cuberite-2a/source/FastRandom.cpp


// FastRandom.cpp

// Implements the cFastRandom class representing a fast random number generator

#include "Globals.h"
#include <time.h>
#include "FastRandom.h"


#if 0 && defined(_DEBUG)
// Self-test
// Both ints and floats are quick-tested to see if the random is calculated correctly, checking the range in ASSERTs,
// and if it performs well in terms of distribution (checked by avg, expected to be in the range midpoint
class cFastRandomTest
{
public:
	cFastRandomTest(void)
	{
		TestInts();
		TestFloats();
	}
	
	
	void TestInts(void)
	{
		printf("Testing ints...\n");
		cFastRandom rnd;
		int sum = 0;
		const int BUCKETS = 8;
		int Counts[BUCKETS];
		memset(Counts, 0, sizeof(Counts));
		const int ITER = 10000;
		for (int i = 0; i < ITER; i++)
		{
			int v = rnd.NextInt(1000);
			ASSERT(v >= 0);
			ASSERT(v < 1000);
			Counts[v % BUCKETS]++;
			sum += v;
		}
		double avg = (double)sum / ITER;
		printf("avg: %f\n", avg);
		for (int i = 0; i < BUCKETS; i++)
		{
			printf("  bucket %d: %d\n", i, Counts[i]);
		}
	}


	void TestFloats(void)
	{
		printf("Testing floats...\n");
		cFastRandom rnd;
		float sum = 0;
		const int BUCKETS = 8;
		int Counts[BUCKETS];
		memset(Counts, 0, sizeof(Counts));
		const int ITER = 10000;
		for (int i = 0; i < ITER; i++)
		{
			float v = rnd.NextFloat(1000);
			ASSERT(v >= 0);
			ASSERT(v <= 1000);
			Counts[((int)v) % BUCKETS]++;
			sum += v;
		}
		sum = sum / ITER;
		printf("avg: %f\n", sum);
		for (int i = 0; i < BUCKETS; i++)
		{
			printf("  bucket %d: %d\n", i, Counts[i]);
		}
	}
} g_Test;

#endif


int cFastRandom::m_SeedCounter = 0;


cFastRandom::cFastRandom(void) :
	m_Seed(m_SeedCounter++)
{
}


int cFastRandom::NextInt(int a_Range)
{
	ASSERT(a_Range <= 1000000);  // The random is not sufficiently linearly distributed with bigger ranges
	ASSERT(a_Range > 0);
	
	// Make the m_Counter operations as minimal as possible, to emulate atomicity
	int Counter = m_Counter++;
	
	// Use a_Range, m_Counter and m_Seed as inputs to the pseudorandom function:
	int n = a_Range + m_Counter * 57 + m_Seed * 57 * 57;
	n = (n << 13) ^ n;
	n = ((n * (n * n * 15731 + 789221) + 1376312589) & 0x7fffffff);
	return ((n / 11) % a_Range);
}


int cFastRandom::NextInt(int a_Range, int a_Salt)
{
	ASSERT(a_Range <= 1000000);  // The random is not sufficiently linearly distributed with bigger ranges
	ASSERT(a_Range > 0);
	
	// Make the m_Counter operations as minimal as possible, to emulate atomicity
	int Counter = m_Counter++;
	
	// Use a_Range, a_Salt, m_Counter and m_Seed as inputs to the pseudorandom function:
	int n = a_Range + m_Counter * 57 + m_Seed * 57 * 57 + a_Salt * 57 * 57 * 57;
	n = (n << 13) ^ n;
	n = ((n * (n * n * 15731 + 789221) + 1376312589) & 0x7fffffff);
	return ((n / 11) % a_Range);
}


float cFastRandom::NextFloat(float a_Range)
{
	// Make the m_Counter operations as minimal as possible, to emulate atomicity
	int Counter = m_Counter++;
	
	// Use a_Range, a_Salt, m_Counter and m_Seed as inputs to the pseudorandom function:
	int n = (int)a_Range + m_Counter * 57 + m_Seed * 57 * 57;
	n = (n << 13) ^ n;
	n = ((n * (n * n * 15731 + 789221) + 1376312589) & 0x7fffffff);
	
	// Convert the integer into float with the specified range:
	return (((float)n / (float)0x7fffffff) * a_Range);
}


float cFastRandom::NextFloat(float a_Range, int a_Salt)
{
	// Make the m_Counter operations as minimal as possible, to emulate atomicity
	int Counter = m_Counter++;
	
	// Use a_Range, a_Salt, m_Counter and m_Seed as inputs to the pseudorandom function:
	int n = (int)a_Range + m_Counter * 57 + m_Seed * 57 * 57 + a_Salt * 57 * 57 * 57;
	n = (n << 13) ^ n;
	n = ((n * (n * n * 15731 + 789221) + 1376312589) & 0x7fffffff);
	
	// Convert the integer into float with the specified range:
	return (((float)n / (float)0x7fffffff) * a_Range);
}
Changed everyting to Unix line endings. 2013-07-29 07:13:03 -04:00
			`// FastRandom.cpp`

			`// Implements the cFastRandom class representing a fast random number generator`

			`#include "Globals.h"`
			`#include <time.h>`
			`#include "FastRandom.h"`





			`#if 0 && defined(_DEBUG)`
			`// Self-test`
			`// Both ints and floats are quick-tested to see if the random is calculated correctly, checking the range in ASSERTs,`
			`// and if it performs well in terms of distribution (checked by avg, expected to be in the range midpoint`
			`class cFastRandomTest`
			`{`
			`public:`
			`cFastRandomTest(void)`
			`{`
			`TestInts();`
			`TestFloats();`
			`}`


			`void TestInts(void)`
			`{`
			`printf("Testing ints...\n");`
			`cFastRandom rnd;`
			`int sum = 0;`
			`const int BUCKETS = 8;`
			`int Counts[BUCKETS];`
			`memset(Counts, 0, sizeof(Counts));`
			`const int ITER = 10000;`
			`for (int i = 0; i < ITER; i++)`
			`{`
			`int v = rnd.NextInt(1000);`
			`ASSERT(v >= 0);`
			`ASSERT(v < 1000);`
			`Counts[v % BUCKETS]++;`
			`sum += v;`
			`}`
			`double avg = (double)sum / ITER;`
			`printf("avg: %f\n", avg);`
			`for (int i = 0; i < BUCKETS; i++)`
			`{`
			`printf(" bucket %d: %d\n", i, Counts[i]);`
			`}`
			`}`


			`void TestFloats(void)`
			`{`
			`printf("Testing floats...\n");`
			`cFastRandom rnd;`
			`float sum = 0;`
			`const int BUCKETS = 8;`
			`int Counts[BUCKETS];`
			`memset(Counts, 0, sizeof(Counts));`
			`const int ITER = 10000;`
			`for (int i = 0; i < ITER; i++)`
			`{`
			`float v = rnd.NextFloat(1000);`
			`ASSERT(v >= 0);`
			`ASSERT(v <= 1000);`
			`Counts[((int)v) % BUCKETS]++;`
			`sum += v;`
			`}`
			`sum = sum / ITER;`
			`printf("avg: %f\n", sum);`
			`for (int i = 0; i < BUCKETS; i++)`
			`{`
			`printf(" bucket %d: %d\n", i, Counts[i]);`
			`}`
			`}`
			`} g_Test;`

			`#endif`






			`int cFastRandom::m_SeedCounter = 0;`





			`cFastRandom::cFastRandom(void) :`
			`m_Seed(m_SeedCounter++)`
			`{`
			`}`





			`int cFastRandom::NextInt(int a_Range)`
			`{`
			`ASSERT(a_Range <= 1000000); // The random is not sufficiently linearly distributed with bigger ranges`
			`ASSERT(a_Range > 0);`

			`// Make the m_Counter operations as minimal as possible, to emulate atomicity`
			`int Counter = m_Counter++;`

			`// Use a_Range, m_Counter and m_Seed as inputs to the pseudorandom function:`
			`int n = a_Range + m_Counter * 57 + m_Seed * 57 * 57;`
			`n = (n << 13) ^ n;`
			`n = ((n * (n * n * 15731 + 789221) + 1376312589) & 0x7fffffff);`
			`return ((n / 11) % a_Range);`
			`}`





			`int cFastRandom::NextInt(int a_Range, int a_Salt)`
			`{`
			`ASSERT(a_Range <= 1000000); // The random is not sufficiently linearly distributed with bigger ranges`
			`ASSERT(a_Range > 0);`

			`// Make the m_Counter operations as minimal as possible, to emulate atomicity`
			`int Counter = m_Counter++;`

			`// Use a_Range, a_Salt, m_Counter and m_Seed as inputs to the pseudorandom function:`
			`int n = a_Range + m_Counter * 57 + m_Seed * 57 * 57 + a_Salt * 57 * 57 * 57;`
			`n = (n << 13) ^ n;`
			`n = ((n * (n * n * 15731 + 789221) + 1376312589) & 0x7fffffff);`
			`return ((n / 11) % a_Range);`
			`}`





			`float cFastRandom::NextFloat(float a_Range)`
			`{`
			`// Make the m_Counter operations as minimal as possible, to emulate atomicity`
			`int Counter = m_Counter++;`

			`// Use a_Range, a_Salt, m_Counter and m_Seed as inputs to the pseudorandom function:`
			`int n = (int)a_Range + m_Counter * 57 + m_Seed * 57 * 57;`
			`n = (n << 13) ^ n;`
			`n = ((n * (n * n * 15731 + 789221) + 1376312589) & 0x7fffffff);`

			`// Convert the integer into float with the specified range:`
			`return (((float)n / (float)0x7fffffff) * a_Range);`
			`}`





			`float cFastRandom::NextFloat(float a_Range, int a_Salt)`
			`{`
			`// Make the m_Counter operations as minimal as possible, to emulate atomicity`
			`int Counter = m_Counter++;`

			`// Use a_Range, a_Salt, m_Counter and m_Seed as inputs to the pseudorandom function:`
			`int n = (int)a_Range + m_Counter * 57 + m_Seed * 57 * 57 + a_Salt * 57 * 57 * 57;`
			`n = (n << 13) ^ n;`
			`n = ((n * (n * n * 15731 + 789221) + 1376312589) & 0x7fffffff);`

			`// Convert the integer into float with the specified range:`
			`return (((float)n / (float)0x7fffffff) * a_Range);`
			`}`