Copyright | (C) 2013-2016 University of Twente 2022 Google Inc. |
---|---|
License | BSD2 (see the file LICENSE) |
Maintainer | Christiaan Baaij <christiaan.baaij@gmail.com> |
Safe Haskell | Trustworthy |
Language | Haskell2010 |
Extensions |
|
Synopsis
- data Bit
- high :: Bit
- low :: Bit
- data BitVector (n :: Nat)
- size# :: KnownNat n => BitVector n -> Int
- maxIndex# :: KnownNat n => BitVector n -> Int
- bLit :: String -> ExpQ
- hLit :: String -> ExpQ
- oLit :: String -> ExpQ
- (++#) :: KnownNat m => BitVector n -> BitVector m -> BitVector (n + m)
- (+>>.) :: forall n. KnownNat n => Bit -> BitVector n -> BitVector n
- (.<<+) :: forall n. KnownNat n => BitVector n -> Bit -> BitVector n
- bitPattern :: String -> Q Pat
Bit
A single bit
NB: The usual Haskell method of converting an integral numeric type to
another, fromIntegral
, is not well suited for Clash as it will go through
Integer
which is arbitrarily bounded in HDL. Instead use
bitCoerce
and the Resize
class.
Instances
Construction
Initialisation
BitVector
data BitVector (n :: Nat) Source #
A vector of bits
- Bit indices are descending
Num
instance performs unsigned arithmetic.
NB: The usual Haskell method of converting an integral numeric type to
another, fromIntegral
, is not well suited for Clash as it will go through
Integer
which is arbitrarily bounded in HDL. Instead use
bitCoerce
and the Resize
class.
BitVector has the type role
>>>
:i BitVector
type role BitVector nominal ...
as it is not safe to coerce between different sizes of BitVector. To change
the size, use the functions in the Resize
class.
Instances
Accessors
Length information
Construction
bLit :: String -> ExpQ Source #
Create a binary literal
>>>
$(bLit "1001")
0b1001
NB: You can also just write:
>>>
0b1001 :: BitVector 4
0b1001
The advantage of bLit
is that you can use computations to create the
string literal:
>>>
import qualified Data.List as List
>>>
$(bLit (List.replicate 4 '1'))
0b1111
Also bLit
can handle don't care bits:
>>>
$(bLit "1.0.")
0b1.0.
NB: From Clash 1.6 an onwards bLit
will deduce the size of the
BitVector from the given string and annotate the splice it produces
accordingly.
hLit :: String -> ExpQ Source #
Create a hexadecimal literal
>>>
$(hLit "dead")
0b1101_1110_1010_1101
Don't care digits set 4 bits:
>>>
$(hLit "de..")
0b1101_1110_...._....
oLit :: String -> ExpQ Source #
Create an octal literal
>>>
$(oLit "5234")
0b1010_1001_1100
Don't care digits set 3 bits:
>>>
$(oLit "52..")
0b1010_10.._....
Concatenation
(++#) :: KnownNat m => BitVector n -> BitVector m -> BitVector (n + m) Source #
Concatenate two BitVector
s
Modification
Pattern matching
bitPattern :: String -> Q Pat Source #
Template Haskell macro for generating a pattern matching on some bits of a value.
This macro compiles to an efficient view pattern that matches the
bits of a given value against the bits specified in the
pattern. The scrutinee can be any type that is an instance of the
Num
, Bits
and Eq
typeclasses.
The bit pattern is specified by a string which contains:
'0'
or'1'
for matching a bit'.'
for bits which are not matched (wildcard)'_'
can be used as a separator similar to the NumericUnderscores language extension- lowercase alphabetical characters can be used to bind some bits to variables.
For example
"0aab11bb"
will bind two variablesaa :: BitVector 2
andbbb :: BitVector 3
with their values set by the corresponding bits
The following example matches a byte against two bit patterns where
some bits are relevant and others are not while binding two variables aa
and bb
:
decode :: Unsigned 8 -> Maybe Bool decode $(bitPattern "00.._.110") = Just True decode $(bitPattern "10.._0001") = Just False decode $(bitPattern "aa.._b0b1") = Just (aa + bb > 1) decode _ = Nothing