I'm quite a beginner in this topic, and couldn't find out the reason: sometimes the program works, sometimes not (after asking the question, it simply doensn't want to take in my answers, than I can write in as much as I want, it doesn't respond, just list out the numbers, I tiped in)
#include <stdio.h>
float abszolut (float szam)
{
float abszoluterteke;
if (szam >=0)
abszoluterteke = szam;
else
abszoluterteke = -szam;
return abszoluterteke;
}
float negyzetgyok (float szam)
{
float pontossag = 0.000001;
float tipp = 1;
if (szam <0)
{
printf ("Megszakítás elfogadva! \nKöszönjük, hogy programunkat választotta!\n");
return -1;
}
else
{while (abszolut (tipp*tipp-szam) >= pontossag)
tipp = (szam/tipp + tipp)/2;
return tipp;
}
}
int main (void)
{
float alap, eredmeny;
for (;;)
{
printf ("Melyik számnak szeretnéd meghatározni a négyzetgyökét ilyen módszerrel?\n");
scanf ("%f", &alap);
eredmeny = negyzetgyok (alap);
if (eredmeny == -1)
return 1;
else
printf ("A(z) %f négyzetgyöke megfelelő közelítéssel: %f\n", alap, eredmeny);
}
return 0;
}
Change for abszolut (tipp*tipp-szam) >= pontossag*szam
The while loop must stop once tipp*tipp is close to szam. But IEEE floating point computations have a limited precision : about 7 digits for float and 15 digits for double.
So the error on float szam is about 0.0000001*szam. It's the same for tipp. Consequently, the error on tipp*tipp-szam is higher than 0.0000001*szam. If szam is large, this error will hardly become lower than 0.000001. Even if double precision is used, it is likely that while (abszolut (tipp*tipp-szam) >= pontossag) triggers an infinite loop for very large numbers.
On the other side, what happens if szam is very small, say 1e-10 ? The while loop prematurely exits and the square root of 1e-10 is computed as something about 1e-3, instead of 1e-5... The relative error is about 10000%... And using double does not change anything !
To avoid this, you can change for abszolut (tipp*tipp-szam) >= pontossag*szam.
Notice that both sides have the same dimension. If szam were in square feet, tipp would be in feet and pontossag, the precision, is dimensionless. It is a good practice to compare things having the same dimension.
If you keep noticing infinite loops, switch to double precision or increase pontossag.
To avoid infinite loop, add a counter int i; and exit the while loop if the number of iteration is 100. 100 should be sufficient, since your Newton-Raphson iteration features a quadratic convergence.
There are a number of problems with your code.
The exit condition in your loop is flawed.
The problem with your square root algorithm is the use of the error limit pontossag. Your algorithm will give erroneous results for very small numbers and it will loop forever for numbers larger than 20 or so. To fix this, change the loop test from abszolut (tipp*tipp-szam) >= pontossag to abszolut (tipp*tipp-szam) >= pontossag*szam.
You aren't checking for all the problem cases.
If your computer uses IEEE 754 floating point, your algorithm happens to work. That's just luck. Never rely on luck when doing numerical programming. It's easy to input an infinity. For example, 3.5e38 (350000000000000000000000000000000000000) does the trick with single precision numbers (float). Your function negyzetgyok should check for infinity:
if (isinf (szam))
{
return szam;
}
You can do much better than an initial guess of 1.0 as the square root.
An initial guess of 1.0 against 3.4e38 means a lot of needless looping. A fast and easy way to form a good initial guess is to take advantage of the fact that floating point numbers are represented internally as (1+fractional_part)*2^exponent. A good first guess is 1*2^(exponent/2). With single precision numbers,
int expo;
float tipp;
frexpf (szam, &expo);
tipp = ldexpf (1.0f, n/2);
You are using %f rather than %g to parse floating point numbers.
The %g format can parse anything that can be parsed with the %f format, plus a whole lot more.
You aren't checking the status of fscanf.
Enter x when prompted to enter a number. The scanner will read that character, which stops the scan. The scanner will put that character (x) back into the input buffer, and return 0, indicating that nothing was scanned. The next time around, the scanner will read the character x again, once again put that character back into the input buffer, and once again return 0. Infinite loop! Always check the status of any of the scanf family of functions to see if the scanner scanned the number of items expected.
You are using fscanf.
There are a number of existing questions and answers at this site that address the many problems with using fscanf to read from a file. This is particularly so when reading human-generated input. People make mistakes. Ignoring that people do make mistakes on entering data is a programming error. A better approach would be to read a line into a buffer using frets and parse that line with sscanf.
Related
I was making a little program to test floats in the C: The program itself is very simple, I just want to based on the User's input, return how much Dollar(s), Quarter(s)... etc, his number has.
//------------------------------> First Part: All the necessary Variables <-----------------------------
int main (void)
{
//Getting the user Input
float number = get_float("Number: ");
//Checking if is a positive number
if (number < 0)
{
printf("A positive number, Please: ");
}
//Declaring my Constant/Temporary variables.
float coinValues[] = {1.00, 0.25, 0.10, 0.5, 0.01};
char *coinNames[] = {"Dollar(s): ", "Quarter(s): ", "Dime(s): ", "Nickel(s): ", "Penny(ies): "};
int i = 0;
int tmp = 0;
//-----------------------------------> Second Part: The code Itself <-----------------------------------
//Checking/Printing the necessary coins.
while (number > 0)
{
//Until the loop stops, check if the number can be divided by the CoinValue.
if (number >= coinValues[i])
{
//Print the current Coin Name from the divided value.
printf("%s", coinNames[i]);
//Check if the Current Number still contains Coin Values inside of it, if True counts one in your "Coin Score".
while (number >= coinValues[i])
{
number -= coinValues[i];
tmp++;
}
//Print the Current "Coin Score", then resets TMP.
printf("%i\n", tmp);
tmp = 0;
}
else
{
//Updating the Coin value
i++;
}
}
}
My program was running very well as long I use Integers, but when I converted this code for Floats the values (Dime(s), Nickel(s), and Penny(ies)) start to return non-expected results in the Int variable tmp.
An expected result for a number like 2.6, will be 2 Dollars, 2 Quarters, and 1 Dime, but sometimes, instead of use the Dime(s), the program skips them entire and make the operation with the Nickel(s), however, what is bugging me is that the program is always returning AWL=+ without any value and then the program stay froze forever.
Considering that my only thought is that I'm "suffering" from Float Imprecision, and I don't know how to solve it, so can anyone Help me?
Ps. The program needs to always return the maximum value from each coin before pass forward.
Floating-point arithmetic is designed to approximate real-number arithmetic. IEEE 754-2008 says “Floating-point arithmetic is a systematic approximation of real arithmetic…” So there is no way to “lock” decimal digits in binary floating-point. It is intended to be used where you want an approximation, such as modeling physics. That even includes some financial applications, such as options evaluation. Although floating-point arithmetic can be used for exact calculations in some situations, these require particular care and are generally only pursued in special circumstances.
So the answer to your question on how to lock decimal places is there is no good way to do that with binary floating-point. Attempting to do so generally just yields the same effects as integer arithmetic but less efficiently and with more difficult code. So use integer arithmetic and scale the amounts according to the smallest unit of currency desired, such as a penny.
So as part of a computer science course I've been doing a little bit of C. One of the challenges was to create a program that would tell a hypothetical cashier how many coins they would need in order to give change to a customer. I accomplished this with a set of while loops, the entire program looking like this:
#include <stdio.h>
#include <cs50.h>
int main(void)
{
float f;
int i;
i=0;
do
{
f = get_float("Input Change: \n");
}
while(f<0);
// This do-while loop uses a get_float operator to get a postive input from the user.
while(f>=0.25)
{
f=f-0.25;
i=i+1;
}
// Each one of these loops represents using one kind of coin. For this one, every time it runs it adds
// one coin to the final tally and removes 25 cents from the change owed.
while(f>=0.10)
{
f=f-0.10;
i=i+1;
}
// Dime loop, subtracts ten from change owed.
while(f>=0.05)
{
f=f-0.0500000;
i=i+1;
}
// Nickel loop, subtracts five from change owed.
while(f>0)
{
f=f-0.01;
i=i+1;
}
// Penny loop, subtracts one from change owed.
printf("You need %i coins.%f\n", i, f);
//This just prints the number of coins needed.
}
The issue is that the last while loop we execute randomly even when there is no reason to do so. For example, $0.42 returns a correct value while $0.15 causes the last while loop to add an extra penny for no reason.
while(f>0)
{
f=f-0.01;
i=i+1;
}
(The problematic while loop in question)
I'm new to programming in general, so this is probably just a problem borne of me doing something stupid, but exactly what I'm doing wrong I do not know. Anyone encountered this before?
It's a precision problem. Equality with floats can be rather problematic. Even though in theory f=0 when you get to the last loop, this fails, and it enters the loop.
A possible workaround is to change it to some number between 0 and 0.01. E.g.
while(f>0.005)
But a better approach would be to use type int to represent money, each unit corresponding to a cent.
With floating point values it gets "weird" comparing them to other floats, like 5, 0.63, and 0.0 because your value may actually be 0.4999999999 or 0.000000000001, which is essentially zero, and in your case fails the condition test and thus adds a final penny when the value then truly goes negative. When comparing floats you must account for this by comparing the difference to some small epsilon value.
float epsilon = 0.0000001;
if ((f - testVal) < epsilon) {
...
}
Here's the body of my code
int OP, NP, first, second, third, blankets, remainder;
printf("How many people are knitting blanket squares at the beginning of the week?\n");
scanf("%d", &OP);
printf("How many new people are knitting blanket squares each day?\n");
scanf("%d", &NP);
//formula
first = 1 + NP;
second = pow(first,7);
third = OP * second;
blankets = third / (double)60;
remainder = third - blankets * 60;
printf("%d blanket squares will be made this week!\n", third);
printf("You will be able to make %d blankets and start next week with %d squares.", blankets, remainder);
This is sufficient except for when I enter a decimal (such as .5) in the place of NP. When I do that, I get an overflow and it outputs the value -2147483648 for the first printf. Is all I have to do change the data type? Sorry for a very simple question, I'm very new.
Doing floating point arithmetics with integers, could overflow the integers. That is possible, but unlikely. You also loose precision of course. You need to use at least float for this calculations.
The real problem:
Using scanf() incorrectly.
Passing a floating point value to scanf() where it expects an integer. It fails but you don't know, because of (1).
Using scanf() like that leads to undefined behavior, your variables NP and OP were never initialized. But you don't know that, because you didn't check the return value of scanf().
You MUST check it, like this
if (scanf("%d", &NP) != 1) {
fprintf(stderr, "Error, bad input, expecting an `int'.\n");
// Now, `NP' is not initialized unless it was before calling
// `scanf' so you can't continue using `NP' safely from
// this point
}
The same goes for OP.
If you want floating point values (and you do, because you say so in your question) use
float NP, OP;
if (scanf("%f", &NP) == 1) ...
I'm currently working on a banking terminal program for the laboratory exercises at my university.
What puts me off my stride is a function supposed to take the user's input of amount to be transfered, check if it fits all requirements and if so, returns the value provided to the program.
Our tutor is mad about all means of securing the input, and so I have to call an error on any kind of inconsistency. Value too high? Error. Negative or zero value? Error. A number more precise than 0.01? Error. Non-digit-non-dot characters in the input? Error.
Due to that, my function is definately overcomplicated, yet I'm fine with that. What drives me up the wall is the fact, that both atof() and strtod() functions reads numbers in a somehow wrong way.
long double take_amount()
{
char input[21];
bool success, correct;
unsigned long int control1;
long double amount, control, control2, control3;
do
{
success = true, correct = true;
printf("\t\tAmount:\t\t");
success = scanf("%20[^ \t\n]c", input);
__fpurge(stdin);
correct = check(input, 'b');
amount = strtod(input, NULL);
printf("\n\tGOT %.20Lf\n", amount); ///
control = amount * 100;
control1 = (unsigned long int)floor(control);
control2 = (long double) control1;
control3 = control2 - control;
printf("\n\tGOT2 %.20Lf\n", control3); ///
if (control3 != 0)
{
if (control3 >= 1 || control3 <= -1)
{
printf("\n\t\tWe are sorry, but for the safety reasons it is impossible to transfer");
printf("\n\t\tsuch a great amounts while online. If you really wish to finalize");
printf("\n\t\tthis operation, please, visit the closest division of our bank.");
printf("\n\t\tWe are sory for the inconvenience and wish you a pleasent day.");
press_enter();
}
correct = false;
printf("\nDAMN\n"); ///
}
if (amount <= 0)
{
correct = false;
printf("\nGOD DAMN\n"); ///
}
if(success == false || correct == false)
{
printf("\n\t\tInvalid input, please try again.\n\n");
}
else
{
printf("\t\t\t\t%.2Lf\n", amount);
printf("\n\t\tIs it correct input? ((Y)es/(N)o/(E)xit)");
if (accept())
{
break;
}
else
{
continue;
}
break;
}
}while (1);
return amount;
As far as my functions used here goes, check() checks if the string contains only legal characters (digits and dot), press_enter() waits for enter-press to leave to main menu and accept() reads only y/n/e, return true on y, false on n and leaves to menu on e.
The lengthy part with control variables is my solution for checking if the number is not more precise than 0.01. Sadly, it doesn't work due to strtod().
My problem is that strtod() doesn't really work! Even with really medicore numbers, being far from underflow or overflow, the value returned doesn't match the input. Some examples:
Enter the amount you would like to deposit.
Amount: 1234.45
GOT 1234.45000000000004547474
Enter the amount you would like to deposit.
Amount: 0.999
GOT 0.99899999999999999911
It is not unlikely that it's my fault, but after several hours with this code I still couldn't come up with a working solution and that's why I'm asking for you help, vise internauts of Stack Overflow.
Is there any way to fix the reading of strtod()? If not, is there another way to take that input that let's me check all that needs to be checked?
EDIT: ATTENTION, PLEASE!
If I haven't stated already, that my tutor is not the easiest guy to work with, I do so now.
He FORCES us to use DOUBLE format to hold the BALANCE stored on accounts. I know it because one of my collegues got his program REJECTED for using two-int, dollar - cent construction.
I highly appreciate you help here, so can you somehow solve that problem? I HAVE TO use double type to store the money. I also HAVE to check if there were no letters in the input (scanf() set on %Lf will just cut all non-digits from the end), HAVE TO check if the input is not more precise then 0.01, HAVE TO accept xxx.xx structure of the input. Any suggestions?
Use strtol to read the dollars and again (or just your own trivial function) to read the cents, then combine them as cents += 100*dollars; Do not use floating point for currency. Ever.
IEEE floating point numbers are meant to hold approximate values over a huge range, not precise values. They cannot represent some very simple values precisely, such as 0.1, but they can represent 1.0, 0.5, 0.25, 0.125, ... precisely. They can also represent 2.0, 4.0, 8.0, 16.0, ... precisely. How far these series go is related to how many bits the floating point value is represented by. You should have noticed that all of the examples values that I've given are powers of 2, and from that you should see that floating point values can also be made up of sums of powers of 2, which is mostly correct. Summing the values of 2 works well for representing whole numbers as the entire range from least to greatest can be represented by integer types, but with fractional values things are different. There are many values between the values that can be represented that are not expressible for a given floating point type (32, 64, 80, or 128 bit floating point variables), so when these are read in by C library functions (or by the compiler from your source code) there are rounding rules that come into play. A very similar thing happens when the numbers are written back out by a C program.
When you need to deal with precise values you must be aware of this. For money, which usually needs this type of precision, you will want to convert it to a type that can represent this type of precision. In many languages there are separate types for this, but in C you get to put the values into integer types or structs made up of integers.
Divide and Conquer
Separate user input from data validation.
User input:
Current code uses input without first validating success
success = scanf("%20[^ \t\n]c", input);
correct = check(input, 'b');
amount = strtod(input, NULL); // Bad: `input` not known to have been successfully scanned.
Instead:
char input[40]; // no need for tight buffer size
if (fgets(input, sizeof input, stdin) == NULL) Handle_EOF();
// remove potential trailing \n
input[strcspn(input, "\n")] = 0;
Now start assessing if input is a valid with various tests
char *endptr;
errno = 0;
double value = strtod(input, &endptr);
if (input == endptr) Handle_NothingScanned();
if (*endptr != '\0') Handle_GarbageAtEndOfInput();
// Use 1 of the 2: First allows input like 1e-1000 which underflows to 0.0
if (errno == ERANGE && fabs(value) > DBL_TRUE_MIN) Handle_Overflow();
if (errno == ERANGE) Handle_OverUnderflow();
// work with numbers in a reasonable range of 'double'
double max_range = pow(10.0, DBL_DIG - 2);
if (!(value >= -max_range && value <= max_range)) Handle_InfinityNotanumberOverflow();
// Test insures that the number entered is the closest possible `double` to xxxxxx.xx
// Method 1: Math
double rvalue = round(value*100.0)/100.0;
if (rvalue != value) Handle_NumberMorePreciseThan_0_01();
// Method 2: round trip: double --> string --> double
char buffer[DBL_DIG + 10];
sprintf(buffer, "%.2f", value);
if (value != strtod(buffer, 0)) Handle_NumberMorePreciseThan_0_01();
// Insure xxxx.xx format
if ((endptr - input) < 3 || endptr[-3] != '.') Handle_BadFormat();
GoodToUse(value);
This is a known "issue" with respect to how numbers are represented in floating point. The representation of 1234.45 in floating point IS what is being entered.
This is due to the fact that when translated into the floating point representation the actual precise string of bits is longer than the space used to store it (when dealing with a number that is not a power of two there is always a chance of this occurring.)
Another option that you can do is create a 'Currency' struct that holds two ints (the dollar part and the fractional part) and pass it around. You'll still need to handle the code for splitting the currency string into those parts though.
If the requirement to make use of a double number is strict then another property of floating point numbers may be of use: An arbitrary integer value stored in a floating point variable will be more likely to be precise than a number with a fractional component.
This fact leads me to ask: Have you thought of storing your currency values such that $1234.45 is 123445?
I'm trying to write a code that asks from the user to give 5 coefficients for a 5th-degree polynomial, and it also asks to give a range (two values) that the programs checks if there is a solution in it or not (I'm asked to find only one), and the solution must be an integer, while the coefficients can be floats.
I'm thinking of writing a code that runs over every integer in the range and substitute it in a description of a polynomial than I define, and check if its equal to zero, but I got stuck at deciding how to make the loops.
And another thing, if there are more than one root in the interval that the user enters, then we must print the minimal value of the roots (but I have no direction how to do that either).
I will show you what I wrote so far, and any kind of help would be appreciated:
#include <stdio.h>
#define zero 0.00001
int main()
{
double a, b, c , d , e , f , y , beginning_of_range, end_of_range;
int x;
printf("please enter the coefficients of the polynomial:\n");
scanf("%lf%lf%lf%lf%lf", &a, &b, &c, &d, &e);
printf("please enter two values to indicate the beginning and end of range:\n");
scanf("%lf%lf", &beginning_of_range, &end_of_range);
while (beginning_of_range > end_of_range)
{
printf("ERROR: the range you have entered isn't valid, please try again:");
scanf("%lf%lf", &beginning_of_range, &end_of_range);
}
while (beginning_of_range < end_of_range)
{
x = beginning_of_range;
y = a + b*x + c*x*x + d*x*x*x + e*x*x*x*x + f*x*x*x*x*x;
if (y == zero)
{
printf("the root is:%d", x);
}
else
{
x = x+1;
}
break;
}
return 0;
}
Your task as written is very questionable, so much so that there is perhaps a mis-interpretation or mis-communication.
A randomly given polynomial with floating point coefficients will have integer roots with probability so close to zero that it is practically impossible.
Even with integer coefficients it requires carefully reverse-engineered coefficients to get an integer root. Just change one coefficient by one and in most cases all roots will be irrational.
What you can do in your framework is to find intervals with a sign change so that there is at least one root inside the interval that can be found using one of bisection, regula falsi, Illinois, secant or Mullers methods. All of them derivative free.
Without identifying all roots, also the complex ones, it is rather hard to guarantee that all real roots have been found. Thus it is only approximately possible to find the smallest real root inside the given interval. There might be an integer interval with two real roots inside so that at the boundaries the sign is the same. You would have to analyse the signs of all derivatives at the integer points to make more reliable guesses in this case, see Descartes rule and Budan-Fourier theorem.
Your first while loop should probably be an if statement instead of a loop.
Your second (main) while loop never increments the beginning of range. This is probably causing an endless loop for you.