The Monad.Reader/Issue5/Number Param Types
1 Number-parameterized types
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This paper describes practical programming with types parameterized by numbers: e.g., an array type parameterized by the array’s size or a modular group type `Zn` parameterized by the modulus. An attempt to add, for example, two integers of different moduli should result in a compile-time error with a clear error message. Number-parameterized types let the programmer capture more invariants through types and eliminate some run-time checks.
We review several encodings of the numeric parameter but concentrate on the phantom type representation of a sequence of decimal digits. The decimal encoding makes programming with number-parameterized types convenient and error messages more comprehensible. We implement arithmetic on decimal number-parameterized types, which lets us statically typecheck operations such as array concatenation.
Overall we demonstrate a practical dependent-type-like system that is just a Haskell library. The basics of the number-parameterized types are written in Haskell98.
Haskell, number-parameterized types, type arithmetic, decimal types, type-directed programming.
Discussions about types parameterized by values — especially types of arrays or finite groups parameterized by their size — reoccur every couple of months on functional programming languages newsgroups and mailing lists. The often expressed wish is to guarantee that, for example, we never attempt to add two vectors of different lengths. As one poster said, “This [feature] would be helpful in the crypto library where I end up having to either define new length Words all the time or using lists and losing the capability of ensuring I am manipulating lists of the same length.” Number-parameterized types as other more expressive types let us tell the typechecker our intentions. The typechecker may then help us write the code correctly. Many errors (which are often trivial) can be detected at compile time. Furthermore, we no longer need to litter the code with array boundary match checks. The code therefore becomes more readable, reliable, and fast. Number-parameterized types when expressed in signatures also provide a better documentation of the code and let the invariants be checked across module boundaries.In this paper, we develop realizations of number-parameterized types in Haskell that indeed have all the above advantages. The numeric parameter is specified in decimal rather than in binary, which makes types smaller and far easier to read. Type error messages also become more comprehensible. The programmer may write or the compiler can infer equality constraints (e.g., two argument vectors of a function must be of the same size), arithmetic constraints (e.g., one vector must be larger by some amount), and inequality constraints (e.g., the size of the argument vector must be at least one). The violations of the constraints are detected at compile time. We can remove run-time tag checks in functions like
Although we come close to the dependent-type programming, we do not extend either a compiler or the language. Our system is a regular Haskell library. In fact, the basic number-parameterized types can be implemented entirely in Haskell98. Advanced operations such as type arithmetic require commonly supported Haskell98 extensions to multi-parameter classes with functional dependencies and higher-ranked types.Our running example is arrays parameterized over their size. The parameter of the vector type is therefore a non-negative integer number. For simplicity, all the vectors in the paper are indexed from zero. In addition to vector constructors and element accessors, we define a
The present paper describes several gradually more sophisticated number-parameterized Haskell libraries. We start by paraphrasing the approach by Chris Okasaki, who represents the size parameter of vectors in a sequence of data constructors. We then switch to the encoding of the size in a sequence of type constructors. The resulting types are phantom and impose no run-time overhead. Section Encoding the number parameter in type constructors describes unary encoding of numerals in type constructors, sections Fixed-precision decimal types and Arbitrary-precision decimal types discuss decimal encodings. Section Fixed-precision decimal types introduces a type representation for fixed-precision decimal numbers. Section Arbitrary-precision decimal types removes the limitation on the maximal size of representable numbers, at a cost of a more complex implementation and of replacing commas with unsightly dollars signs. The decimal encoding is extendible to other bases, e.g., 16 or 64. The latter can be used to develop practical realizations of number-parameterized cryptographically interesting groups.
Section Computations with decimal types describes the first contribution of the paper. We develop addition and subtraction of “decimal types”, i.e., of the type constructor applications representing non-negative integers in decimal notation. The implementation is significantly different from that for more common unary numerals. Although decimal numerals are notably difficult to add, they make number-parameterized programming practical. We can now write arithmetic equality and inequality constraints on number-parameterized types.
Section Statically-sized vectors in a dynamic context briefly describes working with number-parameterized types when the numeric parameter, and even its upper bound, are not known until run time. We show one, quite simple technique, which assures a static constraint by a run-time check — witnessing. The witnessing code, which must be trustworthy, is notably compact. The section uses the method of blending of static and dynamic assurances that was first described in stanamic-trees.
Section Related work compares our approach with the phantom type programming in SML by Matthias Blume, with a practical dependent-type system of Hongwei Xi, with statically-sized and generic arrays in Pascal and C, with the shape inference in array-oriented languages, and with C++ template meta-programming. Section Conclusions concludes.
5 Encoding the number parameter in data constructors
The first approach to vectors parameterized by their size encodes the size as a series of data constructors. This approach has been used extensively by Chris Okasaki. For example, in Okasaki99 he describes square matrices whose dimensions can be proved equal at compile time. He digresses briefly to demonstrate vectors of statically known size. A similar technique has been described by McBride. In this section, we develop a more naive encoding of the size through data constructors, for introduction and comparison with the encoding of the size via type constructors in the following sections.
Our representation of vectors of a statically checked size is reminiscent of the familiar representation of lists:
data List a = Nil | Cons a (List a)
module UnaryDS where data VZero a = VZero deriving Show infixr 3 :+: data Vecp tail a = a :+: (tail a) deriving Show
To generically manipulate the family of differently-sized vectors, we define a class of polymorphic functions:
class Vec t where vlength:: t a -> Int vat:: t a -> Int -> a vzipWith:: (a->b->c) -> t a -> t b -> t c
instance Vec VZero where vlength = const 0 vat = error "null array or index out of range" vzipWith f a b = VZero instance (Vec tail) => Vec (Vecp tail) where vlength (_ :+: t) = 1 + vlength t vat (a :+: _) 0 = a vat (_ :+: ta) n = vat ta (n-1) vzipWith f (a :+: ta) (b :+: tb) = (f a b) :+: (vzipWith f ta tb)
That was the complete implementation of the number-parameterized vectors. We can now define a few sample vectors:
v3c = 'a' :+: 'b' :+: 'c' :+: VZero v3i = 1 :+: 2 :+: 3 :+: VZero v4i = 1 :+: 2 :+: 3 :+: 4 :+: VZero
and a few simple tests:
test1 = vlength v3c test2 = [vat v3c 0, vat v3c 1, vat v3c 2]
We can load the code into a Haskell system and run the tests. Incidentally, we can ask the Haskell system to tell us the inferred type of a sample vector:
*UnaryDS> :t v3c Vecp (Vecp (Vecp VZero)) Char
The inferred type indeed encodes the size of the vector as a Peano numeral. We can try more complex tests, of element-wise operations on two vectors:
test3 = vzipWith (\c i -> (toEnum $ fromEnum c + fromIntegral i)::Char) v3c v3i test4 = vzipWith (+) v3i v3i *UnaryDS> test3 'b' :+: ('d' :+: ('f' :+: VZero))
An attempt to add, by mistake, two vectors of different sizes is revealing:
test5 = vzipWith (+) v3i v4i Couldn't match `VZero' against `Vecp VZero' Expected type: Vecp (Vecp (Vecp VZero)) a Inferred type: Vecp (Vecp (Vecp (Vecp VZero))) a1 In the third argument of `vzipWith', namely `v4i' In the definition of `test5': vzipWith (+) v3i v4i
We get a type error, with a clear error message (the quoted message, here and elsewhere in the paper, is by GHCi. The Hugs error message is essentially the same). The typechecker, at the compile time, has detected that the sizes of the vectors to add elementwise do not match. To be more precise, the sizes are off by one.For vectors described in this section, the element access operation,
6 Encoding the number parameter in type constructors, in unary
To improve the efficiency of number-parameterized vectors, we choose a better run-time representation: Haskell arrays. The code in the present section is in Haskell98.
module UnaryT (..elided..) where import Data.Array
First, we need a type structure (an infinite family of types) to encode non-negative numbers. In the present section, we will use an unary encoding in the form of Peano numerals. The unary type encoding of integers belongs to programming folklore. It is also described in Blume01 in the context of a foreign-function interface library of SML.
data Zero = Zero data Succ a = Succ a
class Card c where c2num:: (Num a) => c -> a -- convert to a number cpred::(Succ c) -> c cpred = undefined instance Card Zero where c2num _ = 0 instance (Card c) => Card (Succ c) where c2num x = 1 + c2num (cpred x)
The same correspondence between the types and the terms suggests that the numeral type alone is enough to describe the size of a vector. We do not need to store the value of the numeral. The shape type of our vectors could be phantom (as in Blume01).
newtype Vec size a = Vec (Array Int a) deriving Show
listVec':: (Card size) => size -> [a] -> Vec size a listVec' size elems = Vec $ listArray (0,(c2num size)-1) elems listVec:: (Card size) => size -> [a] -> Vec size a listVec size elems | not (c2num size == length elems) = error "listVec: static/dynamic sizes mismatch" listVec size elems = listVec' size elems vec:: (Card size) => size -> a -> Vec size a vec size elem = listVec' size $ repeat elem
*UnaryT> listVec (Succ (Succ Zero)) [True,False] Vec (array (0,1) [(0,True),(1,False)])
A Haskell interpreter created the requested value, and printed it out. We can confirm that the inferred type of the vector encodes its size:
*UnaryT> :type listVec (Succ (Succ Zero)) [True,False] Vec (Succ (Succ Zero)) Bool
We can now introduce functions to operate on our vectors. The functions are similar to those in the previous section. As before, they are polymorphic in the shape of vectors (i.e., their sizes). This polymorphism is expressed differently however. In the present section we use just the parametric polymorphism rather than typeclasses.
vlength_t:: Vec size a -> size vlength_t _ = undefined vlength:: Vec size a -> Int vlength (Vec arr) = let (0,last) = bounds arr in last+1 velems:: Vec size a -> [a] velems (Vec v) = elems v vat:: Vec size a -> Int -> a vat (Vec arr) i = arr ! i vzipWith:: Card size => (a->b->c) -> Vec size a -> Vec size b -> Vec size c vzipWith f va vb = listVec' (vlength_t va) $ zipWith f (velems va) (velems vb)
infixl 3 &+ data VC size a = VC size [a] vs:: VC Zero a; vs = VC Zero  (&+):: VC size a -> a -> VC (Succ size) a (&+) (VC size lst) x = VC (Succ size) (x:lst) vc:: (Card size) => VC size a -> Vec size a vc (VC size lst) = listVec' size (reverse lst)
v3c = vc $ vs &+ 'a' &+ 'b' &+ 'c' v3i = vc $ vs &+ 1 &+ 2 &+ 3 v4i = vc $ vs &+ 1 &+ 2 &+ 3 &+ 4 test1 = vlength v3c; test1' = vlength_t v3c test2 = [vat v3c 0, vat v3c 1, vat v3c 2] test3 = vzipWith (\c i -> (toEnum $ fromEnum c + fromIntegral i)::Char) v3c v3i test4 = vzipWith (+) v3i v3i
We can run the tests as follows:
*UnaryT> test3 Vec (array (0,2) [(0,'b'),(1,'d'),(2,'f')]) *UnaryT> :type test3 Vec (Succ (Succ (Succ Zero))) Char
The type of the result bears the clear indication of the size of the vector. If we attempt to perform an element-wise operation on vectors of different sizes, for example:
test5 = vzipWith (+) v3i v4i Couldn't match `Zero' against `Succ Zero' Expected type: Vec (Succ (Succ (Succ Zero))) a Inferred type: Vec (Succ (Succ (Succ (Succ Zero)))) a1 In the third argument of `vzipWith', namely `v4i' In the definition of `test5': vzipWith (+) v3i v4i
we get a message from the typechecker that the sizes are off by one.
7 Fixed-precision decimal types
Peano numerals adequately represent the size of a vector in vector’s type. However, they make the notation quite verbose. We want to offer a programmer a familiar, decimal notation for the terms and the types representing non-negative numerals. This turns out possible even in Haskell98. In this section, we describe a fixed-precision notation, assuming that a programmer will never need a vector with more than 999 elements. The limit is not hard and can be readily extended. The next section will eliminate the limit altogether.
We again will be using Haskell arrays as the run-time representation for our vectors. In fact, the implementation of vectors is the same as that in the previous section. The only change is the use of decimal rather than unary types to describe the sizes of our vectors.
module FixedDecT (..export list elided..) where import Data.Array
Since we will be using the decimal notation, we need the terms and the types for all ten digits:
data D0 = D0 data D1 = D1 ... data D9 = D9
class Digit d where -- class of digits d2num:: (Num a) => d -> a -- convert to a number instance Digit D0 where d2num _ = 0 instance Digit D1 where d2num _ = 1 ... instance Digit D9 where d2num _ = 9 class Digit d => NonZeroDigit d instance NonZeroDigit D1 instance NonZeroDigit D2 ... instance NonZeroDigit D9
We define a class of non-negative numerals. We make all single-digit numerals the members of that class:
class Card c where c2num:: (Num a) => c -> a -- convert to a number -- Single-digit numbers are non-negative numbers instance Card D0 where c2num _ = 0 instance Card D1 where c2num _ = 1 ... instance Card D9 where c2num _ = 9
instance (NonZeroDigit d1,Digit d2) => Card (d1,d2) where c2num c = 10*(d2num $ t12 c) + (d2num $ t22 c) instance (NonZeroDigit d1,Digit d2,Digit d3) => Card (d1,d2,d3) where c2num c = 100*(d2num $ t13 c) + 10*(d2num $ t23 c) + (d2num $ t33 c)
*FixedDecT> vec (D0,D1) 'a' <interactive>:1: No instance for (NonZeroDigit D0)
t12::(a,b) -> a; t12 = undefined t22::(a,b) -> b; t22 = undefined ... t33::(a,b,c) -> c; t33 = undefined
The rest of the code is as before, e.g.:
newtype Vec size a = Vec (Array Int a) deriving Show listVec':: Card size => size -> [a] -> Vec size a listVec' size elems = Vec $ listArray (0,(c2num size)-1) elems
v12c = listVec (D1,D2) $ take 12 ['a'..'z'] v12i = listVec (D1,D2) [1..12] v13i = listVec (D1,D3) [1..13]
The decimal notation is so much convenient. We can now define long vectors without pain. As before, the type of our vectors — the size part of the type — looks precisely the same as the corresponding size term expression:
*FixedDecT> :type v12c Vec (D1, D2) Char
We can use the sample vectors in the tests like those of the previous section. If we attempt to elementwise add two vectors of different sizes, we get a type error:
test5 = vzipWith (+) v12i v13i Couldn't match `D2' against `D3' Expected type: Vec (D1, D2) a Inferred type: Vec (D1, D3) a1 In the third argument of `vzipWith', namely `v13i' In the definition of `test5': vzipWith (+) v12i v13i
The error message literally says that 12 is not equal to 13: the typechecker expected a vector of size 12 but found a vector of size 13 instead.
8 Arbitrary-precision decimal types
From the practical point of view, the fixed-precision number-parameterized vectors of the previous section are sufficient. The imposition of a limit on the width of the decimal numerals — however easily extended — is nevertheless intellectually unsatisfying. One may wish for an encoding of arbitrarily large decimal numbers within a framework that has been set up once and for all. Such an SML framework has been introduced in Blume01, to encode the sizes of arrays in their types. It is interesting to ask if such an encoding is possible in Haskell. The present section demonstrates a representation of arbitrary large decimal numbers in Haskell98. We also show that typeclasses in Haskell have made the encoding easier and precise: our decimal types are in bijection with non-negative integers. As before, we use the decimal types as phantom types describing the shape of number-parameterized vectors.
We start by defining the types for the ten digits:
module ArbPrecDecT (..export list elided..) where import Data.Array data D0 a = D0 a data D1 a = D1 a ... data D9 a = D9 a
class Digits ds where ds2num:: (Num a) => ds -> a -> a
data Sz = Sz -- zero size (or the Nil of the sequence) instance Digits Sz where ds2num _ acc = acc
We now inductively define arbitrarily long sequences of digits:
instance (Digits ds) => Digits (D0 ds) where ds2num dds acc = ds2num (t22 dds) (10*acc) instance (Digits ds) => Digits (D1 ds) where ds2num dds acc = ds2num (t22 dds) (10*acc + 1) ... instance (Digits ds) => Digits (D9 ds) where ds2num dds acc = ds2num (t22 dds) (10*acc + 9) t22::(f x) -> x; t22 = undefined
*ArbPrecDecT> :type D1$ D2$ D3$ D4$ D5$ D6$ D7$ D8$ D9$ D0$ D9$ D8$ D7$ D6$ D5$ D4$ D3$ D2$ D1$ Sz D1 (D2 (D3 (D4 (D5 (D6 (D7 (D8 (D9 (D0 (D9 (D8 (D7 (D6 (D5 (D4 (D3 (D2 (D1 Sz)))))))))))))))))) *ArbPrecDecT> ds2num (D1$ D2$ D3$ D4$ D5$ D6$ D7$ D8$ D9$ D0$ D9$ D8$ D7$ D6$ D5$ D4$ D3$ D2$ D1$ Sz) 0 1234567890987654321
*ArbPrecDecT> :type D1 True D1 Bool *ArbPrecDecT> :type (undefined::D1 Bool) D1 Bool
*ArbPrecDecT> ds2num (undefined::D1 Bool) 0 No instance for (Digits Bool) arising from use of `ds2num' at <interactive>:1 In the definition of `it': ds2num (undefined :: D1 Bool) 0
To guarantee the bijection between non-negative numbers and sequences of digits, we need to impose an additional restriction: the first, i.e., the major, digit of a sequence must be non-zero. Expressing such a restriction is surprisingly straightforward in Haskell, even Haskell98.
class (Digits c) => Card c where c2num:: (Num a) => c -> a c2num c = ds2num c 0 instance Card Sz instance (Digits ds) => Card (D1 ds) instance (Digits ds) => Card (D2 ds) ... instance (Digits ds) => Card (D9 ds)
newtype Vec size a = Vec (Array Int a) deriving Show
v12c = listVec (D1 $ D2 Sz) $ take 12 ['a'..'z'] v12i = listVec (D1 $ D2 Sz) [1..12] v13i = listVec (D1 $ D3 Sz) [1..13]
we should note a slight change of notation compared to the corresponding vectors of section Fixed-precision decimal types. The tests are not changed and continue to work as before:
test4 = vzipWith (+) v12i v12i *ArbPrecDecT> :type test4 Vec (D1 (D2 Sz)) Int *ArbPrecDecT> test4 Vec (array (0,11) [(0,2),(1,4),(2,6),...(11,24)])
test5 = vzipWith (+) v12i v13i Couldn't match `D2 Sz' against `D3 Sz' Expected type: Vec (D1 (D2 Sz)) a Inferred type: Vec (D1 (D3 Sz)) a1 In the third argument of `vzipWith', namely `v13i' In the definition of `test5': vzipWith (+) v12i v13i
The typechecker complains that 2 is not equal to 3: it found the vector of size 13 whereas it expected a vector of size 12. The decimal types make the error message very clear.We must again point out a significant difference of our approach from that of Blume01. We were able to state that only those types of digital sequences that start with a non-zero digit correspond to a non-negative number. SML, as acknowledged in Blume01, is unable to express such a restriction directly. The paper, therefore, prevents the user from building invalid decimal sequences by relying on the module system: by exporting carefully-designed value constructors. The latter use an auxiliary phantom type to keep track of “nonzeroness” of the major digit. Our approach does not incur such a complication. Furthermore, by the very inductive construction of the classes
*ArbPrecDecT> vec (D1$ D0$ D0$ True) 0 No instance for (Digits Bool) arising from use of `vec' at <interactive>:1 In the definition of `it': vec (D1 $ (D0 $ (D0 $ True))) 0 *ArbPrecDecT> vec (D0$ D1$ D0 Sz) 0 No instance for (Card (D0 (D1 (D0 Sz)))) arising from use of `vec' at <interactive>:1 In the definition of `it': vec (D0 $ (D1 $ (D0 Sz))) 0
9 Computations with decimal typesThe previous sections gave many examples of functions such as
class DigitsInReverse' df w dr | df w -> dr instance DigitsInReverse' Sz acc acc instance (Digits (d drest), DigitsInReverse' drest (d acc) dr) => DigitsInReverse' (d drest) acc dr
class DigitsInReverse df dr | df -> dr, dr -> df instance (DigitsInReverse' df Sz dr, DigitsInReverse' dr Sz df) => DigitsInReverse df dr
digits_rev:: (Digits ds, Digits dsr, DigitsInReverse ds dsr) => ds -> dsr digits_rev = undefined
It is again a compile-time function specified entirely by its type. Its body is therefore undefined. We can now run a few examples:
*ArbArithmT> :t digits_rev (D1$D2$D3 Sz) D3 (D2 (D1 Sz)) *ArbArithmT> :t (\v -> digits_rev v `asTypeOf` (D1$D2$D3 Sz)) D3 (D2 (D1 Sz)) -> D1 (D2 (D3 Sz))
class NoLeadingZeros d d0 | d -> d0 instance NoLeadingZeros Sz Sz instance (NoLeadingZeros d d') => NoLeadingZeros (D0 d) d' instance NoLeadingZeros (D1 d) (D1 d) ... instance NoLeadingZeros (D9 d) (D9 d)
We are now ready to build the addition machinery. We draw our inspiration from the computer architecture: the adder of an arithmetical-logical unit (ALU) of the CPU is constructed by chaining of so-called full-adders. A full-adder takes two summands and the carry-in and yields the result of the summation and the carry-out. In our case, the summands and the result are decimal rather than binary. Carry is still binary.
class FullAdder d1 d2 cin dr cout | d1 d2 cin -> cout, d1 d2 cin -> dr, d1 dr cin -> cout, d1 dr cin -> d2 where _unused:: (d1 xd1) -> (d2 xd2) -> cin -> (dr xdr) _unused = undefined
data Carry0 data Carry1 instance FullAdder D0 D0 Carry0 D0 Carry0 instance FullAdder D0 D0 Carry1 D1 Carry0 instance FullAdder D0 D1 Carry0 D1 Carry0 ... instance FullAdder D9 D8 Carry1 D8 Carry1 instance FullAdder D9 D9 Carry0 D8 Carry1 instance FullAdder D9 D9 Carry1 D9 Carry1
make_full_adder = mapM_ putStrLn [unwords $ doit d1 d2 cin | d1<-[0..9], d2<-[0..9], cin<-[0..1]] where doit d1 d2 cin = ["instance FullAdder", tod d1, tod d2, toc cin, tod d12, toc cout] where (d12,cout) = let sum = d1 + d2 + cin in if sum >= 10 then (sum-10,1) else (sum,0) tod n | (n >= 0 && 9 >= n) = "D" ++ (show n) toc 0 = "Carry0"; toc 1 = "Carry1"
That function is ready for Template Haskell. Currently we used a low-tech approach of cutting and pasting from an Emacs buffer with GHCi into the Emacs buffer with the code.We use
class DigitsSum ds1 ds2 cin dsr | ds1 ds2 cin -> dsr instance DigitsSum Sz Sz Carry0 Sz instance DigitsSum Sz Sz Carry1 (D1 Sz) instance (DigitsSum (D0 Sz) (d2 d2rest) cin (d12 d12rest)) => DigitsSum Sz (d2 d2rest) cin (d12 d12rest) instance (DigitsSum (d1 d1rest) (D0 Sz) cin (d12 d12rest)) => DigitsSum (d1 d1rest) Sz cin (d12 d12rest) instance (FullAdder d1 d2 cin d12 cout, DigitsSum d1rest d2rest cout d12rest) => DigitsSum (d1 d1rest) (d2 d2rest) cin (d12 d12rest)
class DigitsDif ds1 ds2 cin dsr | ds1 dsr cin -> ds2 instance DigitsDif Sz ds Carry0 ds instance (DigitsDif (D0 Sz) (d2 d2rest) Carry1 (d12 d12rest)) => DigitsDif Sz (d2 d2rest) Carry1 (d12 d12rest) instance (FullAdder d1 d2 cin d12 cout, DigitsDif d1rest d2rest cout d12rest) => DigitsDif (d1 d1rest) (d2 d2rest) cin (d12 d12rest)
class (Card c1, Card c2, Card c12) => CardSum c1 c2 c12 | c1 c2 -> c12, c1 c12 -> c2 instance (Card c1, Card c2, Card c12, DigitsInReverse c1 c1r, DigitsInReverse c2 c2r, DigitsSum c1r c2r Carry0 c12r, DigitsDif c1r c2r' Carry0 c12r, DigitsInReverse c2r' c2', NoLeadingZeros c2' c2, DigitsInReverse c12r c12) => CardSum c1 c2 c12
card_sum:: CardSum c1 c2 c12 => c1 -> c2 -> c12 card_sum = undefined
*ArbArithmT> :t card_sum (D1 Sz) (D9$D9 Sz) D1 (D0 (D0 Sz)) *ArbArithmT> :t \v -> card_sum (D1 Sz) v `asTypeOf` (D1$D0$D0 Sz) D9 (D9 Sz) -> D1 (D0 (D0 Sz)) *ArbArithmT> :t \v -> card_sum (D9$D9 Sz) v `asTypeOf` (D1$D0$D0 Sz) D1 Sz -> D1 (D0 (D0 Sz))
vappend va vb = listVec (card_sum (vlength_t va) (vlength_t vb)) $ (velems va) ++ (velems vb)
*ArbArithmT> :t vappend vappend :: (CardSum size size1 c12) => Vec size a -> Vec size1 a -> Vec c12 a
*ArbArithmT> :t vappend (vec (D2$D5 Sz) 0) (vec (D9$D7$D9 Sz) 0) (Num a) => Vec (D1 (D0 (D0 (D4 Sz)))) a
vhead:: CardSum (D1 Sz) size1 size => Vec size a -> Vec (D1 Sz) a vhead va = listVec (D1 Sz) $ [head (velems va)] vtail:: CardSum (D1 Sz) size1 size => Vec size a -> Vec size1 a vtail va = result where result = listVec (vlength_t result) $ tail (velems va)
We can now run a few examples. We note that the compiler could correctly infer the type of the result, which includes the size of the vector after appending or truncating it.
*ArbArithmT> let v = vappend (vec (D9 Sz) 0) (vec (D1 Sz) 1) *ArbArithmT> :t v Vec (D1 (D0 Sz)) Integer *ArbArithmT> v Vec (array (0,9) [(0,0),(1,0),...,(8,0),(9,1)]) *ArbArithmT> :type vhead v Vec (D1 Sz) Integer *ArbArithmT> :type vtail v Vec (D9 Sz) Integer *ArbArithmT> vtail v Vec (array (0,8) [(0,0),(1,0),...,(7,0),(8,1)]) *ArbArithmT> :type (vappend (vhead v) (vtail v)) Vec (D1 (D0 Sz)) Integer
*ArbArithmT> vtail (vec Sz 0) <interactive>:1:0: No instances for (DigitsInReverse' c2' Sz c2r', DigitsInReverse' c2r' Sz c2', DigitsDif (D1 Sz) c2r' Carry0 Sz, DigitsSum (D1 Sz) c2r Carry0 Sz, DigitsInReverse' c2r Sz size1, DigitsInReverse' size1 Sz c2r) arising from use of `vtail' at <interactive>:1:0-4
testc1 = let va = vec (D1$D2 Sz) 0 vb = vec (D5 Sz) 1 vc = vec (D8 Sz) 2 in vzipWith (+) va (vappend vb (vtail vc)) *ArbArithmT> testc1 Vec (array (0,11) [(0,1),...,(4,1),(5,2),(6,2),...,(11,2)])
Couldn't match `D9 Sz' against `D8 Sz' Expected type: D9 Sz Inferred type: D8 Sz When using functional dependencies to combine DigitsSum (D1 Sz) c2r Carry0 (D9 Sz), arising from use of `vtail' at ArbArithmT.hs:420:34-38 DigitsSum (D1 Sz) c2r Carry0 (D8 Sz), arising from use of `vtail' at ArbArithmT.hs:411:34-38
10 Statically-sized vectors in a dynamic context
In the present version of the paper, we demonstrate the simplest method of handling number-parameterized vectors in the dynamic context. The method involves run-time checks. The successful result of a run-time check is marked with the appropriate static type. Further computations can therefore rely on the result of the check (e.g., that the vector in question definitely has a particular size) and avoid the need to do that test over and over again. The net advantage is the reduction in the number of run-time checks. The complete elimination of the run-time checks is quite difficult (in general, may not even be possible) and ultimately requires a dependent type system.
For our presentation we use an example of dynamically-sized vectors: reversing a vector by the familiar accumulator-passing algorithm. Each iteration splits the source vector into the head and the tail, and prepends the head to the accumulator. The sizes of the vectors change in the course of the computation, to be precise, on each iteration. We treat vectors as if they were lists. Most of the vector processing code does not have such a degree of variation in vector sizes. The code is quite simple:
vreverse v = listVec (vlength_t v) $ reverse $ velems v
whose inferred type is obviously
*ArbArithmT> :t vreverse vreverse :: (Card size) => Vec size a -> Vec size a
testv = let v = vappend (vec (D3 Sz) 1) (vec (D1 Sz) 4) vr = vreverse v in vhead (vtail (vtail vr))
11 Related work
This paper was inspired by Matthias Blume’s messages on the newsgroup comp.lang.functional in February 2002. Many ideas of this paper were first developed during the USENET discussion, and posted in a series of three messages at that time. In more detail Matthias Blume described his method in Blume01, although that paper uses binary rather than decimal types of array sizes for clarity. The approaches by Matthias Blume and ours both rely on phantom types to encode additional information about a value (e.g., the size of an array) in a manner suitable for a typechecker. The paper exhibits the most pervasive and thorough use of phantom types: to represent the size of arrays and the constness of imported C values, to encode C structure tag names and C function prototypes.
However, paper was written in the context of SML, whereas we use Haskell. The language has greatly influenced the method of specifying and enforcing complex static constraints, e.g., that digit sequences representing non-negative numbers must not have leading zeros. The SML approach in Blume01 relies on the sophisticated module system of SML to restrict the availability of value constructors so that users cannot build values of outlawed types. Haskell typeclasses on the other hand can directly express the constraint, as we saw in section Arbitrary-precision decimal types. Furthermore, Haskell typeclasses let us specify arithmetic equality and inequality constraints — which, as admitted in Blume01, seems quite unlikely to be possible in SML.Arrays of a statically known size — whose size is a part of their type — are a fairly popular feature in programming languages. Such arrays are present in Fortran, Pascal, C . Pascal has the most complete realization of statically sized arrays. A Pascal compiler can therefore typecheck array functions like our
A different approach to array processing is a so-called shape-invariant programming, which is a key feature of array-oriented languages such as APL or SaC. These languages let a programmer define operations that can be applied to arrays of arbitrary shape/dimensionality. The code becomes shorter and free from explicit iterations, and thus more reusable, easier to read and to write. The exact shape of an array has to be known, eventually. Determining it at run-time is greatly inefficient. Therefore, high-performance array-oriented languages employ shape inference Scholz01, which tries to statically infer the dimensionalities or even exact sizes of all arrays in a program. Shape inference is, in general, undecidable, since arrays may be dynamically allocated. Therefore, one can either restrict the class of acceptable shape-invariant programs to a decidable subset, resort to a dependent-type language like Cayenne, or use “soft typing”. The latter approach is described in Scholz01, which introduces a non-unique type system based on a hierarchy of array types: from fully specialized ones with the statically known sizes and dimensionality, to a type of an array with the known dimensionality but not size, to a fully generic array type whose shape can only be determined at run-time. The system remains decidable because at any time the typechecker can throw up hands and give to a value a fully generic array type. Shape inference of SaC is specific to that language, whose type system is otherwise deliberately constrained: SaC lacks parametric polymorphism and higher-order functions. Using shape inference for compilation of shape-invariant array operations into a highly efficient code is presented in Kreye. Their compiler tries to generate as precise shape-specific code as possible. When the shape inference fails to give the exact sizes or dimensionalities, the compiler emits code for a dynamic shape dispatch and generic loops.There is however a great difference in goals and implementation between the shape inference of SaC and our approach. The former aims at accepting more programs than can statically be inferred shape-correct. We strive to express assertions about the array sizes and enforcing the programming style that assures them. We have shown the definitions of functions such as
The approach of the present paper comes close to emulating a dependent type system, of which Cayenne is the epitome. We were particularly influenced by a practical dependent type system of Hongwei Xi Xi98 XiThesis, which is a conservative extension of SML. In Xi98, Hongwei Xi et al. demonstrated an application of their system to the elimination of array bound checking and list tag checking. The related work section of that paper lists a number of other dependent and pseudo-dependent type systems. Using the type system to avoid unnecessary run-time checks is a goal of the present paper too.C++ templates provide parametric polymorphism and indexing of types by true integers. A C++ programmer can therefore define functions like
array code. The type system of C++ however presents innumerable hurdles to the functional style. For example, the result type of a function is not used for the overloading resolution, which significantly restricts the power of the type inference. Templates were introduced in C++ ad hoc, and therefore, are not well integrated with its type system. Violations of static constraints expressed via templates result in error messages so voluminous as to become incomprehensible.McBride gives an extensive survey of the emulation of dependent type systems in Haskell. He also describes number-parameterized arrays that are similar to the ones discussed in section Encoding the number parameter in data constructors. The paper by Fridlender and Indrika shows another example of emulating dependent types within the Hindley-Milner type system: namely, emulating variable-arity functions such as generic
Throughout this paper we have demonstrated several realizations of number-parameterized types in Haskell, using arrays parameterized by their size as an example. We have concentrated on techniques that rely on phantom types to encode the size information in the type of the array value. We have built a family of infinite types so that different values of the vector size can have their own distinct type. That type is a decimal encoding of the corresponding integer (rather than the more common unary, Peano-like encoding). The examples throughout the paper illustrate that the decimal notation for the number-parameterized vectors makes our approach practical.We have used the phantom size types to express non-trivial constraints on the sizes of the argument and the result arrays in the type of functions. The constraints include the size equality, e.g., the type of a function of two arguments may indicate that the arguments must be vectors of the same size. More importantly, we can specify arithmetical constraints: e.g., that the size of the vector after concatenation is the sum of the source vector sizes. Furthermore, we can write inequality constraints by means of an implicit existential quantification, e.g., the function
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