Use time as int for calculation in function? - c++

Hi guys I'm working on a project where I need to find the age of a patient using a function in a header file. I'm trying to use division and remainder to separate the current date into Month, Day, and Year. The problem is I can't seem to find a way to use the current date as an integer. Here's the portion of my code I'm having trouble with.
int PatientDemographicInformation::getPatientAge( )
{
int patientBirthMonth = patientDateOfBirth / 1000000;
int patientBirthDay = (patientDateOfBirth % 1000000) / 10000;
int patientBirthYear = patientDateOfBirth % 10000;
// What can I use on the line below to get the current date/time as an int?
int currentTime = /*What can I use here?*/
int currentMonth = currentTime / 1000000;
int currentDay = (currentTime % 1000000) / 10000;
int currentYear = currentTime % 10000;
if (currentMonth >= patientBirthMonth)
{
if (patientBirthDay < currentDay)
{
int patientAge = (currentYear - patientBirthYear) - 1;
}
else
{
int patientAge = currentYear - patientBirthYear;
}
}
else
{
int patientAge = currentYear - patientBirthYear;
}
return patientBirthMonth;
}
Again, this is a function in my header file, the file is pretty long but I can give more code if needed. Please help me in anyway you can.
Thanks

I'm guessing that your mixing two completely different things.
patientDateOfBirth probably comes from a database where the string "12/21/1994" is stored as the number 12211994. So the code at the top unpacks that.
time is something else completely. Give that it won't let you do a '/' operator on them, the value in time[9] might be a structure, an object, or even a string. You are going to have to find more out about what time[] is, and what its values are.

Related

How to make step in 10 points without save value outside?

Actually what I need is I have a progress bar logic that tracking every second count of files, but case here that I don't need to update every time when I get trigger, like 1%, 3%, 7% ... I would like to define kind of step_progress variable (for example 10) and get this progress bar update steps like 10%, 20%, 30%...
So, for this case I wrote such logic
...
->set_progress_bar_callback([&](int count, int copied_file) {
const int PROGRESS_UPDATE_STEP = 10;
const int MAX_PERCENTAGE = 100;
float progress_step = (float)MAX_PERCENTAGE / (float)count;
float progress_result = progress_step * copied_file;
if ((int)progress_result % PROGRESS_UPDATE_STEP == 0)
{
if (progress_callback != nullptr)
{
printf("HERE!!! execute_copy_process Progress count %f\n", progress_result);
progress_callback(progress_result);
}
}
}
and I need to mention that I don't want to define outside variable(like class member), I would like that all this values should be inside lambda.
So, as you can see count - is a full amount (for example 124), and copied_file - it is a progress(for example 34)
Thus I calculate progress_result and try to get module(%) in order to understand if it is step of 10, but issue here that not every time progress_result value came to round number and eventually I get my progress like 10%, 40%, 60%...
Is there is some kind of trick to do it without to save outside values?
You should stay in integer arithmetic.
[&](int current, int total) {
const int PROGRESS_UPDATE_STEP = 10;
const int MAX_PERCENTAGE = 100;
int step = std::max(total * PROGRESS_UPDATE_STEP / MAX_PERCENTAGE, 1);
if ((current % step) == 0)
{
if (progress_callback != nullptr)
{
float progress_result = static_cast<float>(current) / total;
printf("HERE!!! execute_copy_process Progress count %f\n", progress_result);
progress_callback(progress_result);
}
}
}

Changing date for certain amount of days function

In class where we learn C++, I was given an assignment to make a class "date". Now, there is a specific function that I am required to make but I really do not have idea how to approach this. Members of class are day, month and year. Function takes some integer that represents days, and is supposed to set a new date, that comes after that many days. For example, if date is (DD-MM-YY) 20.01.2015, and we pass as an argument 15, new date is 04.02.2015, the problem is that I have to consider how many days each month has(considering February has 28 days), and if argument is too big, that we pass into next year, create an exception that prints how many days are there until next year(considering year has 365 days). That is, if the date is 20.12.2010, and argument is greater than 11, it should print 11.
My attempt was using while, where I declared at the beginning that int k=0; and where argument of function is a, than I used while(k!=a), but body of the function got really confusing because I used just too many if conditions. Another thing that I tried is to overlap operator++ and that surely gives me simpler function, because than there is only one for loop inside it, but I am not solving the problem, because in that overlapped operator function I am still using many if conditions.
Is there some elegant way to do this? Code and explanation would be great! Thank you!
Simply identify what you need and then create it, like
static unsigned int Date::days_of_month(const Month month, const unsigned int year);
void Date::operator+=(const unsigned int days);
+= could look like
void Date::operator+=(const unsigned int days){
increase current day by days
check if current day too large
if so, increase month (and maybe year)
repeat until day legal
}
Concept is clear? Haven't build in your output on purpose to give you something to do, after all, it's an exercise. Also wrote this in pseudo-code on purpose for the same reason. Try to create some code and if you really can't proceed, I'll add actual code.
const int m_daysInMonth[] = { 0,31,28,31,30,31,30,31,31,30,31,30,31 }; // first for index offset (no "zero" month)
class date {
public:
int days=20, month=11, year=2012;
void addDays(int daysNum)
{
int n_days = days, n_month = month; //new result. not saved, if there is an exception
while (daysNum > 0)
{
int daysToNextMonth = m_daysInMonth[n_month] - n_days + 1; //days before needs to change motn index
if (daysToNextMonth < daysNum) // change month
{
daysNum -= daysToNextMonth;
n_month++;
if (n_month > 12)
{
int daysLeft = m_daysInMonth[month] - days ;
n_month = month + 1;
while (n_month <= 12)
{
daysLeft += m_daysInMonth[n_month];
n_month++;
}
throw daysLeft;
}
n_days = 1; // start of the month
}
else // set day in the month
{
n_days += daysNum;
daysNum = 0;
}
}
days = n_days;
month = n_month;
}
};

Binary Search avoid unreadable entry (hole in list)

I have implemented a binary search function but I have an issue with a list entry that may become unreadable. It's implemented in C++ but ill just use some pseudo code to make it easier. Please to not focus on the unreadable or string implementation, it's just pseudo code. What matter is that there are unreadable entries in the list that have to be navigated around.
int i = 0;
int imin = 0;
int imax = 99;
string search = "test";
while(imin <= imax)
{
i = imin + (imax - imin) / 2;
string text = vector.at(i);
if(text.isUnreadable())
{
continue;
}
if(compare(text, search) = 0)
{
break;
}
else if(compare(text, search) < 0)
{
imin = i + 1;
}
else if(compare(text, search) > 0)
{
imax = i - 1;
}
}
The searching itself is working pretty well, but the problem I have is how to avoid getting an endless loop if the text is unreadable. Anyone has a time tested approach for this? The loop should not just exit when unreadable but rather navigate around the hole.
I had similar task in one of projects - lookup on sequence where some of items are non-comparable.
I am not sure is this the best possible implementation, in my case it looks like this:
int low = first_comparable(0,env);
int high = last_comparable(env.total() - 1,env);
while (low < high)
{
int mid = low + ((high - low) / 2);
int tmid = last_comparable(mid,env);
if( tmid < low )
{
tmid = first_comparable(mid,env);
if( tmid == high )
return high;
if( tmid > high )
return -1;
}
mid = tmid;
...
}
If vector.at(mid) item is non-comparable it does lookup in its neighborhood to find closest comparable.
first/last_comparable() functions return index of first comparable element from given index. Difference is in direction.
inline int first_comparable( int n, E& env)
{
int n_elements = env.total();
for( ; n < n_elements; ++n )
if( env.is_comparable(n) )
return n;
return n;
}
Create a list of pointers to your data items. Do not add "unreadable" ones. Search the resulting list of pointers.
the problem I have is how to avoid getting an endless loop if the text is unreadable.
Seems like that continue should be break instead, so that you break out of the loop. You'd probably want to set a flag or something to indicate the error to whatever code follows the loop.
Another option is to throw an exception.
Really, you should do almost anything other than what you're doing. Currently, when you read one of these 'unreadable' states, you simply continue the loop. But imin and imax still have the same values, so you end up reading the same string from the same place in the vector, and find that it's unreadable again, and so on. You need to decide how you want to respond to one of these 'unreadable' states. I guessed above that you'd want to stop the search, in which case either setting a flag and breaking out of the loop or throwing an exception to accomplish the same thing would be reasonable choices.

Random choices of two values

In my algorithm I have two values that I need to choose at random but each one has to be chosen a predetermined number of times.
So far my solution is to put the choices into a vector the correct number of times and then shuffle it. In C++:
// Example choices (can be any positive int)
int choice1 = 3;
int choice2 = 4;
int number_of_choice1s = 5;
int number_of_choice2s = 1;
std::vector<int> choices;
for(int i = 0; i < number_of_choice1s; ++i) choices.push_back(choice1);
for(int i = 0; i < number_of_choice2s; ++i) choices.push_back(choice2);
std::random_shuffle(choices.begin(), choices.end());
Then I keep an iterator to choices and whenever I need a new one I increase the iterator and grab that value.
This works but it seems like there might be a more efficient way. Since I always know how many of each value I'll use I'm wondering if there is a more algorithmic way to go about doing this, rather than just storing the values.
You are unnecessarily using so much memory. You have two variables:
int number_of_choice1s = 5;
int number_of_choice2s = 1;
Now simply randomize:
int result = rand() % (number_of_choice1s + number_of_choice2s);
if(result < number_of_choice1s) {
--number_of_choice1s;
return choice1;
} else {
--number_of_choice2s;
return choice2;
}
This scales very well two millions of random invocations.
You could write this a bit more simply:
std::vector<int> choices(number_of_choice1s, choice1);
choices.resize(number_of_choice1s + number_of_choice2s, choice2);
std::random_shuffle(choices.begin(), choices.end());
A biased random distribution will keep some kind of order over the resulting set ( the choice that was picked the most have lesser and lesser chance to be picked next ), which give a biased result (specially if the number of time you have to pick the first value is large compared to the second value, you'll endup with something like this {1,1,1,2,1,1,1,1,2}.
Here's the code, which looks a lot like the one written by #Tomasz Nurkiewicz but using a simple even/odd which should give about 50/50 chance to pick either values.
int result = rand();
if ( result & 1 && number_of_choice1s > 0)
{
number_of_choice1s--;
return choice1;
}else if (number_of_choice2s>0)
{
number_of_choice2s--;
return choice2;
}
else
{
return -1;
}

Unusual Speed Difference between Python and C++

I recently wrote a short algorithm to calculate happy numbers in python. The program allows you to pick an upper bound and it will determine all the happy numbers below it. For a speed comparison I decided to make the most direct translation of the algorithm I knew of from python to c++.
Surprisingly, the c++ version runs significantly slower than the python version. Accurate speed tests between the execution times for discovering the first 10,000 happy numbers indicate the python program runs on average in 0.59 seconds and the c++ version runs on average in 8.5 seconds.
I would attribute this speed difference to the fact that I had to write helper functions for parts of the calculations (for example determining if an element is in a list/array/vector) in the c++ version which were already built in to the python language.
Firstly, is this the true reason for such an absurd speed difference, and secondly, how can I change the c++ version to execute more quickly than the python version (the way it should be in my opinion).
The two pieces of code, with speed testing are here: Python Version, C++ Version. Thanks for the help.
#include <iostream>
#include <vector>
#include <string>
#include <ctime>
#include <windows.h>
using namespace std;
bool inVector(int inQuestion, vector<int> known);
int sum(vector<int> given);
int pow(int given, int power);
void calcMain(int upperBound);
int main()
{
while(true)
{
int upperBound;
cout << "Pick an upper bound: ";
cin >> upperBound;
long start, end;
start = GetTickCount();
calcMain(upperBound);
end = GetTickCount();
double seconds = (double)(end-start) / 1000.0;
cout << seconds << " seconds." << endl << endl;
}
return 0;
}
void calcMain(int upperBound)
{
vector<int> known;
for(int i = 0; i <= upperBound; i++)
{
bool next = false;
int current = i;
vector<int> history;
while(!next)
{
char* buffer = new char[10];
itoa(current, buffer, 10);
string digits = buffer;
delete buffer;
vector<int> squares;
for(int j = 0; j < digits.size(); j++)
{
char charDigit = digits[j];
int digit = atoi(&charDigit);
int square = pow(digit, 2);
squares.push_back(square);
}
int squaresum = sum(squares);
current = squaresum;
if(inVector(current, history))
{
next = true;
if(current == 1)
{
known.push_back(i);
//cout << i << "\t";
}
}
history.push_back(current);
}
}
//cout << "\n\n";
}
bool inVector(int inQuestion, vector<int> known)
{
for(vector<int>::iterator it = known.begin(); it != known.end(); it++)
if(*it == inQuestion)
return true;
return false;
}
int sum(vector<int> given)
{
int sum = 0;
for(vector<int>::iterator it = given.begin(); it != given.end(); it++)
sum += *it;
return sum;
}
int pow(int given, int power)
{
int original = given;
int current = given;
for(int i = 0; i < power-1; i++)
current *= original;
return current;
}
#!/usr/bin/env python
import timeit
upperBound = 0
def calcMain():
known = []
for i in range(0,upperBound+1):
next = False
current = i
history = []
while not next:
digits = str(current)
squares = [pow(int(digit), 2) for digit in digits]
squaresum = sum(squares)
current = squaresum
if current in history:
next = True
if current == 1:
known.append(i)
##print i, "\t",
history.append(current)
##print "\nend"
while True:
upperBound = input("Pick an upper bound: ")
result = timeit.Timer(calcMain).timeit(1)
print result, "seconds.\n"
For 100000 elements, the Python code took 6.9 seconds while the C++ originally took above 37 seconds.
I did some basic optimizations on your code and managed to get the C++ code above 100 times faster than the Python implementation. It now does 100000 elements in 0.06 seconds. That is 617 times faster than the original C++ code.
The most important thing is to compile in Release mode, with all optimizations. This code is literally orders of magnitude slower in Debug mode.
Next, I will explain the optimizations I did.
Moved all vector declarations outside of the loop; replaced them by a clear() operation, which is much faster than calling the constructor.
Replaced the call to pow(value, 2) by a multiplication : value * value.
Instead of having a squares vector and calling sum on it, I sum the values in-place using just an integer.
Avoided all string operations, which are very slow compared to integer operations. For instance, it is possible to compute the squares of each digit by repeatedly dividing by 10 and fetching the modulus 10 of the resulting value, instead of converting the value to a string and then each character back to int.
Avoided all vector copies, first by replacing passing by value with passing by reference, and finally by eliminating the helper functions completely.
Eliminated a few temporary variables.
And probably many small details I forgot. Compare your code and mine side-by-side to see exactly what I did.
It may be possible to optimize the code even more by using pre-allocated arrays instead of vectors, but this would be a bit more work and I'll leave it as an exercise to the reader. :P
Here's the optimized code :
#include <iostream>
#include <vector>
#include <string>
#include <ctime>
#include <algorithm>
#include <windows.h>
using namespace std;
void calcMain(int upperBound, vector<int>& known);
int main()
{
while(true)
{
vector<int> results;
int upperBound;
cout << "Pick an upper bound: ";
cin >> upperBound;
long start, end;
start = GetTickCount();
calcMain(upperBound, results);
end = GetTickCount();
for (size_t i = 0; i < results.size(); ++i) {
cout << results[i] << ", ";
}
cout << endl;
double seconds = (double)(end-start) / 1000.0;
cout << seconds << " seconds." << endl << endl;
}
return 0;
}
void calcMain(int upperBound, vector<int>& known)
{
vector<int> history;
for(int i = 0; i <= upperBound; i++)
{
int current = i;
history.clear();
while(true)
{
int temp = current;
int sum = 0;
while (temp > 0) {
sum += (temp % 10) * (temp % 10);
temp /= 10;
}
current = sum;
if(find(history.begin(), history.end(), current) != history.end())
{
if(current == 1)
{
known.push_back(i);
}
break;
}
history.push_back(current);
}
}
}
There's a new, radically faster version as a separate answer, so this answer is deprecated.
I rewrote your algorithm by making it cache whenever it finds the number to be happy or unhappy. I also tried to make it as pythonic as I could, for example by creating separate functions digits() and happy(). Sorry for using Python 3, but I get to show off a couple a useful things from it as well.
This version is much faster. It runs at 1.7s which is 10 times faster than your original program that takes 18s (well, my MacBook is quite old and slow :) )
#!/usr/bin/env python3
from timeit import Timer
from itertools import count
print_numbers = False
upperBound = 10**5 # Default value, can be overidden by user.
def digits(x:'nonnegative number') -> "yields number's digits":
if not (x >= 0): raise ValueError('Number should be nonnegative')
while x:
yield x % 10
x //= 10
def happy(number, known = {1}, happies = {1}) -> 'True/None':
'''This function tells if the number is happy or not, caching results.
It uses two static variables, parameters known and happies; the
first one contains known happy and unhappy numbers; the second
contains only happy ones.
If you want, you can pass your own known and happies arguments. If
you do, you should keep the assumption commented out on the 1 line.
'''
# assert 1 in known and happies <= known # <= is expensive
if number in known:
return number in happies
history = set()
while True:
history.add(number)
number = sum(x**2 for x in digits(number))
if number in known or number in history:
break
known.update(history)
if number in happies:
happies.update(history)
return True
def calcMain():
happies = {x for x in range(upperBound) if happy(x) }
if print_numbers:
print(happies)
if __name__ == '__main__':
upperBound = eval(
input("Pick an upper bound [default {0}]: "
.format(upperBound)).strip()
or repr(upperBound))
result = Timer(calcMain).timeit(1)
print ('This computation took {0} seconds'.format(result))
It looks like you're passing vectors by value to other functions. This will be a significant slowdown because the program will actually make a full copy of your vector before it passes it to your function. To get around this, pass a constant reference to the vector instead of a copy. So instead of:
int sum(vector<int> given)
Use:
int sum(const vector<int>& given)
When you do this, you'll no longer be able to use the vector::iterator because it is not constant. You'll need to replace it with vector::const_iterator.
You can also pass in non-constant references, but in this case, you don't need to modify the parameter at all.
This is my second answer; which caches things like sum of squares for values <= 10**6:
happy_list[sq_list[x%happy_base] + sq_list[x//happy_base]]
That is,
the number is split into 3 digits + 3 digits
the precomputed table is used to get sum of squares for both parts
these two results are added
the precomputed table is consulted to get the happiness of number:
I don't think Python version can be made much faster than that (ok, if you throw away fallback to old version, that is try: overhead, it's 10% faster).
I think this is an excellent question which shows that, indeed,
things that have to be fast should be written in C
however, usually you don't need things to be fast (even if you needed the program to run for a day, it would be less then the combined time of programmers optimizing it)
it's easier and faster to write programs in Python
but for some problems, especially computational ones, a C++ solution, like the ones above, are actually more readable and more beautiful than an attempt to optimize Python program.
Ok, here it goes (2nd version now...):
#!/usr/bin/env python3
'''Provides slower and faster versions of a function to compute happy numbers.
slow_happy() implements the algorithm as in the definition of happy
numbers (but also caches the results).
happy() uses the precomputed lists of sums of squares and happy numbers
to return result in just 3 list lookups and 3 arithmetic operations for
numbers less than 10**6; it falls back to slow_happy() for big numbers.
Utilities: digits() generator, my_timeit() context manager.
'''
from time import time # For my_timeit.
from random import randint # For example with random number.
upperBound = 10**5 # Default value, can be overridden by user.
class my_timeit:
'''Very simple timing context manager.'''
def __init__(self, message):
self.message = message
self.start = time()
def __enter__(self):
return self
def __exit__(self, *data):
print(self.message.format(time() - self.start))
def digits(x:'nonnegative number') -> "yields number's digits":
if not (x >= 0): raise ValueError('Number should be nonnegative')
while x:
yield x % 10
x //= 10
def slow_happy(number, known = {1}, happies = {1}) -> 'True/None':
'''Tell if the number is happy or not, caching results.
It uses two static variables, parameters known and happies; the
first one contains known happy and unhappy numbers; the second
contains only happy ones.
If you want, you can pass your own known and happies arguments. If
you do, you should keep the assumption commented out on the 1 line.
'''
# This is commented out because <= is expensive.
# assert {1} <= happies <= known
if number in known:
return number in happies
history = set()
while True:
history.add(number)
number = sum(x**2 for x in digits(number))
if number in known or number in history:
break
known.update(history)
if number in happies:
happies.update(history)
return True
# This will define new happy() to be much faster ------------------------.
with my_timeit('Preparation time was {0} seconds.\n'):
LogAbsoluteUpperBound = 6 # The maximum possible number is 10**this.
happy_list = [slow_happy(x)
for x in range(81*LogAbsoluteUpperBound + 1)]
happy_base = 10**((LogAbsoluteUpperBound + 1)//2)
sq_list = [sum(d**2 for d in digits(x))
for x in range(happy_base + 1)]
def happy(x):
'''Tell if the number is happy, optimized for smaller numbers.
This function works fast for numbers <= 10**LogAbsoluteUpperBound.
'''
try:
return happy_list[sq_list[x%happy_base] + sq_list[x//happy_base]]
except IndexError:
return slow_happy(x)
# End of happy()'s redefinition -----------------------------------------.
def calcMain(print_numbers, upper_bound):
happies = [x for x in range(upper_bound + 1) if happy(x)]
if print_numbers:
print(happies)
if __name__ == '__main__':
while True:
upperBound = eval(input(
"Pick an upper bound [{0} default, 0 ends, negative number prints]: "
.format(upperBound)).strip() or repr(upperBound))
if not upperBound:
break
with my_timeit('This computation took {0} seconds.'):
calcMain(upperBound < 0, abs(upperBound))
single = 0
while not happy(single):
single = randint(1, 10**12)
print('FYI, {0} is {1}.\n'.format(single,
'happy' if happy(single) else 'unhappy'))
print('Nice to see you, goodbye!')
I can see that you have quite a few heap allocations that are unnecessary
For example:
while(!next)
{
char* buffer = new char[10];
This doesn't look very optimized. So, you probably want to have the array pre-allocated and using it inside your loop. This is a basic optimizing technique which is easy to spot and to do. It might become into a mess too, so be careful with that.
You are also using the atoi() function, which I don't really know if it is really optimized. Maybe doing a modulus 10 and getting the digit might be better (you have to measure thou, I didn't test this).
The fact that you have a linear search (inVector) might be bad. Replacing the vector data structure with a std::set might speed things up. A hash_set could do the trick too.
But I think that the worst problem is the string and this allocation of stuff on the heap inside that loop. That doesn't look good. I would try at those places first.
Well, I also gave it a once-over. I didn't test or even compile, though.
General rules for numerical programs:
Never process numbers as text. That's what makes lesser languages than Python slow, so if you do it in C, the program will be slower than Python.
Don't use data structures if you can avoid them. You were building an array just to add the numbers up. Better keep a running total.
Keep a copy of the STL reference open so you can use it rather than writing your own functions.
void calcMain(int upperBound)
{
vector<int> known;
for(int i = 0; i <= upperBound; i++)
{
int current = i;
vector<int> history;
do
{
squaresum = 0
for ( ; current; current /= 10 )
{
int digit = current % 10;
squaresum += digit * digit;
}
current = squaresum;
history.push_back(current);
} while ( ! count(history.begin(), history.end() - 1, current) );
if(current == 1)
{
known.push_back(i);
//cout << i << "\t";
}
}
//cout << "\n\n";
}
Just to get a little more closure on this issue by seeing how fast I could truely find these numbers, I wrote a multithreaded C++ implementation of Dr_Asik's algorithm. There are two things that are important to realize about the fact that this implementation is multithreaded.
More threads does not necessarily lead to better execution times, there is a happy medium for every situation depending on the volume of numbers you want to calculate.
If you compare the times between this version running with one thread and the original version, the only factors that could cause a difference in time are the overhead from starting the thread and variable system performance issues. Otherwise, the algorithm is the same.
The code for this implementation (all credit for the algorithm goes to Dr_Asik) is here. Also, I wrote some speed tests with a double check for each test to help back up those 3 points.
Calculation of the first 100,000,000 happy numbers:
Original - 39.061 / 39.000 (Dr_Asik's original implementation)
1 Thread - 39.000 / 39.079
2 Threads - 19.750 / 19.890
10 Threads - 11.872 / 11.888
30 Threads - 10.764 / 10.827
50 Threads - 10.624 / 10.561 <--
100 Threads - 11.060 / 11.216
500 Threads - 13.385 / 12.527
From these results it looks like our happy medium is about 50 threads, plus or minus ten or so.
Other optimizations: by using arrays and direct access using the loop index rather than searching in a vector, and by caching prior sums, the following code (inspired by Dr Asik's answer but probably not optimized at all) runs 2445 times faster than the original C++ code, about 400 times faster than the Python code.
#include <iostream>
#include <windows.h>
#include <vector>
void calcMain(int upperBound, std::vector<int>& known)
{
int tempDigitCounter = upperBound;
int numDigits = 0;
while (tempDigitCounter > 0)
{
numDigits++;
tempDigitCounter /= 10;
}
int maxSlots = numDigits * 9 * 9;
int* history = new int[maxSlots + 1];
int* cache = new int[upperBound+1];
for (int jj = 0; jj <= upperBound; jj++)
{
cache[jj] = 0;
}
int current, sum, temp;
for(int i = 0; i <= upperBound; i++)
{
current = i;
while(true)
{
sum = 0;
temp = current;
bool inRange = temp <= upperBound;
if (inRange)
{
int cached = cache[temp];
if (cached)
{
sum = cached;
}
}
if (sum == 0)
{
while (temp > 0)
{
int tempMod = temp % 10;
sum += tempMod * tempMod;
temp /= 10;
}
if (inRange)
{
cache[current] = sum;
}
}
current = sum;
if(history[current] == i)
{
if(current == 1)
{
known.push_back(i);
}
break;
}
history[current] = i;
}
}
}
int main()
{
while(true)
{
int upperBound;
std::vector<int> known;
std::cout << "Pick an upper bound: ";
std::cin >> upperBound;
long start, end;
start = GetTickCount();
calcMain(upperBound, known);
end = GetTickCount();
for (size_t i = 0; i < known.size(); ++i) {
std::cout << known[i] << ", ";
}
double seconds = (double)(end-start) / 1000.0;
std::cout << std::endl << seconds << " seconds." << std::endl << std::endl;
}
return 0;
}
Stumbled over this page whilst bored and thought I'd golf it in js. The algorithm is my own, and I haven't checked it thoroughly against anything other than my own calculations (so it could be wrong). It calculates the first 1e7 happy numbers and stores them in h. If you want to change it, change both the 7s.
m=1e7,C=7*81,h=[1],t=true,U=[,,,,t],n=w=2;
while(n<m){
z=w,s=0;while(z)y=z%10,s+=y*y,z=0|z/10;w=s;
if(U[w]){if(n<C)U[n]=t;w=++n;}else if(w<n)h.push(n),w=++n;}
This will print the first 1000 items for you in console or a browser:
o=h.slice(0,m>1e3?1e3:m);
(!this.document?print(o):document.load=document.write(o.join('\n')));
155 characters for the functional part and it appears to be as fast* as Dr. Asik's offering on firefox or v8 (350-400 times as fast as the original python program on my system when running time d8 happygolf.js or js -a -j -p happygolf.js in spidermonkey).
I shall be in awe of the analytic skills anyone who can figure out why this algorithm is doing so well without referencing the longer, commented, fortran version.
I was intrigued by how fast it was, so I learned fortran to get a comparison of the same algorithm, be kind if there are any glaring newbie mistakes, it's my first fortran program. http://pastebin.com/q9WFaP5C
It's static memory wise, so to be fair to the others, it's in a self-compiling shell script, if you don't have gcc/bash/etc strip out the preprocessor and bash stuff at the top, set the macros manually and compile it as fortran95.
Even if you include compilation time it beats most of the others here. If you don't, it's about ~3000-3500 times as fast as the original python version (and by extension >40,000 times as fast as the C++*, although I didn't run any of the C++ programs).
Surprisingly many of the optimizations I tried in the fortran version (incl some like loop unrolling which I left out of the pasted version due to small effect and readability) were detrimental to the js version. This exercise shows that modern trace compilers are extremely good (within a factor of 7-10 of carefully optimized, static memory fortran) if you get out of their way and don't try any tricky stuff.
get out of their way, and trying to do tricky stuff
Finally, here's a much nicer, more recursive js version.
// to s, then integer divides x by 10.
// Repeats until x is 0.
function sumsq(x) {
var y,s=0;
while(x) {
y = x % 10;
s += y * y;
x = 0| x / 10;
}
return s;
}
// A boolean cache for happy().
// The terminating happy number and an unhappy number in
// the terminating sequence.
var H=[];
H[1] = true;
H[4] = false;
// Test if a number is happy.
// First check the cache, if that's empty
// Perform one round of sumsq, then check the cache
// For that. If that's empty, recurse.
function happy(x) {
// If it already exists.
if(H[x] !== undefined) {
// Return whatever is already in cache.
return H[x];
} else {
// Else calc sumsq, set and return cached val, or if undefined, recurse.
var w = sumsq(x);
return (H[x] = H[w] !== undefined? H[w]: happy(w));
}
}
//Main program loop.
var i, hN = [];
for(i = 1; i < 1e7; i++) {
if(happy(i)) { hN.push(i); }
}
Surprisingly, even though it is rather high level, it did almost exactly as well as the imperative algorithm in spidermonkey (with optimizations on), and close (1.2 times as long) in v8.
Moral of the story I guess, spend a bit of time thinking about your algorithm if it's important. Also high level languages already have a lot of overhead (and sometimes have tricks of their own to reduce it) so sometimes doing something more straightforwared or utilizing their high level features is just as fast. Also micro-optimization doesn't always help.
*Unless my python installation is unusually slow, direct times are somewhat meaningless as this is a first generation eee.
Times are:
12s for fortran version, no output, 1e8 happy numbers.
40s for fortran version, pipe output through gzip to disk.
8-12s for both js versions. 1e7 happy numbers, no output with full optimization
10-100s for both js versions 1e7 with less/no optimization (depending on definition of no optimization, the 100s was with eval()) no output
I'd be interested to see times for these programs on a real computer.
I am not an expert at C++ optimization, but I believe the speed difference may be due to the fact that Python lists have preallocated more space at the beginning while your C++ vectors must reallocate and possibly copy every time it grows.
As for GMan's comment about find, I believe that the Python "in" operator is also a linear search and is the same speed.
Edit
Also I just noticed that you rolled your own pow function. There is no need to do that and the stdlib is likely faster.
Here is another way that relies on memorising all the numbers already explored.
I obtain a factor x4-5, which is oddly stable against DrAsik's code for 1000 and 1000000, I expected the cache to be more efficient the more numbers we were exploring. Otherwise, the same kind of classic optimizations have been applied. BTW, if the compiler accepts NRVO (/RNVO ? I never remember the exact term) or rvalue references, we wouldn't need to pass the vector as an out parameter.
NB: micro-optimizations are still possible IMHO, and moreover the caching is naive as it allocates much more memory than really needed.
enum Status {
never_seen,
being_explored,
happy,
unhappy
};
char const* toString[] = { "never_seen", "being_explored", "happy", "unhappy" };
inline size_t sum_squares(size_t i) {
size_t s = 0;
while (i) {
const size_t digit = i%10;
s += digit * digit;
i /= 10;
}
return s ;
}
struct Cache {
Cache(size_t dim) : m_cache(dim, never_seen) {}
void set(size_t n, Status status) {
if (m_cache.size() <= n) {
m_cache.resize(n+1, never_seen);
}
m_cache[n] = status;
// std::cout << "(c[" << n << "]<-"<<toString[status] << ")";
}
Status operator[](size_t n) const {
if (m_cache.size() <= n) {
return never_seen;
} else {
return m_cache[n];
}
}
private:
std::vector<Status> m_cache;
};
void search_happy_lh(size_t upper_bound, std::vector<size_t> & happy_numbers)
{
happy_numbers.clear();
happy_numbers.reserve(upper_bound); // it doesn't improve much the performances
Cache cache(upper_bound+1);
std::vector<size_t> current_stack;
cache.set(1,happy);
happy_numbers.push_back(1);
for (size_t i = 2; i<=upper_bound ; ++i) {
// std::cout << "\r" << i << std::flush;
current_stack.clear();
size_t s= i;
while ( s != 1 && cache[s]==never_seen)
{
current_stack.push_back(s);
cache.set(s, being_explored);
s = sum_squares(s);
// std::cout << " - " << s << std::flush;
}
const Status update_with = (cache[s]==being_explored ||cache[s]==unhappy) ? unhappy : happy;
// std::cout << " => " << s << ":" << toString[update_with] << std::endl;
for (size_t j=0; j!=current_stack.size(); ++j) {
cache.set(current_stack[j], update_with);
}
if (cache[i] == happy) {
happy_numbers.push_back(i);
}
}
}
Here's a C# version:
using System;
using System.Collections.Generic;
using System.Text;
namespace CSharp
{
class Program
{
static void Main (string [] args)
{
while (true)
{
Console.Write ("Pick an upper bound: ");
String
input = Console.ReadLine ();
uint
upper_bound;
if (uint.TryParse (input, out upper_bound))
{
DateTime
start = DateTime.Now;
CalcHappyNumbers (upper_bound);
DateTime
end = DateTime.Now;
TimeSpan
span = end - start;
Console.WriteLine ("Time taken = " + span.TotalSeconds + " seconds.");
}
else
{
Console.WriteLine ("Error in input, unable to parse '" + input + "'.");
}
}
}
enum State
{
Happy,
Sad,
Unknown
}
static void CalcHappyNumbers (uint upper_bound)
{
SortedDictionary<uint, State>
happy = new SortedDictionary<uint, State> ();
SortedDictionary<uint, bool>
happy_numbers = new SortedDictionary<uint, bool> ();
happy [1] = State.Happy;
happy_numbers [1] = true;
for (uint current = 2 ; current < upper_bound ; ++current)
{
FindState (ref happy, ref happy_numbers, current);
}
//foreach (KeyValuePair<uint, bool> pair in happy_numbers)
//{
// Console.Write (pair.Key.ToString () + ", ");
//}
//Console.WriteLine ("");
}
static State FindState (ref SortedDictionary<uint, State> happy, ref SortedDictionary<uint,bool> happy_numbers, uint value)
{
State
current_state;
if (happy.TryGetValue (value, out current_state))
{
if (current_state == State.Unknown)
{
happy [value] = State.Sad;
}
}
else
{
happy [value] = current_state = State.Unknown;
uint
new_value = 0;
for (uint i = value ; i != 0 ; i /= 10)
{
uint
lsd = i % 10;
new_value += lsd * lsd;
}
if (new_value == 1)
{
current_state = State.Happy;
}
else
{
current_state = FindState (ref happy, ref happy_numbers, new_value);
}
if (current_state == State.Happy)
{
happy_numbers [value] = true;
}
happy [value] = current_state;
}
return current_state;
}
}
}
I compared it against Dr_Asik's C++ code. For an upper bound of 100000 the C++ version ran in about 2.9 seconds and the C# version in 0.35 seconds. Both were compiled using Dev Studio 2005 using default release build options and both were executed from a command prompt.
Here's some food for thought: If given the choice of running a 1979 algorithm for finding prime numbers in a 2009 computer or a 2009 algorithm on a 1979 computer, which would you choose?
The new algorithm on ancient hardware would be the better choice by a huge margin. Have a look at your "helper" functions.
There are quite a few optimizations possible:
(1) Use const references
bool inVector(int inQuestion, const vector<int>& known)
{
for(vector<int>::const_iterator it = known.begin(); it != known.end(); ++it)
if(*it == inQuestion)
return true;
return false;
}
int sum(const vector<int>& given)
{
int sum = 0;
for(vector<int>::const_iterator it = given.begin(); it != given.end(); ++it)
sum += *it;
return sum;
}
(2) Use counting down loops
int pow(int given, int power)
{
int current = 1;
while(power--)
current *= given;
return current;
}
Or, as others have said, use the standard library code.
(3) Don't allocate buffers where not required
vector<int> squares;
for (int temp = current; temp != 0; temp /= 10)
{
squares.push_back(pow(temp % 10, 2));
}
With similar optimizations as PotatoSwatter I got time for 10000 numbers down from 1.063 seconds to 0.062 seconds (except I replaced itoa with standard sprintf in the original).
With all the memory optimizations (don't pass containers by value - in C++ you have to explicitly decide whether you want a copy or a reference; move operations that allocate memory out of inner loops; if you already have the number in a char buffer, what's the point of copying it to std::string etc) I got it down to 0.532.
The rest of the time came from using %10 to access digits, rather than converting numbers to string.
I suppose there might be another algorithmic level optimization (numbers that you have encountered while finding a happy number are themselves also happy numbers?) but I don't know how much that gains (there is not that many happy numbers in the first place) and this optimization is not in the Python version either.
By the way, by not using string conversion and a list to square digits, I got the Python version from 0.825 seconds down to 0.33 too.
#!/usr/bin/env python
import timeit
upperBound = 0
def calcMain():
known = set()
for i in xrange(0,upperBound+1):
next = False
current = i
history = set()
while not next:
squaresum=0
while current > 0:
current, digit = divmod(current, 10)
squaresum += digit * digit
current = squaresum
if current in history:
next = True
if current == 1:
known.add(i)
history.add(current)
while True:
upperBound = input("Pick an upper bound: ")
result = timeit.Timer(calcMain).timeit(1)
print result, "seconds.\n"
I made a couple of minor changes to your original python code example that make a better than 16x improvement to the performance of the code.
The changes I made took the 100,000 case from about 9.64 seconds to about 3.38 seconds.
The major change was to make the mod 10 and accumulator changes to run in a while loop. I made a couple of other changes that improved execution time in only fractions of hundredths of seconds. The first minor change was changing the main for loop from a range list comprehension to an xrange iterator. The second minor change was substituting the set class for the list class for both the known and history variables.
I also experimented with iterator comprehensions and precalculating the squares but they both had negative effects on the efficiency.
I seem to be running a slower version of python or on a slower processor than some of the other contributers. I would be interest in the results of someone else's timing comparison of my python code against one of the optimized C++ versions of the same algorithm.
I also tried using the python -O and -OO optimizations but they had the reverse of the intended effect.
Why is everyone using a vector in the c++ version? Lookup time is O(N).
Even though it's not as efficient as the python set, use std::set. Lookup time is O(log(N)).