------------------------------------------------------------------------ -- | -- Module : Data.Datamining.Clustering.SOMInternal -- Copyright : (c) Amy de Buitléir 2012-2013 -- License : BSD-style -- Maintainer : amy@nualeargais.ie -- Stability : experimental -- Portability : portable -- -- A module containing private @SOM@ internals. Most developers should -- use @SOM@ instead. This module is subject to change without notice. -- ------------------------------------------------------------------------ {-# LANGUAGE TypeFamilies, FlexibleContexts, FlexibleInstances, MultiParamTypeClasses, DeriveGeneric #-} module Data.Datamining.Clustering.SOMInternal where import qualified Data.Foldable as F (Foldable, foldr) import Data.List (foldl', minimumBy) import Data.Ord (comparing) import qualified Math.Geometry.Grid as G (Grid(..)) import qualified Math.Geometry.GridMap as GM (GridMap(..)) import Data.Datamining.Pattern (Pattern(..)) import Data.Datamining.Clustering.Classifier(Classifier(..)) import GHC.Generics (Generic) import Prelude hiding (lookup) -- | A Self-Organising Map (SOM). -- -- Although @SOM@ implements @GridMap@, most users will only need the -- interface provided by @Data.Datamining.Clustering.Classifier@. If -- you chose to use the @GridMap@ functions, please note: -- -- 1. The functions @adjust@, and @adjustWithKey@ do not increment the -- counter. You can do so manually with @incrementCounter@. -- -- 2. The functions @map@ and @mapWithKey@ are not implemented (they -- just return an @error@). It would be problematic to implement -- them because the input SOM and the output SOM would have to have -- the same @Metric@ type. data SOM gm k p = SOM { sGridMap :: gm p, sLearningFunction :: Int -> Int -> Metric p, sCounter :: Int } deriving Generic instance (F.Foldable gm) => F.Foldable (SOM gm k) where foldr f x g = F.foldr f x (sGridMap g) instance (G.Grid (gm p)) => G.Grid (SOM gm k p) where type Index (SOM gm k p) = G.Index (gm p) type Direction (SOM gm k p) = G.Direction (gm p) indices = G.indices . sGridMap distance = G.distance . sGridMap neighbours = G.neighbours . sGridMap contains = G.contains . sGridMap viewpoint = G.viewpoint . sGridMap directionTo = G.directionTo . sGridMap tileCount = G.tileCount . sGridMap null = G.null . sGridMap nonNull = G.nonNull . sGridMap instance (F.Foldable gm, GM.GridMap gm p, G.Grid (GM.BaseGrid gm p)) => GM.GridMap (SOM gm k) p where type BaseGrid (SOM gm k) p = GM.BaseGrid gm p toGrid = GM.toGrid . sGridMap toMap = GM.toMap . sGridMap mapWithKey = error "Not implemented" adjustWithKey f k s = s { sGridMap=gm' } where gm = sGridMap s gm' = GM.adjustWithKey f k gm currentLearningFunction :: SOM gm k p -> (Int -> Metric p) currentLearningFunction s = (sLearningFunction s) (sCounter s) -- | Extracts the grid and current models from the SOM. toGridMap :: GM.GridMap gm p => SOM gm k p -> gm p toGridMap = sGridMap adjustNode :: (Pattern p, G.Grid g, k ~ G.Index g) => g -> (Int -> Metric p) -> p -> k -> k -> p -> p adjustNode g f target bmu k = makeSimilar target (f d) where d = G.distance g bmu k -- | Trains the specified node and the neighbourood around it to better -- match a target. -- Most users should use @train@, which automatically determines -- the BMU and trains it and its neighbourhood. trainNeighbourhood :: (Pattern p, G.Grid (gm p), GM.GridMap gm p, G.Index (GM.BaseGrid gm p) ~ G.Index (gm p)) => SOM gm k p -> G.Index (gm p) -> p -> SOM gm k p trainNeighbourhood s bmu target = s { sGridMap=gm' } where gm = sGridMap s gm' = GM.mapWithKey (adjustNode gm f target bmu) gm f = currentLearningFunction s incrementCounter :: SOM gm k p -> SOM gm k p incrementCounter s = setCounter (sCounter s + 1) s counter :: SOM gm k p -> Int counter = sCounter setCounter :: Int -> SOM gm k p -> SOM gm k p setCounter k s = s { sCounter = k } justTrain :: (Ord (Metric p), Pattern p, G.Grid (gm p), GM.GridMap gm (Metric p), GM.GridMap gm p, G.Index (GM.BaseGrid gm (Metric p)) ~ G.Index (gm p), G.Index (GM.BaseGrid gm p) ~ G.Index (gm p)) => SOM gm k p -> p -> SOM gm k p justTrain s p = trainNeighbourhood s bmu p where ds = GM.toList . GM.map (p `difference`) . sGridMap $ s bmu = fst . minimumBy (comparing snd) $ ds instance (GM.GridMap gm p, k ~ G.Index (GM.BaseGrid gm p), Pattern p, G.Grid (gm p), GM.GridMap gm (Metric p), k ~ G.Index (gm p), k ~ G.Index (GM.BaseGrid gm (Metric p)), Ord (Metric p)) => Classifier (SOM gm) k p where toList = GM.toList . sGridMap numModels = G.tileCount . sGridMap models = GM.elems . sGridMap differences s p = GM.toList . GM.map (p `difference`) . sGridMap $ s trainBatch s = incrementCounter . foldl' justTrain s reportAndTrain s p = (bmu, ds, incrementCounter s') where ds = differences s p bmu = fst . minimumBy (comparing snd) $ ds s' = trainNeighbourhood s bmu p -- | Creates a classifier with a default (bell-shaped) learning -- function. Usage is @'defaultSOM' gm r0 rf w0 wf tf@, where: -- -- [@gm@] The geometry and initial models for this classifier. -- A reasonable choice here is @'lazyGridMap' g ps@, where @g@ is a -- @'HexHexGrid'@, and @ps@ is a set of random patterns. -- -- [@r0@] See description in @'decayingGaussian2'@. -- -- [@rf@] See description in @'decayingGaussian2'@. -- -- [@w0@] See description in @'decayingGaussian2'@. -- -- [@wf@] See description in @'decayingGaussian2'@. -- -- [@tf@] See description in @'decayingGaussian2'@. defaultSOM :: Floating (Metric p) => gm p -> Metric p -> Metric p -> Metric p -> Metric p -> Int -> SOM gm k p defaultSOM gm r0 rf w0 wf tf = SOM { sGridMap=gm, sLearningFunction=decayingGaussian2 r0 rf w0 wf tf, sCounter=0 } -- | Creates a classifier with a custom learning function. -- Usage is @'customSOM' gm g@, where: -- -- [@gm@] The geometry and initial models for this classifier. -- A reasonable choice here is @'lazyGridMap' g ps@, where @g@ is a -- @'HexHexGrid'@, and @ps@ is a set of random patterns. -- -- [@f@] A function used to adjust the models in the classifier. -- This function will be invoked with two parameters. -- The first parameter will indicate how many patterns (or pattern -- batches) have previously been presented to this classifier. -- Typically this is used to make the learning rate decay over time. -- The second parameter to the function is the grid distance from -- the node being updated to the BMU (Best Matching Unit). -- The output is the learning rate for that node (the amount by -- which the node's model should be updated to match the target). -- The learning rate should be between zero and one. customSOM :: gm p -> (Int -> Int -> Metric p) -> SOM gm k p customSOM gm f = SOM { sGridMap=gm, sLearningFunction=f, sCounter=0 } -- | Configures one possible learning function for classifiers. -- @'decayingGaussian' r0 w0 tMax@ returns a bell curve-shaped -- function. At time zero, the maximum learning rate (applied to the -- BMU) is @r0@, and the neighbourhood width is @w0@. Over time the -- neighbourhood width shrinks and the learning rate tapers off. decayingGaussian :: Floating a => a -> a -> Int -> (Int -> Int -> a) decayingGaussian r w0 tMax t d = r * s * exp (-(d'*d')/(2*w0*w0*s*s)) where s = exp (-t'/tMax') t' = fromIntegral t tMax' = fromIntegral tMax d' = fromIntegral d -- | Configures a typical learning function for classifiers. -- @'decayingGaussian' r0 rf w0 wf tf@ returns a bell curve-shaped -- function. At time zero, the maximum learning rate (applied to the -- BMU) is @r0@, and the neighbourhood width is @w0@. Over time the -- bell curve shrinks and the learning rate tapers off, until at time -- @tf@, the maximum learning rate (applied to the BMU) is @rf@, -- and the neighbourhood width is @wf@. Normally the parameters -- should be chosen such that: -- -- * 0 < rf << r0 < 1 -- -- * 0 < wf << w0 -- -- where << means "is much smaller than" (not the Haskell @<<@ -- operator!) decayingGaussian2 :: Floating a => a -> a -> a -> a -> Int -> (Int -> Int -> a) decayingGaussian2 r0 rf w0 wf tf t d = r * exp (-(d'*d')/(w*w)) where a = t'/tf' r = r0 * ((rf/r0)**a) w = w0 * ((wf/w0)**a) t' = fromIntegral t tf' = fromIntegral tf d' = fromIntegral d