# Tag Info

## Hot answers tagged ghci

78

When you are stopped at a breakpoint in GHCi, you can access anything that's in scope. Let's say you have a function like this: foo :: Int -> Int foo x = g (x + 2) where g y = x^y You can set a breakpoint on foo and try calling it: > :break foo Breakpoint 1 activated at /tmp/Foo.hs:(2,1)-(3,17) > foo 42 Stopped at /tmp/Foo.hs:(2,1)-(3,17) ...

36

Because 1.1 and 3.3 are floating point numbers. Decimal fractions, such as .1 or .3, are not exactly representable in a binary floating point number. .1 means 1/10. To represent that in binary, where each fractional digit represents 1/2n (1/2, 1/4, 1/8, etc), you would need an infinite number of digits, 0.000110011... repeating infinitely. This is exactly ...

32

for guards (like your example), you can just put them all on one line and it works (guards do not care about spacing) let abs n | n >= 0 = n | otherwise = -n if you wanted to write your function with multiple definitions that pattern match on the arguments, like this: fact 0 = 1 fact n = n * fact (n-1) then you would use braces with semicolons ...

32

GHCi looks for its configuration file at ~/.ghc/ghci.conf on Unix-like systems. %APPDATA%\ghc\ghci.conf on Windows. The configuration file syntax is simple: it's a list of GHCi commands to execute on startup. For example, your ghci.conf could contain: import Control.Applicative import Data.Char import Data.List :set prompt "> " The last line sets ...

29

Is there a way provide type declarations in GHCi? let numUniques' :: (Eq a) => [a] -> Int; numUniques' = length . nub Or is there another way to define functions like these which doesn't require type declarations? If you turn off the monomorphism restriction with -XNoMonomorphismRestriction, it will infer the right type.

28

The two separate let statements are interpreted independently from each other. First a function ft 0 = 1 is defined, and then a new function ft n = n * ft (n - 1) is defined, overwriting the first definition. To define one function with two cases you have to put both cases into a single let statement. To do this in a single line at the GHCI prompt you can ...

28

Most of the time, you can rely on type inference to work out a signature for you. In your example, the following is sufficient: Prelude> let addTwo x y = x + y If you really want a definition with a type signature, or your definition spans over multiple lines, you can do this in ghci: Prelude> :{ Prelude| let addTwo :: Int -> Int -> Int ...

27

\$ runhaskell MyFile.hs Alternatively, runghc (they're the same thing). ghci MyFile.hs will also start an interactive REPL session with MyFile.hs loaded, but if you want to run a main program then runhaskell is the way to go. It's probably a good idea to get into the habit of testing parts of your program as isolated units in GHCi rather than running the ...

24

titaniumdecoy, I remember being helped with this sort of GHCi mystery when I learned the frequently made point that writing things like 'let square x = x * x' inside the GHCi is like writing let a = f b with do notation in the IO monad -- say in this sort of example: palindromize :: IO () palindromize = do a <- readFile "foo.txt" let b = reverse a ...

24

As far as I know, yes. But it doesn't have to be a big deal, you can do this inside ghci: Prelude Data.List> :set -hide-package mtl package flags have changed, resetting and loading new packages... Prelude> import Control.Monad.Cont Prelude Control.Monad.Cont> There was also a line-item on GHC-7 change log that made me think package imports ...

23

Sure. For a type class: Prelude> :i Enum class Enum a where succ :: a -> a pred :: a -> a toEnum :: Int -> a fromEnum :: a -> Int enumFrom :: a -> [a] enumFromThen :: a -> a -> [a] enumFromTo :: a -> a -> [a] enumFromThenTo :: a -> a -> a -> [a] -- Defined in `GHC.Enum' instance Enum Ordering -- ...

20

This is a quick and ugly hack, but what I usually do is just use the function in the wrong way and read the error message: inc x = x + 1 where f (y, z) = y + z g = f :: Char GHCi output: Couldn't match expected type `Char' against inferred type `(t, t) -> t' In the expression: f :: Char Although this leaves out the context Num t ...

19

From the help manual of ghci (http://www.haskell.org/ghc/docs/6.10.4/html/users_guide/interactive-evaluation.html): Such multiline commands can be used with any GHCi command, and the lines between :{ and :} are simply merged into a single line for interpretation. That implies that each such group must form a single valid command when merged, and that no ...

18

My guess is that you have defined a main function in your source file. If you have defined a main function, loading the module with :l test won't import any functions but main. In that case you can load it by prepending an asterix to the module name: :l *test. The reason is that the compiled binary will hide non-exported top-level functions. Prepending an ...

18

While programming in GHCi, you're like programming in IO monad with do syntax, so for example you can directly call a function with type of IO a, or use monadic bind syntax like r <- someIOFun. let is also a part of do so you can also use this. I think it's being desugared into let .. in <rest of the computation>, so for example when you do this: ...

17

GHC will also load any .ghci file it finds in the current directory. It's very useful to do per-project configuration of GHCi. This is an example from a project I work on: :set -isrc:dist/build/autogen :set -hide-package mtl The first is there to make sure that the modules generated by Cabal are easy to import. The second hides mtl since this ...

17

One way to hack this is to wrap GHCi into a shell wrapper that reads its stdout and unescapes Unicode characters. This is not the Haskell way of course, but it does the job :) For example, this is a wrapper ghci-esc that uses sh and python3 (3 is important here): #!/bin/sh ghci "\$@" | python3 -c ' import sys import re def tr(match): s = ...

16

Dan is correct, but :{ and :} must each appear on their own line: > :{ > let foo a b = a + > b > :} > :t foo foo :: (Num a) => a -> a -> a This also interacts with the layout rule, so when using do-notation it might be easier to use braces and semi-colons explicitly. For example, this definition fails: > :{ | let ...

16

\$ has lower precedence then : (and also anything else) so your function is parsing as (n : collatz') \$ (n `div` 2) This leads to your type error. The second argument of : expects a list but you are passing the collatz function instead. If you still want to avoid the parenthesis around the 3n+1 part you can do something like the following (n:) . collatz' ...

16

It's the Monomorphism restriction. When you define a value with a simple pattern binding (just the name, without any function arguments) and without a type signature, it gets a monomorphic type. Any type variables are tried to be disambiguated according to the defaulting rules, if that doesn't succeed you get a type error. In this case, the Num constrained ...

16

The comparison can take place before the LHS is completely calculated. As soon as filter has produced one element, /= is able to conclude that the list can't possibly be equal to [] and immediately return True. /= on lists is implemented something like this: (/=) :: Eq a => [a] -> [a] -> Bool [] /= [] = False [] /= (y:ys) = True (x:xs) ...

16

This is due to different buffering behaviour in GHCi and GHC. GHCi has stdin (standard input stream) using NoBuffering by default, and GHC-compiled binaries / runhaskell use LineBuffering by default. If you explicitly do hSetBuffering stdin NoBuffering in your Haskell program, you'll be able to reproduce the GHCi behaviour. If you do hSetBuffering stdin ...

15

In GHCi, each let statement introduces a new definition of ex, instead of multiple pattern cases as you expect. So it hangs because, when you enter ex 1 (sum [1..]) afterwards, only the final ex b x = b ** x version exists. If you want to define a function with multiple pattern cases in GHCi, you'll need to put it in a single let statement, like this: let ...

15

EDIT: Actually, I'm no longer sure. Several versions later, it seems that GLFW no longer works in GHCi on OS X. It turns out that GLFW+OpenGL fulfills all four requirements! You need to invoke ghci with ghci -framework Carbon. You need the EnableGUI.hs file, which you can get here. Note that you can't load it right into GHCi, you have to comiple it, ...

15

= is a special reserved symbol in Haskell meaning "is defined as". It is used to introduce definitions. That is, you use it to create new values and functions which may be referenced in the definitions of other values and functions. == is not a reserved symbol but just a run-of-the-mill function of type Eq a => a -> a -> Bool. It happens to be ...

14

The ? and ?? kinds refer to GHC extensions, specifically unboxed types. http://hackage.haskell.org/trac/ghc/wiki/IntermediateTypes has a diagram showing relationships between the extended kinds ? (all possible types), # (unboxed types), ?? (boxed or normal unboxed types — "least upper bound of # and *"), (#) (unboxed tuples, which can only be used in a ...

14

This is not a function code, it's function signature which can only be saved in a module along with function definition and the be loaded to GHCi. This signature means that you're going to define a function lucky which gets an Integer and returns a String. However if you're composing your functions using GHCi as interactive interpreter, you can let Haskell ...

14

The good news: Yes, there is a way to define a new instance within GHCi. The bad news: At the moment, the first step in doing so is "install a development snapshot of GHC". This has been an obvious bit of missing functionality in GHCi for quite a while. There was no inherent reason for it to be absent, but I assume it was somewhat difficult to implement ...

14

Let's do the same analysis: map :: (a -> b) -> [a] -> [b] And take :: Int -> [x] -> [x] But that actually means take :: Int -> ([x] -> [x]) So with a=Int and b=([x] -> [x]) you get map take :: [Int] -> [ [x] -> [x] ] A list of list functions!

14

This is Matlab >> sin(pi) ans = 1.2246e-016 And here's Python >>> from math import sin, pi >>> sin(pi) 1.2246467991473532e-16 You're running into the limits of floating point precision. I recommend having a read of What Every Computer Scientist Should Know About Floating Point Arithmetic. The e at the end of these numbers ...

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