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[#118] Add Eisenstein integers module #121

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421 changes: 421 additions & 0 deletions Math/NumberTheory/EisensteinIntegers.hs

Large diffs are not rendered by default.

29 changes: 11 additions & 18 deletions Math/NumberTheory/GaussianIntegers.hs
Original file line number Diff line number Diff line change
Expand Up @@ -46,6 +46,7 @@ import Math.NumberTheory.Primes.Types (PrimeNat(..))
import qualified Math.NumberTheory.Primes.Factorisation as Factorisation
import qualified Math.NumberTheory.Primes.Sieve as Sieve
import qualified Math.NumberTheory.Primes.Testing as Testing
import Math.NumberTheory.Utils (mergeBy)
import Math.NumberTheory.Utils.FromIntegral (integerToNatural)

infix 6 :+
Expand Down Expand Up @@ -73,17 +74,18 @@ instance Show GaussianInteger where
instance Num GaussianInteger where
(+) (a :+ b) (c :+ d) = (a + c) :+ (b + d)
(*) (a :+ b) (c :+ d) = (a * c - b * d) :+ (a * d + b * c)
abs z@(a :+ b)
| a == 0 && b == 0 = z -- origin
| a > 0 && b >= 0 = z -- first quadrant: (0, inf) x [0, inf)i
| a <= 0 && b > 0 = b :+ (-a) -- second quadrant: (-inf, 0] x (0, inf)i
| a < 0 && b <= 0 = (-a) :+ (-b) -- third quadrant: (-inf, 0) x (-inf, 0]i
| otherwise = (-b) :+ a -- fourth quadrant: [0, inf) x (-inf, 0)i
abs = fst . absSignum
negate (a :+ b) = (-a) :+ (-b)
fromInteger n = n :+ 0
signum z@(a :+ b)
| a == 0 && b == 0 = z -- hole at origin
| otherwise = z `divG` abs z
signum = snd . absSignum

absSignum :: GaussianInteger -> (GaussianInteger, GaussianInteger)
absSignum z@(a :+ b)
| a == 0 && b == 0 = (z, 0) -- origin
| a > 0 && b >= 0 = (z, 1) -- first quadrant: (0, inf) x [0, inf)i
| a <= 0 && b > 0 = (b :+ (-a), ι) -- second quadrant: (-inf, 0] x (0, inf)i
| a < 0 && b <= 0 = ((-a) :+ (-b), -1) -- third quadrant: (-inf, 0) x (-inf, 0]i
| otherwise = ((-b) :+ a, -ι) -- fourth quadrant: [0, inf) x (-inf, 0)i

-- |Simultaneous 'quot' and 'rem'.
quotRemG :: GaussianInteger -> GaussianInteger -> (GaussianInteger, GaussianInteger)
Expand Down Expand Up @@ -145,15 +147,6 @@ primes = (1 :+ 1): mergeBy (comparing norm) l r
l = [p :+ 0 | p <- leftPrimes]
r = [g | p <- rightPrimes, let x :+ y = findPrime p, g <- [x :+ y, y :+ x]]

mergeBy :: (a -> a -> Ordering) -> [a] -> [a] -> [a]
mergeBy cmp = loop
where
loop [] ys = ys
loop xs [] = xs
loop (x:xs) (y:ys)
= case cmp x y of
GT -> y : loop (x:xs) ys
_ -> x : loop xs (y:ys)

-- | Compute the GCD of two Gaussian integers. Result is always
-- in the first quadrant.
Expand Down
12 changes: 12 additions & 0 deletions Math/NumberTheory/UniqueFactorisation.hs
Original file line number Diff line number Diff line change
Expand Up @@ -24,6 +24,7 @@ import Data.Coerce
import qualified Math.NumberTheory.Primes.Factorisation as F (factorise)
import Math.NumberTheory.Primes.Testing.Probabilistic as T (isPrime)
import Math.NumberTheory.Primes.Types (Prime, Prm(..), PrimeNat(..))
import qualified Math.NumberTheory.EisensteinIntegers as E
import qualified Math.NumberTheory.GaussianIntegers as G
import Math.NumberTheory.Utils.FromIntegral

Expand Down Expand Up @@ -76,3 +77,14 @@ instance UniqueFactorisation G.GaussianInteger where

factorise 0 = []
factorise g = map (coerce *** intToWord) $ G.factorise g

newtype EisensteinPrime = EisensteinPrime { _unEisensteinPrime :: E.EisensteinInteger }
deriving (Eq, Show)

type instance Prime E.EisensteinInteger = EisensteinPrime

instance UniqueFactorisation E.EisensteinInteger where
unPrime = coerce

factorise 0 = []
factorise e = map (coerce *** intToWord) $ E.factorise e
16 changes: 15 additions & 1 deletion Math/NumberTheory/Utils.hs
Original file line number Diff line number Diff line change
Expand Up @@ -6,7 +6,7 @@
-- Stability: Provisional
-- Portability: Non-portable (GHC extensions)
--
-- Some utilities for bit twiddling.
-- Some utilities, mostly for bit twiddling.
--
{-# LANGUAGE CPP, MagicHash, UnboxedTuples, BangPatterns #-}
{-# OPTIONS_HADDOCK hide #-}
Expand All @@ -21,6 +21,8 @@ module Math.NumberTheory.Utils
, uncheckedShiftR
, splitOff
, splitOff#

, mergeBy
) where

#include "MachDeps.h"
Expand Down Expand Up @@ -173,3 +175,15 @@ splitOff# p n = go 0# n
(# q, 0## #) -> go (k +# 1#) q
_ -> (# k, m #)
{-# INLINABLE splitOff# #-}

-- | Merges two ordered lists into an ordered list. Checks for neither its
-- precondition or postcondition.
mergeBy :: (a -> a -> Ordering) -> [a] -> [a] -> [a]
mergeBy cmp = loop
where
loop [] ys = ys
loop xs [] = xs
loop (x:xs) (y:ys)
= case cmp x y of
GT -> y : loop (x:xs) ys
_ -> x : loop xs (y:ys)
3 changes: 3 additions & 0 deletions arithmoi.cabal
Original file line number Diff line number Diff line change
Expand Up @@ -57,6 +57,7 @@ library
Math.NumberTheory.ArithmeticFunctions.SieveBlock
Math.NumberTheory.ArithmeticFunctions.Standard
Math.NumberTheory.Curves.Montgomery
Math.NumberTheory.EisensteinIntegers
Math.NumberTheory.GaussianIntegers
Math.NumberTheory.GCD
Math.NumberTheory.GCD.LowLevel
Expand Down Expand Up @@ -137,6 +138,7 @@ test-suite spec
Math.NumberTheory.ArithmeticFunctions.MertensTests
Math.NumberTheory.ArithmeticFunctions.SieveBlockTests
Math.NumberTheory.CurvesTests
Math.NumberTheory.EisensteinIntegersTests
Math.NumberTheory.GaussianIntegersTests
Math.NumberTheory.GCDTests
Math.NumberTheory.Moduli.ChineseTests
Expand Down Expand Up @@ -189,6 +191,7 @@ benchmark criterion
semigroups >=0.8
other-modules:
Math.NumberTheory.ArithmeticFunctionsBench
Math.NumberTheory.EisensteinIntegersBench
Math.NumberTheory.GaussianIntegersBench
Math.NumberTheory.GCDBench
Math.NumberTheory.JacobiBench
Expand Down
2 changes: 2 additions & 0 deletions benchmark/Bench.hs
Original file line number Diff line number Diff line change
Expand Up @@ -3,6 +3,7 @@ module Main where
import Gauge.Main

import Math.NumberTheory.ArithmeticFunctionsBench as ArithmeticFunctions
import Math.NumberTheory.EisensteinIntegersBench as Eisenstein
import Math.NumberTheory.GaussianIntegersBench as Gaussian
import Math.NumberTheory.GCDBench as GCD
import Math.NumberTheory.JacobiBench as Jacobi
Expand All @@ -15,6 +16,7 @@ import Math.NumberTheory.SmoothNumbersBench as SmoothNumbers

main = defaultMain
[ ArithmeticFunctions.benchSuite
, Eisenstein.benchSuite
, Gaussian.benchSuite
, GCD.benchSuite
, Jacobi.benchSuite
Expand Down
26 changes: 26 additions & 0 deletions benchmark/Math/NumberTheory/EisensteinIntegersBench.hs
Original file line number Diff line number Diff line change
@@ -0,0 +1,26 @@
{-# OPTIONS_GHC -fno-warn-type-defaults #-}
{-# OPTIONS_GHC -fno-warn-orphans #-}

module Math.NumberTheory.EisensteinIntegersBench
( benchSuite
) where

import Control.DeepSeq
import Gauge.Main

import Math.NumberTheory.ArithmeticFunctions (tau)
import Math.NumberTheory.EisensteinIntegers

instance NFData EisensteinInteger

benchFindPrime :: Integer -> Benchmark
benchFindPrime n = bench (show n) $ nf findPrime n

benchTau :: Integer -> Benchmark
benchTau n = bench (show n) $ nf (\m -> sum [tau (x :+ y) | x <- [1..m], y <- [0..m]] :: Word) n

benchSuite :: Benchmark
benchSuite = bgroup "Eisenstein"
[ bgroup "findPrime" $ map benchFindPrime [1000003, 10000141, 100000039, 1000000021, 10000000033, 100000000003, 1000000000039, 10000000000051]
, bgroup "tau" $ map benchTau [10, 20, 40, 80]
]
207 changes: 207 additions & 0 deletions test-suite/Math/NumberTheory/EisensteinIntegersTests.hs
Original file line number Diff line number Diff line change
@@ -0,0 +1,207 @@
{-# OPTIONS_GHC -fno-warn-type-defaults #-}

-- |
-- Module: Math.NumberTheory.EisensteinIntegersTests
-- Copyright: (c) 2018 Alexandre Rodrigues Baldé
-- Licence: MIT
-- Maintainer: Alexandre Rodrigues Baldé <alexandrer_b@outlook.
-- Stability: Provisional
--
-- Tests for Math.NumberTheory.EisensteinIntegers
--

module Math.NumberTheory.EisensteinIntegersTests
( testSuite
) where

import qualified Math.NumberTheory.EisensteinIntegers as E
import Math.NumberTheory.Primes (primes)
import Test.Tasty (TestTree, testGroup)
import Test.Tasty.HUnit (Assertion, assertEqual,
testCase)

import Math.NumberTheory.TestUtils (Positive (..),
testSmallAndQuick)

-- | Check that @signum@ and @abs@ satisfy @z == signum z * abs z@, where @z@ is
-- an @EisensteinInteger@.
signumAbsProperty :: E.EisensteinInteger -> Bool
signumAbsProperty z = z == signum z * abs z

-- | Check that @abs@ maps an @EisensteinInteger@ to its associate in first
-- sextant.
absProperty :: E.EisensteinInteger -> Bool
absProperty z = isOrigin || (inFirstSextant && isAssociate)
where
z'@(x' E.:+ y') = abs z
isOrigin = z' == 0 && z == 0
-- The First sextant includes the positive real axis, but not the origin
-- or the line defined by the linear equation @y = (sqrt 3) * x@ in the
-- Cartesian plane.
inFirstSextant = x' > y' && y' >= 0
isAssociate = z' `elem` map (\e -> z * (1 E.:+ 1) ^ e) [0 .. 5]

-- | Verify that @divE@ and @modE@ are what `divModE` produces.
divModProperty1 :: E.EisensteinInteger -> E.EisensteinInteger -> Bool
divModProperty1 x y = y == 0 || (q == q' && r == r')
where
(q, r) = E.divModE x y
q' = E.divE x y
r' = E.modE x y

-- | Verify that @divModE` produces the right quotient and remainder.
divModProperty2 :: E.EisensteinInteger -> E.EisensteinInteger -> Bool
divModProperty2 x y = (y == 0) || (x `E.divE` y) * y + (x `E.modE` y) == x

-- | Verify that @divModE@ produces a remainder smaller than the divisor with
-- regards to the Euclidean domain's function.
modProperty1 :: E.EisensteinInteger -> E.EisensteinInteger -> Bool
modProperty1 x y = (y == 0) || (E.norm $ x `E.modE` y) < (E.norm y)

-- | Verify that @quotE@ and @reE@ are what `quotRemE` produces.
quotRemProperty1 :: E.EisensteinInteger -> E.EisensteinInteger -> Bool
quotRemProperty1 x y = (y == 0) || q == q' && r == r'
where
(q, r) = E.quotRemE x y
q' = E.quotE x y
r' = E.remE x y

-- | Verify that @quotRemE@ produces the right quotient and remainder.
quotRemProperty2 :: E.EisensteinInteger -> E.EisensteinInteger -> Bool
quotRemProperty2 x y = (y == 0) || (x `E.quotE` y) * y + (x `E.remE` y) == x

-- | Verify that @gcd z1 z2@ always divides @z1@ and @z2@.
gcdEProperty1 :: E.EisensteinInteger -> E.EisensteinInteger -> Bool
gcdEProperty1 z1 z2
= z1 == 0 && z2 == 0
|| z1 `E.remE` z == 0 && z2 `E.remE` z == 0 && z == abs z
where
z = E.gcdE z1 z2

-- | Verify that a common divisor of @z1, z2@ is a always divisor of @gcdE z1 z2@.
gcdEProperty2 :: E.EisensteinInteger -> E.EisensteinInteger -> E.EisensteinInteger -> Bool
gcdEProperty2 z z1 z2
= z == 0
|| (E.gcdE z1' z2') `E.remE` z == 0
where
z1' = z * z1
z2' = z * z2

-- | A special case that tests rounding/truncating in GCD.
gcdESpecialCase1 :: Assertion
gcdESpecialCase1 = assertEqual "gcdE" 1 $ E.gcdE (12 E.:+ 23) (23 E.:+ 34)

findPrimesProperty1 :: Positive Int -> Bool
findPrimesProperty1 (Positive index) =
let -- Only retain primes that are of the form @6k + 1@, for some nonzero natural @k@.
prop prime = prime `mod` 6 == 1
p = (!! index) $ filter prop $ drop 3 primes
in E.isPrime $ E.findPrime p

-- | Checks that the @norm@ of the Euclidean domain of Eisenstein integers
-- is multiplicative i.e.
-- @forall e1 e2 in Z[ω] . norm(e1 * e2) == norm(e1) * norm(e2)@.
euclideanDomainProperty1 :: E.EisensteinInteger -> E.EisensteinInteger -> Bool
euclideanDomainProperty1 e1 e2 = E.norm (e1 * e2) == E.norm e1 * E.norm e2

-- | Checks that the numbers produced by @primes@ are actually Eisenstein
-- primes.
primesProperty1 :: Positive Int -> Bool
primesProperty1 (Positive index) = all E.isPrime $ take index $ E.primes

-- | Checks that the infinite list of Eisenstein primes @primes@ is ordered
-- by the numbers' norm.
primesProperty2 :: Positive Int -> Bool
primesProperty2 (Positive index) =
let isOrdered :: [E.EisensteinInteger] -> Bool
isOrdered xs = all (\(x,y) -> E.norm x <= E.norm y) . zip xs $ tail xs
in isOrdered $ take index E.primes

-- | Checks that the numbers produced by @primes@ are all in the first
-- sextant.
primesProperty3 :: Positive Int -> Bool
primesProperty3 (Positive index) =
all (\e -> abs e == e) $ take index $ E.primes

-- | An Eisenstein integer is either zero or associated (i.e. equal up to
-- multiplication by a unit) to the product of its factors raised to their
-- respective exponents.
factoriseProperty1 :: E.EisensteinInteger -> Bool
factoriseProperty1 g = g == 0 || abs g == abs g'
where
factors = E.factorise g
g' = product $ map (uncurry (^)) factors

-- | Check that there are no factors with exponent @0@ in the factorisation.
factoriseProperty2 :: E.EisensteinInteger -> Bool
factoriseProperty2 z = z == 0 || all ((> 0) . snd) (E.factorise z)

-- | Check that no factor produced by @factorise@ is a unit.
factoriseProperty3 :: E.EisensteinInteger -> Bool
factoriseProperty3 z = z == 0 || all ((> 1) . E.norm . fst) (E.factorise z)

-- | Check that every prime factor in the factorisation is primary, excluding
-- @1 - ω@, if it is a factor.
factoriseProperty4 :: E.EisensteinInteger -> Bool
factoriseProperty4 z =
z == 0 ||
(all (\e -> e `E.modE` 3 == 2) $
filter (\e -> not $ elem e $ E.associates $ 1 E.:+ (-1)) $
map fst $ E.factorise z)

factoriseSpecialCase1 :: Assertion
factoriseSpecialCase1 = assertEqual "should be equal"
[(2 E.:+ 1, 3), (2 E.:+ 3, 1)]
(E.factorise (15 E.:+ 12))

testSuite :: TestTree
testSuite = testGroup "EisensteinIntegers" $
[ testSmallAndQuick "forall z . z == signum z * abs z" signumAbsProperty
, testSmallAndQuick "abs z always returns an @EisensteinInteger@ in the\
\ first sextant of the complex plane" absProperty
, testGroup "Division"
[ testSmallAndQuick "divE and modE work properly" divModProperty1
, testSmallAndQuick "divModE works properly" divModProperty2
, testSmallAndQuick "The remainder's norm is smaller than the divisor's"
modProperty1

, testSmallAndQuick "quotE and remE work properly" quotRemProperty1
, testSmallAndQuick "quotRemE works properly" quotRemProperty2
]

, testGroup "g.c.d."
[ testSmallAndQuick "The g.c.d. of two Eisenstein integers divides them"
gcdEProperty1
, testSmallAndQuick "A common divisor of two Eisenstein integers always\
\ divides the g.c.d. of those two integers"
gcdEProperty2
, testCase "g.c.d. (12 :+ 23) (23 :+ 34)" gcdESpecialCase1
]
, testSmallAndQuick "The Eisenstein norm function is multiplicative"
euclideanDomainProperty1
, testGroup "Primality"
[ testSmallAndQuick "Eisenstein primes found by the norm search used in\
\ findPrime are really prime"
findPrimesProperty1
, testSmallAndQuick "Eisenstein primes generated by `primes` are actually\
\ primes"
primesProperty1
, testSmallAndQuick "The infinite list of Eisenstein primes produced by\
\ `primes` is ordered. "
primesProperty2
, testSmallAndQuick "All generated primes are in the first sextant"
primesProperty3
]

, testGroup "Factorisation"
[ testSmallAndQuick "factorise produces correct results"
factoriseProperty1
, testSmallAndQuick "factorise produces no factors with exponent 0"
factoriseProperty2
, testSmallAndQuick "factorise produces no unit factors"
factoriseProperty3
, testSmallAndQuick "factorise only produces primary primes"
factoriseProperty4
, testCase "factorise 15:+12" factoriseSpecialCase1
]
]
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