Modules
-------
$(root)/A/Foo.agda:
module Foo (A:Set)(op:A -> A -> A) where
f : A -> A
f = ..
module Bar (x:A) where
...
import .Baz -- looks for $(root)/A/Baz.agda
import B.Baz -- looks for $(include_dirs)/B/Baz.agda
Observations:
- You can only import actual files.
- The name of the top level module in a file as to match the file name.
Local ::= ... | open m es [ as x | (xs) | ε ]
D ::= ... | import x.x.x.x [ as x | ε ]
open Foo Nat eq as FooNat (f, g) -- import f and g into the new name
-- space FooNat.
open FooNat (f) -- import f into the current name space
open FooNat -- import everything from FooNat into
-- the current name space
At the moment there is a distinction between modules and name spaces.
Above
Foo Nat eq is a module
FooNat is a name space
You can refer to things using name spaces, as in FooNat.f. You cannot do
this with modules. A name space is a sequence of names separated by dot.
Not allowed:
(Foo Nat eq).f
You can open both name spaces and modules. For each non-parameterised
module there is a name space with the same name.
What does abstract and private mean?
abstract takes a list of definitions:
abstract Stack : Set
Stack = List
empty : Stack
empty = []
...
Outside the abstract block the definitions are not known (even inside
the same module).
private just means that the user cannot refer to the name outside the
module. You can still compute with private things.
How to translate to core?
We can just forget about private and abstract. For abstract this means
that the core type checker has more information than the full language
checker. This shouldn't be a problem.
Note: make sure that the type of something in an abstract block doesn't
depend on the value of one of the earlier definitions (the type is
exported).
Typing rules
------------
Γ ⊢ M : Set_i
-------------------
Γ ⊢ El_i M : type^i
Also for prop.
Algorithm
Judgement forms:
Γ ⊢ A s --> V check that A is a type and infer the sort
Γ ⊢ e ↑ V --> v check that e has type V
Γ ⊢ e ↓ V --> v infer the type of e
Rules:
Γ ⊢ M ↓ V --> v v = Sort ?s
------------------------------
Γ ⊢ M ?s --> El_?s v
Γ ⊢ f ↓ V -> v V = (x : ?A) -> ?B Γ ⊢ e ↑ ?A --> w
------------------------------------------------------
Γ ⊢ f e ↓ ?B w --> v w
We need sort meta variables: Γ ⊢ ? ? --> ?
data Type = ... | Sort Sort
data Sort = Type Nat | Prop | Meta MId | Lub Sort Sort
So this means that we don't need the Maybe in the metainfo
data MetaInfo = InstantiatedV Value
| InstantiatedT Type
| Underscore [ConstraintId]
| QuestionmarkV Signature Context Type [ConstraintId]
| QuestionmarkT Signature Context Sort [ConstraintId]
Important observation:
We don't have subtyping, only subsorting.
Γ ⊢ e ↓ W --> v W = V
-----------------------
Γ ⊢ e ↑ V --> v
Plan
----
Things to do/figure out
- Typing rules for the full language
- Translation to Core
- Explanations
- User interactions
- Testing
- Plug-ins
- Documentation
- ( Classes )
This will be done mainly at Chalmers
Things we know how to do
C - concrete and abstract syntax, translation
C - parser, lexer
C - pretty printing
C - infrastructure (Makefile, directories)
J - internal syntax
J - unification and constraints
J - monad and state (partially)
C = Chalmers (Ulf)
J = Japan (Jeff)
Time plan
Sep
Fix signature datatype.
Final version of typing rules.
Finish(ing) infrastructure code ("Things we know how to do").
Oct
Start implementing type checker.
Finish(ing) first version.
Nov
Have a running system.
File organisation
-----------------
src
Syntax
Lexer
Parser
ParseMonad
Position
Concrete
Abstract
Internal
Pretty
ConcreteToAbstract
TypeChecker
Monad
Unification
(MetaVariables, Computation, .. ?)
Testing
... fine grained testing
Interaction
... interaction protocol, ...
Plugins
...
The Haddock trick
-----------------
Haddock doesn't handle circular module dependencies.
Solution: Use a preprocessor before calling Haddock which removes lines
containing REMOVE_IF_HADDOCK.
Example:
import {-# SOURCE #-} Foo (foo) -- REMOVE_IF_HADDOCK
{- REMOVE_IF_HADDOCK
-- | This function is really 'Foo.foo'. It's here to fool Haddock into
-- accept circular module dependencies.
foo :: Int -> Int
REMOVE_IF_HADDOCK -}
Coding conventions
------------------
- Write typesignatures and haddock comments.
- Never use booleans.
- Datatypes should be abstract and accessed by views.
- Scrap boilerplate locally. That is, define useful combinators using
generics, but export non-generic functions. Another way of saying it:
only use generics in close proximity to the definition of the datatype.
The keeping-abstraction-when-splitting-a-module trick
-----------------------------------------------------
You have:
--- A.hs ---
module A ( Foo -- abstract type
, foo
) where
data Foo = Foo Int
foo :: Foo -> Int
foo (Foo n) = n
------------
You want to split this module into two (because it's too big), without
breaking the abstraction of Foo.
Solution: You split the module into three, with the added advantage that
you don't have to change modules importing A.
--- A.hs ---
module A ( Foo, foo ) where
import A.Implementation
import A.Foo
------------
--- A/Implementation.hs ---
module A.Implementation ( Foo(..) ) where -- exports definition of Foo
data Foo = Foo Int
---------------------------
--- A/Foo.hs ---
module A.Foo (foo) where
import A.Implementation
foo :: Foo -> Int
foo (Foo n) = n
----------------
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