Mysterious combination - math

I decided to learn concurrency and wanted to find out in how many ways instructions from two different processes could overlap. The code for both processes is just a 10 iteration loop with 3 instructions performed in each iteration. I figured out the problem consisted of leaving X instructions fixed at a point and then fit the other X instructions from the other process between the spaces taking into account that they must be ordered (instruction 4 of process B must always come before instruction 20).
I wrote a program to count this number, looking at the results I found out that the solution is n Combination k, where k is the number of instructions executed throughout the whole loop of one process, so for 10 iterations it would be 30, and n is k*2 (2 processes). In other words, n number of objects with n/2 fixed and having to fit n/2 among the spaces without the latter n/2 losing their order.
Ok problem solved. No, not really. I have no idea why this is, I understand that the definition of a combination is, in how many ways can you take k elements from a group of n such that all the groups are different but the order in which you take the elements doesn't matter. In this case we have n elements and we are actually taking them all, because all the instructions are executed ( n C n).
If one explains it by saying that there are 2k blue (A) and red (B) objects in a bag and you take k objects from the bag, you are still only taking k instructions when 2k instructions are actually executed. Can you please shed some light into this?
Thanks in advance.

FWIW it can be viewed like this: you have a bag with k blue and k red balls. Balls of same color are indistinguishable (in analogy with the restriction that the order of instructions within the same process/thread is fixed - which is not true in modern processors btw, but let's keep it simple for now). How many different ways can you pull all the balls from the bag?
My combinatorial skills are quite rusty, but my first guess is
(2k!)
-----
2*k!
which, according to Wikipedia, indeed equals
(2k)
(k )
(sorry, I have no better idea how to show this).
For n processes, it can be generalized by having balls of n different color in the bag.
Update: Note that in the strict sense, this models only the situation when different processes are executed on a single processor, so all instructions from all processes must be ordered linearly on the processor level. In a multiprocessor environment, several instructions can be executed literally at the same time.

Generally, I agree with Péter's answer, but since it does not seem to have fully clicked for the OP, here's my shot at it (purely from a mathematical/combinatorial standpoint).
You have 2 sets of 30 (k) instructions that you're putting together, for a total of 60 (n) instructions. Since each set of 30 must be kept in order, we don't need to track which instruction within each set, just which set an instruction is from. So, we have 60 "slots" in which to place 30 instructions from one set (say, red) and 30 instructions from the other set (say, blue).
Let's start by placing the 30 red instructions into the 60 slots. There are (60 choose 30) = 60!/(30!30!) ways to do this (we're choosing which 30 slots of the 60 are filled by red instructions). Now, we still have the 30 blue instructions, but we only have 30 open slots left. There is (30 choose 30) = 30!/(30!0!) = 1 way to place the blue instructions in the remaining slots. So, in total, there are (60 choose 30) * (30 choose 30) = (60 choose 30) * 1 = (60 choose 30) ways to do it.
Now, let's suppose that instead of 2 sets of 30, you have 3 sets (red, green, blue) of k instructions. You have a total of 3k slots to fill. First, place the red ones: (3k choose k) = (3k)!/(k!(3k-k)!) = (3k)!/(k!(2k)!). Now, place the green ones into the remaining 2k slots: (2k choose k) = (2k)!/(k!k!). Finally, place the blue ones into the last k slots: (k choose k) = k!/(k!0!) = 1. In total: (3k choose k) * (2k choose k) * (k choose k) = ( (3k)! * (2k)! * k! ) / ( k!(2k)! * k!k! * k!0! ) = (3k)!/(k!k!k!).
As further extensions (though I'm not going to provide a full explanation):
if you have 3 sets of instructions with length a, b, and c, the number of possibilities is (a+b+c)!/(a!b!c!).
if you have n sets of instructions where the ith set has ki instructions, the number of possibilities is (k1+k2+...+kn)!/(k1!k2!...kn!).

Péter's answer is fine enough, but that doesn't explain just why concurrency is difficult. That's because more and more often nowadays you've got multiple execution units available (be they cores, CPUs, nodes, computers, whatever). That in turn means that the possibilities for overlapping between instructions is increased still further; there's no guarantee that what happens can be modeled correctly with any conventional interleaving.
This is why it is important to think in terms of using semaphores/mutexes correctly, and why memory barriers matter. That's because all of these things end up turning the true nasty picture into something that is far easier to understand. But because mutexes reduce the number of possible executions, they are reducing the overall performance and potential efficiency. It's definitely tricky, and that in turn is why it is far better if you can work in terms of message passing between threads of activity that do not otherwise interact; it's easier to understand and having fewer synchronizations is better.

Related

In what order we need to put weights on scale?

I' am doing my homework in programming, and I don't know how to solve this problem:
We have a set of n weights, we are putting them on a scale one by one until all weights is used. We also have string of n letters "R" or "L" which means which pen is heavier in that moment, they can't be in balance. There are no weights with same mass. Compute in what order we have to put weights on scale and on which pan.
The goal is to find order of putting weights on scale, so the input string is respected.
Input: number 0 < n < 51, number of weights. Then weights and the string.
Output: in n lines, weight and "R" or "L", side where you put weight. If there are many, output any of them.
Example 1:
Input:
3
10 20 30
LRL
Output:
10 L
20 R
30 L
Example 2:
Input:
3
10 20 30
LLR
Output:
20 L
10 R
30 R
Example 3:
Input:
5
10 20 30 40 50
LLLLR
Output:
50 L
10 L
20 R
30 R
40 R
I already tried to compute it with recursion but unsuccessful. Can someone please help me with this problem or just gave me hints how to solve it.
Since you do not show any code of your own, I'll give you some ideas without code. If you need more help, show more of your work then I can show you Python code that solves your problem.
Your problem is suitable for backtracking. Wikipedia's definition of this algorithm is
Backtracking is a general algorithm for finding all (or some) solutions to some computational problems, notably constraint satisfaction problems, that incrementally builds candidates to the solutions, and abandons a candidate ("backtracks") as soon as it determines that the candidate cannot possibly be completed to a valid solution.
and
Backtracking can be applied only for problems which admit the concept of a "partial candidate solution" and a relatively quick test of whether it can possibly be completed to a valid solution.
Your problem satisfies those requirements. At each stage you need to choose one of the remaining weights and one of the two pans of the scale. When you place the chosen weight on the chosen pan, you determine if the corresponding letter from the input string is satisfied. If not, you reject the choice of weight and pan. If so, you continue by choosing another weight and pan.
Your overall routine first inputs and prepares the data. It then calls a recursive routine that chooses one weight and one pan at each level. Some of the information needed by each level could be put into mutable global variables, but it would be more clear if you pass all needed information as parameters. Each call to the recursive routine needs to pass:
the weights not yet used
the input L/R string not yet used
the current state of the weights on the pans, in a format that can easily be printed when finalized (perhaps an array of ordered pairs of a weight and a pan)
the current weight imbalance of the pans. This could be calculated from the previous parameter, but time would be saved by passing this separately. This would be total of the weights on the right pan minus the total of the weights on the left pan (or vice versa).
Your base case for the recursion is when the unused-weights and unused-letters are empty. You then have finished the search and can print the solution and quit the program. Otherwise you loop over all combinations of one of the unused weights and one of the pans. For each combination, calculate what the new imbalance would be if you placed that weight on that pan. If that new imbalance agrees with the corresponding letter, call the routine recursively with appropriately-modified parameters. If not, do nothing for this weight and pan.
You still have a few choices to make before coding, such as the data structure for the unused weights. Show me some of your own coding efforts then I'll give you my Python code.
Be aware that this could be slow for a large number of weights. For n weights and two pans, the total number of ways to place the weights on the pans is n! * 2**n (that is a factorial and an exponentiation). For n = 50 that is over 3e79, much too large to do. The backtracking avoids most groups of choices, since choices are rejected as soon as possible, but my algorithm could still be slow. There may be a better algorithm than backtracking, but I do not see it. Your problem seems to be designed to be handled by backtracking.
Now that you have shown more effort of your own, here is my un-optimized Python 3 code. This works for all the examples you gave, though I got a different valid solution for your third example.
def weights_on_pans():
def solve(unused_weights, unused_tilts, placement, imbalance):
"""Place the weights on the scales using recursive
backtracking. Return True if successful, False otherwise."""
if not unused_weights:
# Done: print the placement and note that we succeeded
for weight, pan in placement:
print(weight, 'L' if pan < 0 else 'R')
return True # success right now
tilt, *later_tilts = unused_tilts
for weight in unused_weights:
for pan in (-1, 1): # -1 means left, 1 means right
new_imbalance = imbalance + pan * weight
if new_imbalance * tilt > 0: # both negative or both positive
# Continue searching since imbalance in proper direction
if solve(unused_weights - {weight},
later_tilts,
placement + [(weight, pan)],
new_imbalance):
return True # success at a lower level
return False # not yet successful
# Get the inputs from standard input. (This version has no validity checks)
cnt_weights = int(input())
weights = {int(item) for item in input().split()}
letters = input()
# Call the recursive routine with appropriate starting parameters.
tilts = [(-1 if letter == 'L' else 1) for letter in letters]
solve(weights, tilts, [], 0)
weights_on_pans()
The main way I can see to speed up that code is to avoid the O(n) operations in the call to solve in the inner loop. That means perhaps changing the data structure of unused_weights and changing how it, placement, and perhaps unused_tilts/later_tilts are modified to use O(1) operations. Those changes would complicate the code, which is why I did not do them.

What is the difference between approaches to "coin change" and "Number of of ways of climbing staircase"

I have come across two dynamic programming problems. One of the problems is
What is the number of possible ways to climb a staircase with n steps given that I can hop either 1 , 2 or 3 steps at a time.
The Dynamic programming approach for solving this problem goes as follows.
If C(n) is number of ways of climbing the staircase, then
C(n) = C(n-1) + C(n-2) + C(n-3) .
This is because , if we reach n-1 stairs, we can hop to n by 1 step hop or
if we reach n-2 stairs, we can hop to n by 2 step hop or
if we reach n-3 stairs, we can hop to n by 3 step hop
As I was about to think, I understood the above approach, I came across the coin change problem which is
What is the number of ways of representing n cents, given infinite number of 25 cent coins, 10 cent coins (dimes), 5 cent coins(nickels) and 1 cent coins
It turns out the solution for this problem is not similar to the one above and is bit complex. That is ,
C(n) = C(n-1) + C(n-5) + C(n-10) + C(n-25) is not true. I am still trying to understand the approach for solving this problem. But my question is How is the coin change problem different from the much simpler climbing steps problem?
In the steps problem, the order matters: (1,2) is not the same as (2,1). With the coin problem, only the number of each type of coin used matters.
Scott's solution is absolutely correct, and he mentions the crux of the difference between the two problems. Here's a little more color on the two problems to help intuitively understand the difference.
For Dynamic Programming problems that involve recursion, the trick is to get the subproblem right. Once the subproblem is correct, it is just a matter of building on top of that.
The Staircase problem deals with sequences so the subproblem is easier to see intuitively. For the Coin-change problem, we are dealing with counts so the subproblem is around whether or not to use a particular denomination. We compute one part of the solution using a denomination, and another without using it. That is a slightly more difficult insight to see, but once you see that, you can recursively compute the rest.
So here's one way to think about the two problems:
Staircase Sequence
Introduce one new step. The nth step has been added. How do we compute S[N]?
S[N] = S[N-1] + S[N-2] + S[N-3]
Coin Change
Introduce a new small coin denomination. Let's say a coin of denomination 'm' has newly been introduced.
How do we now compute C[n], knowing C[N, with all coins except m]?
All the ways to reach N without coin m still hold. But each new coin denomination 'm' fundamentally changes the ways to get to N. So to compute C[N using m] we have to recursively compute C[N-m, using the new coin m], and C[N-2m using m]...and so on.
C[N, with m] = C[N, without m] + C[N-m, with m]
Hope that helps.

Understanding "randomness"

I can't get my head around this, which is more random?
rand()
OR:
rand() * rand()
I´m finding it a real brain teaser, could you help me out?
EDIT:
Intuitively I know that the mathematical answer will be that they are equally random, but I can't help but think that if you "run the random number algorithm" twice when you multiply the two together you'll create something more random than just doing it once.
Just a clarification
Although the previous answers are right whenever you try to spot the randomness of a pseudo-random variable or its multiplication, you should be aware that while Random() is usually uniformly distributed, Random() * Random() is not.
Example
This is a uniform random distribution sample simulated through a pseudo-random variable:
BarChart[BinCounts[RandomReal[{0, 1}, 50000], 0.01]]
While this is the distribution you get after multiplying two random variables:
BarChart[BinCounts[Table[RandomReal[{0, 1}, 50000] *
RandomReal[{0, 1}, 50000], {50000}], 0.01]]
So, both are “random”, but their distribution is very different.
Another example
While 2 * Random() is uniformly distributed:
BarChart[BinCounts[2 * RandomReal[{0, 1}, 50000], 0.01]]
Random() + Random() is not!
BarChart[BinCounts[Table[RandomReal[{0, 1}, 50000] +
RandomReal[{0, 1}, 50000], {50000}], 0.01]]
The Central Limit Theorem
The Central Limit Theorem states that the sum of Random() tends to a normal distribution as terms increase.
With just four terms you get:
BarChart[BinCounts[Table[RandomReal[{0, 1}, 50000] + RandomReal[{0, 1}, 50000] +
Table[RandomReal[{0, 1}, 50000] + RandomReal[{0, 1}, 50000],
{50000}],
0.01]]
And here you can see the road from a uniform to a normal distribution by adding up 1, 2, 4, 6, 10 and 20 uniformly distributed random variables:
Edit
A few credits
Thanks to Thomas Ahle for pointing out in the comments that the probability distributions shown in the last two images are known as the Irwin-Hall distribution
Thanks to Heike for her wonderful torn[] function
I guess both methods are as random although my gutfeel would say that rand() * rand() is less random because it would seed more zeroes. As soon as one rand() is 0, the total becomes 0
Neither is 'more random'.
rand() generates a predictable set of numbers based on a psuedo-random seed (usually based on the current time, which is always changing). Multiplying two consecutive numbers in the sequence generates a different, but equally predictable, sequence of numbers.
Addressing whether this will reduce collisions, the answer is no. It will actually increase collisions due to the effect of multiplying two numbers where 0 < n < 1. The result will be a smaller fraction, causing a bias in the result towards the lower end of the spectrum.
Some further explanations. In the following, 'unpredictable' and 'random' refer to the ability of someone to guess what the next number will be based on previous numbers, ie. an oracle.
Given seed x which generates the following list of values:
0.3, 0.6, 0.2, 0.4, 0.8, 0.1, 0.7, 0.3, ...
rand() will generate the above list, and rand() * rand() will generate:
0.18, 0.08, 0.08, 0.21, ...
Both methods will always produce the same list of numbers for the same seed, and hence are equally predictable by an oracle. But if you look at the the results for multiplying the two calls, you'll see they are all under 0.3 despite a decent distribution in the original sequence. The numbers are biased because of the effect of multiplying two fractions. The resulting number is always smaller, therefore much more likely to be a collision despite still being just as unpredictable.
Oversimplification to illustrate a point.
Assume your random function only outputs 0 or 1.
random() is one of (0,1), but random()*random() is one of (0,0,0,1)
You can clearly see that the chances to get a 0 in the second case are in no way equal to those to get a 1.
When I first posted this answer I wanted to keep it as short as possible so that a person reading it will understand from a glance the difference between random() and random()*random(), but I can't keep myself from answering the original ad litteram question:
Which is more random?
Being that random(), random()*random(), random()+random(), (random()+1)/2 or any other combination that doesn't lead to a fixed result have the same source of entropy (or the same initial state in the case of pseudorandom generators), the answer would be that they are equally random (The difference is in their distribution). A perfect example we can look at is the game of Craps. The number you get would be random(1,6)+random(1,6) and we all know that getting 7 has the highest chance, but that doesn't mean the outcome of rolling two dice is more or less random than the outcome of rolling one.
Here's a simple answer. Consider Monopoly. You roll two six sided dice (or 2d6 for those of you who prefer gaming notation) and take their sum. The most common result is 7 because there are 6 possible ways you can roll a 7 (1,6 2,5 3,4 4,3 5,2 and 6,1). Whereas a 2 can only be rolled on 1,1. It's easy to see that rolling 2d6 is different than rolling 1d12, even if the range is the same (ignoring that you can get a 1 on a 1d12, the point remains the same). Multiplying your results instead of adding them is going to skew them in a similar fashion, with most of your results coming up in the middle of the range. If you're trying to reduce outliers, this is a good method, but it won't help making an even distribution.
(And oddly enough it will increase low rolls as well. Assuming your randomness starts at 0, you'll see a spike at 0 because it will turn whatever the other roll is into a 0. Consider two random numbers between 0 and 1 (inclusive) and multiplying. If either result is a 0, the whole thing becomes a 0 no matter the other result. The only way to get a 1 out of it is for both rolls to be a 1. In practice this probably wouldn't matter but it makes for a weird graph.)
The obligatory xkcd ...
It might help to think of this in more discrete numbers. Consider want to generate random numbers between 1 and 36, so you decide the easiest way is throwing two fair, 6-sided dice. You get this:
1 2 3 4 5 6
-----------------------------
1| 1 2 3 4 5 6
2| 2 4 6 8 10 12
3| 3 6 9 12 15 18
4| 4 8 12 16 20 24
5| 5 10 15 20 25 30
6| 6 12 18 24 30 36
So we have 36 numbers, but not all of them are fairly represented, and some don't occur at all. Numbers near the center diagonal (bottom-left corner to top-right corner) will occur with the highest frequency.
The same principles which describe the unfair distribution between dice apply equally to floating point numbers between 0.0 and 1.0.
Some things about "randomness" are counter-intuitive.
Assuming flat distribution of rand(), the following will get you non-flat distributions:
high bias: sqrt(rand(range^2))
bias peaking in the middle: (rand(range) + rand(range))/2
low:bias: range - sqrt(rand(range^2))
There are lots of other ways to create specific bias curves. I did a quick test of rand() * rand() and it gets you a very non-linear distribution.
Most rand() implementations have some period. I.e. after some enormous number of calls the sequence repeats. The sequence of outputs of rand() * rand() repeats in half the time, so it is "less random" in that sense.
Also, without careful construction, performing arithmetic on random values tends to cause less randomness. A poster above cited "rand() + rand() + rand() ..." (k times, say) which will in fact tend to k times the mean value of the range of values rand() returns. (It's a random walk with steps symmetric about that mean.)
Assume for concreteness that your rand() function returns a uniformly distributed random real number in the range [0,1). (Yes, this example allows infinite precision. This won't change the outcome.) You didn't pick a particular language and different languages may do different things, but the following analysis holds with modifications for any non-perverse implementation of rand(). The product rand() * rand() is also in the range [0,1) but is no longer uniformly distributed. In fact, the product is as likely to be in the interval [0,1/4) as in the interval [1/4,1). More multiplication will skew the result even further toward zero. This makes the outcome more predictable. In broad strokes, more predictable == less random.
Pretty much any sequence of operations on uniformly random input will be nonuniformly random, leading to increased predictability. With care, one can overcome this property, but then it would have been easier to generate a uniformly distributed random number in the range you actually wanted rather than wasting time with arithmetic.
"random" vs. "more random" is a little bit like asking which Zero is more zero'y.
In this case, rand is a PRNG, so not totally random. (in fact, quite predictable if the seed is known). Multiplying it by another value makes it no more or less random.
A true crypto-type RNG will actually be random. And running values through any sort of function cannot add more entropy to it, and may very likely remove entropy, making it no more random.
The concept you're looking for is "entropy," the "degree" of disorder of a string
of bits. The idea is easiest to understand in terms of the concept of "maximum entropy".
An approximate definition of a string of bits with maximum entropy is that it cannot be expressed exactly in terms of a shorter string of bits (ie. using some algorithm to
expand the smaller string back to the original string).
The relevance of maximum entropy to randomness stems from the fact that
if you pick a number "at random", you will almost certainly pick a number
whose bit string is close to having maximum entropy, that is, it can't be compressed.
This is our best understanding of what characterizes a "random" number.
So, if you want to make a random number out of two random samples which is "twice" as
random, you'd concatenate the two bit strings together. Practically, you'd just
stuff the samples into the high and low halves of a double length word.
On a more practical note, if you find yourself saddled with a crappy rand(), it can
sometimes help to xor a couple of samples together --- although, if its truly broken even
that procedure won't help.
The accepted answer is quite lovely, but there's another way to answer your question. PachydermPuncher's answer already takes this alternative approach, and I'm just going to expand it out a little.
The easiest way to think about information theory is in terms of the smallest unit of information, a single bit.
In the C standard library, rand() returns an integer in the range 0 to RAND_MAX, a limit that may be defined differently depending on the platform. Suppose RAND_MAX happens to be defined as 2^n - 1 where n is some integer (this happens to be the case in Microsoft's implementation, where n is 15). Then we would say that a good implementation would return n bits of information.
Imagine that rand() constructs random numbers by flipping a coin to find the value of one bit, and then repeating until it has a batch of 15 bits. Then the bits are independent (the value of any one bit does not influence the likelihood of other bits in the same batch have a certain value). So each bit considered independently is like a random number between 0 and 1 inclusive, and is "evenly distributed" over that range (as likely to be 0 as 1).
The independence of the bits ensures that the numbers represented by batches of bits will also be evenly distributed over their range. This is intuitively obvious: if there are 15 bits, the allowed range is zero to 2^15 - 1 = 32767. Every number in that range is a unique pattern of bits, such as:
010110101110010
and if the bits are independent then no pattern is more likely to occur than any other pattern. So all possible numbers in the range are equally likely. And so the reverse is true: if rand() produces evenly distributed integers, then those numbers are made of independent bits.
So think of rand() as a production line for making bits, which just happens to serve them up in batches of arbitrary size. If you don't like the size, break the batches up into individual bits, and then put them back together in whatever quantities you like (though if you need a particular range that is not a power of 2, you need to shrink your numbers, and by far the easiest way to do that is to convert to floating point).
Returning to your original suggestion, suppose you want to go from batches of 15 to batches of 30, ask rand() for the first number, bit-shift it by 15 places, then add another rand() to it. That is a way to combine two calls to rand() without disturbing an even distribution. It works simply because there is no overlap between the locations where you place the bits of information.
This is very different to "stretching" the range of rand() by multiplying by a constant. For example, if you wanted to double the range of rand() you could multiply by two - but now you'd only ever get even numbers, and never odd numbers! That's not exactly a smooth distribution and might be a serious problem depending on the application, e.g. a roulette-like game supposedly allowing odd/even bets. (By thinking in terms of bits, you'd avoid that mistake intuitively, because you'd realise that multiplying by two is the same as shifting the bits to the left (greater significance) by one place and filling in the gap with zero. So obviously the amount of information is the same - it just moved a little.)
Such gaps in number ranges can't be griped about in floating point number applications, because floating point ranges inherently have gaps in them that simply cannot be represented at all: an infinite number of missing real numbers exist in the gap between each two representable floating point numbers! So we just have to learn to live with gaps anyway.
As others have warned, intuition is risky in this area, especially because mathematicians can't resist the allure of real numbers, which are horribly confusing things full of gnarly infinities and apparent paradoxes.
But at least if you think it terms of bits, your intuition might get you a little further. Bits are really easy - even computers can understand them.
As others have said, the easy short answer is: No, it is not more random, but it does change the distribution.
Suppose you were playing a dice game. You have some completely fair, random dice. Would the die rolls be "more random" if before each die roll, you first put two dice in a bowl, shook it around, picked one of the dice at random, and then rolled that one? Clearly it would make no difference. If both dice give random numbers, then randomly choosing one of the two dice will make no difference. Either way you'll get a random number between 1 and 6 with even distribution over a sufficient number of rolls.
I suppose in real life such a procedure might be useful if you suspected that the dice might NOT be fair. If, say, the dice are slightly unbalanced so one tends to give 1 more often than 1/6 of the time, and another tends to give 6 unusually often, then randomly choosing between the two would tend to obscure the bias. (Though in this case, 1 and 6 would still come up more than 2, 3, 4, and 5. Well, I guess depending on the nature of the imbalance.)
There are many definitions of randomness. One definition of a random series is that it is a series of numbers produced by a random process. By this definition, if I roll a fair die 5 times and get the numbers 2, 4, 3, 2, 5, that is a random series. If I then roll that same fair die 5 more times and get 1, 1, 1, 1, 1, then that is also a random series.
Several posters have pointed out that random functions on a computer are not truly random but rather pseudo-random, and that if you know the algorithm and the seed they are completely predictable. This is true, but most of the time completely irrelevant. If I shuffle a deck of cards and then turn them over one at a time, this should be a random series. If someone peeks at the cards, the result will be completely predictable, but by most definitions of randomness this will not make it less random. If the series passes statistical tests of randomness, the fact that I peeked at the cards will not change that fact. In practice, if we are gambling large sums of money on your ability to guess the next card, then the fact that you peeked at the cards is highly relevant. If we are using the series to simulate the menu picks of visitors to our web site in order to test the performance of the system, then the fact that you peeked will make no difference at all. (As long as you do not modify the program to take advantage of this knowledge.)
EDIT
I don't think I could my response to the Monty Hall problem into a comment, so I'll update my answer.
For those who didn't read Belisarius link, the gist of it is: A game show contestant is given a choice of 3 doors. Behind one is a valuable prize, behind the others something worthless. He picks door #1. Before revealing whether it is a winner or a loser, the host opens door #3 to reveal that it is a loser. He then gives the contestant the opportunity to switch to door #2. Should the contestant do this or not?
The answer, which offends many people's intuition, is that he should switch. The probability that his original pick was the winner is 1/3, that the other door is the winner is 2/3. My initial intuition, along with that of many other people, is that there would be no gain in switching, that the odds have just been changed to 50:50.
After all, suppose that someone switched on the TV just after the host opened the losing door. That person would see two remaining closed doors. Assuming he knows the nature of the game, he would say that there is a 1/2 chance of each door hiding the prize. How can the odds for the viewer be 1/2 : 1/2 while the odds for the contestant are 1/3 : 2/3 ?
I really had to think about this to beat my intuition into shape. To get a handle on it, understand that when we talk about probabilities in a problem like this, we mean, the probability you assign given the available information. To a member of the crew who put the prize behind, say, door #1, the probability that the prize is behind door #1 is 100% and the probability that it is behind either of the other two doors is zero.
The crew member's odds are different than the contestant's odds because he knows something the contestant doesn't, namely, which door he put the prize behind. Likewise, the contestent's odds are different than the viewer's odds because he knows something that the viewer doesn't, namely, which door he initially picked. This is not irrelevant, because the host's choice of which door to open is not random. He will not open the door the contestant picked, and he will not open the door that hides the prize. If these are the same door, that leaves him two choices. If they are different doors, that leaves only one.
So how do we come up with 1/3 and 2/3 ? When the contestant originally picked a door, he had a 1/3 chance of picking the winner. I think that much is obvious. That means there was a 2/3 chance that one of the other doors is the winner. If the host game him the opportunity to switch without giving any additional information, there would be no gain. Again, this should be obvious. But one way to look at it is to say that there is a 2/3 chance that he would win by switching. But he has 2 alternatives. So each one has only 2/3 divided by 2 = 1/3 chance of being the winner, which is no better than his original pick. Of course we already knew the final result, this just calculates it a different way.
But now the host reveals that one of those two choices is not the winner. So of the 2/3 chance that a door he didn't pick is the winner, he now knows that 1 of the 2 alternatives isn't it. The other might or might not be. So he no longer has 2/3 dividied by 2. He has zero for the open door and 2/3 for the closed door.
Consider you have a simple coin flip problem where even is considered heads and odd is considered tails. The logical implementation is:
rand() mod 2
Over a large enough distribution, the number of even numbers should equal the number of odd numbers.
Now consider a slight tweak:
rand() * rand() mod 2
If one of the results is even, then the entire result should be even. Consider the 4 possible outcomes (even * even = even, even * odd = even, odd * even = even, odd * odd = odd). Now, over a large enough distribution, the answer should be even 75% of the time.
I'd bet heads if I were you.
This comment is really more of an explanation of why you shouldn't implement a custom random function based on your method than a discussion on the mathematical properties of randomness.
When in doubt about what will happen to the combinations of your random numbers, you can use the lessons you learned in statistical theory.
In OP's situation he wants to know what's the outcome of X*X = X^2 where X is a random variable distributed along Uniform[0,1]. We'll use the CDF technique since it's just a one-to-one mapping.
Since X ~ Uniform[0,1] it's cdf is: fX(x) = 1
We want the transformation Y <- X^2 thus y = x^2
Find the inverse x(y): sqrt(y) = x this gives us x as a function of y.
Next, find the derivative dx/dy: d/dy (sqrt(y)) = 1/(2 sqrt(y))
The distribution of Y is given as: fY(y) = fX(x(y)) |dx/dy| = 1/(2 sqrt(y))
We're not done yet, we have to get the domain of Y. since 0 <= x < 1, 0 <= x^2 < 1
so Y is in the range [0, 1).
If you wanna check if the pdf of Y is indeed a pdf, integrate it over the domain: Integrate 1/(2 sqrt(y)) from 0 to 1 and indeed, it pops up as 1. Also, notice the shape of the said function looks like what belisarious posted.
As for things like X1 + X2 + ... + Xn, (where Xi ~ Uniform[0,1]) we can just appeal to the Central Limit Theorem which works for any distribution whose moments exist. This is why the Z-test exists actually.
Other techniques for determining the resulting pdf include the Jacobian transformation (which is the generalized version of the cdf technique) and MGF technique.
EDIT: As a clarification, do note that I'm talking about the distribution of the resulting transformation and not its randomness. That's actually for a separate discussion. Also what I actually derived was for (rand())^2. For rand() * rand() it's much more complicated, which, in any case won't result in a uniform distribution of any sorts.
It's not exactly obvious, but rand() is typically more random than rand()*rand(). What's important is that this isn't actually very important for most uses.
But firstly, they produce different distributions. This is not a problem if that is what you want, but it does matter. If you need a particular distribution, then ignore the whole “which is more random” question. So why is rand() more random?
The core of why rand() is more random (under the assumption that it is producing floating-point random numbers with the range [0..1], which is very common) is that when you multiply two FP numbers together with lots of information in the mantissa, you get some loss of information off the end; there's just not enough bit in an IEEE double-precision float to hold all the information that was in two IEEE double-precision floats uniformly randomly selected from [0..1], and those extra bits of information are lost. Of course, it doesn't matter that much since you (probably) weren't going to use that information, but the loss is real. It also doesn't really matter which distribution you produce (i.e., which operation you use to do the combination). Each of those random numbers has (at best) 52 bits of random information – that's how much an IEEE double can hold – and if you combine two or more into one, you're still limited to having at most 52 bits of random information.
Most uses of random numbers don't use even close to as much randomness as is actually available in the random source. Get a good PRNG and don't worry too much about it. (The level of “goodness” depends on what you're doing with it; you have to be careful when doing Monte Carlo simulation or cryptography, but otherwise you can probably use the standard PRNG as that's usually much quicker.)
Floating randoms are based, in general, on an algorithm that produces an integer between zero and a certain range. As such, by using rand()*rand(), you are essentially saying int_rand()*int_rand()/rand_max^2 - meaning you are excluding any prime number / rand_max^2.
That changes the randomized distribution significantly.
rand() is uniformly distributed on most systems, and difficult to predict if properly seeded. Use that unless you have a particular reason to do math on it (i.e., shaping the distribution to a needed curve).
Multiplying numbers would end up in a smaller solution range depending on your computer architecture.
If the display of your computer shows 16 digits rand() would be say 0.1234567890123
multiplied by a second rand(), 0.1234567890123, would give 0.0152415 something
you'd definitely find fewer solutions if you'd repeat the experiment 10^14 times.
Most of these distributions happen because you have to limit or normalize the random number.
We normalize it to be all positive, fit within a range, and even to fit within the constraints of the memory size for the assigned variable type.
In other words, because we have to limit the random call between 0 and X (X being the size limit of our variable) we will have a group of "random" numbers between 0 and X.
Now when you add the random number to another random number the sum will be somewhere between 0 and 2X...this skews the values away from the edge points (the probability of adding two small numbers together and two big numbers together is very small when you have two random numbers over a large range).
Think of the case where you had a number that is close to zero and you add it with another random number it will certainly get bigger and away from 0 (this will be true of large numbers as well as it is unlikely to have two large numbers (numbers close to X) returned by the Random function twice.
Now if you were to setup the random method with negative numbers and positive numbers (spanning equally across the zero axis) this would no longer be the case.
Say for instance RandomReal({-x, x}, 50000, .01) then you would get an even distribution of numbers on the negative a positive side and if you were to add the random numbers together they would maintain their "randomness".
Now I'm not sure what would happen with the Random() * Random() with the negative to positive span...that would be an interesting graph to see...but I have to get back to writing code now. :-P
There is no such thing as more random. It is either random or not. Random means "hard to predict". It does not mean non-deterministic. Both random() and random() * random() are equally random if random() is random. Distribution is irrelevant as far as randomness goes. If a non-uniform distribution occurs, it just means that some values are more likely than others; they are still unpredictable.
Since pseudo-randomness is involved, the numbers are very much deterministic. However, pseudo-randomness is often sufficient in probability models and simulations. It is pretty well known that making a pseudo-random number generator complicated only makes it difficult to analyze. It is unlikely to improve randomness; it often causes it to fail statistical tests.
The desired properties of the random numbers are important: repeatability and reproducibility, statistical randomness, (usually) uniformly distributed, and a large period are a few.
Concerning transformations on random numbers: As someone said, the sum of two or more uniformly distributed results in a normal distribution. This is the additive central limit theorem. It applies regardless of the source distribution as long as all distributions are independent and identical. The multiplicative central limit theorem says the product of two or more independent and indentically distributed random variables is lognormal. The graph someone else created looks exponential, but it is really lognormal. So random() * random() is lognormally distributed (although it may not be independent since numbers are pulled from the same stream). This may be desirable in some applications. However, it is usually better to generate one random number and transform it to a lognormally-distributed number. Random() * random() may be difficult to analyze.
For more information, consult my book at www.performorama.org. The book is under construction, but the relevant material is there. Note that chapter and section numbers may change over time. Chapter 8 (probability theory) -- sections 8.3.1 and 8.3.3, chapter 10 (random numbers).
We can compare two arrays of numbers regarding the randomness by using
Kolmogorov complexity
If the sequence of numbers can not be compressed, then it is the most random we can reach at this length...
I know that this type of measurement is more a theoretical option...
Actually, when you think about it rand() * rand() is less random than rand(). Here's why.
Essentially, there are the same number of odd numbers as even numbers. And saying that 0.04325 is odd, and like 0.388 is even, and 0.4 is even, and 0.15 is odd,
That means that rand() has a equal chance of being an even or odd decimal.
On the other hand, rand() * rand() has it's odds stacked a bit differently.
Lets say:
double a = rand();
double b = rand();
double c = a * b;
a and b both have a 50% precent chance of being even or odd. Knowing that
even * even = even
even * odd = even
odd * odd = odd
odd * even = even
means that there a 75% chance that c is even, while only a 25% chance it's odd, making the value of rand() * rand() more predictable than rand(), therefore less random.
Use a linear feedback shift register (LFSR) that implements a primitive polynomial.
The result will be a sequence of 2^n pseudo-random numbers, ie none repeating in the sequence where n is the number of bits in the LFSR .... resulting in a uniform distribution.
http://en.wikipedia.org/wiki/Linear_feedback_shift_register
http://www.xilinx.com/support/documentation/application_notes/xapp052.pdf
Use a "random" seed based on microsecs of your computer clock or maybe a subset of the md5 result on some continuously changing data in your file system.
For example, a 32-bit LFSR will generate 2^32 unique numbers in sequence (no 2 alike) starting with a given seed.
The sequence will always be in the same order, but the starting point will be different (obviously) for a different seeds.
So, if a possibly repeating sequence between seedings is not a problem, this might be a good choice.
I've used 128-bit LFSR's to generate random tests in hardware simulators using a seed which is the md5 results on continuously changing system data.
Assuming that rand() returns a number between [0, 1) it is obvious that rand() * rand() will be biased toward 0. This is because multiplying x by a number between [0, 1) will result in a number smaller than x. Here is the distribution of 10000 more random numbers:
google.charts.load("current", { packages: ["corechart"] });
google.charts.setOnLoadCallback(drawChart);
function drawChart() {
var i;
var randomNumbers = [];
for (i = 0; i < 10000; i++) {
randomNumbers.push(Math.random() * Math.random());
}
var chart = new google.visualization.Histogram(document.getElementById("chart-1"));
var data = new google.visualization.DataTable();
data.addColumn("number", "Value");
randomNumbers.forEach(function(randomNumber) {
data.addRow([randomNumber]);
});
chart.draw(data, {
title: randomNumbers.length + " rand() * rand() values between [0, 1)",
legend: { position: "none" }
});
}
<script src="https://www.gstatic.com/charts/loader.js"></script>
<div id="chart-1" style="height: 500px">Generating chart...</div>
If rand() returns an integer between [x, y] then you have the following distribution. Notice the number of odd vs even values:
google.charts.load("current", { packages: ["corechart"] });
google.charts.setOnLoadCallback(drawChart);
document.querySelector("#draw-chart").addEventListener("click", drawChart);
function randomInt(min, max) {
return Math.floor(Math.random() * (max - min + 1)) + min;
}
function drawChart() {
var min = Number(document.querySelector("#rand-min").value);
var max = Number(document.querySelector("#rand-max").value);
if (min >= max) {
return;
}
var i;
var randomNumbers = [];
for (i = 0; i < 10000; i++) {
randomNumbers.push(randomInt(min, max) * randomInt(min, max));
}
var chart = new google.visualization.Histogram(document.getElementById("chart-1"));
var data = new google.visualization.DataTable();
data.addColumn("number", "Value");
randomNumbers.forEach(function(randomNumber) {
data.addRow([randomNumber]);
});
chart.draw(data, {
title: randomNumbers.length + " rand() * rand() values between [" + min + ", " + max + "]",
legend: { position: "none" },
histogram: { bucketSize: 1 }
});
}
<script src="https://www.gstatic.com/charts/loader.js"></script>
<input type="number" id="rand-min" value="0" min="0" max="10">
<input type="number" id="rand-max" value="9" min="0" max="10">
<input type="button" id="draw-chart" value="Apply">
<div id="chart-1" style="height: 500px">Generating chart...</div>
OK, so I will try to add some value to complement others answers by saying that you are creating and using a random number generator.
Random number generators are devices (in a very general sense) that have multiple characteristics which can be modified to fit a purpose. Some of them (from me) are:
Entropy: as in Shannon Entropy
Distribution: statistical distribution (poisson, normal, etc.)
Type: what is the source of the numbers (algorithm, natural event, combination of, etc.) and algorithm applied.
Efficiency: rapidity or complexity of execution.
Patterns: periodicity, sequences, runs, etc.
and probably more...
In most answers here, distribution is the main point of interest, but by mix and matching functions and parameters, you create new ways of generating random numbers which will have different characteristics for some of which the evaluation may not be obvious at first glance.
It's easy to show that the sum of the two random numbers is not necessarily random. Imagine you have a 6 sided die and roll. Each number has a 1/6 chance of appearing. Now say you had 2 dice and summed the result. The distribution of those sums is not 1/12. Why? Because certain numbers appear more than others. There are multiple partitions of them. For example the number 2 is the sum of 1+1 only but 7 can be formed by 3+4 or 4+3 or 5+2 etc... so it has a larger chance of coming up.
Therefore, applying a transform, in this case addition on a random function does not make it more random, or necessarily preserve randomness. In the case of the dice above, the distribution is skewed to 7 and therefore less random.
As others already pointed out, this question is hard to answer since everyone of us has his own picture of randomness in his head.
That is why, I would highly recommend you to take some time and read through this site to get a better idea of randomness:
http://www.random.org/
To get back to the real question.
There is no more or less random in this term:
both only appears random!
In both cases - just rand() or rand() * rand() - the situation is the same:
After a few billion of numbers the sequence will repeat(!).
It appears random to the observer, because he does not know the whole sequence, but the computer has no true random source - so he can not produce randomness either.
e.g.: Is the weather random?
We do not have enough sensors or knowledge to determine if weather is random or not.
The answer would be it depends, hopefully the rand()*rand() would be more random than rand(), but as:
both answers depends on the bit size of your value
that in most of the cases you generate depending on a pseudo-random algorithm (which is mostly a number generator that depends on your computer clock, and not that much random).
make your code more readable (and not invoke some random voodoo god of random with this kind of mantra).
Well, if you check any of these above I suggest you go for the simple "rand()".
Because your code would be more readable (wouldn't ask yourself why you did write this, for ...well... more than 2 sec), easy to maintain (if you want to replace you rand function with a super_rand).
If you want a better random, I would recommend you to stream it from any source that provide enough noise (radio static), and then a simple rand() should be enough.

MAD method compression function

I ran across the question below in an old exam. My answers just feels a bit short and inadequate. Any extra ideas I can look into or reasons I have overlooked would be great. Thanx
Consider the MAD method compression function, mapping an object with hash code i to element [(3i + 7)mod9027]mod6000 of the 6000-element bucket array. Explain why this is a poor choice of compression function, and how it could be improved.
I basically just say that the function could be improved by changing the value for p (or 9027) to an prime number and choosing an other constant for a (or 3) could also help.
Rup's comment is essentially the correct answer. 3 and 9027 are both divisible by 3, so 3i + 7 maps onto only 1/3 of the range 0-9026. Then the mapping mod 6000 maps 2/3 of the values to the lower half. So bucket 1 will contain roughly 1/1500 of the values [if I've done the math right] rather than the 1/6000 you would want. Bucket 0 will be empty.
if i is uniformly distributed over a large enough range, then (3i + 7)mod9027 will be evenly distributed over 0-9026, but then taking mod 6000 means two thirds of the hashes will be in the first half of the range (0 to 3026 and 6000 to 9026 inclusive), and one third in the second half (3037 to 5999 inclusive).

Hardware Cache Formulas (Parameter)

The image below was scanned (poorly) from Computer Systems: A Programmer's Perspective. (I apologize to the publisher). This appears on page 489.
Figure 6.26: Summary of cache parameters http://theopensourceu.com/wp-content/uploads/2009/07/Figure-6.26.jpg
I'm having a terribly difficult time understanding some of these calculations. At the current moment, what is troubling me is the calculation for M, which is supposed to be the number of unique addresses. "Maximum number of unique memory addresses." What does 2m suppose to mean? I think m is calculated as log2(M). This seems circular....
For the sake of this post, assume the following in the event you want to draw up an example: 512 sets, 8 blocks per set, 32 words per block, 8 bits per word
Update: All of the answers posted thus far have been helpful but I still think I'm missing something. cwrea's answer provides the biggest bridge for my understand. I feel like the answer is on the tip of my mental tongue. I know it is there but I can't identify it.
Why does M = 2m but then m = log2(M)?
Perhaps the detail I'm missing is that for a 32-bit machine, we'd assume M = 232. Does this single fact allow me to solve for m? m = log2(232)? But then this gets me back to 32... I have to be missing something...
m & M are related to each other, not defined in terms of each other. They call M a derived quantity however since usually the processor/controller is the limiting factor in terms of the word length it uses.
On a real system they are predefined. If you have a 8-bit processor, it generally can handle 8-bit memory addresses (m = 8). Since you can represent 256 values with 8-bits, you can have a total of 256 memory addresses (M = 2^8 = 256). As you can see we start with the little m due to the processor constraints, but you could always decide you want a memory space of size M, and use that to select a processor that can handle it based on word-size = log2(M).
Now if we take your assumptions for your example,
512 sets, 8 blocks per set, 32 words
per block, 8 bits per word
I have to assume this is an 8-bit processor given the 8-bit words. At that point your described cache is larger than your address space (256 words) & therefore pretty meaningless.
You might want to check out Computer Architecture Animations & Java applets. I don't recall if any of the cache ones go into the cache structure (usually they focus on behavior) but it is a resource I saved on the past to tutor students in architecture.
Feel free to further refine your question if it still doesn't make sense.
The two equations for M are just a relationship. They are two ways of saying the same thing. They do not indicate causality, though. I think the assumption made by the author is that the number of unique address bits is defined by the CPU designer at the start via requirements. Then the M can vary per implementation.
m is the width in bits of a memory address in your system, e.g. 32 for x86, 64 for x86-64. Block size on x86, for example, is 4K, so b=12. Block size more or less refers to the smallest chunk of data you can read from durable storage -- you read it into memory, work on that copy, then write it back at some later time. I believe tag bits are the upper t bits that are used to look up data cached locally very close to the CPU (not even in RAM). I'm not sure about the set lines part, although I can make plausible guesses that wouldn't be especially reliable.
Circular ... yes, but I think it's just stating that the two variables m and M must obey the equation. M would likely be a given or assumed quantity.
Example 1: If you wanted to use the formulas for a main memory size of M = 4GB (4,294,967,296 bytes), then m would be 32, since M = 2^32, i.e. m = log2(M). That is, it would take 32 bits to address the entire main memory.
Example 2: If your main memory size assumed were smaller, e.g. M = 16MB (16,777,216 bytes), then m would be 24, which is log2(16,777,216).
It seems you're confused by the math rather than the architectural stuff.
2^m ("2 to the m'th power") is 2 * 2... with m 2's. 2^1 = 2, 2^2 = 2 * 2 = 4, 2^3 = 2 * 2 * 2 = 8, and so on. Notably, if you have an m bit binary number, you can only represent 2^m different numbers. (is this obvious? If not, it might help to replace the 2's with 10's and think about decimal digits)
log2(x) ("logarithm base 2 of x") is the inverse function of 2^x. That is, log2(2^x) = x for all x. (This is a definition!)
You need log2(M) bits to represent M different numbers.
Note that if you start with M=2^m and take log2 of both sides, you get log2(M)=m. The table is just being very explicit.

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