Release notes for Agda 2 version 2.2.10
=======================================
Language
--------
* New flag: `--without-K`.
This flag makes pattern matching more restricted. If the flag is
activated, then Agda only accepts certain case-splits. If the type
of the variable to be split is `D pars ixs`, where `D` is a data (or
record) type, pars stands for the parameters, and `ixs` the indices,
then the following requirements must be satisfied:
- The indices `ixs` must be applications of constructors to distinct
variables.
- These variables must not be free in pars.
The intended purpose of `--without-K` is to enable experiments with
a propositional equality without the K rule. Let us define
propositional equality as follows:
```agda
data _≡_ {A : Set} : A → A → Set where
refl : ∀ x → x ≡ x
```
Then the obvious implementation of the J rule is accepted:
```agda
J : {A : Set} (P : {x y : A} → x ≡ y → Set) →
(∀ x → P (refl x)) →
∀ {x y} (x≡y : x ≡ y) → P x≡y
J P p (refl x) = p x
```
The same applies to Christine Paulin-Mohring's version of the J rule:
```agda
J′ : {A : Set} {x : A} (P : {y : A} → x ≡ y → Set) →
P (refl x) →
∀ {y} (x≡y : x ≡ y) → P x≡y
J′ P p (refl x) = p
```
On the other hand, the obvious implementation of the K rule is not
accepted:
```agda
K : {A : Set} (P : {x : A} → x ≡ x → Set) →
(∀ x → P (refl x)) →
∀ {x} (x≡x : x ≡ x) → P x≡x
K P p (refl x) = p x
```
However, we have *not* proved that activation of `--without-K`
ensures that the K rule cannot be proved in some other way.
* Irrelevant declarations.
Postulates and functions can be marked as irrelevant by prefixing
the name with a dot when the name is declared. Example:
```agda
postulate
.irrelevant : {A : Set} → .A → A
```
Irrelevant names may only be used in irrelevant positions or in
definitions of things which have been declared irrelevant.
The axiom irrelevant above can be used to define a projection from
an irrelevant record field:
```agda
data Subset (A : Set) (P : A → Set) : Set where
_#_ : (a : A) → .(P a) → Subset A P
elem : ∀ {A P} → Subset A P → A
elem (a # p) = a
.certificate : ∀ {A P} (x : Subset A P) → P (elem x)
certificate (a # p) = irrelevant p
```
The right-hand side of certificate is relevant, so we cannot define
```agda
certificate (a # p) = p
```
(because `p` is irrelevant). However, certificate is declared to be
irrelevant, so it can use the axiom irrelevant. Furthermore the
first argument of the axiom is irrelevant, which means that
irrelevant `p` is well-formed.
As shown above the axiom irrelevant justifies irrelevant
projections. Previously no projections were generated for irrelevant
record fields, such as the field certificate in the following
record type:
```agda
record Subset (A : Set) (P : A → Set) : Set where
constructor _#_
field
elem : A
.certificate : P elem
```
Now projections are generated automatically for irrelevant fields
(unless the flag `--no-irrelevant-projections` is used). Note that
irrelevant projections are highly experimental.
* Termination checker recognises projections.
Projections now preserve sizes, both in patterns and expressions.
Example:
```agda
record Wrap (A : Set) : Set where
constructor wrap
field
unwrap : A
open Wrap public
data WNat : Set where
zero : WNat
suc : Wrap WNat → WNat
id : WNat → WNat
id zero = zero
id (suc w) = suc (wrap (id (unwrap w)))
```
In the structural ordering `unwrap w` ≤ `w`. This means that
```agda
unwrap w ≤ w < suc w,
```
and hence the recursive call to id is accepted.
Projections also preserve guardedness.
Tools
-----
* Hyperlinks for top-level module names now point to the start of the
module rather than to the declaration of the module name. This
applies both to the Emacs mode and to the output of `agda --html`.
* Most occurrences of record field names are now highlighted as
"fields". Previously many occurrences were highlighted as
"functions".
* Emacs mode: It is no longer possible to change the behaviour of the
`TAB` key by customising `agda2-indentation`.
* Epic compiler backend.
A new compiler backend is being implemented. This backend makes use
of Edwin Brady's language Epic
(http://www.cs.st-andrews.ac.uk/~eb/epic.php) and its compiler. The
backend should handle most Agda code, but is still at an
experimental stage: more testing is needed, and some things written
below may not be entirely true.
The Epic compiler can be invoked from the command line using the
flag `--epic`:
```
agda --epic --epic-flag=<EPIC-FLAG> --compile-dir=<DIR> <FILE>.agda
```
The `--epic-flag` flag can be given multiple times; each flag is
given verbatim to the Epic compiler (in the given order). The
resulting executable is named after the main module and placed in
the directory specified by the `--compile-dir` flag (default: the
project root). Intermediate files are placed in a subdirectory
called `Epic`.
The backend requires that there is a definition named main. This
definition should be a value of type `IO Unit`, but at the moment
this is not checked (so it is easy to produce a program which
segfaults). Currently the backend represents actions of type `IO A`
as functions from `Unit` to `A`, and main is applied to the unit
value.
The Epic compiler compiles via C, not Haskell, so the pragmas
related to the Haskell FFI (`IMPORT`, `COMPILED_DATA` and
`COMPILED`) are not used by the Epic backend. Instead there is a new
pragma `COMPILED_EPIC`. This pragma is used to give Epic code for
postulated definitions (Epic code can in turn call C code). The form
of the pragma is `{-# COMPILED_EPIC def code #-}`, where `def` is
the name of an Agda postulate and `code` is some Epic code which
should include the function arguments, return type and function
body. As an example the `IO` monad can be defined as follows:
```agda
postulate
IO : Set → Set
return : ∀ {A} → A → IO A
_>>=_ : ∀ {A B} → IO A → (A → IO B) → IO B
{-# COMPILED_EPIC return (u : Unit, a : Any) -> Any =
ioreturn(a) #-}
{-# COMPILED_EPIC
_>>=_ (u1 : Unit, u2 : Unit, x : Any, f : Any) -> Any =
iobind(x,f) #-}
```
Here `ioreturn` and `iobind` are Epic functions which are defined in
the file `AgdaPrelude.e` which is always included.
By default the backend will remove so-called forced constructor
arguments (and case-splitting on forced variables will be
rewritten). This optimisation can be disabled by using the flag
`--no-forcing`.
All data types which look like unary natural numbers after forced
constructor arguments have been removed (i.e. types with two
constructors, one nullary and one with a single recursive argument)
will be represented as "BigInts". This applies to the standard `Fin`
type, for instance.
The backend supports Agda's primitive functions and the BUILTIN
pragmas. If the BUILTIN pragmas for unary natural numbers are used,
then some operations, like addition and multiplication, will use
more efficient "BigInt" operations.
If you want to make use of the Epic backend you need to install some
dependencies, see the README.
* The Emacs mode can compile using either the MAlonzo or the Epic
backend. The variable `agda2-backend` controls which backend is
used.