
  int64_t randi64();
  float randf();
  double randd();
  long long randInt(long long max);
  unsigned long long randUInt(unsigned long long max);
  long long randInt(long long min, long long max);
  unsigned long long randUInt(unsigned long long min, unsigned long long max);
  float randf(float min, float max);
  double randd(double min, double max);
  bool randb();

  float nrandf(float stddev = 1.0f, float mean = 0.0f);
  double nrandd(double stddev = 1.0, double mean = 0.0);

  int64_t stochasticRound(double val);

  void randBytes(char* buf, size_t len);
  ByteArray randBytes(size_t len);

  template <typename Container>
  typename Container::value_type const& randFrom(Container const& container);
  template <typename Container>
  typename Container::value_type& randFrom(Container& container);
  template <typename Container>
  typename Container::value_type randValueFrom(Container const& container);
  template <typename Container>
  typename Container::value_type randValueFrom(Container const& container, typename Container::value_type const& defaultVal);

  template <typename Container>
  void shuffle(Container& container);
}

template <typename Container>
typename Container::value_type const& RandomSource::randFrom(Container const& container) {
  if (container.empty())
    throw RandomException("Empty container in randFrom");

  auto i = container.begin();
  std::advance(i, randUInt(container.size() - 1));
  return *i;
}

template <typename Container>
typename Container::value_type& RandomSource::randFrom(Container& container) {
  if (container.empty())
    throw RandomException("Empty container in randFrom");

  auto i = container.begin();
  std::advance(i, randUInt(container.size() - 1));
  return *i;
}

template <typename Container>
typename Container::value_type const& Random::randFrom(Container const& container) {
  if (container.empty())
    throw RandomException("Empty container in randFrom");

  auto i = container.begin();
  std::advance(i, Random::randUInt(container.size() - 1));
  return *i;
}

template <typename Container>
typename Container::value_type& Random::randFrom(Container& container) {
  if (container.empty())
    throw RandomException("Empty container in randFrom");

  auto i = container.begin();
  std::advance(i, Random::randUInt(container.size() - 1));
  return *i;
}

template <typename Container>
typename Container::value_type RandomSource::randValueFrom(Container const& container) {
  return randValueFrom(container, typename Container::value_type());
}

template <typename Container>
typename Container::value_type RandomSource::randValueFrom(
    Container const& container, typename Container::value_type const& defaultVal) {
  if (container.empty())
    return defaultVal;

  auto i = container.begin();
  std::advance(i, randInt(container.size() - 1));
  return *i;
}

template <typename Container>
void RandomSource::shuffle(Container& container) {
  std::random_shuffle(container.begin(), container.end(), [this](size_t max) { return randUInt(max - 1); });
}

template <typename Container>
typename Container::value_type Random::randValueFrom(Container const& container) {
  return randValueFrom(container, typename Container::value_type());
}

template <typename Container>
typename Container::value_type Random::randValueFrom(
    Container const& container, typename Container::value_type const& defaultVal) {
  if (container.empty())
    return defaultVal;

  auto i = container.begin();
  std::advance(i, Random::randInt(container.size() - 1));
  return *i;
}

template <typename Container>
void Random::shuffle(Container& container) {
  std::random_shuffle(container.begin(), container.end(), [](size_t max) { return Random::randUInt(max - 1); });
}

}

#endif
everything everywhere all at once 2023-06-20 04:33:09 +00:00			`#ifndef STAR_RANDOM_HPP`
			`#define STAR_RANDOM_HPP`

			`#include "StarStaticRandom.hpp"`
			`#include "StarByteArray.hpp"`

			`namespace Star {`

			`STAR_EXCEPTION(RandomException, StarException);`

			`// Deterministic random number source. Uses multiply-with-carry algorithm.`
			`// Much higher quality than the predictable random number generators. Not`
			`// thread safe (won't crash or anything, but might return less than optimal`
			`// values).`
			`class RandomSource {`
			`public:`
			`// Generates a RandomSource with a seed from Random::randu64()`
			`RandomSource();`
			`RandomSource(uint64_t seed);`

			`// Re-initializes the random number generator using the given seed. It is`
			`// exactly equivalent to constructing a new RandomSource, just using the same`
			`// buffer.`
			`void init();`
			`void init(uint64_t seed);`

			`void addEntropy();`
			`void addEntropy(uint64_t seed);`

			`uint32_t randu32();`
			`uint64_t randu64();`

			`int32_t randi32();`
			`int64_t randi64();`

			`// Generates values in the range [0.0, 1.0]`
			`float randf();`
			`// Generates values in the range [0.0, 1.0]`
			`double randd();`

			`// Random integer from [0, max], max must be >= 0`
			`int64_t randInt(int64_t max);`
			`uint64_t randUInt(uint64_t max);`

			`// Random integer from [min, max]`
			`int64_t randInt(int64_t min, int64_t max);`
			`uint64_t randUInt(uint64_t min, uint64_t max);`

			`float randf(float min, float max);`
			`double randd(double min, double max);`

			`bool randb();`

			`// Generates values via normal distribution with box-muller algorithm`
			`float nrandf(float stddev = 1.0f, float mean = 0.0f);`
			`double nrandd(double stddev = 1.0, double mean = 0.0);`

			`// Round a fractional value statistically towards the floor or ceiling. For`
			`// example, if a value is 5.2, 80% of the time it will round to 5, but 20% of`
			`// the time it will round to 6.`
			`int64_t stochasticRound(double val);`

			`void randBytes(char* buf, size_t len);`
			`ByteArray randBytes(size_t len);`

			`// Pick a random value out of a container`
			`template <typename Container>`
			`typename Container::value_type const& randFrom(Container const& container);`
			`template <typename Container>`
			`typename Container::value_type& randFrom(Container& container);`
			`template <typename Container>`
			`typename Container::value_type randValueFrom(Container const& container);`
			`template <typename Container>`
			`typename Container::value_type randValueFrom(Container const& container, typename Container::value_type const& defaultVal);`

			`template <typename Container>`
			`void shuffle(Container& container);`

			`private:`
			`uint32_t gen32();`

			`uint32_t m_data[256];`
			`uint32_t m_carry;`
			`uint8_t m_index;`
			`};`

			`// Global static versions of the methods in RandomSource. It is not necessary`
			`// to initialize the global RandomSource manually, it will be automatically`
			`// initialized with a random seed on first use if it is not already initialized.`
			`namespace Random {`
			`void init();`
			`void init(uint64_t seed);`

			`void addEntropy();`
			`void addEntropy(uint64_t seed);`

			`uint32_t randu32();`
			`uint64_t randu64();`
			`int32_t randi32();`
			`int64_t randi64();`
			`float randf();`
			`double randd();`
			`long long randInt(long long max);`
			`unsigned long long randUInt(unsigned long long max);`
			`long long randInt(long long min, long long max);`
			`unsigned long long randUInt(unsigned long long min, unsigned long long max);`
			`float randf(float min, float max);`
			`double randd(double min, double max);`
			`bool randb();`

			`float nrandf(float stddev = 1.0f, float mean = 0.0f);`
			`double nrandd(double stddev = 1.0, double mean = 0.0);`

			`int64_t stochasticRound(double val);`

			`void randBytes(char* buf, size_t len);`
			`ByteArray randBytes(size_t len);`

			`template <typename Container>`
			`typename Container::value_type const& randFrom(Container const& container);`
			`template <typename Container>`
			`typename Container::value_type& randFrom(Container& container);`
			`template <typename Container>`
			`typename Container::value_type randValueFrom(Container const& container);`
			`template <typename Container>`
			`typename Container::value_type randValueFrom(Container const& container, typename Container::value_type const& defaultVal);`

			`template <typename Container>`
			`void shuffle(Container& container);`
			`}`

			`template <typename Container>`
			`typename Container::value_type const& RandomSource::randFrom(Container const& container) {`
			`if (container.empty())`
			`throw RandomException("Empty container in randFrom");`

			`auto i = container.begin();`
			`std::advance(i, randUInt(container.size() - 1));`
			`return *i;`
			`}`

			`template <typename Container>`
			`typename Container::value_type& RandomSource::randFrom(Container& container) {`
			`if (container.empty())`
			`throw RandomException("Empty container in randFrom");`

			`auto i = container.begin();`
			`std::advance(i, randUInt(container.size() - 1));`
			`return *i;`
			`}`

			`template <typename Container>`
			`typename Container::value_type const& Random::randFrom(Container const& container) {`
			`if (container.empty())`
			`throw RandomException("Empty container in randFrom");`

			`auto i = container.begin();`
			`std::advance(i, Random::randUInt(container.size() - 1));`
			`return *i;`
			`}`

			`template <typename Container>`
			`typename Container::value_type& Random::randFrom(Container& container) {`
			`if (container.empty())`
			`throw RandomException("Empty container in randFrom");`

			`auto i = container.begin();`
			`std::advance(i, Random::randUInt(container.size() - 1));`
			`return *i;`
			`}`

			`template <typename Container>`
			`typename Container::value_type RandomSource::randValueFrom(Container const& container) {`
			`return randValueFrom(container, typename Container::value_type());`
			`}`

			`template <typename Container>`
			`typename Container::value_type RandomSource::randValueFrom(`
			`Container const& container, typename Container::value_type const& defaultVal) {`
			`if (container.empty())`
			`return defaultVal;`

			`auto i = container.begin();`
			`std::advance(i, randInt(container.size() - 1));`
			`return *i;`
			`}`

			`template <typename Container>`
			`void RandomSource::shuffle(Container& container) {`
			`std::random_shuffle(container.begin(), container.end(), [this](size_t max) { return randUInt(max - 1); });`
			`}`

			`template <typename Container>`
			`typename Container::value_type Random::randValueFrom(Container const& container) {`
			`return randValueFrom(container, typename Container::value_type());`
			`}`

			`template <typename Container>`
			`typename Container::value_type Random::randValueFrom(`
			`Container const& container, typename Container::value_type const& defaultVal) {`
			`if (container.empty())`
			`return defaultVal;`

			`auto i = container.begin();`
			`std::advance(i, Random::randInt(container.size() - 1));`
			`return *i;`
			`}`

			`template <typename Container>`
			`void Random::shuffle(Container& container) {`
			`std::random_shuffle(container.begin(), container.end(), [](size_t max) { return Random::randUInt(max - 1); });`
			`}`

			`}`

			`#endif`