Go language provides inbuilt support for basic constants and mathematical functions to perform operations on the numbers with the help of the math package. You are allowed to find the binary exponent of the specified number with the help of Logb() function provided by the math package. So, you need to add a math package in your program with the help of the import keyword to access Logb() function.
Syntax:
func Logb(a float64) float64
- If you pass +Inf or -Inf in this function, then this function will return +Inf.
- If you pass 0 in this function, then this function will return -Inf.
- If you pass NaN in this function, then this function will return NaN.
Example 1:
// Golang program to illustrate how to find the // binary exponent of the given number package main import ( "fmt"
"math"
) // Main function func main() { // Finding binary exponent
// of the given number
// Using Logb() function
res_1 := math.Logb(0)
res_2 := math.Logb(1)
res_3 := math.Logb(math.Inf(1))
res_4 := math.Logb(math.NaN())
res_5 := math.Logb(36)
// Displaying the result
fmt.Printf( "Result 1: %.1f" , res_1)
fmt.Printf( "\nResult 2: %.1f" , res_2)
fmt.Printf( "\nResult 3: %.1f" , res_3)
fmt.Printf( "\nResult 4: %.1f" , res_4)
fmt.Printf( "\nResult 5: %.1f" , res_5)
} |
Output:
Result 1: -Inf Result 2: 0.0 Result 3: +Inf Result 4: NaN Result 5: 5.0
Example 2:
// Golang program to illustrate how to find the // binary exponent of the given number package main import ( "fmt"
"math"
) // Main function func main() { // Finding binary exponent
// of the given number
// Using Logb() function
nvalue_1 := math.Logb(100)
nvalue_2 := math.Logb(26)
res := nvalue_1 + nvalue_2
fmt.Printf( "%.5f + %.5f = %.5f" ,
nvalue_1, nvalue_2, res)
} |
Output:
6.00000 + 4.00000 = 10.00000
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