The java.lang.Math.ceil [] is used to find the smallest integer value that is greater than or equal to the argument or mathematical integer. Syntaxpublic static double ceil[double x] x= a value This method returns smallest floating-point value that is greater than or equal to the argument and is equal to a mathematical integer.
public class CeilExample1 { public static void main[String[] args] { double x = 83.56; // Input positive value, Output ceil value of x System.out.println[Math.ceil[x]]; } } Test it NowOutput: Example 2public class CeilExample2 { public static void main[String[] args] { double x = -94.73; // Input negative value, Output ceil value of x System.out.println[Math.ceil[x]]; } } Test it NowOutput: Example 3public class CeilExample3 { public static void main[String[] args] { double x = -1.0 / 0; // Input negative infinity, Output negative infinity System.out.println[Math.ceil[x]]; } } Test it NowOutput: Example 4public class CeilExample4 { public static void main[String[] args] { double x = 0.0; // Input positive zero, Output positive zero System.out.println[Math.ceil[x]]; } } Test it NowOutput: Example 5public class CeilExample5 { public static void main[String[] args] { double x = -0.25; // Input less than zero but greater than -1.0, Output negative zero System.out.println[Math.ceil[x]]; } } Test it NowOutput: Next TopicJava Math |
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The Math.ceil method is used to return the smallest integer greater than or equal to a given number. The ceil[] is always used as Math.ceil[] since it is a static method of Math.
Syntax:
Math.ceil[value]Parameters: This method accepts single parameters as mentioned above and described below:
- Value: It is the value that is to be tested for Math.ceil.
Return Value: The Math.ceil[] method returns the smallest integer greater than or equal to the given number.
Below is an example of the Math ceil[] Method.
Example:
console.log["Result : " + Math.ceil[.89]]; |
Output:
Result : 1Below examples illustrate the Math ceil[] method in JavaScript:
Example 1:
Input : Math.ceil[.89] Output: 1Example 2:
Input : Math.ceil[-89.02] Output : -89Example 3:
Input : Math.ceil[0] Output : 0More codes for the above method are as follows:
Program 1: When a negative number is passed as a parameter.
console.log["Result : " + Math.ceil[-89.02]]; |
Output:
Result : -89Program 2: When zero is passed as a parameter.
console.log["Result : " + Math.ceil[0]]; |
Output:
Result : 0Supported Browsers:
- Google Chrome
- Internet Explorer
- Firefox
- Opera
- Safari
Java has had several advanced usage application including working with complex calculations in physics, architecture/designing of structures, working with Maps and corresponding latitudes/longitudes, etc.
In this Java tutorial, you will learn:
All such applications require using complex calculations/equations that are tedious to perform manually. Programmatically, such calculations would involve usage of logarithms, trigonometry, exponential equations, etc.
Now, you cannot have all the log or trigonometry tables hard-coded somewhere in your application or data. The data would be enormous and complex to maintain.
Java provides a very useful class for this purpose. It is the Math java class [java.lang.Math].
This class provides methods for performing the operations like exponential, logarithm, roots and trigonometric equations too.
Let us have a look at the methods provided by the Java Math class.
The two most fundamental elements in Math are the ‘e’ [base of the natural logarithm] and ‘pi’ [ratio of the circumference of a circle to its diameter]. These two constants are often required in the above calculations/operations.
Hence the Math class java provides these two constants as double fields.
Math.E – having a value as 2.718281828459045
Math.PI – having a value as 3.141592653589793
A] Let us have a look at the table below that shows us the Basic methods and its description
abs | Returns the absolute value of the argument | Double, float, int, long |
round | Returns the closed int or long [as per the argument] | double or float |
ceil | Math ceil function in Java returns the smallest integer that is greater than or equal to the argument | Double |
floor | Java floor method returns the largest integer that is less than or equal to the argument | Double |
min | Returns the smallest of the two arguments | Double, float, int, long |
max | Returns the largest of the two arguments | Double, float, int, long |
Below is the code implementation of the above methods:
Note: There is no need to explicitly import java.lang.Math as its imported implicitly. All its methods are static.
Integer Variable
int i1 = 27; int i2 = -45;Double[decimal] variables
double d1 = 84.6; double d2 = 0.45;Java Math abs[] method with Example
Java Math abs[] method returns the absolute value of the argument.
public class Guru99 { public static void main[String args[]] { int i1 = 27; int i2 = -45; double d1 = 84.6; double d2 = 0.45; System.out.println["Absolute value of i1: " + Math.abs[i1]]; System.out.println["Absolute value of i2: " + Math.abs[i2]]; System.out.println["Absolute value of d1: " + Math.abs[d1]]; System.out.println["Absolute value of d2: " + Math.abs[d2]]; } }Output:
Absolute value of i1: 27 Absolute value of i2: 45 Absolute value of d1: 84.6 Absolute value of d2: 0.45Java Math.round[] method with Example
Math.round[] method in Java returns the closed int or long as per the argument. Below is the example of math.round Java method.
public class Guru99 { public static void main[String args[]] { double d1 = 84.6; double d2 = 0.45; System.out.println["Round off for d1: " + Math.round[d1]]; System.out.println["Round off for d2: " + Math.round[d2]]; } }Output:
Round off for d1: 85 Round off for d2: 0Java Math.ceil and Math.floor method with Example
The Math.ceil and Math.floor in Java methods are used to return the smallest and largest integer that are greater than or equal to the argument. Below is the Math floor and ceiling Java example.
public class Guru99 { public static void main[String args[]] { double d1 = 84.6; double d2 = 0.45; System.out.println["Ceiling of '" + d1 + "' = " + Math.ceil[d1]]; System.out.println["Floor of '" + d1 + "' = " + Math.floor[d1]]; System.out.println["Ceiling of '" + d2 + "' = " + Math.ceil[d2]]; System.out.println["Floor of '" + d2 + "' = " + Math.floor[d2]]; } }We will get the below output of the math.ceil in Java example.
Output:
Ceiling of '84.6' = 85.0 Floor of '84.6' = 84.0 Ceiling of '0.45' = 1.0 Floor of '0.45' = 0.0Java Math.min[] method with Example
The Java Math.min[] method returns the smallest of the two arguments.
public class Guru99 { public static void main[String args[]] { int i1 = 27; int i2 = -45; double d1 = 84.6; double d2 = 0.45; System.out.println["Minimum out of '" + i1 + "' and '" + i2 + "' = " + Math.min[i1, i2]]; System.out.println["Maximum out of '" + i1 + "' and '" + i2 + "' = " + Math.max[i1, i2]]; System.out.println["Minimum out of '" + d1 + "' and '" + d2 + "' = " + Math.min[d1, d2]]; System.out.println["Maximum out of '" + d1 + "' and '" + d2 + "' = " + Math.max[d1, d2]]; } }Output:
Minimum out of '27' and '-45' = -45 Maximum out of '27' and '-45' = 27 Minimum out of '84.6' and '0.45' = 0.45 Maximum out of '84.6' and '0.45' = 84.6B] Let us have a look at the table below that shows us the Exponential and Logarithmic methods and its description-
exp | Returns the base of natural log [e] to the power of argument | Double |
Log | Returns the natural log of the argument | double |
Pow | Takes 2 arguments as input and returns the value of the first argument raised to the power of the second argument | Double |
floor | Java math floor returns the largest integer that is less than or equal to the argument | Double |
Sqrt | Returns the square root of the argument | Double |
Below is the code implementation of the above methods: [The same variables are used as above]
public class Guru99 { public static void main[String args[]] { double d1 = 84.6; double d2 = 0.45; System.out.println["exp[" + d2 + "] = " + Math.exp[d2]]; System.out.println["log[" + d2 + "] = " + Math.log[d2]]; System.out.println["pow[5, 3] = " + Math.pow[5.0, 3.0]]; System.out.println["sqrt[16] = " + Math.sqrt[16]]; } }Output:
exp[0.45] = 1.568312185490169 log[0.45] = -0.7985076962177716 pow[5, 3] = 125.0 sqrt[16] = 4.0C] Let us have a look at the table below that shows us the Trigonometric methods and its description-
Sin | Returns the Sine of the specified argument | Double |
Cos | Returns the Cosine of the specified argument | double |
Tan | Returns the Tangent of the specified argument | Double |
Atan2 | Converts rectangular coordinates [x, y] to polar[r, theta] and returns theta | Double |
toDegrees | Converts the arguments to degrees | Double |
Sqrt | Returns the square root of the argument | Double |
toRadians | Converts the arguments to radians | Double |
Default Arguments are in Radians
Below is the code implementation:
public class Guru99 { public static void main[String args[]] { double angle_30 = 30.0; double radian_30 = Math.toRadians[angle_30]; System.out.println["sin[30] = " + Math.sin[radian_30]]; System.out.println["cos[30] = " + Math.cos[radian_30]]; System.out.println["tan[30] = " + Math.tan[radian_30]]; System.out.println["Theta = " + Math.atan2[4, 2]]; } }Output:
sin[30] = 0.49999999999999994 cos[30] = 0.8660254037844387 tan[30] = 0.5773502691896257 Theta = 1.1071487177940904Now, with the above, you can also design your own scientific calculator in java.