My try
double sum_squares_from(double x, double n){
return n<=0 ? 0 : x*x + sum_squares_from((x+n-1)*(x+n-1),n-1);
}
Instead of using loops my professor wants us to write functions like this...
What the exercise asks for is a function sum_squares_from() with double x being the starting number and n is the number of number. For example if you do x = 2 and n = 4 you get 2*2+3*3+4*4+5*5. It returns zero if n == 0.
My thinking was that in my example what I have is basically x*x+(x+1)(x+1)+(x+1+1)(x+1+1)+(x+1+1+1)(x+1+1+1) = (x+0)(x+0)+(x+1)(x+1)+(x+2)(x+2)+(x+3)(x+3) = (x+n-1)^2 repeated n times where n gets decremented every time by one until it becomes zero and then you sum everything.
Did I do it right?
(if my professor seems a bit demanding... he somehow does this sort of thing all in his head without auxiliary calculations. Scary guy)
It's not recursive, but it's one line:
int
sum_squares(int x, int n) {
return ((x + n - 1) * (x + n) * (2 * (x + n - 1) + 1) / 6) - ((x - 1) * x * (2 * (x - 1) + 1) / 6);
}
Sum of squares (of integers) has a closed-form solution for 1 .. n. This code calculates the sum of squares from 1 .. (x+n) and then subtracts the sum of squares from 1 .. (x-1).
The original version of this answer used ASCII art.
So,
∑i:0..n i = n(n+1)(½)
∑i:0..n i2 = n(n+1)(2n+1)(⅙)
We note that,
∑i:0..n (x+i)2
= ∑i:0...n x2 + 2xi + i2
= (n+1)x2 + (2x)∑i:0..n i + ∑i:0..n i2
= (n+1)x2 + n(n+1)x + n(n+1)(2n+1)(⅙)
Thus, your sum has the closed form:
double sum_squares_from(double x, int n) {
return ((n-- > 0)
? (n + 1) * x * x
+ x * n * (n + 1)
+ n * (n + 1) * (2 * n + 1) / 6.
: 0);
}
If I apply some obfuscation, the one-line version becomes:
double sum_squares_from(double x, int n) {
return (n-->0)?(n+1)*(x*x+x*n+n*(2*n+1)/6.):0;
}
If the task is to implement the summation in a loop, use tail recursion. Tail recursion can be mechanically replaced with a loop, and many compilers implement this optimization.
static double sum_squares_from_loop(double x, int n, double s) {
return (n <= 0) ? s : sum_squares_from_loop(x+1, n-1, s+x*x);
}
double sum_squares_from(double x, int n) {
return sum_squares_from_loop(x, n, 0);
}
As an illustration, if you observe the generated assembly in GCC at a sufficient optimization level (-Os, -O2, or -O3), you will notice that the recursive call is eliminated (and sum_squares_from_loop is inlined to boot).
Try it online!
As mentioned in my original comment, n should not be type double, but instead be type int to avoid floating point comparison problems with n <= 0. Making the change and simplifying the multiplication and recursive call, you do:
double sum_squares_from(double x, int n)
{
return n <= 0 ? 0 : x * x + sum_squares_from (x + 1, n - 1);
}
If you think about starting with x * x and increasing x by 1, n times, then the simple x * x + sum_squares_from (x + 1, n - 1) is quite easy to understand.
Maybe this?
double sum_squares_from(double x, double n) {
return n <= 0 ? 0 : (x + n - 1) * (x + n - 1) + sum_squares_from(x, n - 1);
}
Is there any way to round systemGuess up. In this case the outcome of systemGuess is 5.5 I want it to be 6 how do I do this?
See code below:
int main(void){
int systemGuess = 0;
stystemGuess = (10 - 1)/2 + 1;
printf(" %d ", stystemmGuess);
}
Use floating point division and ceil:
stystemGuess = ceil((10 - 1)/2.0) + 1;
If you want to round 0.4 down, use round instead.
OP wants to perform an integer division with the result rounded-up.
// If the quotient fraction > 0, return next larger number.
unsigned udiv_ceiling(unsigned n, unsigned d) {
return (n + d - 1)/d;
}
// If the quotient fraction >= 0.5, return next larger number.
unsigned udiv_nearest_ties_up(unsigned n, unsigned d) {
return (n + d/2)/d;
}
stystemGuess = udiv_ceiling(10 - 1, 2) + 1;
// or
stystemGuess = udiv_nearest_ties_up(10 - 1, 2) + 1;
Additional code needed to handle negative numbers and in corner cases, protect against n + d - 1 overflow.
You can use
systemGuess = (10 - 1)/2.0 + 1 + 0.5;
The problem is that you do integer calculation.
So e.g. 9/2 is 4. If you use 9/2.0 you have floating point division, which gives you 4.5. Adding 0.5 in the end gives you 6.0 instead of 5.5, so when storing it in systemGuess, you get 6 instead of 5.
Integer division in C truncates toward 0, so if you do the math on the other side of 0 (i.e., on negative numbers), it will "round up". You might do this by subtracting an amount from the dividend and adding half that amount back to the result:
int main(void)
{
int systemGuess = 0;
//systemGuess = (10 - 1)/2 + 1;
systemGuess = (10 - 1 - 20)/2 + 1 + 10;
printf(" %d ", systemGuess);
}
Probably in your real program there is a more elegant way to make this happen.
Here you go:
#include <stdio.h>
#include <stdlib.h>
int divide(int x, int y);
int main(void){
int systemGuess = 0;
int x = 10-1;
int y = 2;
systemGuess = divide(x,y) + 1;
printf(" %d ", systemGuess);
}
int divide(int x, int y) {
int a = (x -1)/y +1;
return a;
}
I want to check if the / operator has no remainder or not:
int x = 0;
if (x = 16 / 4), if there is no remainder:
then x = x - 1;
if (x = 16 / 5), if remainder is not zero:
then x = x + 1;
How to check if there are remainder in C? and
How to implement it?
Frist, you need % remainder operator:
if (x = 16 % 4){
printf("remainder in X");
}
Note: it will not work with float/double, in that case you need to use fmod (double numer, double denom);.
Second, to implement it as you wish:
if (x = 16 / 4), if there is no remainder, x = x - 1;
If (x = 16 / 5), then x = x + 1;
Useing , comma operator, you can do it in single step as follows (read comments):
int main(){
int x = 0, // Quotient.
n = 16, // Numerator
d = 4; // Denominator
// Remainder is not saved
if(x = n / d, n % d) // == x = n / d; if(n % d)
printf("Remainder not zero, x + 1 = %d", (x + 1));
else
printf("Remainder is zero, x - 1 = %d", (x - 1));
return 1;
}
Check working codes #codepade: first, second, third.
Notice in if-condition I am using Comma Operator: ,, to understand , operator read: comma operator with an example.
If you want to find the remainder of an integer division then you can use the modulus(%):
if( 16 % 4 == 0 )
{
x = x - 1 ;
}
else
{
x = x +1 ;
}
use the % operator to find the remainder of a division
if (number % divisor == 0)
{
//code for perfect divisor
}
else
{
//the number doesn't divide perfectly by divisor
}
use modulous operator for this purpose.
if(x%y == 0) then there is no remainder.
In division operation, if the result is floating point, then only integer part will be returned and decimal part will be discarded.
you can use Modulous operator which deals with remainder.
The modulus operator (represented by the % symbol in C) computes the remainder. So:
x = 16 % 4;
x will be 0.
X = 16 % 5;
x will be 1
What is the most efficient way given to raise an integer to the power of another integer in C?
// 2^3
pow(2,3) == 8
// 5^5
pow(5,5) == 3125
Exponentiation by squaring.
int ipow(int base, int exp)
{
int result = 1;
for (;;)
{
if (exp & 1)
result *= base;
exp >>= 1;
if (!exp)
break;
base *= base;
}
return result;
}
This is the standard method for doing modular exponentiation for huge numbers in asymmetric cryptography.
Note that exponentiation by squaring is not the most optimal method. It is probably the best you can do as a general method that works for all exponent values, but for a specific exponent value there might be a better sequence that needs fewer multiplications.
For instance, if you want to compute x^15, the method of exponentiation by squaring will give you:
x^15 = (x^7)*(x^7)*x
x^7 = (x^3)*(x^3)*x
x^3 = x*x*x
This is a total of 6 multiplications.
It turns out this can be done using "just" 5 multiplications via addition-chain exponentiation.
n*n = n^2
n^2*n = n^3
n^3*n^3 = n^6
n^6*n^6 = n^12
n^12*n^3 = n^15
There are no efficient algorithms to find this optimal sequence of multiplications. From Wikipedia:
The problem of finding the shortest addition chain cannot be solved by dynamic programming, because it does not satisfy the assumption of optimal substructure. That is, it is not sufficient to decompose the power into smaller powers, each of which is computed minimally, since the addition chains for the smaller powers may be related (to share computations). For example, in the shortest addition chain for a¹⁵ above, the subproblem for a⁶ must be computed as (a³)² since a³ is re-used (as opposed to, say, a⁶ = a²(a²)², which also requires three multiplies).
If you need to raise 2 to a power. The fastest way to do so is to bit shift by the power.
2 ** 3 == 1 << 3 == 8
2 ** 30 == 1 << 30 == 1073741824 (A Gigabyte)
Here is the method in Java
private int ipow(int base, int exp)
{
int result = 1;
while (exp != 0)
{
if ((exp & 1) == 1)
result *= base;
exp >>= 1;
base *= base;
}
return result;
}
An extremely specialized case is, when you need say 2^(-x to the y), where x, is of course is negative and y is too large to do shifting on an int. You can still do 2^x in constant time by screwing with a float.
struct IeeeFloat
{
unsigned int base : 23;
unsigned int exponent : 8;
unsigned int signBit : 1;
};
union IeeeFloatUnion
{
IeeeFloat brokenOut;
float f;
};
inline float twoToThe(char exponent)
{
// notice how the range checking is already done on the exponent var
static IeeeFloatUnion u;
u.f = 2.0;
// Change the exponent part of the float
u.brokenOut.exponent += (exponent - 1);
return (u.f);
}
You can get more powers of 2 by using a double as the base type.
(Thanks a lot to commenters for helping to square this post away).
There's also the possibility that learning more about IEEE floats, other special cases of exponentiation might present themselves.
power() function to work for Integers Only
int power(int base, unsigned int exp){
if (exp == 0)
return 1;
int temp = power(base, exp/2);
if (exp%2 == 0)
return temp*temp;
else
return base*temp*temp;
}
Complexity = O(log(exp))
power() function to work for negative exp and float base.
float power(float base, int exp) {
if( exp == 0)
return 1;
float temp = power(base, exp/2);
if (exp%2 == 0)
return temp*temp;
else {
if(exp > 0)
return base*temp*temp;
else
return (temp*temp)/base; //negative exponent computation
}
}
Complexity = O(log(exp))
If you want to get the value of an integer for 2 raised to the power of something it is always better to use the shift option:
pow(2,5) can be replaced by 1<<5
This is much more efficient.
int pow( int base, int exponent)
{ // Does not work for negative exponents. (But that would be leaving the range of int)
if (exponent == 0) return 1; // base case;
int temp = pow(base, exponent/2);
if (exponent % 2 == 0)
return temp * temp;
else
return (base * temp * temp);
}
Just as a follow up to comments on the efficiency of exponentiation by squaring.
The advantage of that approach is that it runs in log(n) time. For example, if you were going to calculate something huge, such as x^1048575 (2^20 - 1), you only have to go thru the loop 20 times, not 1 million+ using the naive approach.
Also, in terms of code complexity, it is simpler than trying to find the most optimal sequence of multiplications, a la Pramod's suggestion.
Edit:
I guess I should clarify before someone tags me for the potential for overflow. This approach assumes that you have some sort of hugeint library.
Late to the party:
Below is a solution that also deals with y < 0 as best as it can.
It uses a result of intmax_t for maximum range. There is no provision for answers that do not fit in intmax_t.
powjii(0, 0) --> 1 which is a common result for this case.
pow(0,negative), another undefined result, returns INTMAX_MAX
intmax_t powjii(int x, int y) {
if (y < 0) {
switch (x) {
case 0:
return INTMAX_MAX;
case 1:
return 1;
case -1:
return y % 2 ? -1 : 1;
}
return 0;
}
intmax_t z = 1;
intmax_t base = x;
for (;;) {
if (y % 2) {
z *= base;
}
y /= 2;
if (y == 0) {
break;
}
base *= base;
}
return z;
}
This code uses a forever loop for(;;) to avoid the final base *= base common in other looped solutions. That multiplication is 1) not needed and 2) could be int*int overflow which is UB.
more generic solution considering negative exponenet
private static int pow(int base, int exponent) {
int result = 1;
if (exponent == 0)
return result; // base case;
if (exponent < 0)
return 1 / pow(base, -exponent);
int temp = pow(base, exponent / 2);
if (exponent % 2 == 0)
return temp * temp;
else
return (base * temp * temp);
}
The O(log N) solution in Swift...
// Time complexity is O(log N)
func power(_ base: Int, _ exp: Int) -> Int {
// 1. If the exponent is 1 then return the number (e.g a^1 == a)
//Time complexity O(1)
if exp == 1 {
return base
}
// 2. Calculate the value of the number raised to half of the exponent. This will be used to calculate the final answer by squaring the result (e.g a^2n == (a^n)^2 == a^n * a^n). The idea is that we can do half the amount of work by obtaining a^n and multiplying the result by itself to get a^2n
//Time complexity O(log N)
let tempVal = power(base, exp/2)
// 3. If the exponent was odd then decompose the result in such a way that it allows you to divide the exponent in two (e.g. a^(2n+1) == a^1 * a^2n == a^1 * a^n * a^n). If the eponent is even then the result must be the base raised to half the exponent squared (e.g. a^2n == a^n * a^n = (a^n)^2).
//Time complexity O(1)
return (exp % 2 == 1 ? base : 1) * tempVal * tempVal
}
int pow(int const x, unsigned const e) noexcept
{
return !e ? 1 : 1 == e ? x : (e % 2 ? x : 1) * pow(x * x, e / 2);
//return !e ? 1 : 1 == e ? x : (((x ^ 1) & -(e % 2)) ^ 1) * pow(x * x, e / 2);
}
Yes, it's recursive, but a good optimizing compiler will optimize recursion away.
One more implementation (in Java). May not be most efficient solution but # of iterations is same as that of Exponential solution.
public static long pow(long base, long exp){
if(exp ==0){
return 1;
}
if(exp ==1){
return base;
}
if(exp % 2 == 0){
long half = pow(base, exp/2);
return half * half;
}else{
long half = pow(base, (exp -1)/2);
return base * half * half;
}
}
I use recursive, if the exp is even,5^10 =25^5.
int pow(float base,float exp){
if (exp==0)return 1;
else if(exp>0&&exp%2==0){
return pow(base*base,exp/2);
}else if (exp>0&&exp%2!=0){
return base*pow(base,exp-1);
}
}
In addition to the answer by Elias, which causes Undefined Behaviour when implemented with signed integers, and incorrect values for high input when implemented with unsigned integers,
here is a modified version of the Exponentiation by Squaring that also works with signed integer types, and doesn't give incorrect values:
#include <stdint.h>
#define SQRT_INT64_MAX (INT64_C(0xB504F333))
int64_t alx_pow_s64 (int64_t base, uint8_t exp)
{
int_fast64_t base_;
int_fast64_t result;
base_ = base;
if (base_ == 1)
return 1;
if (!exp)
return 1;
if (!base_)
return 0;
result = 1;
if (exp & 1)
result *= base_;
exp >>= 1;
while (exp) {
if (base_ > SQRT_INT64_MAX)
return 0;
base_ *= base_;
if (exp & 1)
result *= base_;
exp >>= 1;
}
return result;
}
Considerations for this function:
(1 ** N) == 1
(N ** 0) == 1
(0 ** 0) == 1
(0 ** N) == 0
If any overflow or wrapping is going to take place, return 0;
I used int64_t, but any width (signed or unsigned) can be used with little modification. However, if you need to use a non-fixed-width integer type, you will need to change SQRT_INT64_MAX by (int)sqrt(INT_MAX) (in the case of using int) or something similar, which should be optimized, but it is uglier, and not a C constant expression. Also casting the result of sqrt() to an int is not very good because of floating point precission in case of a perfect square, but as I don't know of any implementation where INT_MAX -or the maximum of any type- is a perfect square, you can live with that.
I have implemented algorithm that memorizes all computed powers and then uses them when need. So for example x^13 is equal to (x^2)^2^2 * x^2^2 * x where x^2^2 it taken from the table instead of computing it once again. This is basically implementation of #Pramod answer (but in C#).
The number of multiplication needed is Ceil(Log n)
public static int Power(int base, int exp)
{
int tab[] = new int[exp + 1];
tab[0] = 1;
tab[1] = base;
return Power(base, exp, tab);
}
public static int Power(int base, int exp, int tab[])
{
if(exp == 0) return 1;
if(exp == 1) return base;
int i = 1;
while(i < exp/2)
{
if(tab[2 * i] <= 0)
tab[2 * i] = tab[i] * tab[i];
i = i << 1;
}
if(exp <= i)
return tab[i];
else return tab[i] * Power(base, exp - i, tab);
}
Here is a O(1) algorithm for calculating x ** y, inspired by this comment. It works for 32-bit signed int.
For small values of y, it uses exponentiation by squaring. For large values of y, there are only a few values of x where the result doesn't overflow. This implementation uses a lookup table to read the result without calculating.
On overflow, the C standard permits any behavior, including crash. However, I decided to do bound-checking on LUT indices to prevent memory access violation, which could be surprising and undesirable.
Pseudo-code:
If `x` is between -2 and 2, use special-case formulas.
Otherwise, if `y` is between 0 and 8, use special-case formulas.
Otherwise:
Set x = abs(x); remember if x was negative
If x <= 10 and y <= 19:
Load precomputed result from a lookup table
Otherwise:
Set result to 0 (overflow)
If x was negative and y is odd, negate the result
C code:
#define POW9(x) x * x * x * x * x * x * x * x * x
#define POW10(x) POW9(x) * x
#define POW11(x) POW10(x) * x
#define POW12(x) POW11(x) * x
#define POW13(x) POW12(x) * x
#define POW14(x) POW13(x) * x
#define POW15(x) POW14(x) * x
#define POW16(x) POW15(x) * x
#define POW17(x) POW16(x) * x
#define POW18(x) POW17(x) * x
#define POW19(x) POW18(x) * x
int mypow(int x, unsigned y)
{
static int table[8][11] = {
{POW9(3), POW10(3), POW11(3), POW12(3), POW13(3), POW14(3), POW15(3), POW16(3), POW17(3), POW18(3), POW19(3)},
{POW9(4), POW10(4), POW11(4), POW12(4), POW13(4), POW14(4), POW15(4), 0, 0, 0, 0},
{POW9(5), POW10(5), POW11(5), POW12(5), POW13(5), 0, 0, 0, 0, 0, 0},
{POW9(6), POW10(6), POW11(6), 0, 0, 0, 0, 0, 0, 0, 0},
{POW9(7), POW10(7), POW11(7), 0, 0, 0, 0, 0, 0, 0, 0},
{POW9(8), POW10(8), 0, 0, 0, 0, 0, 0, 0, 0, 0},
{POW9(9), 0, 0, 0, 0, 0, 0, 0, 0, 0, 0},
{POW9(10), 0, 0, 0, 0, 0, 0, 0, 0, 0, 0}
};
int is_neg;
int r;
switch (x)
{
case 0:
return y == 0 ? 1 : 0;
case 1:
return 1;
case -1:
return y % 2 == 0 ? 1 : -1;
case 2:
return 1 << y;
case -2:
return (y % 2 == 0 ? 1 : -1) << y;
default:
switch (y)
{
case 0:
return 1;
case 1:
return x;
case 2:
return x * x;
case 3:
return x * x * x;
case 4:
r = x * x;
return r * r;
case 5:
r = x * x;
return r * r * x;
case 6:
r = x * x;
return r * r * r;
case 7:
r = x * x;
return r * r * r * x;
case 8:
r = x * x;
r = r * r;
return r * r;
default:
is_neg = x < 0;
if (is_neg)
x = -x;
if (x <= 10 && y <= 19)
r = table[x - 3][y - 9];
else
r = 0;
if (is_neg && y % 2 == 1)
r = -r;
return r;
}
}
}
My case is a little different, I'm trying to create a mask from a power, but I thought I'd share the solution I found anyway.
Obviously, it only works for powers of 2.
Mask1 = 1 << (Exponent - 1);
Mask2 = Mask1 - 1;
return Mask1 + Mask2;
In case you know the exponent (and it is an integer) at compile-time, you can use templates to unroll the loop. This can be made more efficient, but I wanted to demonstrate the basic principle here:
#include <iostream>
template<unsigned long N>
unsigned long inline exp_unroll(unsigned base) {
return base * exp_unroll<N-1>(base);
}
We terminate the recursion using a template specialization:
template<>
unsigned long inline exp_unroll<1>(unsigned base) {
return base;
}
The exponent needs to be known at runtime,
int main(int argc, char * argv[]) {
std::cout << argv[1] <<"**5= " << exp_unroll<5>(atoi(argv[1])) << ;std::endl;
}
I've noticed something strange about the standard exponential squaring algorithm with gnu-GMP :
I implemented 2 nearly-identical functions - a power-modulo function using the most vanilla binary exponential squaring algorithm,
labeled ______2()
then another one basically the same concept, but re-mapped to dividing by 10 at each round instead of dividing by 2,
labeled ______10()
.
( time ( jot - 1456 9999999999 6671 | pvE0 |
gawk -Mbe '
function ______10(_, __, ___, ____, _____, _______) {
__ = +__
____ = (____+=_____=____^= \
(_ %=___=+___)<_)+____++^____—
while (__) {
if (_______= __%____) {
if (__==_______) {
return (_^__ *_____) %___
}
__-=_______
_____ = (_^_______*_____) %___
}
__/=____
_ = _^____%___
}
}
function ______2(_, __, ___, ____, _____) {
__=+__
____+=____=_____^=(_%=___=+___)<_
while (__) {
if (__ %____) {
if (__<____) {
return (_*_____) %___
}
_____ = (_____*_) %___
--__
}
__/=____
_= (_*_) %___
}
}
BEGIN {
OFMT = CONVFMT = "%.250g"
__ = (___=_^= FS=OFS= "=")(_<_)
_____ = __^(_=3)^--_ * ++_-(_+_)^_
______ = _^(_+_)-_ + _^!_
_______ = int(______*_____)
________ = 10 ^ 5 + 1
_________ = 8 ^ 4 * 2 - 1
}
GNU Awk 5.1.1, API: 3.1 (GNU MPFR 4.1.0, GNU MP 6.2.1)
.
($++NF = ______10(_=$___, NR %________ +_________,_______*(_-11))) ^!___'
out9: 48.4MiB 0:00:08 [6.02MiB/s] [6.02MiB/s] [ <=> ]
in0: 15.6MiB 0:00:08 [1.95MiB/s] [1.95MiB/s] [ <=> ]
( jot - 1456 9999999999 6671 | pvE 0.1 in0 | gawk -Mbe ; )
8.31s user 0.06s system 103% cpu 8.058 total
ffa16aa937b7beca66a173ccbf8e1e12 stdin
($++NF = ______2(_=$___, NR %________ +_________,_______*(_-11))) ^!___'
out9: 48.4MiB 0:00:12 [3.78MiB/s] [3.78MiB/s] [<=> ]
in0: 15.6MiB 0:00:12 [1.22MiB/s] [1.22MiB/s] [ <=> ]
( jot - 1456 9999999999 6671 | pvE 0.1 in0 | gawk -Mbe ; )
13.05s user 0.07s system 102% cpu 12.821 total
ffa16aa937b7beca66a173ccbf8e1e12 stdin
For reasons extremely counter-intuitive and unknown to me, for a wide variety of inputs i threw at it, the div-10 variant is nearly always faster. It's the matching of hashes between the 2 that made it truly baffling, despite computers obviously not being built in and for a base-10 paradigm.
Am I missing something critical or obvious in the code/approach that might be skewing the results in a confounding manner ? Thanks.