Copyright	(c) 2014 diagrams-lib team (see LICENSE)
License	BSD-style (see LICENSE)
Maintainer	diagrams-discuss@googlegroups.com
Safe Haskell	Safe-Inferred
Language	Haskell2010

Diagrams.Size

Contents

Size spec

Description

Utilities for working with sizes of objects.

Synopsis

data SizeSpec v n
mkSizeSpec :: (Functor v, Num n) => v (Maybe n) -> SizeSpec v n
dims :: v n -> SizeSpec v n
absolute :: (Additive v, Num n) => SizeSpec v n
getSpec :: (Functor v, Num n, Ord n) => SizeSpec v n -> v (Maybe n)
specToSize :: (Foldable v, Functor v, Num n, Ord n) => n -> SizeSpec v n -> v n
requiredScale :: (Additive v, Foldable v, Fractional n, Ord n) => SizeSpec v n -> v n -> n
requiredScaling :: (Additive v, Foldable v, Fractional n, Ord n) => SizeSpec v n -> v n -> Transformation v n
sized :: (InSpace v n a, HasLinearMap v, Transformable a, Enveloped a) => SizeSpec v n -> a -> a
sizedAs :: (InSpace v n a, SameSpace a b, HasLinearMap v, Transformable a, Enveloped a, Enveloped b) => b -> a -> a
sizeAdjustment :: (Additive v, Foldable v, OrderedField n) => SizeSpec v n -> BoundingBox v n -> (v n, Transformation v n)

Size spec

data SizeSpec v n Source #

A SizeSpec is a way of specifying a size without needed lengths for all the dimensions.

Instances

Instances details

Functor v => Functor (SizeSpec v) Source #
Instance details Defined in Diagrams.Size Methods fmap :: (a -> b) -> SizeSpec v a -> SizeSpec v b # (<$) :: a -> SizeSpec v b -> SizeSpec v a #
Generic (SizeSpec v n) Source #
Instance details Defined in Diagrams.Size Associated Types type Rep (SizeSpec v n) :: Type -> Type # Methods from :: SizeSpec v n -> Rep (SizeSpec v n) x # to :: Rep (SizeSpec v n) x -> SizeSpec v n #
Show (v n) => Show (SizeSpec v n) Source #
Instance details Defined in Diagrams.Size Methods showsPrec :: Int -> SizeSpec v n -> ShowS # show :: SizeSpec v n -> String # showList :: [SizeSpec v n] -> ShowS #
Eq (v n) => Eq (SizeSpec v n) Source #
Instance details Defined in Diagrams.Size Methods (==) :: SizeSpec v n -> SizeSpec v n -> Bool # (/=) :: SizeSpec v n -> SizeSpec v n -> Bool #
Hashable (v n) => Hashable (SizeSpec v n) Source #
Instance details Defined in Diagrams.Size Methods hashWithSalt :: Int -> SizeSpec v n -> Int # hash :: SizeSpec v n -> Int #
type Rep (SizeSpec v n) Source #
Instance details Defined in Diagrams.Size type Rep (SizeSpec v n) = D1 ('MetaData "SizeSpec" "Diagrams.Size" "diagrams-lib-1.4.6.2-52M5Lvgpw038v92AxYP61g" 'True) (C1 ('MetaCons "SizeSpec" 'PrefixI 'False) (S1 ('MetaSel ('Nothing :: Maybe Symbol) 'NoSourceUnpackedness 'NoSourceStrictness 'DecidedLazy) (Rec0 (v n))))
type N (SizeSpec v n) Source #
Instance details Defined in Diagrams.Size type N (SizeSpec v n) = n
type V (SizeSpec v n) Source #
Instance details Defined in Diagrams.Size type V (SizeSpec v n) = v

Making size spec

mkSizeSpec :: (Functor v, Num n) => v (Maybe n) -> SizeSpec v n Source #

Make a SizeSpec from a vector of maybe values. Any negative values will be ignored. For 2D SizeSpecs see mkWidth and mkHeight from Diagrams.TwoD.Size.

dims :: v n -> SizeSpec v n Source #

Make a SizeSpec from a vector. Any negative values will be ignored.

absolute :: (Additive v, Num n) => SizeSpec v n Source #

A size spec with no hints to the size.

Extracting size specs

getSpec :: (Functor v, Num n, Ord n) => SizeSpec v n -> v (Maybe n) Source #

Retrieve a size spec as a vector of maybe values. Only positive sizes are returned.

specToSize :: (Foldable v, Functor v, Num n, Ord n) => n -> SizeSpec v n -> v n Source #

specToSize n spec extracts a size from a SizeSpec sz. Any values not specified in the spec are replaced by the smallest of the values that are specified. If there are no specified values (i.e. absolute) then n is used.

Functions on size specs

requiredScale :: (Additive v, Foldable v, Fractional n, Ord n) => SizeSpec v n -> v n -> n Source #

requiredScale spec sz returns the largest scaling factor to make something of size sz fit the requested size spec without changing the aspect ratio. sz should be non-zero (otherwise a scale of 1 is returned). For non-uniform scaling see boxFit.

requiredScaling :: (Additive v, Foldable v, Fractional n, Ord n) => SizeSpec v n -> v n -> Transformation v n Source #

Return the Transformation calcuated from requiredScale.

sized :: (InSpace v n a, HasLinearMap v, Transformable a, Enveloped a) => SizeSpec v n -> a -> a Source #

Uniformly scale any enveloped object so that it fits within the given size. For non-uniform scaling see boxFit.

sizedAs :: (InSpace v n a, SameSpace a b, HasLinearMap v, Transformable a, Enveloped a, Enveloped b) => b -> a -> a Source #

Uniformly scale an enveloped object so that it "has the same size as" (fits within the width and height of) some other object.

sizeAdjustment :: (Additive v, Foldable v, OrderedField n) => SizeSpec v n -> BoundingBox v n -> (v n, Transformation v n) Source #

Get the adjustment to fit a BoundingBox in the given SizeSpec. The vector is the new size and the transformation to position the lower corner at the origin and scale to the size spec.