# Tag Info

## Hot answers tagged ceil

37

Math.ceil() will always round up, however you are doing integer division with 3/2. Thus, since in integer division 3/2 = 1 (not 1.5) the ceiling of 1 is 1. What you would need to do to achieve the results you want is Math.ceil(3/2.0); By doing the division by a double amount (2.0), you end up doing floating point division instead of integer division. ...

34

The range of double is greater than that of long. For example: double x = Long.MAX_VALUE; x = x * 1000; x = Math.ceil(x); What would you expect the last line to do if Math.ceil returned long? Note that at very large values (positive or negative) the numbers end up being distributed very sparsely - so the next integer greater than integer x won't be x + 1 ...

13

Why use external script languages? You get floor by default. To get ceil, do \$ divide=8; by=3; let result=(\$divide+\$by-1)/\$by; echo \$result 3 \$ divide=9; by=3; let result=(\$divide+\$by-1)/\$by; echo \$result 3 \$ divide=10; by=3; let result=(\$divide+\$by-1)/\$by; echo \$result 4 \$ divide=11; by=3; let result=(\$divide+\$by-1)/\$by; echo \$result 4 \$ divide=12; by=3; ...

10

In the C language, 0xfe is a hexadecimal int literal. Specifically, it is equal to 254, so the result is the double-precision value ceil(x) + 254.0. If you explicitly convert to int8_t or another 8-bit signed type, like so: (int8_t)0xfe then you may get the value -2, but this is not guaranteed by the standard. This is because 0xfe has the value 254, ...

10

First off, I note that you should always use decimal for this task; never use double. If you are using double, stop what you are doing right now and fix your program so that you stop using a type designed for physics problems and start using a type designed for money problems to solve your money problem. Second, you are simply wrong when you say This ...

9

After a night lost trying to solve this problem I believe I've found a rather simple solution, here it is: function bcceil(\$number) { if (strpos(\$number, '.') !== false) { if (preg_match("~\.[0]+\$~", \$number)) return bcround(\$number, 0); if (\$number[0] != '-') return bcadd(\$number, 1, 0); return bcsub(\$number, 0, 0); } ...

9

Since you're looking for fourths (.00, .25, .50, .75), multiply your number by 4, round to nearest whole number as desired (floor if down, ceil if up), then divide by 4. 1.32, down to nearest fourth: 1.32 * 4 = 5.28 floor(5.28) = 5.00 5.00 / 4 = 1.25 Same principle applies for any other fractions, such as thirds or eighths (.0, .125, .25, .375, ...

8

I don't know of any python function to do so, but you can easily code one : import math def ceil(x, s): return s * math.ceil(float(x)/s) The conversion to float is necessary in python 2 to avoid the integer division if both arguments are integers. You can also use from __future__ import division. This is not needed with python 3.

8

What's happening is this: \$n contains a floating point value, and thus is not exactly equal to 3, on my computer it's 3.00000000000000044409. Perl is smart enough to round that to 3 when printing it, but when you explicitly use a floating point function, it will do exactly what it advertises: ceil that to the next integral number: 4. This is a reality of ...

7

The problem here is that floating-point numbers cannot be reliably represented by computer. That means, 4.11 is not represented as 4.11, but something very close to it. And when this "very close to 4.11" number is multiplied by 100, the ceil of the product turns out to be 412, much to your surprise! But once you know how floating-point numbers are stored and ...

7

Check out http://www.php.net/manual/en/function.round.php <?php echo round(3.6451895227869, 2); ?> EDIT Try using this custom function http://www.php.net/manual/en/function.round.php#102641 <?php function round_up ( \$value, \$precision ) { \$pow = pow ( 10, \$precision ); return ( ceil ( \$pow * \$value ) + ceil ( \$pow * \$value - ceil ( ...

7

You can take apart the ingredients of an IEEE754 floating point number and implement the logic yourself: #include <cstring> float my_ceil(float f) { unsigned input; memcpy(&input, &f, 4); int exponent = ((input >> 23) & 255) - 127; if (exponent < 0) return (f > 0); // small numbers get rounded to 0 or 1, ...

7

The default rounding mode of DecimalFormat which is been used by <fmt:formatNumber> is RoundingMode.HALF_EVEN. There is no way to change that by some tag attribute. Just add 0.5 to the value to make it to behave like RoundingMode.CEILING. <fmt:formatNumber value="\${bean.number + 0.5}" type="number" pattern="#" />

6

I don't think it's possible. Regardless of the value of sqrt(a/b), what it produces is some value N that we use as: int s1 = ceil(N); int s2 = ceil(N) + 0.1; Since ceil always produces an integer value (albeit represented as a double), we will always have some value X, for which the first produces X.0 and the second X.1. Conversion to int will always ...

6

The most direct way to take the ceiling of a Decimal instance x is to use x.to_integral_exact(rounding=ROUND_CEILING). There's no need to mess with the context here. Note that this sets the Inexact and Rounded flags where appropriate; if you don't want the flags touched, use x.to_integral_value(rounding=ROUND_CEILING) instead. Example: >>> from ...

6

use strict; use warnings; use POSIX; my \$g = 6.65; my \$t = \$g * 4; my \$r = \$t - \$g; my \$n = \$r / \$g; # Should be exactly 3. # But it's not. print "Equals 3\n" if \$n == 3; # Check it more closely. printf "%.18f\n", \$n; # So ceil() is doing the right thing after all. my \$c = ceil(\$n); print "g=\$g t=\$t r=\$r n=\$n c=\$c\n";

6

Say you want to get a ceiling division a by b (in your example a = 1200 b = 500). You can do it in integer arithmetic like this. result = (a + b - 1) / b; Or you could use floating point numbers and do it like this (probably a bad idea) result = (int) ceil( (double) a / b ); The thing is that as this is a homework, you could just make it up in small ...

6

Since SAS time is actually a number of seconds since midnight, CEIL will give you start of next second. To get start of next minute, use INTNX function. data _null_; t='09:31:23.12'T; nextsecond=ceil(t); nextminute=intnx('minute', t, 1, 'BEGINNING'); put t= time12.2 nextsecond= time12.2 nextminute= time12.2; run; LOG: t=9:31:23.12 ...

6

This is guaranteed by the construction of IEEE-754 numbers. (To be clear: C does not guarantee IEEE-754, but the following analysis holds for all other floating-point formats with which I am familiar as well; the crucial property is that all sufficiently large numbers in the format are integers). Recall that a normal IEEE-754 number has the form ...

5

Obligatory Goldberg reference: What Every Computer Scientist Should Know About Floating-Point Arithmetic. Using Perl, the ability to treat a string as a number in a numerical operation turns into an advantage because you can easily use sprintf to explicitly specify the amount of precision you want: use strict; use warnings; use POSIX qw( ceil ); my \$g = ...

5

The wonderful world of floating point numbers: printf("%.18f\n", 40.7*100); //prints 4070.000000000000454747 printf("%.18f\n", 20.7*100); //prints 2070.000000000000000000 In short: floating point numbers cannot represent all rational numbers exactly. In particular, neither 407/10 nor 207/10 can be represented exactly, and so the result of integer ...

5

That is essentially what you have to do, but without converting to string. A floating-point number is represented as (+/-) M * 2^E. The exponent, E, tells you how far away you are from the binary point*. If E is big enough, there is no fractional part, so there's nothing to do. If E is small enough, there is no integer part, so the answer is 1 (assuming ...

5

At a guess, it's probably written in assembly language. It's basically done in three steps: Change rounding mode to "round up" round to integer (FRNDINT) restore previous rounding mode. Unfortunately, the code to change the rounding mode is fairly ugly. The rounding mode is a few bits in the floating point control register. You can't change the FPCR ...

5

The line d := float64(length / pagesize) transforms to float the result of the division. Since the division itself is integer division, it results in 4, so d = 4.0 and math.Ceil(d) is 4. Replace the line with d := float64(length) / float64(pagesize) and you'll have d=4.3 and int(math.Ceil(d))=5.

4

Not a Perl problem, as such #include <stdlib.h> #include <math.h> #include <stdio.h> main() { double n = (6.65 * 4.0 - 6.65) / 6.65; double c = ceil(n); printf("c is %g, n was %.18f\n", c, n); } c is 4, n was 3.000000000000000444

4

From the FAQ: [29.16] Why is floating point so inaccurate? Why doesn't this print 0.43? #include <iostream> int main() { float a = 1000.43; float b = 1000.0; std::cout << a - b << '\n'; ... } Disclaimer: Frustration with rounding/truncation/approximation isn't really a C++ issue; it's a computer science ...

4

This is just down to the inherent inaccuracy of floating point arithmetic. Two of your values are not exactly representable in binary floating point, 1.8 and -0.1. So, those numbers are approximated by the closest representable values. And that means that it's quite plausible that your equation won't evaluate to exactly 7. Now consider your two expressions: ...

3

This is correct behavior. See Unary Operator-() on zero values - c++ and http://en.wikipedia.org/wiki/Signed_zero I am partial to doing a static_cast<int>(ceil(-0.5)); but I don't claim that is "best practice". Edit: You could of course cast to whatever integral type was appropriate (uint64_t, long, etc.)

3

Some numbers (like 6.65) have an exact representation in decimal, but cannot be represented exactly in the binary floating point that computers use (just like 1/3 has no exact decimal representation). As a result, floating point numbers are frequently slightly different than what you would expect. The result of your calculation is not 3, but about ...

3

Here's ones that support negative numbers and precision argument for rounding. function bcceil(\$val) { if ((\$pos = strpos(\$val, '.')) !== false) { if (\$val[\$pos+1] != 0 && \$val[0] != '-') return bcadd(substr(\$val, 0, \$pos), 1, 0); else return substr(\$val, 0, \$pos); } return \$val; } function ...

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