| Safe Haskell | None |
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Quipper.Labels
Contents
Description
This module provides functionality for labelling endpoints in wires. The goal is to achieve two things:
- Label qubits individually. For example, we would like to label three qubits (a, b, c) as "a", "b", and "c", respectively.
- Label data structures all at once. For example, if a=[x,y,z] is a piece of quantum data, and we label this data structure "a", then the individual qubits will be labelled: x = a[0], y = a[1], z = a[2].
We can also combine both methods to arbitrary nesting levels. For example, we can label (([x,y,z], t), [u,v,w]) as ("a", ["u", "v", "w"]), to get the labelling x = a[0,0], y = a[0,1], z = a[0,2], t = a[1], u = u, v = v, w = w.
- type IndexList = (String, [String])
- indexlist_format :: IndexList -> String
- indexlist_empty :: IndexList
- indexlist_subscript :: IndexList -> String -> IndexList
- indexlist_dotted :: IndexList -> String -> IndexList
- newtype LabelMonad a = LabelMonad {
- getLabelMonad :: IndexList -> (Map Wire String, a)
- labelmonad_get_indexlist :: LabelMonad IndexList
- labelmonad_put_binding :: Wire -> String -> LabelMonad ()
- labelmonad_with_indexlist :: IndexList -> LabelMonad a -> LabelMonad a
- labelmonad_run :: LabelMonad () -> Map Wire String
- label_wire :: Wire -> String -> LabelMonad ()
- with_index :: String -> LabelMonad () -> LabelMonad ()
- with_dotted_index :: String -> LabelMonad () -> LabelMonad ()
- indexed :: LabelMonad () -> String -> LabelMonad ()
- dotted_indexed :: LabelMonad () -> String -> LabelMonad ()
- label_empty :: LabelMonad ()
- class Labelable a s where
- label_rec :: a -> s -> LabelMonad ()
- mklabel :: Labelable a s => a -> s -> [(Wire, String)]
- comment :: String -> Circ ()
- label :: Labelable qa labels => qa -> labels -> Circ ()
- comment_with_label :: Labelable qa labels => String -> qa -> labels -> Circ ()
Helper functions
Indices
type IndexList = (String, [String])Source
An index list is something that can be appended to a string. We consider subscript indices of the form "[i]", dotted indices of the form ".i", and perhaps arbitrary suffixes. A complication is that we want consecutive subscript indices to be combined, as in "[i,j,k]". We therefore need a special data structure to hold an index list "under construction".
An index list consists of a string and a list of current subscripts. For efficiency, the list of subscripts is reversed, i.e., the most recent subscript is at the head of the list.
indexlist_format :: IndexList -> StringSource
Convert an index list to a string.
indexlist_empty :: IndexListSource
The empty index list.
indexlist_subscript :: IndexList -> String -> IndexListSource
Append a subscript to an index list.
indexlist_dotted :: IndexList -> String -> IndexListSource
Append a dotted index to an index list.
The LabelMonad monad
newtype LabelMonad a Source
A monad to provide a convenient syntax for specifying Labelable
instances. Computations in this monad have access to a read-only
"current index list", and they output a binding from wires to
strings.
Constructors
| LabelMonad | |
Fields
| |
Instances
labelmonad_get_indexlist :: LabelMonad IndexListSource
Get the current string and index.
labelmonad_put_binding :: Wire -> String -> LabelMonad ()Source
Output a binding for a label
labelmonad_with_indexlist :: IndexList -> LabelMonad a -> LabelMonad aSource
Run a subcomputation with a new current index list.
labelmonad_run :: LabelMonad () -> Map Wire StringSource
Extract a labelling from a label monad computation. This is the run function of the label monad.
Formatting of labels
label_wire :: Wire -> String -> LabelMonad ()Source
Label a wire with the given name, using the current index.
with_index :: String -> LabelMonad () -> LabelMonad ()Source
Run a subcomputation with a subscript index appended to the current index list. Sample usage:
with_index "0" $ do <<<labelings>>>
with_dotted_index :: String -> LabelMonad () -> LabelMonad ()Source
Run a subcomputation with a dotted index appended to the current index list. Sample usage:
with_dotted_index "left" $ do <<<labelings>>>
indexed :: LabelMonad () -> String -> LabelMonad ()Source
Like with_index, except the order of the arguments is
reversed. This is intended to be used as an infix operator:
<<<labeling>>> `indexed` "0"
dotted_indexed :: LabelMonad () -> String -> LabelMonad ()Source
Like with_dotted_index, except the order of the arguments is
reversed. This is intended to be used as an infix operator:
<<<labeling>>> `dotted_indexed` "left"
label_empty :: LabelMonad ()Source
Do nothing.
The Labelable type class
class Labelable a s whereSource
Labelable a s means that a is a data structure that can
be labelled with the format s. A "format" is a string, or a
data structure with strings at the leaves.
Methods
label_rec :: a -> s -> LabelMonad ()Source
Recursively label a data structure with the given format.
Instances
mklabel :: Labelable a s => a -> s -> [(Wire, String)]Source
Given a data structure and a format, return a list of labelled wires.
High-level functions
comment :: String -> Circ ()Source
Insert a comment in the circuit. This is not a gate, and has no effect, except to mark a spot in the circuit. How the comment is displayed depends on the printing backend.
label :: Labelable qa labels => qa -> labels -> Circ ()Source
Label qubits in the circuit. This is not a gate, and has no effect, except to make the circuit more readable. How the labels are displayed depends on the printing backend. This can take several different forms. Examples:
Label q as q and r as r:
label (q,r) ("q", "r")
Label a, b, and c as a, b, and c, respectively:
label [a,b,c] ["a", "b", "c"]
Label q as x[0] and r as x[1]:
label (q,r) "x"
Label a, b, and c as x[0], x[1], x[2]:
label [a,b,c] "x"
comment_with_label :: Labelable qa labels => String -> qa -> labels -> Circ ()Source
Defining new Labelable instances
A Labelable instance should be defined for each new instance of
QCData. The general idea is that the structure of the label
should exactly follow the structure of the data being labeled,
except that at any level the label can be a string (which will then
be decorated with appropriate subscripts for each leaf in the
data structure).
In practice, there are two cases to consider: adding a new
QCData constructor, and adding a new atomic QCData.
- New
QCshapeconstructors
Consider the case of a new QCData constructor:
instance (QCData a) => QCData (Constructor a).
There are two required Labelable instances. The first instance
deals with a label that is a string, and takes the following form:
instance (Labelable a String) => Labelable (Constructor a) String where
label_rec as s = do
label_rec <<<a1>>> s `indexed` <<<index1>>>
...
label_rec <<<an>>> s `indexed` <<<indexn>>>
Here, a1...an are the components of the data
structure, and index1...indexn/ are the
corresponding subscripts. The function indexed appends a
subscript of the form "[i]". There is a similar function
dotted_indexed, which appends a subscript of the form ".i".
The second required instance deals with a label that is a data structure of the same shape as the data being labeled. It takes the form:
instance (Labelable a s) => Labelable (Constructor a) (Constructor s) where
label_rec as ss idx = do
label_rec <<<a1>>> <<<s1>>>
...
label_rec <<<an>>> <<<sn>>>
Here, a1...an are the components of the data structure, and s1...sn are the corresponding components of the label.
- Example
As a concrete example, consider a constructor
data MaybeTwo a = One a | Two a a instance (QCData a) => QCData (MaybeTwo a)
The following instance declarations would be appropriate:
instance (Labelable a String) => Labelable (MaybeTwo a) String where
label_rec (One x) s =
with_dotted_index "one" $ do
label_rec x s
label_rec (Two x y) s =
with_dotted_index "two" $ do
label_rec x s `indexed` "0"
label_rec y s `indexed` "1"
instance (Labelable a s) => Labelable (MaybeTwo a) (MaybeTwo s) where
label_rec (One x) (One s) = label_rec x s
label_rec (Two x y) (Two s t) = do
label_rec x s
label_rec y t
label_rec _ _ = return () -- fail silently
With this example, the commands
mklabel (One x) "s" mklabel (Two y z) "s"
produce the respective labelings
x -> s.one y -> s.two[0] z -> s.two[1]
- New atomic QCShape
Consider the case of a new atomic QCData instance:
instance QCData (Atomic x).
We usually need a Labelable instance for the cases x=Qubit
and x=Bit. This should be done uniformly, by using the QCLeaf
type class. The instance takes the following form:
instance QCLeaf x => Labelable (Atomic x) String where
label_rec a s = do
label_rec <<<a1>>> s `indexed` <<<index1>>>
...
label_rec <<<an>>> s `indexed` <<<indexn>>>
Here, a1...an are the components of the data structure, and index1...indexn/ are the corresponding subscripts. It is up to the designer of the data structure to decide what are "components" and how they should be labelled. On or more layers of string or numeric indices can be added as appropriate.
- Example
Consider the following sample atomic quantum data. A real number consists of an exponent, a sign, and a list of digits.
data MyReal x = MyReal Int x [x] instance QCLeaf x => QCData (MyReal x)
The following instance declaration would be appropriate:
instance QCLeaf x => Labelable (MyReal x) String where
label_rec (MyReal exp sign digits) s = do
label_rec sign s `dotted_indexed` "sign"
with_dotted_index "digit" $ do
sequence_ [ label_rec d s `indexed` show i | (d,i) <- zip digits [-exp..] ]
With this example, the command
mklabel (MyReal 2 x [y0, y1, y2, y3]) "s"
produces the labeling
x -> "s.sign" y0 -> "s.digit[-2]" y1 -> "s.digit[-1]" y2 -> "s.digit[0]" y3 -> "s.digit[1]"
Note that we could have also used the default labeling for the members of a list, but in this case, it was convenient to use a custom labeling.