poly-0.3.1.0: README.md
# poly [](https://travis-ci.org/Bodigrim/poly) [](https://hackage.haskell.org/package/poly) [](https://matrix.hackage.haskell.org/package/poly) [](http://stackage.org/lts/package/poly) [](http://stackage.org/nightly/package/poly)
Haskell library for univariate polynomials, backed by `Vector`.
```haskell
> (X + 1) + (X - 1) :: VPoly Integer
2 * X + 0
> (X + 1) * (X - 1) :: UPoly Int
1 * X^2 + 0 * X + (-1)
```
## Vectors
`Poly v a` is polymorphic over a container `v`, implementing `Vector` interface, and coefficients of type `a`. Usually `v` is either a boxed vector from `Data.Vector` or an unboxed vector from `Data.Vector.Unboxed`. Use unboxed vectors whenever possible, e. g., when coefficients are `Int` or `Double`.
There are handy type synonyms:
```haskell
type VPoly a = Poly Data.Vector.Vector a
type UPoly a = Poly Data.Vector.Unboxed.Vector a
```
## Construction
The simplest way to construct a polynomial is using the pattern `X`:
```haskell
> X^2 - 3 * X + 2 :: UPoly Int
1 * X^2 + (-3) * X + 2
```
(Unfortunately, a type is often ambiguous and must be given explicitly.)
While being convenient to read and write in REPL, `X` is relatively slow. The fastest approach is to use `toPoly`, providing it with a vector of coefficients (head is the constant term):
```haskell
> toPoly (Data.Vector.Unboxed.fromList [2, -3, 1 :: Int])
1 * X^2 + (-3) * X + 2
```
Alternatively one can enable `{-# LANGUAGE OverloadedLists #-}` and simply write
```haskell
> [2, -3, 1] :: UPoly Int
1 * X^2 + (-3) * X + 2
```
There is a shortcut to construct a monomial:
```haskell
> monomial 2 3.5 :: UPoly Double
3.5 * X^2 + 0.0 * X + 0.0
```
## Operations
Most operations are provided by means of instances, like `Eq` and `Num`. For example,
```haskell
> (X^2 + 1) * (X^2 - 1) :: UPoly Int
1 * X^4 + 0 * X^3 + 0 * X^2 + 0 * X + (-1)
```
One can also find convenient to `scale` by monomial (cf. `monomial` above):
```haskell
> scale 2 3.5 (X^2 + 1) :: UPoly Double
3.5 * X^4 + 0.0 * X^3 + 3.5 * X^2 + 0.0 * X + 0.0
```
While `Poly` cannot be made an instance of `Integral` (because there is no meaningful `toInteger`),
it is an instance of `GcdDomain` and `Euclidean` from `semirings` package. These type classes
cover main functionality of `Integral`, providing division with remainder and `gcd` / `lcm`:
```haskell
> Data.Euclidean.gcd (X^2 + 7 * X + 6) (X^2 - 5 * X - 6) :: Data.Poly.UPoly Int
1 * X + 1
> Data.Euclidean.quotRem (X^3 + 2) (X^2 - 1 :: Data.Poly.UPoly Double)
(1.0 * X + 0.0,1.0 * X + 2.0)
```
Miscellaneous utilities include `eval` for evaluation at a given value of indeterminate,
and reciprocals `deriv` / `integral`:
```haskell
> eval (X^2 + 1 :: UPoly Int) 3
10
> deriv (X^3 + 3 * X) :: UPoly Double
3.0 * X^2 + 0.0 * X + 3.0
> integral (3 * X^2 + 3) :: UPoly Double
1.0 * X^3 + 0.0 * X^2 + 3.0 * X + 0.0
```
## Deconstruction
Use `unPoly` to deconstruct a polynomial to a vector of coefficients (head is the constant term):
```haskell
> unPoly (X^2 - 3 * X + 2 :: UPoly Int)
[2,-3,1]
```
Further, `leading` is a shortcut to obtain the leading term of a non-zero polynomial,
expressed as a power and a coefficient:
```haskell
> leading (X^2 - 3 * X + 2 :: UPoly Double)
Just (2,1.0)
```
## Flavours
The same API is exposed in four flavours:
* `Data.Poly` provides dense polynomials with `Num`-based interface.
This is a default choice for most users.
* `Data.Poly.Semiring` provides dense polynomials with `Semiring`-based interface.
* `Data.Poly.Sparse` provides sparse polynomials with `Num`-based interface.
Besides that, you may find it easier to use in REPL
because of a more readable `Show` instance, skipping zero coefficients.
* `Data.Poly.Sparse.Semiring` provides sparse polynomials with `Semiring`-based interface.
All flavours are available backed by boxed or unboxed vectors.
## Performance
As a rough guide, `poly` is at least 20x-40x faster than [`polynomial`](http://hackage.haskell.org/package/polynomial) library.
Multiplication is implemented via Karatsuba algorithm.
Here is a couple of benchmarks for `UPoly Int`.
| Benchmark | polynomial, μs | poly, μs | speedup
| :---------------------------- | --------------: | -------: | ------:
| addition, 100 coeffs. | 45 | 2 | 22x
| addition, 1000 coeffs. | 441 | 17 | 25x
| addition, 10000 coeffs. | 6545 | 167 | 39x
| multiplication, 100 coeffs. | 1733 | 33 | 52x
| multiplication, 1000 coeffs. | 442000 | 1456 | 303x