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This is my homework:
I haven't tried to write the part of Natural Logarithm because I can't solve the part of Exponential.
This is the the approximations of Exponential in C using Taylor Series expansion I wrote.
However, it returns inf. What did I do wrong?
#include <stdio.h>
// Returns approximate value of e^x
// using sum of first n terms of Taylor Series
float exponential(int n, float x)
{
float sum = 1.0f; // initialize sum of series
for (int a = n; a >= 0; ++a ) {
while (x * sum / a < 0.00001) {
break;
}
sum = 1 + x * sum / a;
return sum;
}
}
int main()
{
int n = 0;
float x = 1.0f;
printf("e^x = %.5f", exponential(n, x));
return 0;
}
With How do I ask and answer homework questions? in mind, I will give you a few things to have a careful look at.
From comment by Spektre:
from a quick look you are dividing by zero in while (x * sum / a < 0.00001) during first iteration of for loop as a=n and you called the function with n=0 ... also your code does not match the expansion for e^x at all
Have a look at the for loop:
for (int a = n; a >= 0; ++a )
What is the first value of a? The second? The third?
Keep in mind that the values are determined by ++a.
When will that loop end? It is determined by a >= 0. When is that false?
What is this loop doing?
while (x * sum / a < 0.00001) {
break;
}
I suspect that you programmed "English to C", as "do the outer loop while ...", which is practically from the assignment.
But the loop does something else. Apart from risking the division by 0 mentioned above, if the condition is true it will stay true and cause an endless loop, which then however is immediatly canceled in the first iteration.
The head of your function float exponential(int n, float x) expects n as a parameter. In main you init it with 0. I suspect you are unclear about where that value n is supposed to come from. In fact it is unknown. It is more a result of the calculation than an input.
You are supposed to add up until something happens.
You do not actually ever need the value of n. This means that your for loop is meaningless. The inner loop (though currently pointless) is much closer to your goal.
I will leave it at this for now. Try to use this input.
Feel free to edit the code in your question with improvements.
(Normally that is not appreciated, but in case of homework dialog questions I am fine with it.)
Your current implementation attempt is quite a bit off. Therefore I will describe how you should approach calculating such a series as given in your quesiton.
Let's look at your first formula:
You need to sum up terms e(n) = x^n / n!
To check with your series: 1 == x^0 / 0! - x == x^1 / 1! - ...
To calculate these terms, you need a simple rule how to get from e(n) to e(n+1). Looking at the formula above we see that you can use this rule:
e(n+1) = e(n) * x / (n+1)
Then you need to create a loop around that and sum up all the bits & pieces.
You are clearly not supposed to calculate x^n/n! from scratch in each iteration.
Your condition to stop the loop is when you reach the limit of 1e-5. The limit is for the new e(n+1), not for the sum.
For the other formulas you can use the same approach to find a rule how to calculate the single terms.
You might need to multiply the value by -1 in each step or do something like *x*n/(n+1) instead of *x/(n+1) etc.
Maybe you need to add some check if the formula is supposed to converge. Then maybe print some error message. This part is not clear in your question.
As this is homework, I only point into the direction and leave the implementation work to you.
If you have problems with implementation, I suggest to create a new question.
#include <stdio.h>
int main() {
float power;
printf("Enter the power of e\n");
scanf("%f", &power);
float ans = 1;
float temp = 1;
int i = 1;
while ((temp * power) / i >= 0.00001) {
temp = (temp * power) / i;
ans = ans + temp;
i++;
}
printf("%.5f", ans);
return 0;
}
I think I solved the problem
But the part about Natural Log is not solved, I will try.
I am trying to make from f_rec (recursive function) to f_iter (iterative function) but I can't.
(My logic was to create a loop to calculate the results of f_rec(n-1).
int f_rec(int n)
{
if(n>=3)
return f_rec(n-1)+2*f_rec(n-2)+f_rec(n-3);
else
return 1;
}
int f_iter(int n)
{
}
I also think that my time complexity for the f_rec is 3^n , please correct me if I'm wrong.
Thank you
There are two options:
1) Use the discrete math lessons and derive the formula. The complexity (well if #Sasha mentioned it) will be O(1) for both memory and algorithm. No loops, no recursion, just the formula.
At first you need to find the characteristic polynomial and calculate its roots. Let's asssume that our roots are r1, r2, r3, r4. Then the n'th element is F(n) = A * r1^n + B * r2^n + C * r3^n + D * r4^n, where A, B, C, D are some unknown coefficients. You can find these coefficients using your initial conditions (F(n) = 1 for n <= 3).
I can explain it on russian if you need.
2) Use additional variables to store intermediate values. Just like #6052 have answered (he has answered really fast :) ).
You can always calculate the newest value from the last three. Just start calculating from the beginning and always save the last three:
int f_iter (int n) {
int last3[3] = {1,1,1}; // The three initial values. Use std::array if C++
for (int i = 3; i <= n; ++i) {
int new_value = last3[0] + 2 * last3[1] + last3[2];
last3[0] = last3[1];
last3[1] = last3[2];
last3[2] = new_value;
}
return last3[2];
}
This solution need O(1) memory and O(n) runtime. There might exist a formula that calculates this in O(1) (there most likely is), but I guess for the sake of demonstrating the iteration technique, this is the way to go.
Your solution has exponential runtime: Every additional level spawns three evaluations, so you end up with O(3^n) operations and stack-memory.
The following is the idea
int first=1,second=1,third=1; /* if n<=3 then the respective is the answer */
for(i=4;i<=n;i++)
{
int next=first+2*second+third;
first=second;
second=third;
third=next;
}
cout<<"The answer is "<<next<<endl;
Memory is O(1) and time is O(n).
EDIT
Your recursive function is indeed exponential in time , to keep it linear you can make use
of an array F[n], and use memoization. First initialize F[] as -1.
int f_rec(int n)
{
if(n>=3)
{
if(F[n]!=-1)return F[n];
F[n]=f_rec(n-1)+2*f_rec(n-2)+f_rec(n-3);
return F[n];
}
else
return 1;
}
Just keep three variables and roll them over
start with a, b and c all equal to 1
at each step new_a is a + 2*b + c
roll over: new_c is b, new_b is a
repeat the required number of steps
A bit of an overkill, but this can be further optimized by letting the what the variables represent change in an unfolded loop, combined with (link) Duff's device to enter the loop:
int f_iter(int n){
int a=1, b=1, c=1;
if(n < 3)
return(1);
switch(n%3){
for( ; n > 2; n -= 3){
case 2:
b = c + 2*a + b;
case 1:
a = b + 2*c + a;
case 0:
c = a + 2*b + c;
}
}
return c;
}
Hi I am new to C programming, I am just trying to replace part of my code with a function call but I don't know how to do it properly, please help.
I just want the line d = ... to be equivalent to the line e = ...
#include <stdio.h>
#include <math.h>
double dist(int i, int j, double v[100][2])
{
return sqrt( pow((v[j][0] - v[i][0]),2) + pow((v[j][1] - v[i][1]), 2) )
}
main()
{
double v[100][2], d, e;
v[1][0] = 0;
v[1][1] = 1;
v[2][0] = 1;
v[2][1] = 1;
d = sqrt( pow((v[1][0] - v[2][0]),2) + pow((v[1][1] - v[2][1]), 2) );
e = dist(1,2,v);
printf("\n%f\n",d);
printf("\n%f\n",e);
}
double dist(int i, int j, double (*v)[2])
{
return sqrt( pow((v[j][0] - v[i][0]),2) + pow((v[j][1] - v[i][1]), 2) );
}
d = dist(0,1,v)
Or dist(1,0,v)
Distance between point 0 and point 1 ... Order does not matter.
EDIT: What I have above is a function CALL, as requested. d= is equivalent to e= ... to write another function is quite the waste of code and more importantly, not a realization of what a function is used for. I stick by my answer.
If you wanted the same thing for different types, you can use a macro (not recommended for this case since a decent compiler will inline the function call to Cato's function) but just for educational purposes
#define dist(i,j,v) sqrt(pow((v[j][0]-v[i][0]),2)+pow((v[j][1]-v[i][1]),2))
Just keep in mind that sqrt returns a double, so if you want float or long double returns, you'll need sqrtf or sqrtl.
The advantage to using macros for mathematical "functions" is that they get expanded out into the code prior to compile such that constants can be evaluated into the computation and can sometimes reduce the entire calculation down to a much simpler computation or sometimes even a constant value.
Mike is correct on the mathematical properties, though precision may cause the 2 values to differ slightly (usually this difference is unwanted).
I don't know where I am doing wrong in trying to calculate prime factorizations using Pollard's rho algorithm.
#include<stdio.h>
#define f(x) x*x-1
int pollard( int );
int gcd( int, int);
int main( void ) {
int n;
scanf( "%d",&n );
pollard( n );
return 0;
}
int pollard( int n ) {
int i=1,x,y,k=2,d;
x = rand()%n;
y = x;
while(1) {
i++;
x = f( x ) % n;
d = gcd( y-x, n);
if(d!=1 && d!=n)
printf( "%d\n", d);
if(i == k) {
y = x;
k = 2 * k;
}
}
}
int gcd( int a, int b ) {
if( b == 0)
return a;
else
return gcd( b, a % b);
}
One immediate problem is, as Peter de Rivaz suspected the
#define f(x) x*x-1
Thus the line
x = f(x)%n;
becomes
x = x*x-1%n;
and the precedence of % is higher than that of -, hence the expression is implicitly parenthesised as
x = (x*x) - (1%n);
which is equivalent to x = x*x - 1; (I assume n > 1, anyway it's x = x*x - constant;) and if you start with a value x >= 2, you have overflow before you had a realistic chance of finding a factor:
2 -> 2*2-1 = 3 -> 3*3 - 1 = 8 -> 8*8 - 1 = 63 -> 3968 -> 15745023 -> overflow if int is 32 bits
That doesn't immediately make it impossible that gcd(y-x,n) is a factor, though. It just makes it likely that at a stage where theoretically, you would have found a factor, the overflow destroys the common factor that mathematically would exist - more likely than a common factor introduced by overflow.
Overflow of signed integers is undefined behaviour, so there are no guarantees how the programme behaves, but usually it behaves consistently so the iteration of f still produces a well-defined sequence for which the algorithm in principle works.
Another problem is that y-x will frequently be negative, and then the computed gcd can also be negative - often -1. In that case, you print -1.
And then, it is a not too rare occurrence that iterating f from a starting value doesn't detect a common factor because the cycles modulo both prime factors (for the example of n a product of two distinct primes) have equal length and are entered at the same time. You make no attempt at detecting such a case; whenever gcd(|y-x|, n) == n, any further work in that sequence is pointless, so you should break out of the loop when d == n.
Also, you never check whether n is a prime, in which case trying to find a factor is a futile undertaking from the start.
Furthermore, after fixing f(x) so that the % n applies to the complete result of f(x), you have the problem that x*x still overflows for relatively small x (with the standard signed 32-bit ints, for x >= 46341), so factoring larger n may fail due to overflow. At least, you should use unsigned long long for the computations, so that overflow is avoided for n < 2^32. However, factorising such small numbers is typically done more efficiently with trial division. Pollard's Rho method and other advanced factoring algorithms are meant for larger numbers, where trial division is no longer efficient or even feasible.
I'm just a novice at C++, and I am new to Stack Overflow, so some of what I have written is going to look sloppy, but this should get you going in the right direction. The program posted here should generally find and return one non-trivial factor of the number you enter at the prompt, or it will apologize if it cannot find such a factor.
I tested it with a few semiprime numbers, and it worked for me. For 371156167103, it finds 607619 without any detectable delay after I hit the enter key. I didn't check it with larger numbers than this. I used unsigned long long variables, but if possible, you should get and use a library that provides even larger integer types.
Editing to add, the single call to the method f for X and 2 such calls for Y is intentional and is in accordance with the way the algorithm works. I thought to nest the call for Y inside another such call to keep it on one line, but I decided to do it this way so it's easier to follow.
#include "stdafx.h"
#include <stdio.h>
#include <iostream>
typedef unsigned long long ULL;
ULL pollard(ULL numberToFactor);
ULL gcd(ULL differenceBetweenCongruentFunctions, ULL numberToFactor);
ULL f(ULL x, ULL numberToFactor);
int main(void)
{
ULL factor;
ULL n;
std::cout<<"Enter the number for which you want a prime factor: ";
std::cin>>n;
factor = pollard(n);
if (factor == 0) std::cout<<"No factor found. Your number may be prime, but it is not certain.\n\n";
else std::cout<<"One factor is: "<<factor<<"\n\n";
}
ULL pollard(ULL n)
{
ULL x = 2ULL;
ULL y = 2ULL;
ULL d = 1ULL;
while(d==1||d==n)
{
x = f(x,n);
y = f(y,n);
y = f(y,n);
if (y>x)
{
d = gcd(y-x, n);
}
else
{
d = gcd(x-y, n);
}
}
return d;
}
ULL gcd(ULL a, ULL b)
{
if (a==b||a==0)
return 0; // If x==y or if the absolute value of (x-y) == the number to be factored, then we have failed to find
// a factor. I think this is not proof of primality, so the process could be repeated with a new function.
// For example, by replacing x*x+1 with x*x+2, and so on. If many such functions fail, primality is likely.
ULL currentGCD = 1;
while (currentGCD!=0) // This while loop is based on Euclid's algorithm
{
currentGCD = b % a;
b=a;
a=currentGCD;
}
return b;
}
ULL f(ULL x, ULL n)
{
return (x * x + 1) % n;
}
Sorry for the long delay getting back to this. As I mentioned in my first answer, I am a novice at C++, which will be evident in my excessive use of global variables, excessive use of BigIntegers and BigUnsigned where other types might be better, lack of error checking, and other programming habits on display which a more skilled person might not exhibit. That being said, let me explain what I did, then will post the code.
I am doing this in a second answer because the first answer is useful as a very simple demo of how a Pollard's Rho algorithm is to implement once you understand what it does. And what it does is to first take 2 variables, call them x and y, assign them the starting values of 2. Then it runs x through a function, usually (x^2+1)%n, where n is the number you want to factor. And it runs y through the same function twice each cycle. Then the difference between x and y is calculated, and finally the greatest common divisor is found for this difference and n. If that number is 1, then you run x and y through the function again.
Continue this process until the GCD is not 1 or until x and y are equal again. If the GCD is found which is not 1, then that GCD is a non-trivial factor of n. If x and y become equal, then the (x^2+1)%n function has failed. In that case, you should try again with another function, maybe (x^2+2)%n, and so on.
Here is an example. Take 35, for which we know the prime factors are 5 and 7. I'll walk through Pollard Rho and show you how it finds a non-trivial factor.
Cycle #1: X starts at 2. Then using the function (x^2+1)%n, (2^2+1)%35, we get 5 for x. Y starts at 2 also, and after one run through the function, it also has a value of 5. But y always goes through the function twice, so the second run is (5^2+1)%35, or 26. The difference between x and y is 21. The GCD of 21 (the difference) and 35 (n) is 7. We have already found a prime factor of 35! Note that the GCD for any 2 numbers, even extremely large exponents, can be found very quickly by formula using Euclid's algorithm, and that's what the program I will post here does.
On the subject of the GCD function, I am using one library I downloaded for this program, a library that allows me to use BigIntegers and BigUnsigned. That library also has a GCD function built in, and I could have used it. But I decided to stay with the hand-written GCD function for instructional purposes. If you want to improve the program's execution time, it might be a good idea to use the library's GCD function because there are faster methods than Euclid, and the library may be written to use one of those faster methods.
Another side note. The .Net 4.5 library supports the use of BigIntegers and BigUnsigned also. I decided not to use that for this program because I wanted to write the whole thing in C++, not C++/CLI. You could get better performance from the .Net library, or you might not. I don't know, but I wanted to share that that is also an option.
I am jumping around a bit here, so let me start now by explaining in broad strokes what the program does, and lastly I will explain how to set it up on your computer if you use Visual Studio 11 (also called Visual Studio 2012).
The program allocates 3 arrays for storing the factors of any number you give it to process. These arrays are 1000 elements wide, which is excessive, maybe, but it ensures any number with 1000 prime factors or less will fit.
When you enter the number at the prompt, it assumes the number is composite and puts it in the first element of the compositeFactors array. Then it goes through some admittedly inefficient while loops, which use Miller-Rabin to check if the number is composite. Note this test can either say a number is composite with 100% confidence, or it can say the number is prime with extremely high (but not 100%) confidence. The confidence is adjustable by a variable confidenceFactor in the program. The program will make one check for every value between 2 and confidenceFactor, inclusive, so one less total check than the value of confidenceFactor itself.
The setting I have for confidenceFactor is 101, which does 100 checks. If it says a number is prime, the odds that it is really composite are 1 in 4^100, or the same as the odds of correctly calling the flip of a fair coin 200 consecutive times. In short, if it says the number is prime, it probably is, but the confidenceFactor number can be increased to get greater confidence at the cost of speed.
Here might be as good a place as any to mention that, while Pollard's Rho algorithm can be pretty effective factoring smaller numbers of type long long, the Miller-Rabin test to see if a number is composite would be more or less useless without the BigInteger and BigUnsigned types. A BigInteger library is pretty much a requirement to be able to reliably factor large numbers all the way to their prime factors like this.
When Miller Rabin says the factor is composite, it is factored, the factor stored in a temp array, and the original factor in the composites array divided by the same factor. When numbers are identified as likely prime, they are moved into the prime factors array and output to screen. This process continues until there are no composite factors left. The factors tend to be found in ascending order, but this is coincidental. The program makes no effort to list them in ascending order, but only lists them as they are found.
Note that I could not find any function (x^2+c)%n which will factor the number 4, no matter what value I gave c. Pollard Rho seems to have a very hard time with all perfect squares, but 4 is the only composite number I found which is totally impervious to it using functions in the format described. Therefore I added a check for an n of 4 inside the pollard method, returning 2 instantly if so.
So to set this program up, here is what you should do. Go to https://mattmccutchen.net/bigint/ and download bigint-2010.04.30.zip. Unzip this and put all of the .hh files and all of the C++ source files in your ~\Program Files\Microsoft Visual Studio 11.0\VC\include directory, excluding the Sample and C++ Testsuite source files. Then in Visual Studio, create an empty project. In the solution explorer, right click on the resource files folder and select Add...existing item. Add all of the C++ source files in the directory I just mentioned. Then also in solution expolorer, right click the Source Files folder and add a new item, select C++ file, name it, and paste the below source code into it, and it should work for you.
Not to flatter overly much, but there are folks here on Stack Overflow who know a great deal more about C++ than I do, and if they modify my code below to make it better, that's fantastic. But even if not, the code is functional as-is, and it should help illustrate the principles involved in programmatically finding prime factors of medium sized numbers. It will not threaten the general number field sieve, but it can factor numbers with 12 - 14 digit prime factors in a reasonably short time, even on an old Core2 Duo computer like the one I am using.
The code follows. Good luck.
#include <string>
#include <stdio.h>
#include <iostream>
#include "BigIntegerLibrary.hh"
typedef BigInteger BI;
typedef BigUnsigned BU;
using std::string;
using std::cin;
using std::cout;
BU pollard(BU numberToFactor);
BU gcda(BU differenceBetweenCongruentFunctions, BU numberToFactor);
BU f(BU x, BU numberToFactor, int increment);
void initializeArrays();
BU getNumberToFactor ();
void factorComposites();
bool testForComposite (BU num);
BU primeFactors[1000];
BU compositeFactors[1000];
BU tempFactors [1000];
int primeIndex;
int compositeIndex;
int tempIndex;
int numberOfCompositeFactors;
bool allJTestsShowComposite;
int main ()
{
while(1)
{
primeIndex=0;
compositeIndex=0;
tempIndex=0;
initializeArrays();
compositeFactors[0] = getNumberToFactor();
cout<<"\n\n";
if (compositeFactors[0] == 0) return 0;
numberOfCompositeFactors = 1;
factorComposites();
}
}
void initializeArrays()
{
for (int i = 0; i<1000;i++)
{
primeFactors[i] = 0;
compositeFactors[i]=0;
tempFactors[i]=0;
}
}
BU getNumberToFactor ()
{
std::string s;
std::cout<<"Enter the number for which you want a prime factor, or 0 to quit: ";
std::cin>>s;
return stringToBigUnsigned(s);
}
void factorComposites()
{
while (numberOfCompositeFactors!=0)
{
compositeIndex = 0;
tempIndex = 0;
// This while loop finds non-zero values in compositeFactors.
// If they are composite, it factors them and puts one factor in tempFactors,
// then divides the element in compositeFactors by the same amount.
// If the element is prime, it moves it into tempFactors (zeros the element in compositeFactors)
while (compositeIndex < 1000)
{
if(compositeFactors[compositeIndex] == 0)
{
compositeIndex++;
continue;
}
if(testForComposite(compositeFactors[compositeIndex]) == false)
{
tempFactors[tempIndex] = compositeFactors[compositeIndex];
compositeFactors[compositeIndex] = 0;
tempIndex++;
compositeIndex++;
}
else
{
tempFactors[tempIndex] = pollard (compositeFactors[compositeIndex]);
compositeFactors[compositeIndex] /= tempFactors[tempIndex];
tempIndex++;
compositeIndex++;
}
}
compositeIndex = 0;
// This while loop moves all remaining non-zero values from compositeFactors into tempFactors
// When it is done, compositeFactors should be all 0 value elements
while (compositeIndex < 1000)
{
if (compositeFactors[compositeIndex] != 0)
{
tempFactors[tempIndex] = compositeFactors[compositeIndex];
compositeFactors[compositeIndex] = 0;
tempIndex++;
compositeIndex++;
}
else compositeIndex++;
}
compositeIndex = 0;
tempIndex = 0;
// This while loop checks all non-zero elements in tempIndex.
// Those that are prime are shown on screen and moved to primeFactors
// Those that are composite are moved to compositeFactors
// When this is done, all elements in tempFactors should be 0
while (tempIndex<1000)
{
if(tempFactors[tempIndex] == 0)
{
tempIndex++;
continue;
}
if(testForComposite(tempFactors[tempIndex]) == false)
{
primeFactors[primeIndex] = tempFactors[tempIndex];
cout<<primeFactors[primeIndex]<<"\n";
tempFactors[tempIndex]=0;
primeIndex++;
tempIndex++;
}
else
{
compositeFactors[compositeIndex] = tempFactors[tempIndex];
tempFactors[tempIndex]=0;
compositeIndex++;
tempIndex++;
}
}
compositeIndex=0;
numberOfCompositeFactors=0;
// This while loop just checks to be sure there are still one or more composite factors.
// As long as there are, the outer while loop will repeat
while(compositeIndex<1000)
{
if(compositeFactors[compositeIndex]!=0) numberOfCompositeFactors++;
compositeIndex ++;
}
}
return;
}
// The following method uses the Miller-Rabin primality test to prove with 100% confidence a given number is composite,
// or to establish with a high level of confidence -- but not 100% -- that it is prime
bool testForComposite (BU num)
{
BU confidenceFactor = 101;
if (confidenceFactor >= num) confidenceFactor = num-1;
BU a,d,s, nMinusOne;
nMinusOne=num-1;
d=nMinusOne;
s=0;
while(modexp(d,1,2)==0)
{
d /= 2;
s++;
}
allJTestsShowComposite = true; // assume composite here until we can prove otherwise
for (BI i = 2 ; i<=confidenceFactor;i++)
{
if (modexp(i,d,num) == 1)
continue; // if this modulus is 1, then we cannot prove that num is composite with this value of i, so continue
if (modexp(i,d,num) == nMinusOne)
{
allJTestsShowComposite = false;
continue;
}
BU exponent(1);
for (BU j(0); j.toInt()<=s.toInt()-1;j++)
{
exponent *= 2;
if (modexp(i,exponent*d,num) == nMinusOne)
{
// if the modulus is not right for even a single j, then break and increment i.
allJTestsShowComposite = false;
continue;
}
}
if (allJTestsShowComposite == true) return true; // proven composite with 100% certainty, no need to continue testing
}
return false;
/* not proven composite in any test, so assume prime with a possibility of error =
(1/4)^(number of different values of i tested). This will be equal to the value of the
confidenceFactor variable, and the "witnesses" to the primality of the number being tested will be all integers from
2 through the value of confidenceFactor.
Note that this makes this primality test cryptographically less secure than it could be. It is theoretically possible,
if difficult, for a malicious party to pass a known composite number for which all of the lowest n integers fail to
detect that it is composite. A safer way is to generate random integers in the outer "for" loop and use those in place of
the variable i. Better still if those random numbers are checked to ensure no duplicates are generated.
*/
}
BU pollard(BU n)
{
if (n == 4) return 2;
BU x = 2;
BU y = 2;
BU d = 1;
int increment = 1;
while(d==1||d==n||d==0)
{
x = f(x,n, increment);
y = f(y,n, increment);
y = f(y,n, increment);
if (y>x)
{
d = gcda(y-x, n);
}
else
{
d = gcda(x-y, n);
}
if (d==0)
{
x = 2;
y = 2;
d = 1;
increment++; // This changes the pseudorandom function we use to increment x and y
}
}
return d;
}
BU gcda(BU a, BU b)
{
if (a==b||a==0)
return 0; // If x==y or if the absolute value of (x-y) == the number to be factored, then we have failed to find
// a factor. I think this is not proof of primality, so the process could be repeated with a new function.
// For example, by replacing x*x+1 with x*x+2, and so on. If many such functions fail, primality is likely.
BU currentGCD = 1;
while (currentGCD!=0) // This while loop is based on Euclid's algorithm
{
currentGCD = b % a;
b=a;
a=currentGCD;
}
return b;
}
BU f(BU x, BU n, int increment)
{
return (x * x + increment) % n;
}
As far as I can see, Pollard Rho normally uses f(x) as (x*x+1) (e.g. in these lecture notes ).
Your choice of x*x-1 appears not as good as it often seems to get stuck in a loop:
x=0
f(x)=-1
f(f(x))=0
This programming problem is #85 from a page of Microsoft interview questions. The complete problem description and my solution are posted below, but I wanted to ask my question first.
The rules say that you can loop for a fixed number of times. That is, if 'x' is a variable, you can loop over a block of code based on the value of 'x' at the time that you enter the loop. If 'x' changes during the loop, that won't change how many times you loop. Also, that is the only way to loop. You can't, for instance, loop until some condition is met.
In my solution to the problem, I have a loop which will be set to execute zero or more times. The problem is, in reality, it only ever executes 0 times or 1 time because the only statement in my loop is a return statement. So if we enter the loop, it only has a chance to run once. I am using this tactic instead of using an if-else block, because logical comparisons and if statements are not allowed. The rules don't explicitly say that you can't do this, but I am wondering if you would consider my solution invalid. I couldn't really figure out another way to do it.
So here are my questions:
Do you think my solution is invalid?
If so, did you think of another way to solve the problem?
Problem description:
85) You have an abstract computer, so just forget everything you know
about computers, this one only does what I'm about to tell you it
does. You can use as many variables as you need, there are no negative
numbers, all numbers are integers. You do not know the size of the
integers, they could be infinitely large, so you can't count on
truncating at any point. There are NO comparisons allowed, no if
statements or anything like that. There are only four operations you
can do on a variable.
You can set a variable to 0.
You can set a variable = another variable.
You can increment a variable (only by 1), and it's a post increment.
You can loop. So, if you were to say loop(v1) and v1 = 10, your loop would execute 10 times, but the value in v1 wouldn't change so
the first line in the loop can change value of v1 without changing the
number of times you loop.
You need to do 3 things.
Write a function that decrements by 1.
Write a function that subtracts one variable from another.
Write a function that divides one variable by another.
See if you can implement all 3 using at most 4 variables. Meaning, you're not making function calls now, you're making macros. And at
most you can have 4 variables. The restriction really only applies to
divide, the other 2 are easy to do with 4 vars or less. Division on
the other hand is dependent on the other 2 functions, so, if subtract
requires 3 variables, then divide only has 1 variable left unchanged
after a call to subtract. Basically, just make your function calls to
decrement and subtract so you pass your vars in by reference, and you
can't declare any new variables in a function, what you pass in is all
it gets.
My psuedocode solution (loop(x) means loop through this block of code x times):
// returns number - 1
int decrement(int number)
{
int previous = 0;
int i = 0;
loop(number)
{
previous = i;
i++;
}
return previous;
}
// returns number1 - number2
int subtract(int number1, int number2)
{
loop(number2)
{
number1= decrement(number1);
}
return number1;
}
//returns numerator/denominator
divide(int numerator, int denominator)
{
loop(subtract(numerator+1, denominator))
{
return (1 + divide(subtract(numerator, denominator), denominator));
}
return 0;
}
Here are C# methods that you can build and run. I had to make an artificial way for me to
satisfy the looping rules.
public int decrement(int num)
{
int previous = 0;
int LOOP = 0;
while (LOOP < num)
{
previous = LOOP;
LOOP++;
}
return previous;
}
public int subtract(int number1, int number2)
{
int LOOP = 0;
while (LOOP < number2)
{
number1 = decrement(number1);
LOOP++;
}
return number1;
}
public int divide(int numerator, int denominator)
{
int LOOP = 0;
while (LOOP < subtract(numerator+1, denominator))
{
return (1 + divide(subtract(numerator, denominator), denominator));
}
return 0;
}
Ok so the reason I think your answer might be invalid is because of how you use return. In fact I think just using the return is too much of an assumption. in a few places you use the return value of a function call as an extra variable. Now if the return statement is ok, then your answer is valid. The reason i think its not valid is because the problem hints at the fact that you need to think of these as macros, not function calls. Everything should be done by reference, you should change the variables and the return values are how you left those variables. Here is my solution:
int x, y, v, z;
//This function leaves x decremented by one and v equal to x
def decrement(x,v):
v=0;
loop(x):
x=v;
v++;
//this function leaves x decremented by y (x-y) and v equal to x
def subtract(x,y,v):
loop(y):
decrement(x,v);
//this function leaves x and z as the result of x divided by y, leaves y as is, and v as 0
//input of v and z dont matter, x should be greater than or equal to y or be 0, y should be greater than 0.
def divide(x,y,v,z):
z=0;
loop(x):
//these loops give us z+1 if x is >0 or leave z alone otherwise
loop(x):
z++;
decrement(x,v);
loop(x):
decrement(z,v)
//restore x
x++;
//reduce x by y until, when x is zero z will no longer increment
subtract(x,y,v);
//leave x as z so x is the result
x=z;