This answer is a wiki. I'm working on a library and examples in .NET, feel free to add your own in any language...
Without external 'random' input (such as monitoring street noise), as a deterministic machine, a computer cannot generate truly random numbers: Random Number Generation.
Since most of us don't have the money and expertise to utilize the special equipment to provide chaotic input, there are ways to utitlize the somewhat unpredictable nature of your OS, task scheduler, process manager, and user inputs (e.g. mouse movement), to generate the improved pseudo-randomness.
Unfortunately, I do not know enough about C++ TR1 to know if it has the capability to do this.
As others have pointed out, you get different number sequences (which eventually repeat, so they aren't truly random), by seeding your RNG with different inputs. So you have two options in improving your generation:
Periodically reseed your RNG with some sort of chaotic input OR make the output of your RNG unreliable based on how your system operates.
The former can be accomplished by creating algorithms that explicitly produce seeds by examining the system environment. This may require setting up some event handlers, delegate functions, etc.
The latter can be accomplished by poor parallel computing practice: i.e. setting many RNG threads/processes to compete in an 'unsafe manner' to create each subsequent random number (or number sequence). This implicitly adds chaos from the sum total of activity on your system, because every minute event will have an impact on which thread's output ends up having being written and eventually read when a 'GetNext()' type method is called. Below is a crude proof of concept in .NET 3.5. Note two things: 1) Even though the RNG is seeded with the same number everytime, 24 identical rows are not created; 2) There is a noticeable hit on performance and obvious increase in resource consumption, which is a given when improving random number generation:
static int _randomRepository;
static Queue<int> _randomSource = new Queue<int>();
static void Main(string args)
InitializeRepository(0, 1, 40);
for (int i = 0; i < 24; i++)
for (int j = 0; j < 40; j++)
Console.Write(GetNext() + " ");
static void InitializeRepository(int min, int max, int size)
_randomRepository = new int[size];
var rand = new Random(1024);
for (int i = 0; i < size; i++)
_randomRepository[i] = rand.Next(min, max + 1);
static void FillSource()
Thread threads = new Thread[Environment.ProcessorCount * 8];
for (int j = 0; j < threads.Length; j++)
threads[j] = new Thread((myNum) =>
int i = (int)myNum * _randomRepository.Length / threads.Length;
int max = (((int)myNum + 1) * _randomRepository.Length / threads.Length) - 1;
for (int k = i; k <= max; k++)
threads[j].Priority = ThreadPriority.Highest;
for (int k = 0; k < threads.Length; k++)
static int GetNext()
if (_randomSource.Count > 0)
As long as there is user(s) input/interaction during the generation, this technique will produce an uncrackable, non-repeating sequence of 'random' numbers. In such a scenario, knowing the initial state of the machine would be insufficient to predict the outcome.