Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I need a Random Number Generator that produces same sequence of numbers both in iOS and Android if we give the same Seed in both.

I tried the rand() function with the srand(1000). But it gave different outputs. Then I tried mersenne twister. But that too gave difference sequence for same seed.

Could any one please help me on this.

I am using cocos2d-x for my development.

share|improve this question
    
hmm I would think mersenne twister should give the same result, using the same seed. –  Ivaylo Strandjev Feb 8 '13 at 12:55
    
:-(...Nope. I checked. –  Aaron Feb 8 '13 at 12:56
3  
I don't want to sound picky, but in these days, I wouldn't call this a random number generator if it's completely predictable on different devices. It's a pseudo random number generator at best... Hope it's not for security... –  Class Stacker Feb 8 '13 at 12:57
    
@ClassStacker I am making a game that should show same sequence object for a particular condition in both ios and android. :-) –  Aaron Feb 8 '13 at 13:00
    
I thought all pseudo random generators were deterministic by definition given the same seed? Are you using different implementations of MT on your platforms? They could use different parameters etc. –  user1773602 Feb 8 '13 at 13:07

3 Answers 3

up vote 2 down vote accepted

I have adapted an online CRandomMersenne library and I am really sorry I can no longer find the source for that one. But here is my Mersenne Twister implementation:

// Define 32 bit signed and unsigned integers.
// Change these definitions, if necessary, to match a particular platform
#if defined(_WIN16) || defined(__MSDOS__) || defined(_MSDOS) 
   // 16 bit systems use long int for 32 bit integer
   typedef long int           int32;   // 32 bit signed integer
   typedef unsigned long int  uint32;  // 32 bit unsigned integer
#else
   // Most other systems use int for 32 bit integer
   typedef int                int32;   // 32 bit signed integer
   typedef unsigned int       uint32;  // 32 bit unsigned integer
#endif

// Define 64 bit signed and unsigned integers, if possible
#if (defined(__WINDOWS__) || defined(_WIN32)) && (defined(_MSC_VER) || defined(__INTEL_COMPILER))
   // Microsoft and other compilers under Windows use __int64
   typedef __int64            int64;   // 64 bit signed integer
   typedef unsigned __int64   uint64;  // 64 bit unsigned integer
   #define INT64_DEFINED               // Remember that int64 is defined
#elif defined(__unix__) && (defined(_M_IX86) || defined(_M_X64))
   // Gnu and other compilers under Linux etc. use long long
   typedef long long          int64;   // 64 bit signed integer
   typedef unsigned long long uint64;  // 64 bit unsigned integer
   #define INT64_DEFINED               // Remember that int64 is defined
#else
   // 64 bit integers not defined
   // You may include definitions for other platforms here
#endif

void EndOfProgram(void);               // System-specific exit code (userintf.cpp)

void FatalError(char * ErrorText);     // System-specific error reporting (userintf.cpp)

class CRandomMersenne {                // Encapsulate random number generator
#if 0
   // Define constants for type MT11213A:
#define MERS_N   351
#define MERS_M   175
#define MERS_R   19
#define MERS_U   11
#define MERS_S   7
#define MERS_T   15
#define MERS_L   17
#define MERS_A   0xE4BD75F5
#define MERS_B   0x655E5280
#define MERS_C   0xFFD58000
#else    
   // or constants for type MT19937:
#define MERS_N   624
#define MERS_M   397
#define MERS_R   31
#define MERS_U   11
#define MERS_S   7
#define MERS_T   15
#define MERS_L   18
#define MERS_A   0x9908B0DF
#define MERS_B   0x9D2C5680
#define MERS_C   0xEFC60000
#endif
public:
   CRandomMersenne(uint32 seed) {      // Constructor
      RandomInit(seed); LastInterval = 0;}
   void RandomInit(uint32 seed);       // Re-seed
   void RandomInitByArray(uint32 seeds[], int length); // Seed by more than 32 bits
   int IRandom (int min, int max);     // Output random integer
   int IRandomX(int min, int max);     // Output random integer, exact
   double Random();                    // Output random float
   uint32 BRandom();                   // Output random bits
private:
   void Init0(uint32 seed);            // Basic initialization procedure
   uint32 mt[MERS_N];                  // State vector
   int mti;                            // Index into mt
   uint32 LastInterval;                // Last interval length for IRandomX
   uint32 RLimit;                      // Rejection limit used by IRandomX
   enum TArch {LITTLE_ENDIAN1, BIG_ENDIAN1, NONIEEE}; // Definition of architecture
   TArch Architecture;                 // Conversion to float depends on architecture
};    


class CRandomMother {             // Encapsulate random number generator
public:
   void RandomInit(uint32 seed);       // Initialization
   int IRandom(int min, int max);      // Get integer random number in desired interval
   double Random();                    // Get floating point random number
   uint32 BRandom();                   // Output random bits
   CRandomMother(uint32 seed) {   // Constructor
      RandomInit(seed);}
protected:
   uint32 x[5];                        // History buffer
};

#endif

void CRandomMersenne::Init0(uint32 seed) {
   // Detect computer architecture
   union {double f; uint32 i[2];} convert;
   convert.f = 1.0;
   if (convert.i[1] == 0x3FF00000) Architecture = LITTLE_ENDIAN1;
   else if (convert.i[0] == 0x3FF00000) Architecture = BIG_ENDIAN1;
   else Architecture = NONIEEE;

   // Seed generator
   mt[0]= seed;
   for (mti=1; mti < MERS_N; mti++) {
      mt[mti] = (1812433253UL * (mt[mti-1] ^ (mt[mti-1] >> 30)) + mti);
   }
}

void CRandomMersenne::RandomInit(uint32 seed) {
   // Initialize and seed
   Init0(seed);

   // Randomize some more
   for (int i = 0; i < 37; i++) BRandom();
}


void CRandomMersenne::RandomInitByArray(uint32 seeds[], int length) {
   // Seed by more than 32 bits
   int i, j, k;

   // Initialize
   Init0(19650218);

   if (length <= 0) return;

   // Randomize mt[] using whole seeds[] array
   i = 1;  j = 0;
   k = (MERS_N > length ? MERS_N : length);
   for (; k; k--) {
      mt[i] = (mt[i] ^ ((mt[i-1] ^ (mt[i-1] >> 30)) * 1664525UL)) + seeds[j] + j;
      i++; j++;
      if (i >= MERS_N) {mt[0] = mt[MERS_N-1]; i=1;}
      if (j >= length) j=0;}
   for (k = MERS_N-1; k; k--) {
      mt[i] = (mt[i] ^ ((mt[i-1] ^ (mt[i-1] >> 30)) * 1566083941UL)) - i;
      if (++i >= MERS_N) {mt[0] = mt[MERS_N-1]; i=1;}}
   mt[0] = 0x80000000UL;  // MSB is 1; assuring non-zero initial array

   // Randomize some more
   mti = 0;
   for (int i = 0; i <= MERS_N; i++) BRandom();
}


uint32 CRandomMersenne::BRandom() {
   // Generate 32 random bits
   uint32 y;

   if (mti >= MERS_N) {
      // Generate MERS_N words at one time
      const uint32 LOWER_MASK = (1LU << MERS_R) - 1;       // Lower MERS_R bits
      const uint32 UPPER_MASK = 0xFFFFFFFF << MERS_R;      // Upper (32 - MERS_R) bits
      static const uint32 mag01[2] = {0, MERS_A};

      int kk;
      for (kk=0; kk < MERS_N-MERS_M; kk++) {    
         y = (mt[kk] & UPPER_MASK) | (mt[kk+1] & LOWER_MASK);
         mt[kk] = mt[kk+MERS_M] ^ (y >> 1) ^ mag01[y & 1];}

      for (; kk < MERS_N-1; kk++) {    
         y = (mt[kk] & UPPER_MASK) | (mt[kk+1] & LOWER_MASK);
         mt[kk] = mt[kk+(MERS_M-MERS_N)] ^ (y >> 1) ^ mag01[y & 1];}      

      y = (mt[MERS_N-1] & UPPER_MASK) | (mt[0] & LOWER_MASK);
      mt[MERS_N-1] = mt[MERS_M-1] ^ (y >> 1) ^ mag01[y & 1];
      mti = 0;
   }

   y = mt[mti++];

#if 1
   // Tempering (May be omitted):
   y ^=  y >> MERS_U;
   y ^= (y << MERS_S) & MERS_B;
   y ^= (y << MERS_T) & MERS_C;
   y ^=  y >> MERS_L;
#endif

   return y;
}


double CRandomMersenne::Random() {
   // Output random float number in the interval 0 <= x < 1
   union {double f; uint32 i[2];} convert;
   uint32 r = BRandom();               // Get 32 random bits
   // The fastest way to convert random bits to floating point is as follows:
   // Set the binary exponent of a floating point number to 1+bias and set
   // the mantissa to random bits. This will give a random number in the 
   // interval [1,2). Then subtract 1.0 to get a random number in the interval
   // [0,1). This procedure requires that we know how floating point numbers
   // are stored. The storing method is tested in function RandomInit and saved 
   // in the variable Architecture.

   // This shortcut allows the compiler to optimize away the following switch
   // statement for the most common architectures:
#if defined(_M_IX86) || defined(_M_X64) || defined(__LITTLE_ENDIAN__)
   Architecture = LITTLE_ENDIAN1;
#elif defined(__BIG_ENDIAN__)
   Architecture = BIG_ENDIAN1;
#endif

   switch (Architecture) {
   case LITTLE_ENDIAN1:
      convert.i[0] =  r << 20;
      convert.i[1] = (r >> 12) | 0x3FF00000;
      return convert.f - 1.0;
   case BIG_ENDIAN1:
      convert.i[1] =  r << 20;
      convert.i[0] = (r >> 12) | 0x3FF00000;
      return convert.f - 1.0;
   case NONIEEE: default: ;
   } 
   // This somewhat slower method works for all architectures, including 
   // non-IEEE floating point representation:
   return (double)r * (1./((double)(uint32)(-1L)+1.));
}


int CRandomMersenne::IRandom(int min, int max) {
   // Output random integer in the interval min <= x <= max
   // Relative error on frequencies < 2^-32
   if (max <= min) {
      if (max == min) return min; else return 0x80000000;
   }
   // Multiply interval with random and truncate
   int r = int((max - min + 1) * Random()) + min; 
   if (r > max) r = max;
   return r;
}


int CRandomMersenne::IRandomX(int min, int max) {
   // Output random integer in the interval min <= x <= max
   // Each output value has exactly the same probability.
   // This is obtained by rejecting certain bit values so that the number
   // of possible bit values is divisible by the interval length
   if (max <= min) {
      if (max == min) return min; else return 0x80000000;
   }
#ifdef  INT64_DEFINED
   // 64 bit integers available. Use multiply and shift method
   uint32 interval;                    // Length of interval
   uint64 longran;                     // Random bits * interval
   uint32 iran;                        // Longran / 2^32
   uint32 remainder;                   // Longran % 2^32

   interval = uint32(max - min + 1);
   if (interval != LastInterval) {
      // Interval length has changed. Must calculate rejection limit
      // Reject when remainder = 2^32 / interval * interval
      // RLimit will be 0 if interval is a power of 2. No rejection then
      RLimit = uint32(((uint64)1 << 32) / interval) * interval - 1;
      LastInterval = interval;
   }
   do { // Rejection loop
      longran  = (uint64)BRandom() * interval;
      iran = (uint32)(longran >> 32);
      remainder = (uint32)longran;
   } while (remainder > RLimit);
   // Convert back to signed and return result
   return (int32)iran + min;

#else
   // 64 bit integers not available. Use modulo method
   uint32 interval;                    // Length of interval
   uint32 bran;                        // Random bits
   uint32 iran;                        // bran / interval
   uint32 remainder;                   // bran % interval

   interval = uint32(max - min + 1);
   if (interval != LastInterval) {
      // Interval length has changed. Must calculate rejection limit
      // Reject when iran = 2^32 / interval
      // We can't make 2^32 so we use 2^32-1 and correct afterwards
      RLimit = (uint32)0xFFFFFFFF / interval;
      if ((uint32)0xFFFFFFFF % interval == interval - 1) RLimit++;
   }
   do { // Rejection loop
      bran = BRandom();
      iran = bran / interval;
      remainder = bran % interval;
   } while (iran >= RLimit);
   // Convert back to signed and return result
   return (int32)remainder + min;

#endif
}

Usage of the above class is quite simple:

CRandomMersenne generator(<some_seed>);
generator.random(); // random value [0,1]
generator.IRandom(a,b); // random value [a,b]

I have tested this many times and it performs better and faster than most random number generators I have seen.

A lot of times I have relied on the fact that it is deterministic given a seed so you can use it I guess. I will try to find the original source for that code and give the credit to the author.

EDIT: author of the code above is Agner Fog and on his website there is a whole section for random number generators. All credit for the code goes to him.

share|improve this answer
    
Thanks Man....It just worked as I needed. :) –  Aaron Feb 8 '13 at 13:23

You can just write your own random number generator like this. The quality is low but will suit for most of the purpose.

// RAND_MAX assumed to be 32767.
static unsigned long int next = 1;
void srand(unsigned int seed) { next = seed; }
int rand(void) {
    next = next * 1103515245 + 12345;
    return (unsigned int)(next/65536) % 32768;
}
share|improve this answer
    
Thank you. :).. –  Aaron Feb 8 '13 at 13:24

you can use:

#import <stdlib.h>
int randomNumber = arc4random() % limiteNumber;
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.