Difference between revisions of "Cookbook/Numbers"
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ceiling 3.1 --> 4 |
ceiling 3.1 --> 4 |
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floor 3.5 --> 3 |
floor 3.5 --> 3 |
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Revision as of 11:33, 23 April 2009
Numbers in Haskell can be of the type Int, Integer, Float, Double, or Rational.
Rounding numbers
| Problem | Solution | Examples |
|---|---|---|
| rounding | round | round 3.4 --> 3
round 3.5 --> 4
|
finding the nearest integer greater than or equal to x
|
ceiling | ceiling 3.1 --> 4
ceiling 4.0 --> 4
|
finding the nearest integer less than or equal to x
|
floor | floor 3.5 --> 3
floor 3.0 --> 3
|
Taking logarithms
log 2.718281828459045 --> 1.0
logBase 10 10000 --> 4.0
Generating random numbers
import System.Random
main = do
gen <- getStdGen
let ns = randoms gen :: [Int]
print $ take 10 ns
Binary representation of numbers
import Data.Bits
import Data.List (foldl')
-- Extract a range of bits, most-significant first
bitRange :: Bits a => a -> Int -> Int -> [Bool]
bitRange n lo hi = foldl' (\l -> \x -> testBit n x : l) [] [lo..hi]
-- Extract all bits, most-significant first
bits :: Bits a => a -> [Bool]
bits n = bitRange n 0 (bitSize n - 1)
-- Display a number in binary, including leading zeroes.
-- c.f. Numeric.showHex
showBits :: Bits a => a -> ShowS
showBits = showString . map (\b -> if b then '1' else '0') . bits
Using complex numbers
| Problem | Solution | Examples |
|---|---|---|
| creating a complex number from real and imaginary rectangular components | (:+) | import Complex
1.0 :+ 0.0 --> 1.0 :+ 0.0
|
| creating a complex number from polar components | mkPolar | import Complex
mkPolar 1.0 pi --> (-1.0) :+ 1.2246063538223773e-16
|