Agda

A dependently typed functional programming language and proof assistant

http://wiki.portal.chalmers.se/agda/

Version on this page:2.5.2@rev:2
LTS Haskell 22.13:2.6.4.3
Stackage Nightly 2024-03-14:2.6.4.3
Latest on Hackage:2.6.4.3

See all snapshots Agda appears in

LicenseRef-OtherLicense licensed by Ulf Norell, Andreas Abel, Nils Anders Danielsson, Makoto Takeyama, Catarina Coquand, with contributions by Stevan Andjelkovic, Marcin Benke, Jean-Philippe Bernardy, James Chapman, Jesper Cockx, Dominique Devriese, Peter Divanski, Fredrik Nordvall Forsberg, Olle Fredriksson, Daniel Gustafsson, Philipp Hausmann, Patrik Jansson, Alan Jeffrey, Wolfram Kahl, Fredrik Lindblad, Francesco Mazzoli, Stefan Monnier, Darin Morrison, Guilhem Moulin, Nicolas Pouillard, Andrés Sicard-Ramírez, Andrea Vezzosi and many more.
Maintained by Ulf Norell
This version can be pinned in stack with:Agda-2.5.2@sha256:4db0b12bc07e72fe1b180acad2a0d59ac11d9a1d45698b46cede7b634fb6bfff,27524

Module documentation for 2.5.2

  • Agda
    • Agda.Auto
      • Agda.Auto.Auto
      • Agda.Auto.CaseSplit
      • Agda.Auto.Convert
      • Agda.Auto.NarrowingSearch
      • Agda.Auto.SearchControl
      • Agda.Auto.Syntax
      • Agda.Auto.Typecheck
    • Agda.Benchmarking
    • Agda.Compiler
      • Agda.Compiler.CallCompiler
      • Agda.Compiler.Common
      • Agda.Compiler.Epic
        • Agda.Compiler.Epic.AuxAST
        • Agda.Compiler.Epic.CaseOpts
        • Agda.Compiler.Epic.CompileState
        • Agda.Compiler.Epic.Compiler
        • Agda.Compiler.Epic.Epic
        • Agda.Compiler.Epic.Erasure
        • Agda.Compiler.Epic.ForceConstrs
        • Agda.Compiler.Epic.Forcing
        • Agda.Compiler.Epic.FromAgda
        • Agda.Compiler.Epic.Injection
        • Agda.Compiler.Epic.Interface
        • Agda.Compiler.Epic.NatDetection
        • Agda.Compiler.Epic.Primitive
        • Agda.Compiler.Epic.Smashing
        • Agda.Compiler.Epic.Static
      • Agda.Compiler.HaskellTypes
      • Agda.Compiler.JS
        • Agda.Compiler.JS.Compiler
        • Agda.Compiler.JS.Pretty
        • Agda.Compiler.JS.Substitution
        • Agda.Compiler.JS.Syntax
      • Agda.Compiler.MAlonzo
        • Agda.Compiler.MAlonzo.Compiler
        • Agda.Compiler.MAlonzo.Encode
        • Agda.Compiler.MAlonzo.Misc
        • Agda.Compiler.MAlonzo.Pretty
        • Agda.Compiler.MAlonzo.Primitives
      • Agda.Compiler.ToTreeless
      • Agda.Compiler.Treeless
        • Agda.Compiler.Treeless.AsPatterns
        • Agda.Compiler.Treeless.Builtin
        • Agda.Compiler.Treeless.Compare
        • Agda.Compiler.Treeless.DelayCoinduction
        • Agda.Compiler.Treeless.EliminateLiteralPatterns
        • Agda.Compiler.Treeless.Erase
        • Agda.Compiler.Treeless.GuardsToPrims
        • Agda.Compiler.Treeless.Identity
        • Agda.Compiler.Treeless.NormalizeNames
        • Agda.Compiler.Treeless.Pretty
        • Agda.Compiler.Treeless.Simplify
        • Agda.Compiler.Treeless.Subst
        • Agda.Compiler.Treeless.Uncase
        • Agda.Compiler.Treeless.Unused
      • Agda.Compiler.UHC
        • Agda.Compiler.UHC.Bridge
        • Agda.Compiler.UHC.CompileState
        • Agda.Compiler.UHC.Compiler
        • Agda.Compiler.UHC.FromAgda
        • Agda.Compiler.UHC.MagicTypes
        • Agda.Compiler.UHC.Pragmas
          • Agda.Compiler.UHC.Pragmas.Base
          • Agda.Compiler.UHC.Pragmas.Parse
        • Agda.Compiler.UHC.Primitives
    • Agda.ImpossibleTest
    • Agda.Interaction
      • Agda.Interaction.BasicOps
      • Agda.Interaction.CommandLine
      • Agda.Interaction.EmacsCommand
      • Agda.Interaction.EmacsTop
      • Agda.Interaction.FindFile
      • Agda.Interaction.Highlighting
        • Agda.Interaction.Highlighting.Dot
        • Agda.Interaction.Highlighting.Emacs
        • Agda.Interaction.Highlighting.Generate
        • Agda.Interaction.Highlighting.HTML
        • Agda.Interaction.Highlighting.LaTeX
        • Agda.Interaction.Highlighting.Precise
        • Agda.Interaction.Highlighting.Range
        • Agda.Interaction.Highlighting.Vim
      • Agda.Interaction.Imports
      • Agda.Interaction.InteractionTop
      • Agda.Interaction.Library
        • Agda.Interaction.Library.Base
        • Agda.Interaction.Library.Parse
      • Agda.Interaction.MakeCase
      • Agda.Interaction.Monad
      • Agda.Interaction.Options
        • Agda.Interaction.Options.Lenses
      • Agda.Interaction.Response
      • Agda.Interaction.SearchAbout
    • Agda.Main
    • Agda.Syntax
      • Agda.Syntax.Abstract
        • Agda.Syntax.Abstract.Copatterns
        • Agda.Syntax.Abstract.Name
        • Agda.Syntax.Abstract.Pretty
        • Agda.Syntax.Abstract.Views
      • Agda.Syntax.Common
      • Agda.Syntax.Concrete
        • Agda.Syntax.Concrete.Definitions
        • Agda.Syntax.Concrete.Generic
        • Agda.Syntax.Concrete.Name
        • Agda.Syntax.Concrete.Operators
          • Agda.Syntax.Concrete.Operators.Parser
            • Agda.Syntax.Concrete.Operators.Parser.Monad
        • Agda.Syntax.Concrete.Pretty
      • Agda.Syntax.Fixity
      • Agda.Syntax.IdiomBrackets
      • Agda.Syntax.Info
      • Agda.Syntax.Internal
        • Agda.Syntax.Internal.Defs
        • Agda.Syntax.Internal.Generic
        • Agda.Syntax.Internal.Names
        • Agda.Syntax.Internal.Pattern
        • Agda.Syntax.Internal.SanityCheck
      • Agda.Syntax.Literal
      • Agda.Syntax.Notation
      • Agda.Syntax.Parser
        • Agda.Syntax.Parser.Alex
        • Agda.Syntax.Parser.Comments
        • Agda.Syntax.Parser.Layout
        • Agda.Syntax.Parser.LexActions
        • Agda.Syntax.Parser.Lexer
        • Agda.Syntax.Parser.Literate
        • Agda.Syntax.Parser.LookAhead
        • Agda.Syntax.Parser.Monad
        • Agda.Syntax.Parser.Parser
        • Agda.Syntax.Parser.StringLiterals
        • Agda.Syntax.Parser.Tokens
      • Agda.Syntax.Position
      • Agda.Syntax.Reflected
      • Agda.Syntax.Scope
        • Agda.Syntax.Scope.Base
        • Agda.Syntax.Scope.Monad
      • Agda.Syntax.Translation
        • Agda.Syntax.Translation.AbstractToConcrete
        • Agda.Syntax.Translation.ConcreteToAbstract
        • Agda.Syntax.Translation.InternalToAbstract
        • Agda.Syntax.Translation.ReflectedToAbstract
      • Agda.Syntax.Treeless
    • Agda.Termination
      • Agda.Termination.CallGraph
      • Agda.Termination.CallMatrix
      • Agda.Termination.CutOff
      • Agda.Termination.Inlining
      • Agda.Termination.Monad
      • Agda.Termination.Order
      • Agda.Termination.RecCheck
      • Agda.Termination.Semiring
      • Agda.Termination.SparseMatrix
      • Agda.Termination.TermCheck
      • Agda.Termination.Termination
    • Agda.TheTypeChecker
    • Agda.TypeChecking
      • Agda.TypeChecking.Abstract
      • Agda.TypeChecking.CheckInternal
      • Agda.TypeChecking.CompiledClause
        • Agda.TypeChecking.CompiledClause.Compile
        • Agda.TypeChecking.CompiledClause.Match
      • Agda.TypeChecking.Constraints
      • Agda.TypeChecking.Conversion
      • Agda.TypeChecking.Coverage
        • Agda.TypeChecking.Coverage.Match
        • Agda.TypeChecking.Coverage.SplitTree
      • Agda.TypeChecking.Datatypes
      • Agda.TypeChecking.DeadCode
      • Agda.TypeChecking.DisplayForm
      • Agda.TypeChecking.DropArgs
      • Agda.TypeChecking.Empty
      • Agda.TypeChecking.Errors
      • Agda.TypeChecking.EtaContract
      • Agda.TypeChecking.Forcing
      • Agda.TypeChecking.Free
        • Agda.TypeChecking.Free.Lazy
        • Agda.TypeChecking.Free.Old
      • Agda.TypeChecking.Implicit
      • Agda.TypeChecking.Injectivity
      • Agda.TypeChecking.InstanceArguments
      • Agda.TypeChecking.Irrelevance
      • Agda.TypeChecking.Level
      • Agda.TypeChecking.LevelConstraints
      • Agda.TypeChecking.MetaVars
        • Agda.TypeChecking.MetaVars.Mention
        • Agda.TypeChecking.MetaVars.Occurs
      • Agda.TypeChecking.Monad
        • Agda.TypeChecking.Monad.Base
        • Agda.TypeChecking.Monad.Benchmark
        • Agda.TypeChecking.Monad.Builtin
        • Agda.TypeChecking.Monad.Caching
        • Agda.TypeChecking.Monad.Closure
        • Agda.TypeChecking.Monad.Constraints
        • Agda.TypeChecking.Monad.Context
        • Agda.TypeChecking.Monad.Env
        • Agda.TypeChecking.Monad.Exception
        • Agda.TypeChecking.Monad.Imports
        • Agda.TypeChecking.Monad.Local
        • Agda.TypeChecking.Monad.MetaVars
        • Agda.TypeChecking.Monad.Mutual
        • Agda.TypeChecking.Monad.Open
        • Agda.TypeChecking.Monad.Options
        • Agda.TypeChecking.Monad.Sharing
        • Agda.TypeChecking.Monad.Signature
        • Agda.TypeChecking.Monad.SizedTypes
        • Agda.TypeChecking.Monad.State
        • Agda.TypeChecking.Monad.Statistics
        • Agda.TypeChecking.Monad.Trace
      • Agda.TypeChecking.Patterns
        • Agda.TypeChecking.Patterns.Abstract
        • Agda.TypeChecking.Patterns.Match
      • Agda.TypeChecking.Polarity
      • Agda.TypeChecking.Positivity
        • Agda.TypeChecking.Positivity.Occurrence
      • Agda.TypeChecking.Pretty
      • Agda.TypeChecking.Primitive
      • Agda.TypeChecking.ProjectionLike
      • Agda.TypeChecking.Quote
      • Agda.TypeChecking.ReconstructParameters
      • Agda.TypeChecking.RecordPatterns
      • Agda.TypeChecking.Records
      • Agda.TypeChecking.Reduce
        • Agda.TypeChecking.Reduce.Fast
        • Agda.TypeChecking.Reduce.Monad
      • Agda.TypeChecking.Rewriting
        • Agda.TypeChecking.Rewriting.NonLinMatch
      • Agda.TypeChecking.Rules
        • Agda.TypeChecking.Rules.Builtin
          • Agda.TypeChecking.Rules.Builtin.Coinduction
        • Agda.TypeChecking.Rules.Data
        • Agda.TypeChecking.Rules.Decl
        • Agda.TypeChecking.Rules.Def
        • Agda.TypeChecking.Rules.Display
        • Agda.TypeChecking.Rules.LHS
          • Agda.TypeChecking.Rules.LHS.AsPatterns
          • Agda.TypeChecking.Rules.LHS.Implicit
          • Agda.TypeChecking.Rules.LHS.Instantiate
          • Agda.TypeChecking.Rules.LHS.Problem
          • Agda.TypeChecking.Rules.LHS.ProblemRest
          • Agda.TypeChecking.Rules.LHS.Split
          • Agda.TypeChecking.Rules.LHS.Unify
        • Agda.TypeChecking.Rules.Record
        • Agda.TypeChecking.Rules.Term
      • Agda.TypeChecking.Serialise
        • Agda.TypeChecking.Serialise.Base
        • Agda.TypeChecking.Serialise.Instances
          • Agda.TypeChecking.Serialise.Instances.Abstract
          • Agda.TypeChecking.Serialise.Instances.Common
          • Agda.TypeChecking.Serialise.Instances.Compilers
          • Agda.TypeChecking.Serialise.Instances.Highlighting
          • Agda.TypeChecking.Serialise.Instances.Internal
      • Agda.TypeChecking.SizedTypes
        • Agda.TypeChecking.SizedTypes.Solve
        • Agda.TypeChecking.SizedTypes.Syntax
        • Agda.TypeChecking.SizedTypes.Utils
        • Agda.TypeChecking.SizedTypes.WarshallSolver
      • Agda.TypeChecking.Substitute
        • Agda.TypeChecking.Substitute.Class
        • Agda.TypeChecking.Substitute.DeBruijn
      • Agda.TypeChecking.SyntacticEquality
      • Agda.TypeChecking.Telescope
      • Agda.TypeChecking.Unquote
      • Agda.TypeChecking.With
    • Agda.Utils
      • Agda.Utils.AssocList
      • Agda.Utils.Bag
      • Agda.Utils.Benchmark
      • Agda.Utils.BiMap
      • Agda.Utils.Char
      • Agda.Utils.Cluster
      • Agda.Utils.Either
      • Agda.Utils.Empty
      • Agda.Utils.Environment
      • Agda.Utils.Except
      • Agda.Utils.Favorites
      • Agda.Utils.FileName
      • Agda.Utils.Function
      • Agda.Utils.Functor
      • Agda.Utils.Geniplate
      • Agda.Utils.Graph
        • Agda.Utils.Graph.AdjacencyMap
          • Agda.Utils.Graph.AdjacencyMap.Unidirectional
      • Agda.Utils.Hash
      • Agda.Utils.HashMap
      • Agda.Utils.Haskell
        • Agda.Utils.Haskell.Syntax
      • Agda.Utils.IO
        • Agda.Utils.IO.Binary
        • Agda.Utils.IO.Directory
        • Agda.Utils.IO.UTF8
      • Agda.Utils.IORef
      • Agda.Utils.Impossible
      • Agda.Utils.Lens
        • Agda.Utils.Lens.Examples
      • Agda.Utils.List
      • Agda.Utils.ListT
      • Agda.Utils.Map
      • Agda.Utils.Maybe
        • Agda.Utils.Maybe.Strict
      • Agda.Utils.Memo
      • Agda.Utils.Monad
      • Agda.Utils.Null
      • Agda.Utils.Parser
        • Agda.Utils.Parser.MemoisedCPS
        • Agda.Utils.Parser.ReadP
      • Agda.Utils.PartialOrd
      • Agda.Utils.Permutation
      • Agda.Utils.Pointer
      • Agda.Utils.Pretty
      • Agda.Utils.SemiRing
      • Agda.Utils.Singleton
      • Agda.Utils.Size
      • Agda.Utils.String
      • Agda.Utils.Suffix
      • Agda.Utils.Time
      • Agda.Utils.Trie
      • Agda.Utils.Tuple
      • Agda.Utils.Update
      • Agda.Utils.VarSet
      • Agda.Utils.Warshall
    • Agda.Version
    • Agda.VersionCommit

Agda 2

Hackage version Stackage version Build Status

Table of contents:

Note that this README only discusses installation of Agda, not its standard library. See the Agda Wiki for information about the library.

Documentation

Prerequisites

You need recent versions of the following programs/libraries:

You should also make sure that programs installed by cabal-install are on your shell’s search path.

For instructions on installing a suitable version of Emacs under Windows, see [below]((#installing-emacs-under-windows).

Non-Windows users need to ensure that the development files for the C libraries zlib and ncurses are installed (see http://zlib.net and http://www.gnu.org/software/ncurses/). Your package manager may be able to install these files for you. For instance, on Debian or Ubuntu it should suffice to run

apt-get install zlib1g-dev libncurses5-dev

as root to get the correct files installed.

Note on GHC’s CPP language extension

Recent versions of Clang’s preprocessor don’t work well with Haskell. In order to get some dependencies to build, you may need to set up Cabal to have GHC use cpphs by default. You can do this by adding

program-default-options
  ghc-options: -pgmPcpphs -optP--cpp

to your .cabal/config file. (You must be using cabal >= 1.18. Note that some packages may not compile with this option set.)

You don’t need to set this option to install Agda from the current development source; Agda.cabal now uses cpphs.

Installing Agda

There are several ways to install Agda:

Using a binary package prepared for your platform

Recommended if such a package exists. See the Agda Wiki.

Using a released source package from Hackage

Install the prerequisites mentioned below, then run the following commands:

cabal update
cabal install Agda
agda-mode setup

The last command tries to set up Emacs for use with Agda. As an alternative you can copy the following text to your .emacs file:

(load-file (let ((coding-system-for-read 'utf-8))
                (shell-command-to-string "agda-mode locate")))

It is also possible (but not necessary) to compile the Emacs mode’s files:

agda-mode compile

This can, in some cases, give a noticeable speedup.

WARNING: If you reinstall the Agda mode without recompiling the Emacs Lisp files, then Emacs may continue using the old, compiled files.

Using the development version of the code

You can obtain tarballs of the development version from the Agda Wiki, or clone the repository.

Install the prerequisites discussed in Prerequisites.

Then, either:

(1a) Run the following commands in the top-level directory of the Agda source tree to install Agda:

cabal update
cabal install

(1b) Run agda-mode setup to set up Emacs for use with Agda. Alternatively, add the following text to your .emacs file:

(load-file (let ((coding-system-for-read 'utf-8))
                (shell-command-to-string "agda-mode locate")))

It is also possible (but not necessary) to compile the Emacs mode’s files:

agda-mode compile

This can, in some cases, give a noticeable speedup.

WARNING: If you reinstall the Agda mode without recompiling the Emacs Lisp files, then Emacs may continue using the old compiled files.

(2) Or, you can try to install Agda (including a compiled Emacs mode) by running the following command:

make install

Configuring the Emacs mode

If you want to you can customise the Emacs mode. Just start Emacs and type the following:

M-x load-library RET agda2-mode RET
M-x customize-group RET agda2 RET

This is useful if you want to change the Agda search path, in which case you should change the agda2-include-dirs variable.

If you want some specific settings for the Emacs mode you can add them to agda2-mode-hook. For instance, if you do not want to use the Agda input method (for writing various symbols like ∀≥ℕ→π⟦⟧) you can add the following to your .emacs:

(add-hook 'agda2-mode-hook
          '(lambda ()
            ; If you do not want to use any input method:
            (deactivate-input-method)
            ; (In some versions of Emacs you should use
            ; inactivate-input-method instead of
            ; deactivate-input-method.)

            ; If you want to use the X input method:
            (set-input-method "X")))

Note that, on some systems, the Emacs mode changes the default font of the current frame in order to enable many Unicode symbols to be displayed. This only works if the right fonts are available, though. If you want to turn off this feature, then you should customise the agda2-fontset-name variable.


Installing Emacs under Windows

A precompiled version of Emacs 24.3, with the necessary mathematical fonts, is available at http://homepage.cs.uiowa.edu/~astump/agda/

Hacking on Agda

Head to HACKING

Changes

Release notes for Agda version 2.5.2

Installation and infrastructure

  • Modular support for literate programming

    Literate programming support has been moved out of the lexer and into the Agda.Syntax.Parser.Literate module.

    Files ending in .lagda are still interpreted as literate TeX. The extension .lagda.tex may now also be used for literate TeX files.

    Support for more literate code formats and extensions can be added modularly.

    By default, .lagda.* files are opened in the Emacs mode corresponding to their last extension. One may switch to and from Agda mode manually.

  • reStructuredText

    Literate Agda code can now be written in reStructuredText format, using the .lagda.rst extension.

    As a general rule, Agda will parse code following a line ending in ::, as long as that line does not start with ... The module name must match the path of the file in the documentation, and must be given explicitly. Several files have been converted already, for instance:

    • language/mixfix-operators.lagda.rst
    • tools/compilers.lagda.rst

    Note that:

    • Code blocks inside an rST comment block will be type-checked by Agda, but not rendered in the documentation.
    • Code blocks delimited by .. code-block:: agda will be rendered in the final documenation, but not type-checked by Agda.
    • All lines inside a codeblock must be further indented than the first line of the code block.
    • Indentation must be consistent between code blocks. In other words, the file as a whole must be a valid Agda file if all the literate text is replaced by white space.
  • Documentation testing

    All documentation files in the doc/user-manual directory that end in .lagda.rst can be typechecked by running make user-manual-test, and also as part of the general test suite.

  • Support installation through Stack

    The Agda sources now also include a configuration for the stack install tool (tested through continuous integration).

    It should hence be possible to repeatably build any future Agda version (including unreleased commits) from source by checking out that version and running stack install from the checkout directory. By using repeatable builds, this should keep selecting the same dependencies in the face of new releases on Hackage.

    For further motivation, see Issue #2005.

  • Removed the --test command-line option

    This option ran the internal test-suite. This test-suite was implemented using Cabal supports for test-suites. [Issue #2083].

  • The --no-default-libraries flag has been split into two flags [Issue #1937]

    • --no-default-libraries: Ignore the defaults file but still look for local .agda-lib files
    • --no-libraries: Don’t use any .agda-lib files (the previous behaviour of --no-default-libraries).
  • If agda was built inside git repository, then the --version flag will display the hash of the commit used, and whether the tree was -dirty (i.e. there were uncommited changes in the working directory). Otherwise, only the version number is shown.

Language

  • Dot patterns are now optional

    Consider the following program

    data Vec (A : Set) : Nat → Set where
      []   : Vec A zero
      cons : ∀ n → A → Vec A n → Vec A (suc n)
    
    vmap : ∀ {A B} n → (A → B) → Vec A n → Vec B n
    vmap .zero    f []            = []
    vmap .(suc m) f (cons m x xs) = cons m (f x) (vmap m f xs)
    

    If we don’t care about the dot patterns they can (and could previously) be replaced by wildcards:

    vmap : ∀ {A B} n → (A → B) → Vec A n → Vec B n
    vmap _ f []            = []
    vmap _ f (cons m x xs) = cons m (f x) (vmap m f xs)
    

    Now it is also allowed to give a variable pattern in place of the dot pattern. In this case the variable will be bound to the value of the dot pattern. For our example:

    vmap : ∀ {A B} n → (A → B) → Vec A n → Vec B n
    vmap n f []            = []
    vmap n f (cons m x xs) = cons m (f x) (vmap m f xs)
    

    In the first clause n reduces to zero and in the second clause n reduces to suc m.

  • Module parameters can now be refined by pattern matching

    Previously, pattern matches that would refine a variable outside the current left-hand side was disallowed. For instance, the following would give an error, since matching on the vector would instantiate n.

    module _ {A : Set} {n : Nat} where
      f : Vec A n → Vec A n
      f []       = []
      f (x ∷ xs) = x ∷ xs
    

    Now this is no longer disallowed. Instead n is bound to the appropriate value in each clause.

  • With-abstraction now abstracts also in module parameters

    The change that allows pattern matching to refine module parameters also allows with-abstraction to abstract in them. For instance,

    module _ (n : Nat) (xs : Vec Nat (n + n)) where
      f : Nat
      f with n + n
      f    | nn = ? -- xs : Vec Nat nn
    

    Note: Any function argument or lambda-bound variable bound outside a given function counts as a module parameter.

    To prevent abstraction in a parameter you can hide it inside a definition. In the above example,

    module _ (n : Nat) (xs : Vec Nat (n + n)) where
    
      ys : Vec Nat (n + n)
      ys = xs
    
      f : Nat
      f with n + n
      f    | nn = ? -- xs : Vec Nat nn, ys : Vec Nat (n + n)
    
  • As-patterns [Issue #78].

    As-patterns (@-patterns) are finally working and can be used to name a pattern. The name has the same scope as normal pattern variables (i.e. the right-hand side, where clause, and dot patterns). The name reduces to the value of the named pattern. For example::

    module _ {A : Set} (_<_ : A → A → Bool) where
      merge : List A → List A → List A
      merge xs [] = xs
      merge [] ys = ys
      merge xs@(x ∷ xs₁) ys@(y ∷ ys₁) =
        if x < y then x ∷ merge xs₁ ys
                 else y ∷ merge xs ys₁
    
  • Idiom brackets.

    There is new syntactic sugar for idiom brackets:

    (| e a1 .. an |) expands to

    pure e <*> a1 <*> .. <*> an

    The desugaring takes place before scope checking and only requires names pure and _<*>_ in scope. Idiom brackets work well with operators, for instance

    (| if a then b else c |) desugars to

    pure if_then_else_ <*> a <*> b <*> c

    Limitations:

    • The top-level application inside idiom brackets cannot include implicit applications, so (| foo {x = e} a b |) is illegal. In the case e is pure you can write (| (foo {x = e}) a b |) which desugars to

      pure (foo {x = e}) <*> a <*> b

    • Binding syntax and operator sections cannot appear immediately inside idiom brackets.

  • Layout for pattern matching lambdas.

    You can now write pattern matching lambdas using the syntax

    λ where false → true
            true  → false
    

    avoiding the need for explicit curly braces and semicolons.

  • Overloaded projections [Issue #1944].

    Ambiguous projections are no longer a scope error. Instead they get resolved based on the type of the record value they are eliminating. This corresponds to constructors, which can be overloaded and get disambiguated based on the type they are introducing. Example:

    module _ (A : Set) (a : A) where
    
    record R B : Set where
      field f : B
    open R public
    
    record S B : Set where
      field f : B
    open S public
    

    Exporting f twice from both R and S is now allowed. Then,

    r : R A
    f r = a
    
    s : S A
    f s = f r
    

    disambiguates to:

    r : R A
    R.f r = a
    
    s : S A
    S.f s = R.f r
    

    If the type of the projection is known, it can also be disambiguated unapplied.

    unapplied : R A -> A
    unapplied = f
    
  • Postfix projections [Issue #1963].

    Agda now supports a postfix syntax for projection application. This style is more in harmony with copatterns. For example:

    record Stream (A : Set) : Set where
      coinductive
      field head : A
            tail : Stream A
    
    open Stream
    
    repeat : ∀{A} (a : A) → Stream A
    repeat a .head = a
    repeat a .tail = repeat a
    
    zipWith : ∀{A B C} (f : A → B → C) (s : Stream A) (t : Stream B) → Stream C
    zipWith f s t .head = f (s .head) (t .head)
    zipWith f s t .tail = zipWith f (s .tail) (t .tail)
    
    module Fib (Nat : Set) (zero one : Nat) (plus : Nat → Nat → Nat) where
    
      {-# TERMINATING #-}
      fib : Stream Nat
      fib .head = zero
      fib .tail .head = one
      fib .tail .tail = zipWith plus fib (fib .tail)
    

    The thing we eliminate with projection now is visibly the head, i.e., the left-most expression of the sequence (e.g. repeat in repeat a .tail).

    The syntax overlaps with dot patterns, but for type correct left hand sides there is no confusion: Dot patterns eliminate function types, while (postfix) projection patterns eliminate record types.

    By default, Agda prints system-generated projections (such as by eta-expansion or case splitting) prefix. This can be changed with the new option:

    {-# OPTIONS --postfix-projections #-}
    

    Result splitting in extended lambdas (aka pattern lambdas) always produces postfix projections, as prefix projection pattern do not work here: a prefix projection needs to go left of the head, but the head is omitted in extended lambdas.

    dup : ∀{A : Set}(a : A) → A × A
    dup = λ{ a → ? }
    

    Result splitting (C-c C-c RET) here will yield:

    dup = λ{ a .proj₁ → ? ; a .proj₂ → ? }
    
  • Projection parameters [Issue #1954].

    When copying a module, projection parameters will now stay hidden arguments, even if the module parameters are visible. This matches the situation we had for constructors since long. Example:

    module P (A : Set) where
      record R : Set where
        field f : A
    
    open module Q A = P A
    

    Parameter A is now hidden in R.f:

    test : ∀{A} → R A → A
    test r = R.f r
    

    Note that a module parameter that corresponds to the record value argument of a projection will not be hidden.

    module M (A : Set) (r : R A) where
      open R A r public
    
    test' : ∀{A} → R A → A
    test' r = M.f r
    
  • Eager insertion of implicit arguments [Issue #2001]

    Implicit arguments are now (again) eagerly inserted in left-hand sides. The previous behaviour of inserting implicits for where blocks, but not right-hand sides was not type safe.

  • Module applications can now be eta expanded/contracted without changing their behaviour [Issue #1985]

    Previously definitions exported using open public got the incorrect type for underapplied module applications.

    Example:

    module A where
      postulate A : Set
    
    module B (X : Set) where
      open A public
    
    module C₁ = B
    module C₂ (X : Set) = B X
    

    Here both C₁.A and C₂.A have type (X : Set) → Set.

  • Polarity pragmas.

    Polarity pragmas can be attached to postulates. The polarities express how the postulate’s arguments are used. The following polarities are available:

    _: Unused.

    ++: Strictly positive.

    +: Positive.

    -: Negative.

    *: Unknown/mixed.

    Polarity pragmas have the form

    {-# POLARITY name <zero or more polarities> #-}
    

    and can be given wherever fixity declarations can be given. The listed polarities apply to the given postulate’s arguments (explicit/implicit/instance), from left to right. Polarities currently cannot be given for module parameters. If the postulate takes n arguments (excluding module parameters), then the number of polarities given must be between 0 and n (inclusive).

    Polarity pragmas make it possible to use postulated type formers in recursive types in the following way:

    postulate
      ∥_∥ : Set → Set
    
    {-# POLARITY ∥_∥ ++ #-}
    
    data D : Set where
      c : ∥ D ∥ → D
    

    Note that one can use postulates that may seem benign, together with polarity pragmas, to prove that the empty type is inhabited:

    postulate
      _⇒_    : Set → Set → Set
      lambda : {A B : Set} → (A → B) → A ⇒ B
      apply  : {A B : Set} → A ⇒ B → A → B
    
    {-# POLARITY _⇒_ ++ #-}
    
    data ⊥ : Set where
    
    data D : Set where
      c : D ⇒ ⊥ → D
    
    not-inhabited : D → ⊥
    not-inhabited (c f) = apply f (c f)
    
    inhabited : D
    inhabited = c (lambda not-inhabited)
    
    bad : ⊥
    bad = not-inhabited inhabited
    

    Polarity pragmas are not allowed in safe mode.

  • Declarations in a where-block are now private. [Issue #2101] This means that

    f ps = body where
      decls
    

    is now equivalent to

    f ps = body where
      private
        decls
    

    This changes little, since the decls were anyway not in scope outside body. However, it makes a difference for abstract definitions, because private type signatures can see through abstract definitions. Consider:

    record Wrap (A : Set) : Set where
      field unwrap : A
    
    postulate
      P : ∀{A : Set} → A → Set
    
    abstract
    
      unnamedWhere : (A : Set) → Set
      unnamedWhere A = A
        where  -- the following definitions are private!
        B : Set
        B = Wrap A
    
        postulate
          b : B
          test : P (Wrap.unwrap b)  -- succeeds
    

    The abstract is inherited in where-blocks from the parent (here: function unnamedWhere). Thus, the definition of B is opaque and the type equation B = Wrap A cannot be used to check type signatures, not even of abstract definitions. Thus, checking the type P (Wrap.unwrap b) would fail. However, if test is private, abstract definitions are translucent in its type, and checking succeeds. With the implemented change, all where-definitions are private, in this case B, b, and test, and the example succeeds.

    Nothing changes for the named forms of where,

    module M where
    module _ where
    

    For instance, this still fails:

    abstract
    
      unnamedWhere : (A : Set) → Set
      unnamedWhere A = A
        module M where
        B : Set
        B = Wrap A
    
        postulate
          b : B
          test : P (Wrap.unwrap b)  -- fails
    
  • Private anonymous modules now work as expected [Issue #2199]

    Previously the private was ignored for anonymous modules causing its definitions to be visible outside the module containing the anonymous module. This is no longer the case. For instance,

    module M where
      private
        module _ (A : Set) where
          Id : Set
          Id = A
    
      foo : Set → Set
      foo = Id
    
    open M
    
    bar : Set → Set
    bar = Id -- Id is no longer in scope here
    
  • Pattern synonyms are now expanded on left hand sides of DISPLAY pragmas [Issue #2132]. Example:

    data D : Set where
      C c : D
      g : D → D
    
    pattern C′ = C
    
    {-# DISPLAY C′ = C′ #-}
    {-# DISPLAY g C′ = c #-}
    

    This now behaves as:

    {-# DISPLAY C = C′ #-}
    {-# DISPLAY g C = c #-}
    

    Expected error for

    test : C ≡ g C
    test = refl
    

    is thus:

    C′ != c of type D
    
  • The built-in floats have new semantics to fix inconsistencies and to improve cross-platform portability.

    • Float equality has been split into two primitives. primFloatEquality is designed to establish decidable propositional equality while primFloatNumericalEquality is intended for numerical computations. They behave as follows:

      primFloatEquality NaN NaN = True
      primFloatEquality 0.0 -0.0 = False
      
      primFloatNumericalEquality NaN NaN = False
      primFloatNumericalEquality 0.0 -0.0 = True
      

      This change fixes an inconsistency, see [Issue #2169]. For further detail see the user manual.

    • Floats now have only one NaN value. This is necessary for proper Float support in the JavaScript backend, as JavaScript (and some other platforms) only support one NaN value.

    • The primitive function primFloatLess was renamed primFloatNumericalLess.

  • Added new primitives to built-in floats:

    • primFloatNegate : Float → Float [Issue #2194]

    • Trigonometric primitives [Issue #2200]:

      primCos   : Float → Float
      primTan   : Float → Float
      primASin  : Float → Float
      primACos  : Float → Float
      primATan  : Float → Float
      primATan2 : Float → Float → Float
      
  • Anonymous declarations [Issue #1465].

    A module can contain an arbitrary number of declarations named _ which will scoped-checked and type-checked but won’t be made available in the scope (nor exported). They cannot introduce arguments on the LHS (but one can use lambda-abstractions on the RHS) and they cannot be defined by recursion.

    _ : Set → Set
    _ = λ x → x
    

Rewriting

  • The REWRITE pragma can now handle several names. E.g.:
    {-# REWRITE eq1 eq2 #-}
    

Reflection

  • You can now use macros in reflected terms [Issue #2130].

    For instance, given a macro

    macro
      some-tactic : Term → TC ⊤
      some-tactic = ...
    

    the term def (quote some-tactic) [] represents a call to the macro. This makes it a lot easier to compose tactics.

  • The reflection machinery now uses normalisation less often:

    • Macros no longer normalise the (automatically quoted) term arguments.

    • The TC primitives inferType, checkType and quoteTC no longer normalise their arguments.

    • The following deprecated constructions may also have been changed: quoteGoal, quoteTerm, quoteContext and tactic.

  • New TC primitive: withNormalisation.

    To recover the old normalising behaviour of inferType, checkType, quoteTC and getContext, you can wrap them inside a call to withNormalisation true:

      withNormalisation : ∀ {a} {A : Set a} → Bool → TC A → TC A
    
  • New TC primitive: reduce.

    reduce : Term → TC Term
    

    Reduces its argument to weak head normal form.

  • Added new TC primitive: isMacro [Issue #2182]

    isMacro : Name → TC Bool
    

    Returns true if the name refers to a macro, otherwise false.

Type checking

  • Files with open metas can be imported now [Issue #964]. This should make simultaneous interactive development on several modules more pleasant.

    Requires option: --allow-unsolved-metas

    Internally, before serialization, open metas are turned into postulates named

      unsolved#meta.<nnn>
    

    where <nnn> is the internal meta variable number.

  • The performance of the compile-time evaluator has been greatly improved.

    • Fixed a memory leak in evaluator (Issue #2147).

    • Reduction speed improved by an order of magnitude and is now comparable to the performance of GHCi. Still call-by-name though.

  • The detection of types that satisfy K added in Agda 2.5.1 has been rolled back (see Issue #2003).

  • Eta-equality for record types is now only on after the positivity checker has confirmed it is safe to have it. Eta-equality for unguarded inductive records previously lead to looping of the type checker. [See Issue #2197]

    record R : Set where
      inductive
      field r : R
    
      loops : R
      loops = ?
    

    As a consequence of this change, the following example does not type-check any more:

    mutual
      record ⊤ : Set where
    
      test : ∀ {x y : ⊤} → x ≡ y
      test = refl
    

    It fails because the positivity checker is only run after the mutual block, thus, eta-equality for is not available when checking test.

    One can declare eta-equality explicitly, though, to make this example work.

    mutual
      record ⊤ : Set where
        eta-equality
    
      test : ∀ {x y : ⊤} → x ≡ y
      test = refl
    
  • Records with instance fields are now eta expanded before instance search.

    For instance, assuming Eq and Ord with boolean functions _==_ and _<_ respectively,

      record EqAndOrd (A : Set) : Set where
        field {{eq}}  : Eq A
              {{ord}} : Ord A
    
    
      leq : {A : Set} {{_ : EqAndOrd A}} → A → A → Bool
      leq x y = x == y || x < y
    

    Here the EqAndOrd record is automatically unpacked before instance search, revealing the component Eq and Ord instances.

    This can be used to simulate superclass dependencies.

  • Overlappable record instance fields.

    Instance fields in records can be marked as overlappable using the new overlap keyword:

      record Ord (A : Set) : Set where
        field
          _<_ : A → A → Bool
          overlap {{eqA}} : Eq A
    

    When instance search finds multiple candidates for a given instance goal and they are all overlappable it will pick the left-most candidate instead of refusing to solve the instance goal.

    This can be use to solve the problem arising from shared “superclass” dependencies. For instance, if you have, in addition to Ord above, a Num record that also has an Eq field and want to write a function requiring both Ord and Num, any Eq constraint will be solved by the Eq instance from whichever argument that comes first.

      record Num (A : Set) : Set where
        field
          fromNat : Nat → A
          overlap {{eqA}} : Eq A
    
      lessOrEqualFive : {A : Set} {{NumA : Num A}} {{OrdA : Ord A}} → A → Bool
      lessOrEqualFive x = x == fromNat 5 || x < fromNat 5
    

    In this example the call to _==_ will use the eqA field from NumA rather than the one from OrdA. Note that these may well be different.

  • Instance fields can be left out of copattern matches [Issue #2288]

    Missing cases for instance fields (marked {{ }}) in copattern matches will be solved using instance search. This makes defining instances with superclass fields much nicer. For instance, we can define Nat instances of Eq, Ord and Num from above as follows:

      instance
        EqNat : Eq Nat
        _==_ {{EqNat}} n m = eqNat n m
    
        OrdNat : Ord Nat
        _<_ {{OrdNat}} n m = lessNat n m
    
        NumNat : Num Nat
        fromNat {{NumNat}} n = n
    

    The eqA fields of Ord and Num are filled in using instance search (with EqNat in this case).

  • Limited instance search depth [Issue #2269]

    To prevent instance search from looping on bad instances (see Issue #1743) the search depth of instance search is now limited. The maximum depth can be set with the --instance-search-depth flag and the default value is 500.

Emacs mode

  • New command C-u C-u C-c C-n: Use show to display the result of normalisation.

    Calling C-u C-u C-c C-n on an expression e (in a hole or at top level) normalises show e and prints the resulting string, or an error message if the expression does not normalise to a literal string.

    This is useful when working with complex data structures for which you have defined a nice Show instance.

    Note that the name show is hardwired into the command.

  • Changed feature: Interactively split result.

    Make-case (C-c C-c) with no variables will now either introduce function arguments or do a copattern split (or fail).

    This is as before:

    test : {A B : Set} (a : A) (b : B) → A × B
    test a b = ?
    
    -- expected:
    -- proj₁ (test a b) = {!!}
    -- proj₂ (test a b) = {!!}
    
    testFun : {A B : Set} (a : A) (b : B) → A × B
    testFun = ?
    
    -- expected:
    -- testFun a b = {!!}
    

    This is has changed:

    record FunRec A : Set where
      field funField : A → A
    open FunRec
    
    testFunRec : ∀{A} → FunRec A
    testFunRec = ?
    
    -- expected (since 2016-05-03):
    -- funField testFunRec = {!!}
    
    -- used to be:
    -- funField testFunRec x = {!!}
    
  • Changed feature: Split on hidden variables.

    Make-case (C-c C-c) will no longer split on the given hidden variables, but only make them visible. (Splitting can then be performed in a second go.)

    test : ∀{N M : Nat} → Nat → Nat → Nat
    test N M = {!.N N .M!}
    

    Invoking splitting will result in:

    test {N} {M} zero M₁ = ?
    test {N} {M} (suc N₁) M₁ = ?
    

    The hidden .N and .M have been brought into scope, the visible N has been split upon.

  • Non-fatal errors/warnings.

    Non-fatal errors and warnings are now displayed in the info buffer and do not interrupt the typechecking of the file.

    Currently termination errors, unsolved metavariables, unsolved constraints, positivity errors, deprecated BUILTINs, and empty REWRITING pragmas are non-fatal errors.

  • Highlighting for positivity check failures

    Negative occurences of a datatype in its definition are now highlighted in a way similar to termination errors.

  • The abbrev for codata was replaced by an abbrev for code environments.

    If you type c C-x ' (on a suitably standard setup), then Emacs will insert the following text:

    \begin{code}<newline>  <cursor><newline>\end{code}<newline>.
    
  • The LaTeX backend can now be invoked from the Emacs mode.

    Using the compilation command (C-c C-x C-c).

    The flag --latex-dir can be used to set the output directory (by default: latex). Note that if this directory is a relative path, then it is interpreted relative to the “project root”. (When the LaTeX backend is invoked from the command line the path is interpreted relative to the current working directory.) Example: If the module A.B.C is located in the file /foo/A/B/C.agda, then the project root is /foo/, and the default output directory is /foo/latex/.

  • The compilation command (C-c C-x C-c) now by default asks for a backend.

    To avoid this question, set the customisation variable agda2-backend to an appropriate value.

  • The command agda2-measure-load-time no longer “touches” the file, and the optional argument DONT-TOUCH has been removed.

  • New command C-u (C-u) C-c C-s: Simplify or normalise the solution C-c C-s produces

    When writing examples, it is nice to have the hole filled in with a normalised version of the solution. Calling C-c C-s on

    _ : reverse (0 ∷ 1 ∷ []) ≡ ?
    _ = refl
    

    used to yield the non informative reverse (0 ∷ 1 ∷ []) when we would have hopped to get 1 ∷ 0 ∷ [] instead. We can now control finely the degree to which the solution is simplified.

  • Changed feature: Solving the hole at point

    Calling C-c C-s inside a specific goal does not solve all the goals already instantiated internally anymore: it only solves the one at hand (if possible).

  • New bindings: All the blackboard bold letters are now available [Pull Request #2305]

    The Agda input method only bound a handful of the blackboard bold letters but programmers were actually using more than these. They are now all available: lowercase and uppercase. Some previous bindings had to be modified for consistency. The naming scheme is as follows:

    • \bx for lowercase blackboard bold
    • \bX for uppercase blackboard bold
    • \bGx for lowercase greek blackboard bold (similar to \Gx for greeks)
    • \bGX for uppercase greek blackboard bold (similar to \GX for uppercase greeks)
  • Replaced binding for go back

    Use M-, (instead of M-*) for go back in Emacs ≥ 25.1 (and continue using M-* with previous versions of Emacs).

Compiler backends

  • JS compiler backend

    The JavaScript backend has been (partially) rewritten. The JavaScript backend now supports most Agda features, notably copatterns can now be compiled to JavaScript. Furthermore, the existing optimizations from the other backends now apply to the JavaScript backend as well.

  • GHC, JS and UHC compiler backends

    Added new primitives to built-in floats [Issues #2194 and #2200]:

    primFloatNegate : Float → Float
    primCos         : Float → Float
    primTan         : Float → Float
    primASin        : Float → Float
    primACos        : Float → Float
    primATan        : Float → Float
    primATan2       : Float → Float → Float
    

LaTeX backend

  • Code blocks are now (by default) surrounded by vertical space. [Issue #2198]

    Use \AgdaNoSpaceAroundCode{} to avoid this vertical space, and \AgdaSpaceAroundCode{} to reenable it.

    Note that, if \AgdaNoSpaceAroundCode{} is used, then empty lines before or after a code block will not necessarily lead to empty lines in the generated document. However, empty lines inside the code block do (by default) lead to empty lines in the output.

    If you prefer the previous behaviour, then you can use the agda.sty file that came with the previous version of Agda.

  • \AgdaHide{...} now eats trailing spaces (using \ignorespaces).

  • New environments: AgdaAlign, AgdaSuppressSpace and AgdaMultiCode.

    Sometimes one might want to break up a code block into multiple pieces, but keep code in different blocks aligned with respect to each other. Then one can use the AgdaAlign environment. Example usage:

      \begin{AgdaAlign}
      \begin{code}
        code
          code  (more code)
      \end{code}
      Explanation...
      \begin{code}
        aligned with "code"
          code  (aligned with (more code))
      \end{code}
      \end{AgdaAlign}
    

    Note that AgdaAlign environments should not be nested.

    Sometimes one might also want to hide code in the middle of a code block. This can be accomplished in the following way:

      \begin{AgdaAlign}
      \begin{code}
        visible
      \end{code}
      \AgdaHide{
      \begin{code}
        hidden
      \end{code}}
      \begin{code}
        visible
      \end{code}
      \end{AgdaAlign}
    

    However, the result may be ugly: extra space is perhaps inserted around the code blocks.

    The AgdaSuppressSpace environment ensures that extra space is only inserted before the first code block, and after the last one (but not if \AgdaNoSpaceAroundCode{} is used).

    The environment takes one argument, the number of wrapped code blocks (excluding hidden ones). Example usage:

      \begin{AgdaAlign}
      \begin{code}
        code
          more code
      \end{code}
      Explanation...
      \begin{AgdaSuppressSpace}{2}
      \begin{code}
        aligned with "code"
          aligned with "more code"
      \end{code}
      \AgdaHide{
      \begin{code}
        hidden code
      \end{code}}
      \begin{code}
          also aligned with "more code"
      \end{code}
      \end{AgdaSuppressSpace}
      \end{AgdaAlign}
    

    Note that AgdaSuppressSpace environments should not be nested.

    There is also a combined environment, AgdaMultiCode, that combines the effects of AgdaAlign and AgdaSuppressSpace.

Tools

agda-ghc-names

The agda-ghc-names now has its own repository at

https://github.com/agda/agda-ghc-names

and is no longer distributed with Agda.

Release notes for Agda version 2.5.1.2

  • Fixed broken type signatures that were incorrectly accepted due to GHC #12784.

Release notes for Agda version 2.5.1.1

Installation and infrastructure

  • Added support for GHC 8.0.1.

  • Documentation is now built with Python >=3.3, as done by readthedocs.org.

Bug fixes

  • Fixed a serious performance problem with instance search

    Issues #1952 and #1998. Also related: #1955 and #2025

  • Interactively splitting variable with C-c C-c no longer introduces new trailing patterns. This fixes Issue #1950.

    data Ty : Set where
      _⇒_ : Ty → Ty → Ty
    
    ⟦_⟧ : Ty → Set
    ⟦ A ⇒ B ⟧ = ⟦ A ⟧ → ⟦ B ⟧
    
    data Term : Ty → Set where
      K : (A B : Ty) → Term (A ⇒ (B ⇒ A))
    
    test : (A : Ty) (a : Term A) → ⟦ A ⟧
    test A a = {!a!}
    

    Before change, case splitting on a would give

    test .(A ⇒ (B ⇒ A)) (K A B) x x₁ = ?
    

    Now, it yields

    test .(A ⇒ (B ⇒ A)) (K A B) = ?
    
  • In literate TeX files, \begin{code} and \end{code} can be preceded (resp. followed) by TeX code on the same line. This fixes Issue #2077.

  • Other issues fixed (see bug tracker):

    #1951 (mixfix binders not working in ‘syntax’)

    #1967 (too eager insteance search error)

    #1974 (lost constraint dependencies)

    #1982 (internal error in unifier)

    #2034 (function type instance goals)

Compiler backends

  • UHC compiler backend

    Added support for UHC 1.1.9.4.

Release notes for Agda version 2.5.1

Documentation

Installation and infrastructure

  • Builtins and primitives are now defined in a new set of modules available to all users, independent of any particular library. The modules are

    Agda.Builtin.Bool
    Agda.Builtin.Char
    Agda.Builtin.Coinduction
    Agda.Builtin.Equality
    Agda.Builtin.Float
    Agda.Builtin.FromNat
    Agda.Builtin.FromNeg
    Agda.Builtin.FromString
    Agda.Builtin.IO
    Agda.Builtin.Int
    Agda.Builtin.List
    Agda.Builtin.Nat
    Agda.Builtin.Reflection
    Agda.Builtin.Size
    Agda.Builtin.Strict
    Agda.Builtin.String
    Agda.Builtin.TrustMe
    Agda.Builtin.Unit
    

    The standard library reexports the primitives from the new modules.

    The Agda.Builtin modules are installed in the same way as Agda.Primitive, but unlike Agda.Primitive they are not loaded automatically.

Pragmas and options

  • Library management

    There is a new ‘library’ concept for managing include paths. A library consists of

    • a name,
    • a set of libraries it depends on, and
    • a set of include paths.

    A library is defined in a .agda-lib file using the following format:

    name: LIBRARY-NAME  -- Comment
    depend: LIB1 LIB2
      LIB3
      LIB4
    include: PATH1
      PATH2
      PATH3
    

    Dependencies are library names, not paths to .agda-lib files, and include paths are relative to the location of the library-file.

    To be useable, a library file has to be listed (with its full path) in AGDA_DIR/libraries (or AGDA_DIR/libraries-VERSION, for a given Agda version). AGDA_DIR defaults to ~/.agda on Unix-like systems and C:/Users/USERNAME/AppData/Roaming/agda or similar on Windows, and can be overridden by setting the AGDA_DIR environment variable.

    Environment variables in the paths (of the form $VAR or ${VAR}) are expanded. The location of the libraries file used can be overridden using the --library-file=FILE flag, although this is not expected to be very useful.

    You can find out the precise location of the ‘libraries’ file by calling agda -l fjdsk Dummy.agda and looking at the error message (assuming you don’t have a library called fjdsk installed).

    There are three ways a library gets used:

    • You supply the --library=LIB (or -l LIB) option to Agda. This is equivalent to adding a -iPATH for each of the include paths of LIB and its (transitive) dependencies.

    • No explicit --library flag is given, and the current project root (of the Agda file that is being loaded) or one of its parent directories contains a .agda-lib file defining a library LIB. This library is used as if a --librarary=LIB option had been given, except that it is not necessary for the library to be listed in the AGDA_DIR/libraries file.

    • No explicit --library flag, and no .agda-lib file in the project root. In this case the file AGDA_DIR/defaults is read and all libraries listed are added to the path. The defaults file should contain a list of library names, each on a separate line. In this case the current directory is also added to the path.

      To disable default libraries, you can give the flag --no-default-libraries.

    Library names can end with a version number (for instance, mylib-1.2.3). When resolving a library name (given in a --library flag, or listed as a default library or library dependency) the following rules are followed:

    • If you don’t give a version number, any version will do.

    • If you give a version number an exact match is required.

    • When there are multiple matches an exact match is preferred, and otherwise the latest matching version is chosen.

    For example, suppose you have the following libraries installed: mylib, mylib-1.0, otherlib-2.1, and otherlib-2.3. In this case, aside from the exact matches you can also say --library=otherlib to get otherlib-2.3.

  • New Pragma COMPILED_DECLARE_DATA for binding recursively defined Haskell data types to recursively defined Agda data types.

    If you have a Haskell type like

    {-# LANGUAGE GADTs #-}
    
    module Issue223 where
    
    data A where
      BA :: B -> A
    
    data B where
      AB :: A -> B
      BB :: B
    

    You can now bind it to corresponding mutual Agda inductive data types as follows:

    {-# IMPORT Issue223 #-}
    
    data A : Set
    {-# COMPILED_DECLARE_DATA A Issue223.A #-}
    data B : Set
    {-# COMPILED_DECLARE_DATA B Issue223.B #-}
    
    data A where
      BA : B → A
    
    {-# COMPILED_DATA A Issue223.A Issue223.BA #-}
    data B where
      AB : A → B
      BB : B
    
    {-# COMPILED_DATA B Issue223.B Issue223.AB Issue223.BB #-}
    

    This fixes Issue #223.

  • New pragma HASKELL for adding inline Haskell code (GHC backend only)

    Arbitrary Haskell code can be added to a module using the HASKELL pragma. For instance,

    {-# HASKELL
      echo :: IO ()
      echo = getLine >>= putStrLn
    #-}
    
    postulate echo : IO ⊤
    {-# COMPILED echo echo #-}
    
  • New option --exact-split.

    The --exact-split flag causes Agda to raise an error whenever a clause in a definition by pattern matching cannot be made to hold definitionally (i.e. as a reduction rule). Specific clauses can be excluded from this check by means of the {-# CATCHALL #-} pragma.

    For instance, the following definition will be rejected as the second clause cannot be made to hold definitionally:

    min : Nat → Nat → Nat
    min zero    y       = zero
    min x       zero    = zero
    min (suc x) (suc y) = suc (min x y
    

    Catchall clauses have to be marked as such, for instance:

    eq : Nat → Nat → Bool
    eq zero    zero    = true
    eq (suc m) (suc n) = eq m n
    {-# CATCHALL #-}
    eq _       _       = false
    
  • New option: --no-exact-split.

    This option can be used to override a global --exact-split in a file, by adding a pragma {-# OPTIONS --no-exact-split #-}.

  • New options: --sharing and --no-sharing.

    These options are used to enable/disable sharing and call-by-need evaluation. The default is --no-sharing.

    Note that they cannot appear in an OPTIONS pragma, but have to be given as command line arguments or added to the Agda Program Args from Emacs with M-x customize-group agda2.

  • New pragma DISPLAY.

    {-# DISPLAY f e1 .. en = e #-}
    

    This causes f e1 .. en to be printed in the same way as e, where ei can bind variables used in e. The expressions ei and e are scope checked, but not type checked.

    For example this can be used to print overloaded (instance) functions with the overloaded name:

    instance
      NumNat : Num Nat
      NumNat = record { ..; _+_ = natPlus }
    
    {-# DISPLAY natPlus a b = a + b #-}
    

    Limitations

    • Left-hand sides are restricted to variables, constructors, defined functions or types, and literals. In particular, lambdas are not allowed in left-hand sides.

    • Since DISPLAY pragmas are not type checked implicit argument insertion may not work properly if the type of f computes to an implicit function space after pattern matching.

  • Removed pragma {-# ETA R #-}

    The pragma {-# ETA R #-} is replaced by the eta-equality directive inside record declarations.

  • New option --no-eta-equality.

    The --no-eta-equality flag disables eta rules for declared record types. It has the same effect as no-eta-equality inside each declaration of a record type R.

    If used with the OPTIONS pragma it will not affect records defined in other modules.

  • The semantics of {-# REWRITE r #-} pragmas in parametrized modules has changed (see Issue #1652).

    Rewrite rules are no longer lifted to the top context. Instead, they now only apply to terms in (extensions of) the module context. If you want the old behaviour, you should put the {-# REWRITE r #-} pragma outside of the module (i.e. unindent it).

  • New pragma {-# INLINE f #-} causes f to be inlined during compilation.

  • The STATIC pragma is now taken into account during compilation.

    Calls to a function marked STATIC are normalised before compilation. The typical use case for this is to mark the interpreter of an embedded language as STATIC.

  • Option --type-in-type no longer implies --no-universe-polymorphism, thus, it can be used with explicit universe levels. [Issue #1764] It simply turns off error reporting for any level mismatch now. Examples:

    {-# OPTIONS --type-in-type #-}
    
    Type : Set
    Type = Set
    
    data D {α} (A : Set α) : Set where
      d : A → D A
    
    data E α β : Set β where
      e : Set α → E α β
    
  • New NO_POSITIVITY_CHECK pragma to switch off the positivity checker for data/record definitions and mutual blocks.

    The pragma must precede a data/record definition or a mutual block.

    The pragma cannot be used in --safe mode.

    Examples (see Issue1614*.agda and Issue1760*.agda in test/Succeed/):

    1. Skipping a single data definition.

      {-# NO_POSITIVITY_CHECK #-}
      data D : Set where
        lam : (D → D) → D
      
    2. Skipping a single record definition.

      {-# NO_POSITIVITY_CHECK #-}
      record U : Set where
        field ap : U → U
      
    3. Skipping an old-style mutual block: Somewhere within a mutual block before a data/record definition.

      mutual
        data D : Set where
          lam : (D → D) → D
      
        {-# NO_POSITIVITY_CHECK #-}
        record U : Set where
          field ap : U → U
      
    4. Skipping an old-style mutual block: Before the mutual keyword.

      {-# NO_POSITIVITY_CHECK #-}
      mutual
        data D : Set where
          lam : (D → D) → D
      
        record U : Set where
          field ap : U → U
      
    5. Skipping a new-style mutual block: Anywhere before the declaration or the definition of data/record in the block.

      record U : Set
      data D   : Set
      
      record U where
        field ap : U → U
      
      {-# NO_POSITIVITY_CHECK #-}
      data D where
        lam : (D → D) → D
      
  • Removed --no-coverage-check option. [Issue #1918]

Language

Operator syntax

  • The default fixity for syntax declarations has changed from -666 to 20.

  • Sections.

    Operators can be sectioned by replacing arguments with underscores. There must not be any whitespace between these underscores and the adjacent nameparts. Examples:

    pred : ℕ → ℕ
    pred = _∸ 1
    
    T : Bool → Set
    T = if_then ⊤ else ⊥
    
    if : {A : Set} (b : Bool) → A → A → A
    if b = if b then_else_
    

    Sections are translated into lambda expressions. Examples:

    _∸ 1              ↦  λ section → section ∸ 1
    
    if_then ⊤ else ⊥  ↦  λ section → if section then ⊤ else ⊥
    
    if b then_else_   ↦  λ section section₁ →
                             if b then section else section₁
    

    Operator sections have the same fixity as the underlying operator (except in cases like if b then_else_, in which the section is “closed”, but the operator is not).

    Operator sections are not supported in patterns (with the exception of dot patterns), and notations coming from syntax declarations cannot be sectioned.

  • A long-standing operator fixity bug has been fixed. As a consequence some programs that used to parse no longer do.

    Previously each precedence level was (incorrectly) split up into five separate ones, ordered as follows, with the earlier ones binding less tightly than the later ones:

    • Non-associative operators.

    • Left associative operators.

    • Right associative operators.

    • Prefix operators.

    • Postfix operators.

    Now this problem has been addressed. It is no longer possible to mix operators of a given precedence level but different associativity. However, prefix and right associative operators are seen as having the same associativity, and similarly for postfix and left associative operators.

    Examples

    The following code is no longer accepted:

    infixl 6 _+_
    infix  6 _∸_
    
    rejected : ℕ
    rejected = 1 + 0 ∸ 1
    

    However, the following previously rejected code is accepted:

    infixr 4 _,_
    infix  4 ,_
    
    ,_ : {A : Set} {B : A → Set} {x : A} → B x → Σ A B
    , y = _ , y
    
    accepted : Σ ℕ λ i → Σ ℕ λ j → Σ (i ≡ j) λ _ → Σ ℕ λ k → j ≡ k
    accepted = 5 , , refl , , refl
    
  • The classification of notations with binders into the categories infix, prefix, postfix or closed has changed. [Issue #1450]

    The difference is that, when classifying the notation, only regular holes are taken into account, not binding ones.

    Example: The notation

    syntax m >>= (λ x → f) = x <- m , f
    

    was previously treated as infix, but is now treated as prefix.

  • Notation can now include wildcard binders.

    Example: syntax Σ A (λ _ → B) = A × B

  • If an overloaded operator is in scope with several distinct precedence levels, then several instances of this operator will be included in the operator grammar, possibly leading to ambiguity. Previously the operator was given the default fixity [Issue #1436].

    There is an exception to this rule: If there are multiple precedences, but at most one is explicitly declared, then only one instance will be included in the grammar. If there are no explicitly declared precedences, then this instance will get the default precedence, and otherwise it will get the declared precedence.

    If multiple occurrences of an operator are “merged” in the grammar, and they have distinct associativities, then they are treated as being non-associative.

    The three paragraphs above also apply to identical notations (coming from syntax declarations) for a given overloaded name.

    Examples:

    module A where
    
      infixr 5 _∷_
      infixr 5 _∙_
      infixl 3 _+_
      infix  1 bind
    
      syntax bind c (λ x → d) = x ← c , d
    
    module B where
    
      infix  5 _∷_
      infixr 4 _∙_
      -- No fixity declaration for _+_.
      infixl 2 bind
    
      syntax bind c d = c ∙ d
    
    module C where
    
      infixr 2 bind
    
      syntax bind c d = c ∙ d
    
    open A
    open B
    open C
    
    -- _∷_ is infix 5.
    -- _∙_ has two fixities: infixr 4 and infixr 5.
    -- _+_ is infixl 3.
    -- A.bind's notation is infix 1.
    -- B.bind and C.bind's notations are infix 2.
    
    -- There is one instance of "_ ∷ _" in the grammar, and one
    -- instance of "_ + _".
    
    -- There are three instances of "_ ∙ _" in the grammar, one
    -- corresponding to A._∙_, one corresponding to B._∙_, and one
    -- corresponding to both B.bind and C.bind.
    

Reflection

  • The reflection framework has received a massive overhaul.

    A new type of reflected type checking computations supplants most of the old reflection primitives. The quoteGoal, quoteContext and tactic primitives are deprecated and will be removed in the future, and the unquoteDecl and unquote primitives have changed behaviour. Furthermore the following primitive functions have been replaced by builtin type checking computations:

    - primQNameType              --> AGDATCMGETTYPE
    - primQNameDefinition        --> AGDATCMGETDEFINITION
    - primDataConstructors       --> subsumed by AGDATCMGETDEFINITION
    - primDataNumberOfParameters --> subsumed by AGDATCMGETDEFINITION
    

    See below for details.

  • Types are no longer packaged with a sort.

    The AGDATYPE and AGDATYPEEL built-ins have been removed. Reflected types are now simply terms.

  • Reflected definitions have more information.

    The type for reflected definitions has changed to

    data Definition : Set where
      fun-def     : List Clause  → Definition
      data-type   : Nat → List Name → Definition -- parameters and constructors
      record-type : Name → Definition            -- name of the data/record type
      data-con    : Name → Definition            -- name of the constructor
      axiom       : Definition
      prim-fun    : Definition
    

    Correspondingly the built-ins for function, data and record definitions (AGDAFUNDEF, AGDAFUNDEFCON, AGDADATADEF, AGDARECORDDEF) have been removed.

  • Reflected type checking computations.

    There is a primitive TC monad representing type checking computations. The unquote, unquoteDecl, and the new unquoteDef all expect computations in this monad (see below). The interface to the monad is the following

    -- Error messages can contain embedded names and terms.
    data ErrorPart : Set where
      strErr  : String → ErrorPart
      termErr : Term → ErrorPart
      nameErr : Name → ErrorPart
    
    {-# BUILTIN AGDAERRORPART       ErrorPart #-}
    {-# BUILTIN AGDAERRORPARTSTRING strErr    #-}
    {-# BUILTIN AGDAERRORPARTTERM   termErr   #-}
    {-# BUILTIN AGDAERRORPARTNAME   nameErr   #-}
    
    postulate
      TC         : ∀ {a} → Set a → Set a
      returnTC   : ∀ {a} {A : Set a} → A → TC A
      bindTC     : ∀ {a b} {A : Set a} {B : Set b} → TC A → (A → TC B) → TC B
    
      -- Unify two terms, potentially solving metavariables in the process.
      unify      : Term → Term → TC ⊤
    
      -- Throw a type error. Can be caught by catchTC.
      typeError  : ∀ {a} {A : Set a} → List ErrorPart → TC A
    
      -- Block a type checking computation on a metavariable. This will abort
      -- the computation and restart it (from the beginning) when the
      -- metavariable is solved.
      blockOnMeta : ∀ {a} {A : Set a} → Meta → TC A
    
      -- Backtrack and try the second argument if the first argument throws a
      -- type error.
      catchTC    : ∀ {a} {A : Set a} → TC A → TC A → TC A
    
      -- Infer the type of a given term
      inferType  : Term → TC Type
    
      -- Check a term against a given type. This may resolve implicit arguments
      -- in the term, so a new refined term is returned. Can be used to create
      -- new metavariables: newMeta t = checkType unknown t
      checkType  : Term → Type → TC Term
    
      -- Compute the normal form of a term.
      normalise  : Term → TC Term
    
      -- Get the current context.
      getContext : TC (List (Arg Type))
    
      -- Extend the current context with a variable of the given type.
      extendContext : ∀ {a} {A : Set a} → Arg Type → TC A → TC A
    
      -- Set the current context.
      inContext     : ∀ {a} {A : Set a} → List (Arg Type) → TC A → TC A
    
      -- Quote a value, returning the corresponding Term.
      quoteTC : ∀ {a} {A : Set a} → A → TC Term
    
      -- Unquote a Term, returning the corresponding value.
      unquoteTC : ∀ {a} {A : Set a} → Term → TC A
    
      -- Create a fresh name.
      freshName  : String → TC QName
    
      -- Declare a new function of the given type. The function must be defined
      -- later using 'defineFun'. Takes an Arg Name to allow declaring instances
      -- and irrelevant functions. The Visibility of the Arg must not be hidden.
      declareDef : Arg QName → Type → TC ⊤
    
      -- Define a declared function. The function may have been declared using
      -- 'declareDef' or with an explicit type signature in the program.
      defineFun  : QName → List Clause → TC ⊤
    
      -- Get the type of a defined name. Replaces 'primQNameType'.
      getType    : QName → TC Type
    
      -- Get the definition of a defined name. Replaces 'primQNameDefinition'.
      getDefinition : QName → TC Definition
    
    {-# BUILTIN AGDATCM                   TC                 #-}
    {-# BUILTIN AGDATCMRETURN             returnTC           #-}
    {-# BUILTIN AGDATCMBIND               bindTC             #-}
    {-# BUILTIN AGDATCMUNIFY              unify              #-}
    {-# BUILTIN AGDATCMNEWMETA            newMeta            #-}
    {-# BUILTIN AGDATCMTYPEERROR          typeError          #-}
    {-# BUILTIN AGDATCMBLOCKONMETA        blockOnMeta        #-}
    {-# BUILTIN AGDATCMCATCHERROR         catchTC            #-}
    {-# BUILTIN AGDATCMINFERTYPE          inferType          #-}
    {-# BUILTIN AGDATCMCHECKTYPE          checkType          #-}
    {-# BUILTIN AGDATCMNORMALISE          normalise          #-}
    {-# BUILTIN AGDATCMGETCONTEXT         getContext         #-}
    {-# BUILTIN AGDATCMEXTENDCONTEXT      extendContext      #-}
    {-# BUILTIN AGDATCMINCONTEXT          inContext          #-}
    {-# BUILTIN AGDATCMQUOTETERM          quoteTC            #-}
    {-# BUILTIN AGDATCMUNQUOTETERM        unquoteTC          #-}
    {-# BUILTIN AGDATCMFRESHNAME          freshName          #-}
    {-# BUILTIN AGDATCMDECLAREDEF         declareDef         #-}
    {-# BUILTIN AGDATCMDEFINEFUN          defineFun          #-}
    {-# BUILTIN AGDATCMGETTYPE            getType            #-}
    {-# BUILTIN AGDATCMGETDEFINITION      getDefinition      #-}
    
  • Builtin type for metavariables

    There is a new builtin type for metavariables used by the new reflection framework. It is declared as follows and comes with primitive equality, ordering and show.

    postulate Meta : Set
    {-# BUILTIN AGDAMETA Meta #-}
    primitive primMetaEquality : Meta → Meta → Bool
    primitive primMetaLess : Meta → Meta → Bool
    primitive primShowMeta : Meta → String
    

    There are corresponding new constructors in the Term and Literal data types:

    data Term : Set where
      ...
      meta : Meta → List (Arg Term) → Term
    
    {-# BUILTIN AGDATERMMETA meta #-}
    
    data Literal : Set where
      ...
      meta : Meta → Literal
    
    {-# BUILTIN AGDALITMETA meta #-}
    
  • Builtin unit type

    The type checker needs to know about the unit type, which you can allow by

    record ⊤ : Set where
    {-# BUILTIN UNIT ⊤ #-}
    
  • Changed behaviour of unquote

    The unquote primitive now expects a type checking computation instead of a pure term. In particular unquote e requires

    e : Term → TC ⊤
    

    where the argument is the representation of the hole in which the result should go. The old unquote behaviour (where unquote expected a Term argument) can be recovered by

    OLD: unquote v
    NEW: unquote λ hole → unify hole v
    
  • Changed behaviour of unquoteDecl

    The unquoteDecl primitive now expects a type checking computation instead of a pure function definition. It is possible to define multiple (mutually recursive) functions at the same time. More specifically

    unquoteDecl x₁ .. xₙ = m
    

    requires m : TC ⊤ and that x₁ .. xₙ are defined (using declareDef and defineFun) after executing m. As before x₁ .. xₙ : QName in m, but have their declared types outside the unquoteDecl.

  • New primitive unquoteDef

    There is a new declaration

    unquoteDef x₁ .. xₙ = m
    

    This works exactly as unquoteDecl (see above) with the exception that x₁ .. xₙ are required to already be declared.

    The main advantage of unquoteDef over unquoteDecl is that unquoteDef is allowed in mutual blocks, allowing mutually recursion between generated definitions and hand-written definitions.

  • The reflection interface now exposes the name hint (as a string) for variables. As before, the actual binding structure is with de Bruijn indices. The String value is just a hint used as a prefix to help display the variable. The type Abs is a new builtin type used for the constructors Term.lam, Term.pi, Pattern.var (bultins AGDATERMLAM, AGDATERMPI and AGDAPATVAR).

    data Abs (A : Set) : Set where
      abs : (s : String) (x : A) → Abs A
    {-# BUILTIN ABS    Abs #-}
    {-# BUILTIN ABSABS abs #-}
    

    Updated constructor types:

    Term.lam    : Hiding   → Abs Term → Term
    Term.pi     : Arg Type → Abs Type → Term
    Pattern.var : String   → Pattern
    
  • Reflection-based macros

    Macros are functions of type t1 → t2 → .. → Term → TC ⊤ that are defined in a macro block. Macro application is guided by the type of the macro, where Term arguments desugar into the quoteTerm syntax and Name arguments into the quote syntax. Arguments of any other type are preserved as-is. The last Term argument is the hole term given to unquote computation (see above).

    For example, the macro application f u v w where the macro f has the type Term → Name → Bool → Term → TC ⊤ desugars into unquote (f (quoteTerm u) (quote v) w)

    Limitations:

    • Macros cannot be recursive. This can be worked around by defining the recursive function outside the macro block and have the macro call the recursive function.

    Silly example:

    macro
      plus-to-times : Term → Term → TC ⊤
      plus-to-times (def (quote _+_) (a ∷ b ∷ [])) hole = unify hole (def (quote _*_) (a ∷ b ∷ []))
      plus-to-times v hole = unify hole v
    
    thm : (a b : Nat) → plus-to-times (a + b) ≡ a * b
    thm a b = refl
    

    Macros are most useful when writing tactics, since they let you hide the reflection machinery. For instance, suppose you have a solver

    magic : Type → Term
    

    that takes a reflected goal and outputs a proof (when successful). You can then define the following macro

    macro
      by-magic : Term → TC ⊤
      by-magic hole =
        bindTC (inferType hole) λ goal →
        unify hole (magic goal)
    

    This lets you apply the magic tactic without any syntactic noise at all:

    thm : ¬ P ≡ NP
    thm = by-magic
    

Literals and built-ins

  • Overloaded number literals.

    You can now overload natural number literals using the new builtin FROMNAT:

    {-# BUILTIN FROMNAT fromNat #-}
    

    The target of the builtin should be a defined name. Typically you would do something like

    record Number (A : Set) : Set where
      field fromNat : Nat → A
    
    open Number {{...}} public
    
    {-# BUILTIN FROMNAT fromNat #-}
    

    This will cause number literals n to be desugared to fromNat n before type checking.

  • Negative number literals.

    Number literals can now be negative. For floating point literals it works as expected. For integer literals there is a new builtin FROMNEG that enables negative integer literals:

    {-# BUILTIN FROMNEG fromNeg #-}
    

    This causes negative literals -n to be desugared to fromNeg n.

  • Overloaded string literals.

    String literals can be overladed using the FROMSTRING builtin:

    {-# BUILTIN FROMSTRING fromString #-}
    

    The will cause string literals s to be desugared to fromString s before type checking.

  • Change to builtin integers.

    The INTEGER builtin now needs to be bound to a datatype with two constructors that should be bound to the new builtins INTEGERPOS and INTEGERNEGSUC as follows:

    data Int : Set where
      pos    : Nat -> Int
      negsuc : Nat -> Int
    {-# BUILTIN INTEGER       Int    #-}
    {-# BUILTIN INTEGERPOS    pos    #-}
    {-# BUILTIN INTEGERNEGSUC negsuc #-}
    

    where negsuc n represents the integer -n - 1. For instance, -5 is represented as negsuc 4. All primitive functions on integers except primShowInteger have been removed, since these can be defined without too much trouble on the above representation using the corresponding functions on natural numbers.

    The primitives that have been removed are

    primIntegerPlus
    primIntegerMinus
    primIntegerTimes
    primIntegerDiv
    primIntegerMod
    primIntegerEquality
    primIntegerLess
    primIntegerAbs
    primNatToInteger
    
  • New primitives for strict evaluation

    primitive
      primForce      : ∀ {a b} {A : Set a} {B : A → Set b} (x : A) → (∀ x → B x) → B x
      primForceLemma : ∀ {a b} {A : Set a} {B : A → Set b} (x : A) (f : ∀ x → B x) → primForce x f ≡ f x
    

    primForce x f evaluates to f x if x is in weak head normal form, and primForceLemma x f evaluates to refl in the same situation. The following values are considered to be in weak head normal form:

    • constructor applications
    • literals
    • lambda abstractions
    • type constructor (data/record types) applications
    • function types
    • Set a

Modules

  • Modules in import directives

    When you use using/hiding/renaming on a name it now automatically applies to any module of the same name, unless you explicitly mention the module. For instance,

    open M using (D)
    

    is equivalent to

    open M using (D; module D)
    

    if M defines a module D. This is most useful for record and data types where you always get a module of the same name as the type.

    With this feature there is no longer useful to be able to qualify a constructor (or field) by the name of the data type even when it differs from the name of the corresponding module. The follow (weird) code used to work, but doesn’t work anymore:

    module M where
      data D where
        c : D
    open M using (D) renaming (module D to MD)
    foo : D
    foo = D.c
    

    If you want to import only the type name and not the module you have to hide it explicitly:

    open M using (D) hiding (module D)
    

    See discussion on Issue #836.

  • Private definitions of a module are no longer in scope at the Emacs mode top-level.

    The reason for this change is that .agdai-files are stripped of unused private definitions (which can yield significant performance improvements for module-heavy code).

    To test private definitions you can create a hole at the bottom of the module, in which private definitions will be visible.

Records

  • New record directives eta-equality/no-eta-equality

    The keywords eta-equality/no-eta-equality enable/disable eta rules for the (inductive) record type being declared.

    record Σ (A : Set) (B : A -> Set) : Set where
      no-eta-equality
      constructor _,_
      field
        fst : A
        snd : B fst
    open Σ
    
    -- fail : ∀ {A : Set}{B : A -> Set} → (x : Σ A B) → x ≡ (fst x , snd x)
    -- fail x = refl
    --
    -- x != fst x , snd x of type Σ .A .B
    -- when checking that the expression refl has type x ≡ (fst x , snd x)
    
  • Building records from modules.

    The record { <fields> } syntax is now extended to accept module names as well. Fields are thus defined using the corresponding definitions from the given module.

    For instance assuming this record type R and module M:

    record R : Set where
      field
        x : X
        y : Y
        z : Z
    
    module M where
      x = {! ... !}
      y = {! ... !}
    
    r : R
    r = record { M; z = {! ... !} }
    

    Previously one had to write record { x = M.x; y = M.y; z = {! ... !} }.

    More precisely this construction now supports any combination of explicit field definitions and applied modules.

    If a field is both given explicitly and available in one of the modules, then the explicit one takes precedence.

    If a field is available in more than one module then this is ambiguous and therefore rejected. As a consequence the order of assignments does not matter.

    The modules can be both applied to arguments and have import directives such as hiding, using, and renaming. In particular this construct subsumes the record update construction.

    Here is an example of record update:

    -- Record update. Same as: record r { y = {! ... !} }
    r2 : R
    r2 = record { R r; y = {! ... !} }
    

    A contrived example showing the use of hiding/renaming:

    module M2 (a : A) where
      w = {! ... !}
      z = {! ... !}
    
    r3 : A → R
    r3 a = record { M hiding (y); M2 a renaming (w to y) }
    
  • Record patterns are now accepted.

    Examples:

    swap : {A B : Set} (p : A × B) → B × A
    swap record{ proj₁ = a; proj₂ = b } = record{ proj₁ = b; proj₂ = a }
    
    thd3 : ...
    thd3 record{ proj₂ = record { proj₂ = c }} = c
    
  • Record modules now properly hide all their parameters [Issue #1759]

    Previously parameters to parent modules were not hidden in the record module, resulting in different behaviour between

    module M (A : Set) where
      record R (B : Set) : Set where
    

    and

    module M where
      record R (A B : Set) : Set where
    

    where in the former case, A would be an explicit argument to the module M.R, but implicit in the latter case. Now A is implicit in both cases.

Instance search

  • Performance has been improved, recursive instance search which was previously exponential in the depth is now only quadratic.

  • Constructors of records and datatypes are not anymore automatically considered as instances, you have to do so explicitely, for instance:

    -- only [b] is an instance of D
    data D : Set where
      a : D
      instance
        b : D
      c : D
    
    -- the constructor is now an instance
    record tt : Set where
      instance constructor tt
    
  • Lambda-bound variables are no longer automatically considered instances.

    Lambda-bound variables need to be bound as instance arguments to be considered for instance search. For example,

    _==_ : {A : Set} {{_ : Eq A}} → A → A → Bool
    
    fails : {A : Set} → Eq A → A → Bool
    fails eqA x = x == x
    
    works : {A : Set} {{_ : Eq A}} → A → Bool
    works x = x == x
    
  • Let-bound variables are no longer automatically considered instances.

    To make a let-bound variable available as an instance it needs to be declared with the instance keyword, just like top-level instances. For example,

    mkEq : {A : Set} → (A → A → Bool) → Eq A
    
    fails : {A : Set} → (A → A → Bool) → A → Bool
    fails eq x = let eqA = mkEq eq in x == x
    
    works : {A : Set} → (A → A → Bool) → A → Bool
    works eq x = let instance eqA = mkEq eq in x == x
    
  • Record fields can be declared instances.

    For example,

    record EqSet : Set₁ where
      field
        set : Set
        instance eq : Eq set
    

    This causes the projection function eq : (E : EqSet) → Eq (set E) to be considered for instance search.

  • Instance search can now find arguments in variable types (but such candidates can only be lambda-bound variables, they can’t be declared as instances)

    module _ {A : Set} (P : A → Set) where
    
      postulate
        bla : {x : A} {{_ : P x}} → Set → Set
    
      -- Works, the instance argument is found in the context
      test :  {x : A} {{_ : P x}} → Set → Set
      test B = bla B
    
      -- Still forbidden, because [P] could be instantiated later to anything
      instance
       postulate
        forbidden : {x : A} → P x
    
  • Instance search now refuses to solve constraints with unconstrained metavariables, since this can lead to non-termination.

    See [Issue #1532] for an example.

  • Top-level instances are now only considered if they are in scope. [Issue #1913]

    Note that lambda-bound instances need not be in scope.

Other changes

  • Unicode ellipsis character is allowed for the ellipsis token ... in with expressions.

  • Prop is no longer a reserved word.

Type checking

  • Large indices.

    Force constructor arguments no longer count towards the size of a datatype. For instance, the definition of equality below is accepted.

    data _≡_ {a} {A : Set a} : A → A → Set where
      refl : ∀ x → x ≡ x
    

    This gets rid of the asymmetry that the version of equality which indexes only on the second argument could be small, but not the version above which indexes on both arguments.

  • Detection of datatypes that satisfy K (i.e. sets)

    Agda will now try to detect datatypes that satisfy K when --without-K is enabled. A datatype satisfies K when it follows these three rules:

    • The types of all non-recursive constructor arguments should satisfy K.

    • All recursive constructor arguments should be first-order.

    • The types of all indices should satisfy K.

    For example, the types Nat, List Nat, and x ≡ x (where x : Nat) are all recognized by Agda as satisfying K.

  • New unifier for case splitting

    The unifier used by Agda for case splitting has been completely rewritten. The new unifier takes a much more type-directed approach in order to avoid the problems in issues #1406, #1408, #1427, and #1435.

    The new unifier also has eta-equality for record types built-in. This should avoid unnecessary case splitting on record constructors and improve the performance of Agda on code that contains deeply nested record patterns (see issues #473, #635, #1575, #1603, #1613, and #1645).

    In some cases, the locations of the dot patterns computed by the unifier did not correspond to the locations given by the user (see Issue #1608). This has now been fixed by adding an extra step after case splitting that checks whether the user-written patterns are compatible with the computed ones.

    In some rare cases, the new unifier is still too restrictive when --without-K is enabled because it cannot generalize over the datatype indices (yet). For example, the following code is rejected:

    data Bar : Set₁ where
      bar : Bar
      baz : (A : Set) → Bar
    
    data Foo : Bar → Set where
      foo : Foo bar
    
    test : foo ≡ foo → Set₁
    test refl = Set
    
  • The aggressive behaviour of with introduced in 2.4.2.5 has been rolled back [Issue #1692]. With no longer abstracts in the types of variables appearing in the with-expressions. [Issue #745]

    This means that the following example no longer works:

    fails : (f : (x : A) → a ≡ x) (b : A) → b ≡ a
    fails f b with a | f b
    fails f b | .b | refl = f b
    

    The with no longer abstracts the type of f over a, since f appears in the second with-expression f b. You can use a nested with to make this example work.

    This example does work again:

    test : ∀{A : Set}{a : A}{f : A → A} (p : f a ≡ a) → f (f a) ≡ a
    test p rewrite p = p
    

    After rewrite p the goal has changed to f a ≡ a, but the type of p has not been rewritten, thus, the final p solves the goal.

    The following, which worked in 2.4.2.5, no longer works:

    fails : (f : (x : A) → a ≡ x) (b : A) → b ≡ a
    fails f b rewrite f b = f b
    

    The rewrite with f b : a ≡ b is not applied to f as the latter is part of the rewrite expression f b. Thus, the type of f remains untouched, and the changed goal b ≡ b is not solved by f b.

  • When using rewrite on a term eq of type lhs ≡ rhs, the lhs is no longer abstracted in rhs [Issue #520]. This means that

    f pats rewrite eq = body
    

    is more than syntactic sugar for

    f pats with lhs | eq
    f pats | _ | refl = body
    

    In particular, the following application of rewrite is now possible

    id : Bool → Bool
    id true  = true
    id false = false
    
    is-id : ∀ x → x ≡ id x
    is-id true  = refl
    is-id false = refl
    
    postulate
      P : Bool → Set
      b : Bool
      p : P (id b)
    
    proof : P b
    proof rewrite is-id b = p
    

    Previously, this was desugared to

    proof with b | is-id b
    proof | _ | refl = p
    

    which did not type check as refl does not have type b ≡ id b. Now, Agda gets the task of checking refl : _ ≡ id b leading to instantiation of _ to id b.

Compiler backends

  • Major Bug Fixes:

    • Function clauses with different arities are now always compiled correctly by the GHC/UHC backends. (Issue #727)
  • Co-patterns

    • The GHC/UHC backends now support co-patterns. (Issues #1567, #1632)
  • Optimizations

    • Builtin naturals are now represented as arbitrary-precision Integers. See the user manual, section “Agda Compilers -> Optimizations” for details.
  • GHC Haskell backend (MAlonzo)

    • Pragmas

      Since builtin naturals are compiled to Integer you can no longer give a {-# COMPILED_DATA #-} pragma for Nat. The same goes for builtin booleans, integers, floats, characters and strings which are now hard-wired to appropriate Haskell types.

  • UHC compiler backend

    A new backend targeting the Utrecht Haskell Compiler (UHC) is available. It targets the UHC Core language, and it’s design is inspired by the Epic backend. See the user manual, section “Agda Compilers -> UHC Backend” for installation instructions.

    • FFI

      The UHC backend has a FFI to Haskell similar to MAlonzo’s. The target Haskell code also needs to be compilable using UHC, which does not support the Haskell base library version 4.*.

      FFI pragmas for the UHC backend are not checked in any way. If the pragmas are wrong, bad things will happen.

    • Imports

      Additional Haskell modules can be brought into scope with the IMPORT_UHC pragma:

      {-# IMPORT_UHC Data.Char #-}
      

      The Haskell modules UHC.Base and UHC.Agda.Builtins are always in scope and don’t need to be imported explicitly.

    • Datatypes

      Agda datatypes can be bound to Haskell datatypes as follows:

      Haskell:

      data HsData a = HsCon1 | HsCon2 (HsData a)
      

      Agda:

      data AgdaData (A : Set) : Set where
        AgdaCon1 : AgdaData A
        AgdaCon2 : AgdaData A -> AgdaData A
      {-# COMPILED_DATA_UHC AgdaData HsData HsCon1 HsCon2 #-}
      

      The mapping has to cover all constructors of the used Haskell datatype, else runtime behavior is undefined!

      There are special reserved names to bind Agda datatypes to certain Haskell datatypes. For example, this binds an Agda datatype to Haskell’s list datatype:

      Agda:

      data AgdaList (A : Set) : Set where
        Nil : AgdaList A
        Cons : A -> AgdaList A -> AgdaList A
      {-# COMPILED_DATA_UHC AgdaList __LIST__ __NIL__ __CONS__ #-}
      

      The following “magic” datatypes are available:

      HS Datatype | Datatype Pragma | HS Constructor | Constructor Pragma
      ()            __UNIT__          ()               __UNIT__
      List          __LIST__          (:)              __CONS__
                                      []               __NIL__
      Bool          __BOOL__          True             __TRUE__
                                      False            __FALSE__
      
    • Functions

      Agda postulates can be bound to Haskell functions. Similar as in MAlonzo, all arguments of type Set need to be dropped before calling Haskell functions. An example calling the return function:

      Agda:

      postulate hs-return : {A : Set} -> A -> IO A
      {-# COMPILED_UHC hs-return (\_ -> UHC.Agda.Builtins.primReturn) #-}
      

Emacs mode and interaction

  • Module contents (C-c C-o) now also works for records. [See Issue #1926 ] If you have an inferable expression of record type in an interaction point, you can invoke C-c C-o to see its fields and types. Example

    record R : Set where
      field f : A
    
    test : R → R
    test r = {!r!}  -- C-c C-o here
    
  • Less aggressive error notification.

    Previously Emacs could jump to the position of an error even if the type-checking process was not initiated in the current buffer. Now this no longer happens: If the type-checking process was initiated in another buffer, then the cursor is moved to the position of the error in the buffer visiting the file (if any) and in every window displaying the file, but focus should not change from one file to another.

    In the cases where focus does change from one file to another, one can now use the go-back functionality to return to the previous position.

  • Removed the agda-include-dirs customization parameter.

    Use agda-program-args with -iDIR or -lLIB instead, or add libraries to ~/.agda/defaults (C:/Users/USERNAME/AppData/Roaming/agda/defaults or similar on Windows). See Library management, above, for more information.

Tools

LaTeX-backend

agda-ghc-names

  • New tool: The command

    agda-ghc-names fixprof <compile-dir> <ProgName>.prof
    

    converts *.prof files obtained from profiling runs of MAlonzo-compiled code to *.agdaIdents.prof, with the original Agda identifiers replacing the MAlonzo-generated Haskell identifiers.

    For usage and more details, see src/agda-ghc-names/README.txt.

Highlighting and textual backends

  • Names in import directives are now highlighted and are clickable. [Issue #1714] This leads also to nicer printing in the LaTeX and html backends.

Fixed issues

See bug tracker (milestone 2.5.1)

Release notes for Agda version 2.4.2.5

Installation and infrastructure

  • Added support for GHC 7.10.3.

  • Added cpphs Cabal flag

    Turn on/off this flag to choose cpphs/cpp as the C preprocessor.

    This flag is turn on by default.

    (This flag was added in Agda 2.4.2.1 but it was not documented)

Pragmas and options

  • Termination pragmas are no longer allowed inside where clauses [Issue #1137].

Type checking

  • with-abstraction is more aggressive, abstracts also in types of variables that are used in the with-expressions, unless they are also used in the types of the with-expressions. [Issue #1692]

    Example:

    test : (f : (x : A) → a ≡ x) (b : A) → b ≡ a
    test f b with a | f b
    test f b | .b | refl = f b
    

    Previously, with would not abstract in types of variables that appear in the with-expressions, in this case, both f and b, leaving their types unchanged. Now, it tries to abstract in f, as only b appears in the types of the with-expressions which are A (of a) and a ≡ b (of f b). As a result, the type of f changes to (x : A) → b ≡ x and the type of the goal to b ≡ b (as previously).

    This also affects rewrite, which is implemented in terms of with.

    test : (f : (x : A) → a ≡ x) (b : A) → b ≡ a
    test f b rewrite f b = f b
    

    As the new with is not fully backwards-compatible, some parts of your Agda developments using with or rewrite might need maintenance.

Fixed issues

See bug tracker

#1407

#1518

#1670

#1677

#1698

#1701

#1710

#1718

Release notes for Agda version 2.4.2.4

Installation and infrastructure

  • Removed support for GHC 7.4.2.

Pragmas and options

  • Option --copatterns is now on by default. To switch off parsing of copatterns, use:

    {-# OPTIONS --no-copatterns #-}
    
  • Option --rewriting is now needed to use REWRITE pragmas and rewriting during reduction. Rewriting is not --safe.

    To use rewriting, first specify a relation symbol R that will later be used to add rewrite rules. A canonical candidate would be propositional equality

    {-# BUILTIN REWRITE _≡_ #-}
    

    but any symbol R of type Δ → A → A → Set i for some A and i is accepted. Then symbols q can be added to rewriting provided their type is of the form Γ → R ds l r. This will add a rewrite rule

    Γ ⊢ l ↦ r : A[ds/Δ]
    

    to the signature, which fires whenever a term is an instance of l. For example, if

    plus0 : ∀ x → x + 0 ≡ x
    

    (ideally, there is a proof for plus0, but it could be a postulate), then

    {-# REWRITE plus0 #-}
    

    will prompt Agda to rewrite any well-typed term of the form t + 0 to t.

    Some caveats: Agda accepts and applies rewrite rules naively, it is very easy to break consistency and termination of type checking. Some examples of rewrite rules that should not be added:

    refl     : ∀ x → x ≡ x             -- Agda loops
    plus-sym : ∀ x y → x + y ≡ y + x   -- Agda loops
    absurd   : true ≡ false            -- Breaks consistency
    

    Adding only proven equations should at least preserve consistency, but this is only a conjecture, so know what you are doing! Using rewriting, you are entering into the wilderness, where you are on your own!

Language

  • forall / now parses like λ, i.e., the following parses now [Issue #1583]:

    ⊤ × ∀ (B : Set) → B → B
    
  • The underscore pattern _ can now also stand for an inaccessible pattern (dot pattern). This alleviates the need for writing ._. [Issue #1605] Instead of

    transVOld : ∀{A : Set} (a b c : A) → a ≡ b → b ≡ c → a ≡ c
    transVOld _ ._ ._ refl refl = refl
    

    one can now write

      transVNew : ∀{A : Set} (a b c : A) → a ≡ b → b ≡ c → a ≡ c
      transVNew _ _ _ refl refl = refl
    

    and let Agda decide where to put the dots. This was always possible by using hidden arguments

    transH : ∀{A : Set}{a b c : A} → a ≡ b → b ≡ c → a ≡ c
    transH refl refl = refl
    

    which is now equivalent to

    transHNew : ∀{A : Set}{a b c : A} → a ≡ b → b ≡ c → a ≡ c
    transHNew {a = _}{b = _}{c = _} refl refl = refl
    

    Before, underscore _ stood for an unnamed variable that could not be instantiated by an inaccessible pattern. If one no wants to prevent Agda from instantiating, one needs to use a variable name other than underscore (however, in practice this situation seems unlikely).

Type checking

  • Polarity of phantom arguments to data and record types has changed. [Issue #1596] Polarity of size arguments is Nonvariant (both monotone and antitone). Polarity of other arguments is Covariant (monotone). Both were Invariant before (neither monotone nor antitone).

    The following example type-checks now:

    open import Common.Size
    
    -- List should be monotone in both arguments
    -- (even when `cons' is missing).
    
    data List (i : Size) (A : Set) : Set where
      [] : List i A
    
    castLL : ∀{i A} → List i (List i A) → List ∞ (List ∞ A)
    castLL x = x
    
    -- Stream should be antitone in the first and monotone in the second argument
    -- (even with field `tail' missing).
    
    record Stream (i : Size) (A : Set) : Set where
      coinductive
      field
        head : A
    
    castSS : ∀{i A} → Stream ∞ (Stream ∞ A) → Stream i (Stream i A)
    castSS x = x
    
  • SIZELT lambdas must be consistent [Issue #1523, see Abel and Pientka, ICFP 2013]. When lambda-abstracting over type (Size< size) then size must be non-zero, for any valid instantiation of size variables.

    • The good:

      data Nat (i : Size) : Set where
        zero : ∀ (j : Size< i) → Nat i
        suc  : ∀ (j : Size< i) → Nat j → Nat i
      
      {-# TERMINATING #-}
      -- This definition is fine, the termination checker is too strict at the moment.
      fix : ∀ {C : Size → Set}
         → (∀ i → (∀ (j : Size< i) → Nat j -> C j) → Nat i → C i)
         → ∀ i → Nat i → C i
      fix t i (zero j)  = t i (λ (k : Size< i) → fix t k) (zero j)
      fix t i (suc j n) = t i (λ (k : Size< i) → fix t k) (suc j n)
      

      The λ (k : Size< i) is fine in both cases, as context

      i : Size, j : Size< i
      

      guarantees that i is non-zero.

    • The bad:

      record Stream {i : Size} (A : Set) : Set where
        coinductive
        constructor _∷ˢ_
        field
          head  : A
          tail  : ∀ {j : Size< i} → Stream {j} A
      open Stream public
      
      _++ˢ_ : ∀ {i A} → List A → Stream {i} A → Stream {i} A
      []        ++ˢ s = s
      (a ∷ as)  ++ˢ s = a ∷ˢ (as ++ˢ s)
      

      This fails, maybe unjustified, at

      i : Size, s : Stream {i} A
        ⊢
          a ∷ˢ (λ {j : Size< i} → as ++ˢ s)
      

      Fixed by defining the constructor by copattern matching:

      record Stream {i : Size} (A : Set) : Set where
        coinductive
        field
          head  : A
          tail  : ∀ {j : Size< i} → Stream {j} A
      open Stream public
      
      _∷ˢ_ : ∀ {i A} → A → Stream {i} A → Stream {↑ i} A
      head  (a ∷ˢ as) = a
      tail  (a ∷ˢ as) = as
      
      _++ˢ_ : ∀ {i A} → List A → Stream {i} A → Stream {i} A
      []        ++ˢ s = s
      (a ∷ as)  ++ˢ s = a ∷ˢ (as ++ˢ s)
      
    • The ugly:

      fix : ∀ {C : Size → Set}
         → (∀ i → (∀ (j : Size< i) → C j) → C i)
         → ∀ i → C i
      fix t i = t i λ (j : Size< i) → fix t j
      

      For i=0, there is no such j at runtime, leading to looping behavior.

Interaction

  • Issue #635 has been fixed. Case splitting does not spit out implicit record patterns any more.

    record Cont : Set₁ where
      constructor _◃_
      field
        Sh  : Set
        Pos : Sh → Set
    
    open Cont
    
    data W (C : Cont) : Set where
      sup : (s : Sh C) (k : Pos C s → W C) → W C
    
    bogus : {C : Cont} → W C → Set
    bogus w = {!w!}
    

    Case splitting on w yielded, since the fix of Issue #473,

    bogus {Sh ◃ Pos} (sup s k) = ?
    

    Now it gives, as expected,

    bogus (sup s k) = ?
    

Performance

  • As one result of the 21st Agda Implementor’s Meeting (AIM XXI), serialization of the standard library is 50% faster (time reduced by a third), without using additional disk space for the interface files.

Bug fixes

Issues fixed (see bug tracker):

#1546 (copattern matching and with-clauses)

#1560 (positivity checker inefficiency)

#1584 (let pattern with trailing implicit)

Release notes for Agda version 2.4.2.3

Installation and infrastructure

  • Added support for GHC 7.10.1.

  • Removed support for GHC 7.0.4.

Language

  • _ is no longer a valid name for a definition. The following fails now: [Issue #1465]

    postulate _ : Set
    
  • Typed bindings can now contain hiding information [Issue #1391]. This means you can now write

    assoc : (xs {ys zs} : List A) → ((xs ++ ys) ++ zs) ≡ (xs ++ (ys ++ zs))
    

    instead of the longer

    assoc : (xs : List A) {ys zs : List A} → ...
    

    It also works with irrelevance

    .(xs {ys zs} : List A) → ...
    

    but of course does not make sense if there is hiding information already. Thus, this is (still) a parse error:

    {xs {ys zs} : List A} → ...
    
  • The builtins for sized types no longer need accompanying postulates. The BUILTIN pragmas for size stuff now also declare the identifiers they bind to.

    {-# BUILTIN SIZEUNIV SizeUniv #-}  --  SizeUniv : SizeUniv
    {-# BUILTIN SIZE     Size     #-}  --  Size     : SizeUniv
    {-# BUILTIN SIZELT   Size<_   #-}  --  Size<_   : ..Size → SizeUniv
    {-# BUILTIN SIZESUC  ↑_       #-}  --  ↑_       : Size → Size
    {-# BUILTIN SIZEINF  ∞        #-}  --  ∞       : Size
    

    Size and Size< now live in the new universe SizeUniv. It is forbidden to build function spaces in this universe, in order to prevent the malicious assumption of a size predecessor

    pred : (i : Size) → Size< i
    

    [Issue #1428].

  • Unambiguous notations (coming from syntax declarations) that resolve to ambiguous names are now parsed unambiguously [Issue #1194].

  • If only some instances of an overloaded name have a given associated notation (coming from syntax declarations), then this name can only be resolved to the given instances of the name, not to other instances [Issue #1194].

    Previously, if different instances of an overloaded name had different associated notations, then none of the notations could be used. Now all of them can be used.

    Note that notation identity does not only involve the right-hand side of the syntax declaration. For instance, the following notations are not seen as identical, because the implicit argument names are different:

    module A where
    
      data D : Set where
        c : {x y : D} → D
    
      syntax c {x = a} {y = b} = a ∙ b
    
    module B where
    
      data D : Set where
        c : {y x : D} → D
    
      syntax c {y = a} {x = b} = a ∙ b
    
  • If an overloaded operator is in scope with at least two distinct fixities, then it gets the default fixity [Issue #1436].

    Similarly, if two or more identical notations for a given overloaded name are in scope, and these notations do not all have the same fixity, then they get the default fixity.

Type checking

  • Functions of varying arity can now have with-clauses and use rewrite.

    Example:

    NPred : Nat → Set
    NPred 0       = Bool
    NPred (suc n) = Nat → NPred n
    
    const : Bool → ∀{n} → NPred n
    const b {0}       = b
    const b {suc n} m = const b {n}
    
    allOdd : ∀ n → NPred n
    allOdd 0 = true
    allOdd (suc n) m with even m
    ... | true  = const false
    ... | false = allOdd n
    
  • Function defined by copattern matching can now have with-clauses and use rewrite.

    Example:

    {-# OPTIONS --copatterns #-}
    
    record Stream (A : Set) : Set where
      coinductive
      constructor delay
      field
        force : A × Stream A
    open Stream
    
    map : ∀{A B} → (A → B) → Stream A → Stream B
    force (map f s) with force s
    ... | a , as = f a , map f as
    
    record Bisim {A B} (R : A → B → Set) (s : Stream A) (t : Stream B) : Set where
      coinductive
      constructor ~delay
      field
        ~force : let a , as = force s
                     b , bs = force t
                 in  R a b × Bisim R as bs
    open Bisim
    
    SEq : ∀{A} (s t : Stream A) → Set
    SEq = Bisim (_≡_)
    
    -- Slightly weird definition of symmetry to demonstrate rewrite.
    
    ~sym' : ∀{A} {s t : Stream A} → SEq s t → SEq t s
    ~force (~sym' {s = s} {t} p) with force s | force t | ~force p
    ... | a , as | b , bs | r , q rewrite r = refl , ~sym' q
    
  • Instances can now be defined by copattern matching. [Issue #1413] The following example extends the one in [Abel, Pientka, Thibodeau, Setzer, POPL 2013, Section 2.2]:

    {-# OPTIONS --copatterns #-}
    
    -- The Monad type class
    
    record Monad (M : Set → Set) : Set1 where
      field
        return : {A : Set}   → A → M A
        _>>=_  : {A B : Set} → M A → (A → M B) → M B
    open Monad {{...}}
    
    -- The State newtype
    
    record State (S A : Set) : Set where
      field
        runState : S → A × S
    open State
    
    -- State is an instance of Monad
    
    instance
      stateMonad : {S : Set} → Monad (State S)
      runState (return {{stateMonad}} a  ) s  = a , s    -- NEW
      runState (_>>=_  {{stateMonad}} m k) s₀ =          -- NEW
        let a , s₁ = runState m s₀
        in  runState (k a) s₁
    
    -- stateMonad fulfills the monad laws
    
    leftId : {A B S : Set}(a : A)(k : A → State S B) →
      (return a >>= k) ≡ k a
    leftId a k = refl
    
    rightId : {A B S : Set}(m : State S A) →
      (m >>= return) ≡ m
    rightId m = refl
    
    assoc : {A B C S : Set}(m : State S A)(k : A → State S B)(l : B → State S C) →
       ((m >>= k) >>= l) ≡ (m >>= λ a → k a >>= l)
    assoc m k l = refl
    

Emacs mode

  • The new menu option Switch to another version of Agda tries to do what it says.

  • Changed feature: Interactively split result.

    [ This is as before: ] Make-case (C-c C-c) with no variables given tries to split on the result to introduce projection patterns. The hole needs to be of record type, of course.

    test : {A B : Set} (a : A) (b : B) → A × B
    test a b = ?
    

    Result-splitting ? will produce the new clauses:

    proj₁ (test a b) = ?
    proj₂ (test a b) = ?
    

    [ This has changed: ] If hole is of function type, make-case will introduce only pattern variables (as much as it can).

    testFun : {A B : Set} (a : A) (b : B) → A × B
    testFun = ?
    

    Result-splitting ? will produce the new clause:

    testFun a b = ?
    

    A second invocation of make-case will then introduce projection patterns.

Error messages

  • Agda now suggests corrections of misspelled options, e.g.

    {-# OPTIONS
      --dont-termination-check
      --without-k
      --senf-gurke
      #-}
    

    Unrecognized options:

    --dont-termination-check (did you mean --no-termination-check ?)
    --without-k (did you mean --without-K ?)
    --senf-gurke
    

    Nothing close to --senf-gurke, I am afraid.

Compiler backends

  • The Epic backend has been removed [Issue #1481].

Bug fixes

Release notes for Agda version 2.4.2.2

Bug fixes

Release notes for Agda version 2.4.2.1

Pragmas and options

  • New pragma {-# TERMINATING #-} replacing {-# NO_TERMINATION_CHECK #-}

    Complements the existing pragma {-# NON_TERMINATING #-}. Skips termination check for the associated definitions and marks them as terminating. Thus, it is a replacement for {-# NO_TERMINATION_CHECK #-} with the same semantics.

    You can no longer use pragma {-# NO_TERMINATION_CHECK #-} to skip the termination check, but must label your definitions as either {-# TERMINATING #-} or {-# NON_TERMINATING #-} instead.

    Note: {-# OPTION --no-termination-check #-} labels all your definitions as {-# TERMINATING #-}, putting you in the danger zone of a loop in the type checker.

Language

  • Referring to a local variable shadowed by module opening is now an error. Previous behavior was preferring the local over the imported definitions. [Issue #1266]

    Note that module parameters are locals as well as variables bound by λ, dependent function type, patterns, and let.

    Example:

    module M where
      A = Set1
    
    test : (A : Set) → let open M in A
    

    The last A produces an error, since it could refer to the local variable A or to the definition imported from module M.

  • with on a variable bound by a module telescope or a pattern of a parent function is now forbidden. [Issue #1342]

    data Unit : Set where
      unit : Unit
    
    id : (A : Set) → A → A
    id A a = a
    
    module M (x : Unit) where
    
      dx : Unit → Unit
      dx unit = x
    
      g : ∀ u → x ≡ dx u
      g with x
      g | unit  = id (∀ u → unit ≡ dx u) ?
    

    Even though this code looks right, Agda complains about the type expression ∀ u → unit ≡ dx u. If you ask Agda what should go there instead, it happily tells you that it wants ∀ u → unit ≡ dx u. In fact what you do not see and Agda will never show you is that the two expressions actually differ in the invisible first argument to dx, which is visible only outside module M. What Agda wants is an invisible unit after dx, but all you can write is an invisible x (which is inserted behind the scenes).

    To avoid those kinds of paradoxes, with is now outlawed on module parameters. This should ensure that the invisible arguments are always exactly the module parameters.

    Since a where block is desugared as module with pattern variables of the parent clause as module parameters, the same strikes you for uses of with on pattern variables of the parent function.

    f : Unit → Unit
    f x = unit
      where
        dx : Unit → Unit
        dx unit = x
    
        g : ∀ u → x ≡ dx u
        g with x
        g | unit  = id ((u : Unit) → unit ≡ dx u) ?
    

    The with on pattern variable x of the parent clause f x = unit is outlawed now.

Type checking

  • Termination check failure is now a proper error.

    We no longer continue type checking after termination check failures. Use pragmas {-# NON_TERMINATING #-} and {-# NO_TERMINATION_CHECK #-} near the offending definitions if you want to do so. Or switch off the termination checker altogether with {-# OPTIONS --no-termination-check #-} (at your own risk!).

  • (Since Agda 2.4.2): Termination checking --without-K restricts structural descent to arguments ending in data types or Size. Likewise, guardedness is only tracked when result type is data or record type.

    mutual
      data WOne : Set where wrap : FOne → WOne
      FOne = ⊥ → WOne
    
    noo : (X : Set) → (WOne ≡ X) → X → ⊥
    noo .WOne refl (wrap f) = noo FOne iso f
    

    noo is rejected since at type X the structural descent f < wrap f is discounted --without-K.

    data Pandora : Set where
      C : ∞ ⊥ → Pandora
    
    loop : (A : Set) → A ≡ Pandora → A
    loop .Pandora refl = C (♯ (loop ⊥ foo))
    

    loop is rejected since guardedness is not tracked at type A --without-K.

    See issues #1023, #1264, #1292.

Termination checking

  • The termination checker can now recognize simple subterms in dot patterns.

    data Subst : (d : Nat) → Set where
      c₁ : ∀ {d} → Subst d → Subst d
      c₂ : ∀ {d₁ d₂} → Subst d₁ → Subst d₂ → Subst (suc d₁ + d₂)
    
    postulate
      comp : ∀ {d₁ d₂} → Subst d₁ → Subst d₂ → Subst (d₁ + d₂)
    
    lookup : ∀ d → Nat → Subst d → Set₁
    lookup d             zero    (c₁ ρ)             = Set
    lookup d             (suc v) (c₁ ρ)             = lookup d v ρ
    lookup .(suc d₁ + d₂) v      (c₂ {d₁} {d₂} ρ σ) = lookup (d₁ + d₂) v (comp ρ σ)
    

    The dot pattern here is actually normalized, so it is

    suc (d₁ + d₂)
    

    and the corresponding recursive call argument is (d₁ + d₂). In such simple cases, Agda can now recognize that the pattern is constructor applied to call argument, which is valid descent.

    Note however, that Agda only looks for syntactic equality when identifying subterms, since it is not allowed to normalize terms on the rhs during termination checking.

    Actually writing the dot pattern has no effect, this works as well, and looks pretty magical… ;-)

    hidden : ∀{d} → Nat → Subst d → Set₁
    hidden zero    (c₁ ρ)   = Set
    hidden (suc v) (c₁ ρ)   = hidden v ρ
    hidden v       (c₂ ρ σ) = hidden v (comp ρ σ)
    

Tools

LaTeX-backend

  • Fixed the issue of identifiers containing operators being typeset with excessive math spacing.

Bug fixes

  • Issue #1194

  • Issue #836: Fields and constructors can be qualified by the record/data type as well as by their record/data module. This now works also for record/data type imported from parametrized modules:

    module M (_ : Set₁) where
    
      record R : Set₁ where
        field
          X : Set
    
    open M Set using (R)  -- rather than using (module R)
    
    X : R → Set
    X = R.X
    

Release notes for Agda version 2.4.2

Pragmas and options

  • New option: --with-K

    This can be used to override a global --without-K in a file, by adding a pragma {-# OPTIONS --with-K #-}.

  • New pragma {-# NON_TERMINATING #-}

    This is a safer version of NO_TERMINATION_CHECK which doesn’t treat the affected functions as terminating. This means that NON_TERMINATING functions do not reduce during type checking. They do reduce at run-time and when invoking C-c C-n at top-level (but not in a hole).

Language

  • Instance search is now more efficient and recursive (see Issue #938) (but without termination check yet).

    A new keyword instance has been introduced (in the style of abstract and private) which must now be used for every definition/postulate that has to be taken into account during instance resolution. For example:

    record RawMonoid (A : Set) : Set where
      field
        nil  : A
        _++_ : A -> A -> A
    
    open RawMonoid {{...}}
    
    instance
      rawMonoidList : {A : Set} -> RawMonoid (List A)
      rawMonoidList = record { nil = []; _++_ = List._++_ }
    
      rawMonoidMaybe : {A : Set} {{m : RawMonoid A}} -> RawMonoid (Maybe A)
      rawMonoidMaybe {A} = record { nil = nothing ; _++_ = catMaybe }
        where
          catMaybe : Maybe A -> Maybe A -> Maybe A
          catMaybe nothing mb = mb
          catMaybe ma nothing = ma
          catMaybe (just a) (just b) = just (a ++ b)
    

    Moreover, each type of an instance must end in (something that reduces to) a named type (e.g. a record, a datatype or a postulate). This allows us to build a simple index structure

    data/record name  -->  possible instances
    

    that speeds up instance search.

    Instance search takes into account all local bindings and all global instance bindings and the search is recursive. For instance, searching for

    ? : RawMonoid (Maybe (List A))
    

    will consider the candidates {rawMonoidList, rawMonoidMaybe}, fail to unify the first one, succeeding with the second one

    ? = rawMonoidMaybe {A = List A} {{m = ?m}} : RawMonoid (Maybe (List A))
    

    and continue with goal

    ?m : RawMonoid (List A)
    

    This will then find

    ?m = rawMonoidList {A = A}
    

    and putting together we have the solution.

    Be careful that there is no termination check for now, you can easily make Agda loop by declaring the identity function as an instance. But it shouldn’t be possible to make Agda loop by only declaring structurally recursive instances (whatever that means).

    Additionally:

    • Uniqueness of instances is up to definitional equality (see Issue #899).

    • Instances of the following form are allowed:

      EqSigma : {A : Set} {B : A → Set} {{EqA : Eq A}}
                {{EqB : {a : A} → Eq (B a)}}
                → Eq (Σ A B)
      

      When searching recursively for an instance of type {a : A} → Eq (B a), a lambda will automatically be introduced and instance search will search for something of type Eq (B a) in the context extended by a : A. When searching for an instance, the a argument does not have to be implicit, but in the definition of EqSigma, instance search will only be able to use EqB if a is implicit.

    • There is no longer any attempt to solve irrelevant metas by instance search.

    • Constructors of records and datatypes are automatically added to the instance table.

  • You can now use quote in patterns.

    For instance, here is a function that unquotes a (closed) natural number term.

    unquoteNat : Term → Maybe Nat
    unquoteNat (con (quote Nat.zero) [])            = just zero
    unquoteNat (con (quote Nat.suc) (arg _ n ∷ [])) = fmap suc (unquoteNat n)
    unquoteNat _                                    = nothing
    
  • The builtin constructors AGDATERMUNSUPPORTED and AGDASORTUNSUPPORTED are now translated to meta variables when unquoting.

  • New syntactic sugar tactic e and tactic e | e1 | .. | en.

    It desugars as follows and makes it less unwieldy to call reflection-based tactics.

    tactic e                --> quoteGoal g in unquote (e g)
    tactic e | e1 | .. | en --> quoteGoal g in unquote (e g) e1 .. en
    

    Note that in the second form the tactic function should generate a function from a number of new subgoals to the original goal. The type of e should be Term -> Term in both cases.

  • New reflection builtins for literals.

    The term data type AGDATERM now needs an additional constructor AGDATERMLIT taking a reflected literal defined as follows (with appropriate builtin bindings for the types Nat, Float, etc).

    data Literal : Set where
      nat    : Nat    → Literal
      float  : Float  → Literal
      char   : Char   → Literal
      string : String → Literal
      qname  : QName  → Literal
    
    {-# BUILTIN AGDALITERAL   Literal #-}
    {-# BUILTIN AGDALITNAT    nat     #-}
    {-# BUILTIN AGDALITFLOAT  float   #-}
    {-# BUILTIN AGDALITCHAR   char    #-}
    {-# BUILTIN AGDALITSTRING string  #-}
    {-# BUILTIN AGDALITQNAME  qname   #-}
    

    When quoting (quoteGoal or quoteTerm) literals will be mapped to the AGDATERMLIT constructor. Previously natural number literals were quoted to suc/zero application and other literals were quoted to AGDATERMUNSUPPORTED.

  • New reflection builtins for function definitions.

    AGDAFUNDEF should now map to a data type defined as follows

    (with

    {-# BUILTIN QNAME       QName   #-}
    {-# BUILTIN ARG         Arg     #-}
    {-# BUILTIN AGDATERM    Term    #-}
    {-# BUILTIN AGDATYPE    Type    #-}
    {-# BUILTIN AGDALITERAL Literal #-}
    

    ).

    data Pattern : Set where
      con    : QName → List (Arg Pattern) → Pattern
      dot    : Pattern
      var    : Pattern
      lit    : Literal → Pattern
      proj   : QName → Pattern
      absurd : Pattern
    
    {-# BUILTIN AGDAPATTERN   Pattern #-}
    {-# BUILTIN AGDAPATCON    con     #-}
    {-# BUILTIN AGDAPATDOT    dot     #-}
    {-# BUILTIN AGDAPATVAR    var     #-}
    {-# BUILTIN AGDAPATLIT    lit     #-}
    {-# BUILTIN AGDAPATPROJ   proj    #-}
    {-# BUILTIN AGDAPATABSURD absurd  #-}
    
    data Clause : Set where
      clause        : List (Arg Pattern) → Term → Clause
      absurd-clause : List (Arg Pattern) → Clause
    
    {-# BUILTIN AGDACLAUSE       Clause        #-}
    {-# BUILTIN AGDACLAUSECLAUSE clause        #-}
    {-# BUILTIN AGDACLAUSEABSURD absurd-clause #-}
    
    data FunDef : Set where
      fun-def : Type → List Clause → FunDef
    
    {-# BUILTIN AGDAFUNDEF    FunDef  #-}
    {-# BUILTIN AGDAFUNDEFCON fun-def #-}
    
  • New reflection builtins for extended (pattern-matching) lambda.

    The AGDATERM data type has been augmented with a constructor

    AGDATERMEXTLAM : List AGDACLAUSE → List (ARG AGDATERM) → AGDATERM
    

    Absurd lambdas (λ ()) are quoted to extended lambdas with an absurd clause.

  • Unquoting declarations.

    You can now define (recursive) functions by reflection using the new unquoteDecl declaration

    unquoteDecl x = e
    

    Here e should have type AGDAFUNDEF and evaluate to a closed value. This value is then spliced in as the definition of x. In the body e, x has type QNAME which lets you splice in recursive definitions.

    Standard modifiers, such as fixity declarations, can be applied to x as expected.

  • Quoted levels

    Universe levels are now quoted properly instead of being quoted to AGDASORTUNSUPPORTED. Setω still gets an unsupported sort, however.

  • Module applicants can now be operator applications.

    Example:

    postulate
      [_] : A -> B
    
    module M (b : B) where
    
    module N (a : A) = M [ a ]
    

    [See Issue #1245]

  • Minor change in module application semantics. [Issue #892]

    Previously re-exported functions were not redefined when instantiating a module. For instance

    module A where f = ...
    module B (X : Set) where
      open A public
    module C = B Nat
    

    In this example C.f would be an alias for A.f, so if both A and C were opened f would not be ambiguous. However, this behaviour is not correct when A and B share some module parameters (Issue #892). To fix this C now defines its own copy of f (which evaluates to A.f), which means that opening A and C results in an ambiguous f.

Type checking

  • Recursive records need to be declared as either inductive or coinductive. inductive is no longer default for recursive records. Examples:

    record _×_ (A B : Set) : Set where
      constructor _,_
      field
        fst : A
        snd : B
    
    record Tree (A : Set) : Set where
      inductive
      constructor tree
      field
        elem     : A
        subtrees : List (Tree A)
    
    record Stream (A : Set) : Set where
      coinductive
      constructor _::_
      field
        head : A
        tail : Stream A
    

    If you are using old-style (musical) coinduction, a record may have to be declared as inductive, paradoxically.

    record Stream (A : Set) : Set where
      inductive -- YES, THIS IS INTENDED !
      constructor _∷_
      field
        head : A
        tail : ∞ (Stream A)
    

    This is because the “coinduction” happens in the use of and not in the use of record.

Tools

Emacs mode

  • A new menu option Display can be used to display the version of the running Agda process.

LaTeX-backend

  • New experimental option references has been added. When specified, i.e.:

    \usepackage[references]{agda}
    

    a new command called \AgdaRef is provided, which lets you reference previously typeset commands, e.g.:

    Let us postulate \AgdaRef{apa}.

    \begin{code}
    postulate
      apa : Set
    \end{code}
    

    Above apa will be typeset (highlighted) the same in the text as in the code, provided that the LaTeX output is post-processed using src/data/postprocess-latex.pl, e.g.:

    cp $(dirname $(dirname $(agda-mode locate)))/postprocess-latex.pl .
    agda -i. --latex Example.lagda
    cd latex/
    perl ../postprocess-latex.pl Example.tex > Example.processed
    mv Example.processed Example.tex
    xelatex Example.tex
    

    Mix-fix and Unicode should work as expected (Unicode requires XeLaTeX/LuaLaTeX), but there are limitations:

    • Overloading identifiers should be avoided, if multiples exist \AgdaRef will typeset according to the first it finds.

    • Only the current module is used, should you need to reference identifiers in other modules then you need to specify which other module manually, i.e. \AgdaRef[module]{identifier}.

Release notes for Agda 2 version 2.4.0.2

  • The Agda input mode now supports alphabetical super and subscripts, in addition to the numerical ones that were already present. [Issue #1240]

  • New feature: Interactively split result.

    Make case (C-c C-c) with no variables given tries to split on the result to introduce projection patterns. The hole needs to be of record type, of course.

    test : {A B : Set} (a : A) (b : B) → A × B
    test a b = ?
    

    Result-splitting ? will produce the new clauses:

    proj₁ (test a b) = ?
    proj₂ (test a b) = ?
    

    If hole is of function type ending in a record type, the necessary pattern variables will be introduced before the split. Thus, the same result can be obtained by starting from:

    test : {A B : Set} (a : A) (b : B) → A × B
    test = ?
    
  • The so far undocumented ETA pragma now throws an error if applied to definitions that are not records.

    ETA can be used to force eta-equality at recursive record types, for which eta is not enabled automatically by Agda. Here is such an example:

    mutual
      data Colist (A : Set) : Set where
        [] : Colist A
        _∷_ : A → ∞Colist A → Colist A
    
      record ∞Colist (A : Set) : Set where
        coinductive
        constructor delay
        field       force : Colist A
    
    open ∞Colist
    
    {-# ETA ∞Colist #-}
    
    test : {A : Set} (x : ∞Colist A) → x ≡ delay (force x)
    test x = refl
    

    Note: Unsafe use of ETA can make Agda loop, e.g. by triggering infinite eta expansion!

  • Bugs fixed (see bug tracker):

    #1203

    #1205

    #1209

    #1213

    #1214

    #1216

    #1225

    #1226

    #1231

    #1233

    #1239

    #1241

    #1243

Release notes for Agda 2 version 2.4.0.1

  • The option --compile-no-main has been renamed to --no-main.

  • COMPILED_DATA pragmas can now be given for records.

  • Various bug fixes.

Release notes for Agda 2 version 2.4.0

Installation and infrastructure

  • A new module called Agda.Primitive has been introduced. This module is available to all users, even if the standard library is not used. Currently the module contains level primitives and their representation in Haskell when compiling with MAlonzo:

    infixl 6 _⊔_
    
    postulate
      Level : Set
      lzero : Level
      lsuc  : (ℓ : Level) → Level
      _⊔_   : (ℓ₁ ℓ₂ : Level) → Level
    
    {-# COMPILED_TYPE Level ()      #-}
    {-# COMPILED lzero ()           #-}
    {-# COMPILED lsuc  (\_ -> ())   #-}
    {-# COMPILED _⊔_   (\_ _ -> ()) #-}
    
    {-# BUILTIN LEVEL     Level  #-}
    {-# BUILTIN LEVELZERO lzero  #-}
    {-# BUILTIN LEVELSUC  lsuc   #-}
    {-# BUILTIN LEVELMAX  _⊔_    #-}
    

    To bring these declarations into scope you can use a declaration like the following one:

    open import Agda.Primitive using (Level; lzero; lsuc; _⊔_)
    

    The standard library reexports these primitives (using the names zero and suc instead of lzero and lsuc) from the Level module.

    Existing developments using universe polymorphism might now trigger the following error message:

    Duplicate binding for built-in thing LEVEL, previous binding to
      .Agda.Primitive.Level
    

    To fix this problem, please remove the duplicate bindings.

    Technical details (perhaps relevant to those who build Agda packages):

    The include path now always contains a directory <DATADIR>/lib/prim, and this directory is supposed to contain a subdirectory Agda containing a file Primitive.agda.

    The standard location of <DATADIR> is system- and installation-specific. E.g., in a Cabal --user installation of Agda-2.3.4 on a standard single-ghc Linux system it would be $HOME/.cabal/share/Agda-2.3.4 or something similar.

    The location of the <DATADIR> directory can be configured at compile-time using Cabal flags (--datadir and --datasubdir). The location can also be set at run-time, using the Agda_datadir environment variable.

Pragmas and options

  • Pragma NO_TERMINATION_CHECK placed within a mutual block is now applied to the whole mutual block (rather than being discarded silently). Adding to the uses 1.-4. outlined in the release notes for 2.3.2 we allow:

    3a. Skipping an old-style mutual block: Somewhere within mutual block before a type signature or first function clause.

    mutual
      {-# NO_TERMINATION_CHECK #-}
      c : A
      c = d
    
      d : A
      d = c
    
  • New option --no-pattern-matching

    Disables all forms of pattern matching (for the current file). You can still import files that use pattern matching.

  • New option -v profile:7

    Prints some stats on which phases Agda spends how much time. (Number might not be very reliable, due to garbage collection interruptions, and maybe due to laziness of Haskell.)

  • New option --no-sized-types

    Option --sized-types is now default. --no-sized-types will turn off an extra (inexpensive) analysis on data types used for subtyping of sized types.

Language

  • Experimental feature: quoteContext

    There is a new keyword quoteContext that gives users access to the list of names in the current local context. For instance:

    open import Data.Nat
    open import Data.List
    open import Reflection
    
    foo : ℕ → ℕ → ℕ
    foo 0 m = 0
    foo (suc n) m = quoteContext xs in ?
    

    In the remaining goal, the list xs will consist of two names, n and m, corresponding to the two local variables. At the moment it is not possible to access let bound variables (this feature may be added in the future).

  • Experimental feature: Varying arity. Function clauses may now have different arity, e.g.,

    Sum : ℕ → Set
    Sum 0       = ℕ
    Sum (suc n) = ℕ → Sum n
    
    sum : (n : ℕ) → ℕ → Sum n
    sum 0       acc   = acc
    sum (suc n) acc m = sum n (m + acc)
    

    or,

    T : Bool → Set
    T true  = Bool
    T false = Bool → Bool
    
    f : (b : Bool) → T b
    f false true  = false
    f false false = true
    f true = true
    

    This feature is experimental. Yet unsupported:

    • Varying arity and with.

    • Compilation of functions with varying arity to Haskell, JS, or Epic.

  • Experimental feature: copatterns. (Activated with option --copatterns)

    We can now define a record by explaining what happens if you project the record. For instance:

    {-# OPTIONS --copatterns #-}
    
    record _×_ (A B : Set) : Set where
      constructor _,_
      field
        fst : A
        snd : B
    open _×_
    
    pair : {A B : Set} → A → B → A × B
    fst (pair a b) = a
    snd (pair a b) = b
    
    swap : {A B : Set} → A × B → B × A
    fst (swap p) = snd p
    snd (swap p) = fst p
    
    swap3 : {A B C : Set} → A × (B × C) → C × (B × A)
    fst (swap3 t)       = snd (snd t)
    fst (snd (swap3 t)) = fst (snd t)
    snd (snd (swap3 t)) = fst t
    

    Taking a projection on the left hand side (lhs) is called a projection pattern, applying to a pattern is called an application pattern. (Alternative terms: projection/application copattern.)

    In the first example, the symbol pair, if applied to variable patterns a and b and then projected via fst, reduces to a. pair by itself does not reduce.

    A typical application are coinductive records such as streams:

    record Stream (A : Set) : Set where
      coinductive
      field
        head : A
        tail : Stream A
    open Stream
    
    repeat : {A : Set} (a : A) -> Stream A
    head (repeat a) = a
    tail (repeat a) = repeat a
    

    Again, repeat a by itself will not reduce, but you can take a projection (head or tail) and then it will reduce to the respective rhs. This way, we get the lazy reduction behavior necessary to avoid looping corecursive programs.

    Application patterns do not need to be trivial (i.e., variable patterns), if we mix with projection patterns. E.g., we can have

    nats : Nat -> Stream Nat
    head (nats zero) = zero
    tail (nats zero) = nats zero
    head (nats (suc x)) = x
    tail (nats (suc x)) = nats x
    

    Here is an example (not involving coinduction) which demostrates records with fields of function type:

    -- The State monad
    
    record State (S A : Set) : Set where
      constructor state
      field
        runState : S → A × S
    open State
    
    -- The Monad type class
    
    record Monad (M : Set → Set) : Set1 where
      constructor monad
      field
        return : {A : Set}   → A → M A
        _>>=_  : {A B : Set} → M A → (A → M B) → M B
    
    
    -- State is an instance of Monad
    -- Demonstrates the interleaving of projection and application patterns
    
    stateMonad : {S : Set} → Monad (State S)
    runState (Monad.return stateMonad a  ) s  = a , s
    runState (Monad._>>=_  stateMonad m k) s₀ =
      let a , s₁ = runState m s₀
      in  runState (k a) s₁
    
    module MonadLawsForState {S : Set} where
    
      open Monad (stateMonad {S})
    
      leftId : {A B : Set}(a : A)(k : A → State S B) →
        (return a >>= k) ≡ k a
      leftId a k = refl
    
      rightId : {A B : Set}(m : State S A) →
        (m >>= return) ≡ m
      rightId m = refl
    
      assoc : {A B C : Set}(m : State S A)(k : A → State S B)(l : B → State S C) →
        ((m >>= k) >>= l) ≡ (m >>= λ a → (k a >>= l))
      assoc m k l = refl
    

    Copatterns are yet experimental and the following does not work:

    • Copatterns and with clauses.

    • Compilation of copatterns to Haskell, JS, or Epic.

    • Projections generated by

      open R {{...}}
      

      are not handled properly on lhss yet.

    • Conversion checking is slower in the presence of copatterns, since stuck definitions of record type do no longer count as neutral, since they can become unstuck by applying a projection. Thus, comparing two neutrals currently requires comparing all they projections, which repeats a lot of work.

  • Top-level module no longer required.

    The top-level module can be omitted from an Agda file. The module name is then inferred from the file name by dropping the path and the .agda extension. So, a module defined in /A/B/C.agda would get the name C.

    You can also suppress only the module name of the top-level module by writing

    module _ where
    

    This works also for parameterised modules.

  • Module parameters are now always hidden arguments in projections. For instance:

    module M (A : Set) where
    
      record Prod (B : Set) : Set where
        constructor _,_
        field
          fst : A
          snd : B
      open Prod public
    
    open M
    

    Now, the types of fst and snd are

    fst : {A : Set}{B : Set} → Prod A B → A
    snd : {A : Set}{B : Set} → Prod A B → B
    

    Until 2.3.2, they were

    fst : (A : Set){B : Set} → Prod A B → A
    snd : (A : Set){B : Set} → Prod A B → B
    

    This change is a step towards symmetry of constructors and projections. (Constructors always took the module parameters as hidden arguments).

  • Telescoping lets: Local bindings are now accepted in telescopes of modules, function types, and lambda-abstractions.

    The syntax of telescopes as been extended to support let:

    id : (let ★ = Set) (A : ★) → A → A
    id A x = x
    

    In particular one can now open modules inside telescopes:

    module Star where
      ★ : Set₁
      ★ = Set
    
    
    module MEndo (let open Star) (A : ★) where
      Endo : ★
      Endo = A → A
    

    Finally a shortcut is provided for opening modules:

    module N (open Star) (A : ★) (open MEndo A) (f : Endo) where
      ...
    

    The semantics of the latter is

    module _ where
      open Star
      module _ (A : ★) where
        open MEndo A
        module N (f : Endo) where
          ...
    

    The semantics of telescoping lets in function types and lambda abstractions is just expanding them into ordinary lets.

  • More liberal left-hand sides in lets [Issue #1028]:

    You can now write left-hand sides with arguments also for let bindings without a type signature. For instance,

    let f x = suc x in f zero
    

    Let bound functions still can’t do pattern matching though.

  • Ambiguous names in patterns are now optimistically resolved in favor of constructors. [Issue #822] In particular, the following succeeds now:

    module M where
    
      data D : Set₁ where
        [_] : Set → D
    
    postulate [_] : Set → Set
    
    open M
    
    Foo : _ → Set
    Foo [ A ] = A
    
  • Anonymous where-modules are opened public. [Issue #848]

    <clauses>
    f args = rhs
      module _ telescope where
        body
    <more clauses>
    

    means the following (not proper Agda code, since you cannot put a module in-between clauses)

    <clauses>
    module _ {arg-telescope} telescope where
      body
    
    f args = rhs
    <more clauses>
    

    Example:

    A : Set1
    A = B module _ where
      B : Set1
      B = Set
    
    C : Set1
    C = B
    
  • Builtin ZERO and SUC have been merged with NATURAL.

    When binding the NATURAL builtin, ZERO and SUC are bound to the appropriate constructors automatically. This means that instead of writing

    {-# BUILTIN NATURAL Nat #-}
    {-# BUILTIN ZERO zero #-}
    {-# BUILTIN SUC suc #-}
    

    you just write

    {-# BUILTIN NATURAL Nat #-}
    
  • Pattern synonym can now have implicit arguments. [Issue #860]

    For example,

    pattern tail=_ {x} xs = x ∷ xs
    
    len : ∀ {A} → List A → Nat
    len []         = 0
    len (tail= xs) = 1 + len xs
    
  • Syntax declarations can now have implicit arguments. [Issue #400]

    For example

    id : ∀ {a}{A : Set a} -> A -> A
    id x = x
    
    syntax id {A} x = x ∈ A
    
  • Minor syntax changes

    • -} is now parsed as end-comment even if no comment was begun. As a consequence, the following definition gives a parse error

      f : {A- : Set} -> Set
      f {A-} = A-
      

      because Agda now sees ID(f) LBRACE ID(A) END-COMMENT, and no longer ID(f) LBRACE ID(A-) RBRACE.

      The rational is that the previous lexing was to context-sensitive, attempting to comment-out f using {- and -} lead to a parse error.

    • Fixities (binding strengths) can now be negative numbers as well. [Issue #1109]

      infix -1 _myop_
      
    • Postulates are now allowed in mutual blocks. [Issue #977]

    • Empty where blocks are now allowed. [Issue #947]

    • Pattern synonyms are now allowed in parameterised modules. [Issue #941]

    • Empty hiding and renaming lists in module directives are now allowed.

    • Module directives using, hiding, renaming and public can now appear in arbitrary order. Multiple using/hiding/renaming directives are allowed, but you still cannot have both using and hiding (because that doesn’t make sense). [Issue #493]

Goal and error display

  • The error message Refuse to construct infinite term has been removed, instead one gets unsolved meta variables. Reason: the error was thrown over-eagerly. [Issue #795]

  • If an interactive case split fails with message

      Since goal is solved, further case distinction is not supported;
      try `Solve constraints' instead
    

    then the associated interaction meta is assigned to a solution. Press C-c C-= (Show constraints) to view the solution and C-c C-s (Solve constraints) to apply it. [Issue #289]

Type checking

  • [ Issue #376 ] Implemented expansion of bound record variables during meta assignment. Now Agda can solve for metas X that are applied to projected variables, e.g.:

    X (fst z) (snd z) = z
    
    X (fst z)         = fst z
    

    Technically, this is realized by substituting (x , y) for z with fresh bound variables x and y. Here the full code for the examples:

    record Sigma (A : Set)(B : A -> Set) : Set where
      constructor _,_
      field
        fst : A
        snd : B fst
    open Sigma
    
    test : (A : Set) (B : A -> Set) ->
      let X : (x : A) (y : B x) -> Sigma A B
          X = _
      in  (z : Sigma A B) -> X (fst z) (snd z) ≡ z
    test A B z = refl
    
    test' : (A : Set) (B : A -> Set) ->
      let X : A -> A
          X = _
      in  (z : Sigma A B) -> X (fst z) ≡ fst z
    test' A B z = refl
    

    The fresh bound variables are named fst(z) and snd(z) and can appear in error messages, e.g.:

    fail : (A : Set) (B : A -> Set) ->
      let X : A -> Sigma A B
          X = _
      in  (z : Sigma A B) -> X (fst z) ≡ z
    fail A B z = refl
    

    results in error:

    Cannot instantiate the metavariable _7 to solution fst(z) , snd(z)
    since it contains the variable snd(z) which is not in scope of the
    metavariable or irrelevant in the metavariable but relevant in the
    solution
    when checking that the expression refl has type _7 A B (fst z) ≡ z
    
  • Dependent record types and definitions by copatterns require reduction with previous function clauses while checking the current clause. [Issue #907]

    For a simple example, consider

    test : ∀ {A} → Σ Nat λ n → Vec A n
    proj₁ test = zero
    proj₂ test = []
    

    For the second clause, the lhs and rhs are typed as

    proj₂ test : Vec A (proj₁ test)
    []         : Vec A zero
    

    In order for these types to match, we have to reduce the lhs type with the first function clause.

    Note that termination checking comes after type checking, so be careful to avoid non-termination! Otherwise, the type checker might get into an infinite loop.

  • The implementation of the primitive primTrustMe has changed. It now only reduces to REFL if the two arguments x and y have the same computational normal form. Before, it reduced when x and y were definitionally equal, which included type-directed equality laws such as eta-equality. Yet because reduction is untyped, calling conversion from reduction lead to Agda crashes [Issue #882].

    The amended description of primTrustMe is (cf. release notes for 2.2.6):

    primTrustMe : {A : Set} {x y : A} → x ≡ y
    

    Here _≡_ is the builtin equality (see BUILTIN hooks for equality, above).

    If x and y have the same computational normal form, then primTrustMe {x = x} {y = y} reduces to refl.

    A note on primTrustMe’s runtime behavior: The MAlonzo compiler replaces all uses of primTrustMe with the REFL builtin, without any check for definitional equality. Incorrect uses of primTrustMe can potentially lead to segfaults or similar problems of the compiled code.

  • Implicit patterns of record type are now only eta-expanded if there is a record constructor. [Issues #473, #635]

    data D : Set where
      d : D
    
    data P : D → Set where
      p : P d
    
    record Rc : Set where
      constructor c
      field f : D
    
    works : {r : Rc} → P (Rc.f r) → Set
    works p = D
    

    This works since the implicit pattern r is eta-expanded to c x which allows the type of p to reduce to P x and x to be unified with d. The corresponding explicit version is:

    works' : (r : Rc) → P (Rc.f r) → Set
    works' (c .d) p = D
    

    However, if the record constructor is removed, the same example will fail:

    record R : Set where
      field f : D
    
    fails : {r : R} → P (R.f r) → Set
    fails p = D
    
    -- d != R.f r of type D
    -- when checking that the pattern p has type P (R.f r)
    

    The error is justified since there is no pattern we could write down for r. It would have to look like

    record { f = .d }
    

    but anonymous record patterns are not part of the language.

  • Absurd lambdas at different source locations are no longer different. [Issue #857] In particular, the following code type-checks now:

    absurd-equality : _≡_ {A = ⊥ → ⊥} (λ()) λ()
    absurd-equality = refl
    

    Which is a good thing!

  • Printing of named implicit function types.

    When printing terms in a context with bound variables Agda renames new bindings to avoid clashes with the previously bound names. For instance, if A is in scope, the type (A : Set) → A is printed as (A₁ : Set) → A₁. However, for implicit function types the name of the binding matters, since it can be used when giving implicit arguments.

    For this situation, the following new syntax has been introduced: {x = y : A} → B is an implicit function type whose bound variable (in scope in B) is y, but where the name of the argument is x for the purposes of giving it explicitly. For instance, with A in scope, the type {A : Set} → A is now printed as {A = A₁ : Set} → A₁.

    This syntax is only used when printing and is currently not being parsed.

  • Changed the semantics of --without-K. [Issue #712, Issue #865, Issue #1025]

    New specification of --without-K:

    When --without-K is enabled, the unification of indices for pattern matching is restricted in two ways:

    1. Reflexive equations of the form x == x are no longer solved, instead Agda gives an error when such an equation is encountered.

    2. When unifying two same-headed constructor forms c us and c vs of type D pars ixs, the datatype indices ixs (but not the parameters) have to be self-unifiable, i.e. unification of ixs with itself should succeed positively. This is a nontrivial requirement because of point 1.

    Examples:

    • The J rule is accepted.

      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
      ```agda
      
      This definition is accepted since unification of `x` with `y`
      doesn't require deletion or injectivity.
      
      
    • The K rule is rejected.

      K : {A : Set} (P : {x : A} → x ≡ x → Set) →
          (∀ x → P (refl {x = x})) →
         ∀ {x} (x≡x : x ≡ x) → P x≡x
      K P p refl = p _
      

      Definition is rejected with the following error:

      Cannot eliminate reflexive equation x = x of type A because K has
      been disabled.
      when checking that the pattern refl has type x ≡ x
      
    • Symmetry of the new criterion.

      test₁ : {k l m : ℕ} → k + l ≡ m → ℕ
      test₁ refl = zero
      
      test₂ : {k l m : ℕ} → k ≡ l + m → ℕ
      test₂ refl = zero
      

      Both versions are now accepted (previously only the first one was).

    • Handling of parameters.

      cons-injective : {A : Set} (x y : A) → (x ∷ []) ≡ (y ∷ []) → x ≡ y
      cons-injective x .x refl = refl
      

      Parameters are not unified, so they are ignored by the new criterion.

    • A larger example: antisymmetry of ≤.

      data _≤_ : ℕ → ℕ → Set where
        lz : (n : ℕ) → zero ≤ n
        ls : (m n : ℕ) → m ≤ n → suc m ≤ suc n
      
      ≤-antisym : (m n : ℕ) → m ≤ n → n ≤ m → m ≡ n
      ≤-antisym .zero    .zero    (lz .zero) (lz .zero)   = refl
      ≤-antisym .(suc m) .(suc n) (ls m n p) (ls .n .m q) =
                   cong suc (≤-antisym m n p q)
      
    • [ Issue #1025 ]

      postulate mySpace : Set
      postulate myPoint : mySpace
      
      data Foo : myPoint ≡ myPoint → Set where
        foo : Foo refl
      
      test : (i : foo ≡ foo) → i ≡ refl
      test refl = {!!}
      

      When applying injectivity to the equation foo ≡ foo of type Foo refl, it is checked that the index refl of type myPoint ≡ myPoint is self-unifiable. The equation refl ≡ refl again requires injectivity, so now the index myPoint is checked for self-unifiability, hence the error:

      Cannot eliminate reflexive equation myPoint = myPoint of type
      mySpace because K has been disabled.
      when checking that the pattern refl has type foo ≡ foo
      

Termination checking

  • A buggy facility coined “matrix-shaped orders” that supported uncurried functions (which take tuples of arguments instead of one argument after another) has been removed from the termination checker. [Issue #787]

  • Definitions which fail the termination checker are not unfolded any longer to avoid loops or stack overflows in Agda. However, the termination checker for a mutual block is only invoked after type-checking, so there can still be loops if you define a non-terminating function. But termination checking now happens before the other supplementary checks: positivity, polarity, injectivity and projection-likeness. Note that with the pragma {-# NO_TERMINATION_CHECK #-} you can make Agda treat any function as terminating.

  • Termination checking of functions defined by with has been improved.

    Cases which previously required --termination-depth to pass the termination checker (due to use of with) no longer need the flag. For example

    merge : List A → List A → List A
    merge [] ys = ys
    merge xs [] = xs
    merge (x ∷ xs) (y ∷ ys) with x ≤ y
    merge (x ∷ xs) (y ∷ ys)    | false = y ∷ merge (x ∷ xs) ys
    merge (x ∷ xs) (y ∷ ys)    | true  = x ∷ merge xs (y ∷ ys)
    

    This failed to termination check previously, since the with expands to an auxiliary function merge-aux:

    merge-aux x y xs ys false = y ∷ merge (x ∷ xs) ys
    merge-aux x y xs ys true  = x ∷ merge xs (y ∷ ys)
    

    This function makes a call to merge in which the size of one of the arguments is increasing. To make this pass the termination checker now inlines the definition of merge-aux before checking, thus effectively termination checking the original source program.

    As a result of this transformation doing with on a variable no longer preserves termination. For instance, this does not termination check:

    bad : Nat → Nat
    bad n with n
    ... | zero  = zero
    ... | suc m = bad m
    
  • The performance of the termination checker has been improved. For higher --termination-depth the improvement is significant. While the default --termination-depth is still 1, checking with higher --termination-depth should now be feasible.

Compiler backends

  • The MAlonzo compiler backend now has support for compiling modules that are not full programs (i.e. don’t have a main function). The goal is that you can write part of a program in Agda and the rest in Haskell, and invoke the Agda functions from the Haskell code. The following features were added for this reason:

    • A new command-line option --compile-no-main: the command

      agda --compile-no-main Test.agda
      

      will compile Test.agda and all its dependencies to Haskell and compile the resulting Haskell files with --make, but (unlike --compile) not tell GHC to treat Test.hs as the main module. This type of compilation can be invoked from Emacs by customizing the agda2-backend variable to value MAlonzoNoMain and then calling C-c C-x C-c as before.

    • A new pragma COMPILED_EXPORT was added as part of the MAlonzo FFI. If we have an Agda file containing the following:

       module A.B where
      
       test : SomeType
       test = someImplementation
      
       {-# COMPILED_EXPORT test someHaskellId #-}
      

      then test will be compiled to a Haskell function called someHaskellId in module MAlonzo.Code.A.B that can be invoked from other Haskell code. Its type will be translated according to the normal MAlonzo rules.

Tools

Emacs mode

  • A new goal command Helper Function Type (C-c C-h) has been added.

    If you write an application of an undefined function in a goal, the Helper Function Type command will print the type that the function needs to have in order for it to fit the goal. The type is also added to the Emacs kill-ring and can be pasted into the buffer using C-y.

    The application must be of the form f args where f is the name of the helper function you want to create. The arguments can use all the normal features like named implicits or instance arguments.

    Example:

    Here’s a start on a naive reverse on vectors:

    reverse : ∀ {A n} → Vec A n → Vec A n
    reverse [] = []
    reverse (x ∷ xs) = {!snoc (reverse xs) x!}
    

    Calling C-c C-h in the goal prints

    snoc : ∀ {A} {n} → Vec A n → A → Vec A (suc n)
    
  • A new command Explain why a particular name is in scope (C-c C-w) has been added. [Issue #207]

    This command can be called from a goal or from the top-level and will as the name suggests explain why a particular name is in scope.

    For each definition or module that the given name can refer to a trace is printed of all open statements and module applications leading back to the original definition of the name.

    For example, given

    module A (X : Set₁) where
      data Foo : Set where
        mkFoo : Foo
    module B (Y : Set₁) where
      open A Y public
    module C = B Set
    open C
    

    Calling C-c C-w on mkFoo at the top-level prints

    mkFoo is in scope as
    * a constructor Issue207.C._.Foo.mkFoo brought into scope by
      - the opening of C at Issue207.agda:13,6-7
      - the application of B at Issue207.agda:11,12-13
      - the application of A at Issue207.agda:9,8-9
      - its definition at Issue207.agda:6,5-10
    

    This command is useful if Agda complains about an ambiguous name and you need to figure out how to hide the undesired interpretations.

  • Improvements to the make case command (C-c C-c)

    • One can now also split on hidden variables, using the name (starting with .) with which they are printed. Use C-c C-, to see all variables in context.

    • Concerning the printing of generated clauses:

      • Uses named implicit arguments to improve readability.

      • Picks explicit occurrences over implicit ones when there is a choice of binding site for a variable.

      • Avoids binding variables in implicit positions by replacing dot patterns that uses them by wildcards (._).

  • Key bindings for lots of “mathematical” characters (examples: 𝐴𝑨𝒜𝓐𝔄) have been added to the Agda input method. Example: type \MiA\MIA\McA\MCA\MfA to get 𝐴𝑨𝒜𝓐𝔄.

    Note: \McB does not exist in Unicode (as well as others in that style), but the \MC (bold) alphabet is complete.

  • Key bindings for “blackboard bold” B (𝔹) and 0-9 (𝟘-𝟡) have been added to the Agda input method (\bb and \b[0-9]).

  • Key bindings for controlling simplification/normalisation:

    [TODO: Simplification should be explained somewhere.]

    Commands like Goal type and context (C-c C-,) could previously be invoked in two ways. By default the output was normalised, but if a prefix argument was used (for instance via C-u C-c C-,), then no explicit normalisation was performed. Now there are three options:

    • By default (C-c C-,) the output is simplified.

    • If C-u is used exactly once (C-u C-c C-,), then the result is neither (explicitly) normalised nor simplified.

    • If C-u is used twice (C-u C-u C-c C-,), then the result is normalised.

    [TODO: As part of the release of Agda 2.3.4 the key binding page on the wiki should be updated.]

LaTeX-backend

  • Two new color scheme options were added to agda.sty:

    \usepackage[bw]{agda}, which highlights in black and white; \usepackage[conor]{agda}, which highlights using Conor’s colors.

    The default (no options passed) is to use the standard colors.

  • If agda.sty cannot be found by the LateX environment, it is now copied into the LateX output directory (latex by default) instead of the working directory. This means that the commands needed to produce a PDF now is

    agda --latex -i . <file>.lagda
    cd latex
    pdflatex <file>.tex
    
  • The LaTeX-backend has been made more tool agnostic, in particular XeLaTeX and LuaLaTeX should now work. Here is a small example (test/LaTeXAndHTML/succeed/UnicodeInput.lagda):

    \documentclass{article}
    \usepackage{agda}
    \begin{document}
    
    \begin{code}
    data αβγδεζθικλμνξρστυφχψω : Set₁ where
    
    postulate
      →⇒⇛⇉⇄↦⇨↠⇀⇁ : Set
    \end{code}
    
    \[
    ∀X [ ∅ ∉ X ⇒ ∃f:X ⟶  ⋃ X\ ∀A ∈ X (f(A) ∈ A) ]
    \]
    \end{document}
    

    Compiled as follows, it should produce a nice looking PDF (tested with TeX Live 2012):

    agda --latex <file>.lagda
    cd latex
    xelatex <file>.tex (or lualatex <file>.tex)
    

    If symbols are missing or XeLaTeX/LuaLaTeX complains about the font missing, try setting a different font using:

    \setmathfont{<math-font>}
    

    Use the fc-list tool to list available fonts.

  • Add experimental support for hyperlinks to identifiers

    If the hyperref LateX package is loaded before the Agda package and the links option is passed to the Agda package, then the Agda package provides a function called \AgdaTarget. Identifiers which have been declared targets, by the user, will become clickable hyperlinks in the rest of the document. Here is a small example (test/LaTeXAndHTML/succeed/Links.lagda):

    \documentclass{article}
    \usepackage{hyperref}
    \usepackage[links]{agda}
    \begin{document}
    
    \AgdaTarget{ℕ}
    \AgdaTarget{zero}
    \begin{code}
    data ℕ : Set where
      zero  : ℕ
      suc   : ℕ → ℕ
    \end{code}
    
    See next page for how to define \AgdaFunction{two} (doesn't turn into a
    link because the target hasn't been defined yet). We could do it
    manually though; \hyperlink{two}{\AgdaDatatype{two}}.
    
    \newpage
    
    \AgdaTarget{two}
    \hypertarget{two}{}
    \begin{code}
    two : ℕ
    two = suc (suc zero)
    \end{code}
    
    \AgdaInductiveConstructor{zero} is of type
    \AgdaDatatype{ℕ}. \AgdaInductiveConstructor{suc} has not been defined to
    be a target so it doesn't turn into a link.
    
    \newpage
    
    Now that the target for \AgdaFunction{two} has been defined the link
    works automatically.
    
    \begin{code}
    data Bool : Set where
      true false : Bool
    \end{code}
    
    The AgdaTarget command takes a list as input, enabling several
    targets to be specified as follows:
    
    \AgdaTarget{if, then, else, if\_then\_else\_}
    \begin{code}
    if_then_else_ : {A : Set} → Bool → A → A → A
    if true  then t else f = t
    if false then t else f = f
    \end{code}
    
    \newpage
    
    Mixfix identifier need their underscores escaped:
    \AgdaFunction{if\_then\_else\_}.
    
    \end{document}
    

    The boarders around the links can be suppressed using hyperref’s hidelinks option:

      \usepackage[hidelinks]{hyperref}
    

    Note that the current approach to links does not keep track of scoping or types, and hence overloaded names might create links which point to the wrong place. Therefore it is recommended to not overload names when using the links option at the moment, this might get fixed in the future.

Release notes for Agda 2 version 2.3.2.2

  • Fixed a bug that sometimes made it tricky to use the Emacs mode on Windows [Issue #757].

  • Made Agda build with newer versions of some libraries.

  • Fixed a bug that caused ambiguous parse error messages [Issue #147].

Release notes for Agda 2 version 2.3.2.1

Installation

  • Made it possible to compile Agda with more recent versions of hashable, QuickCheck and Win32.

  • Excluded mtl-2.1.

Type checking

  • Fixed bug in the termination checker (Issue #754).

Release notes for Agda 2 version 2.3.2

Installation

  • The Agda-executable package has been removed.

    The executable is now provided as part of the Agda package.

  • The Emacs mode no longer depends on haskell-mode or GHCi.

  • Compilation of Emacs mode Lisp files.

    You can now compile the Emacs mode Lisp files by running agda-mode compile. This command is run by make install.

    Compilation can, in some cases, give a noticeable speedup.

    WARNING: If you reinstall the Agda mode without recompiling the Emacs Lisp files, then Emacs may continue using the old, compiled files.

Pragmas and options

  • The --without-K check now reconstructs constructor parameters.

    New specification of --without-K:

    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 (or literals) to distinct variables. Constructors are usually not applied to parameters, but for the purposes of this check constructor parameters are treated as other arguments.

    • These distinct variables must not be free in pars.

  • Irrelevant arguments are printed as _ by default now. To turn on printing of irrelevant arguments, use option

    --show-irrelevant
    
  • New: Pragma NO_TERMINATION_CHECK to switch off termination checker for individual function definitions and mutual blocks.

    The pragma must precede a function definition or a mutual block. Examples (see test/Succeed/NoTerminationCheck.agda):

    1. Skipping a single definition: before type signature.

      {-# NO_TERMINATION_CHECK #-}
      a : A
      a = a
      
    2. Skipping a single definition: before first clause.

      b : A
      {-# NO_TERMINATION_CHECK #-}
      b = b
      
    3. Skipping an old-style mutual block: Before mutual keyword.

      {-# NO_TERMINATION_CHECK #-}
      mutual
        c : A
        c = d
      
        d : A
        d = c
      
    4. Skipping a new-style mutual block: Anywhere before a type signature or first function clause in the block

      i : A
      j : A
      
      i = j
      {-# NO_TERMINATION_CHECK #-}
      j = i
      

    The pragma cannot be used in --safe mode.

Language

  • Let binding record patterns

    record _×_ (A B : Set) : Set where
      constructor _,_
      field
        fst : A
        snd : B
    open _×_
    
    let (x , (y , z)) = t
    in  u
    

    will now be interpreted as

    let x = fst t
        y = fst (snd t)
        z = snd (snd t)
    in  u
    

    Note that the type of t needs to be inferable. If you need to provide a type signature, you can write the following:

    let a : ...
        a = t
        (x , (y , z)) = a
    in  u
    
  • Pattern synonyms

    A pattern synonym is a declaration that can be used on the left hand side (when pattern matching) as well as the right hand side (in expressions). For example:

    pattern z    = zero
    pattern ss x = suc (suc x)
    
    f : ℕ -> ℕ
    f z       = z
    f (suc z) = ss z
    f (ss n)  = n
    

    Pattern synonyms are implemented by substitution on the abstract syntax, so definitions are scope-checked but not type-checked. They are particularly useful for universe constructions.

  • Qualified mixfix operators

    It is now possible to use a qualified mixfix operator by qualifying the first part of the name. For instance

    import Data.Nat as Nat
    import Data.Bool as Bool
    
    two = Bool.if true then 1 Nat.+ 1 else 0
    
  • Sections [Issue #735]. Agda now parses anonymous modules as sections:

    module _ {a} (A : Set a) where
    
      data List : Set a where
        []  : List
        _∷_ : (x : A) (xs : List) → List
    
    module _ {a} {A : Set a} where
    
      _++_ : List A → List A → List A
      []       ++ ys = ys
      (x ∷ xs) ++ ys = x ∷ (xs ++ ys)
    
    test : List Nat
    test = (5 ∷ []) ++ (3 ∷ [])
    

    In general, now the syntax

    module _ parameters where
      declarations
    

    is accepted and has the same effect as

    private
      module M parameters where
        declarations
    open M public
    

    for a fresh name M.

  • Instantiating a module in an open import statement [Issue #481]. Now accepted:

    open import Path.Module args [using/hiding/renaming (...)]
    

    This only brings the imported identifiers from Path.Module into scope, not the module itself! Consequently, the following is pointless, and raises an error:

      import Path.Module args [using/hiding/renaming (...)]
    

    You can give a private name M to the instantiated module via

    import Path.Module args as M [using/hiding/renaming (...)]
    open import Path.Module args as M [using/hiding/renaming (...)]
    

    Try to avoid as as part of the arguments. as is not a keyword; the following can be legal, although slightly obfuscated Agda code:

    open import as as as as as as
    
  • Implicit module parameters can be given by name. E.g.

    open M {namedArg = bla}
    

    This feature has been introduced in Agda 2.3.0 already.

  • Multiple type signatures sharing a same type can now be written as a single type signature.

    one two : ℕ
    one = suc zero
    two = suc one
    

Goal and error display

  • Meta-variables that were introduced by hidden argument arg are now printed as _arg_number instead of just _number. [Issue #526]

  • Agda expands identifiers in anonymous modules when printing. Should make some goals nicer to read. [Issue #721]

  • When a module identifier is ambiguous, Agda tells you if one of them is a data type module. [Issues #318, #705]

Type checking

  • Improved coverage checker. The coverage checker splits on arguments that have constructor or literal pattern, committing to the left-most split that makes progress. Consider the lookup function for vectors:

    data Fin : Nat → Set where
      zero : {n : Nat} → Fin (suc n)
      suc  : {n : Nat} → Fin n → Fin (suc n)
    
    data Vec (A : Set) : Nat → Set where
      []  : Vec A zero
      _∷_ : {n : Nat} → A → Vec A n → Vec A (suc n)
    
    _!!_ : {A : Set}{n : Nat} → Vec A n → Fin n → A
    (x ∷ xs) !! zero  = x
    (x ∷ xs) !! suc i = xs !! i
    

    In Agda up to 2.3.0, this definition is rejected unless we add an absurd clause

    [] !! ()
    

    This is because the coverage checker committed on splitting on the vector argument, even though this inevitably lead to failed coverage, because a case for the empty vector [] is missing.

    The improvement to the coverage checker consists on committing only on splits that have a chance of covering, since all possible constructor patterns are present. Thus, Agda will now split first on the Fin argument, since cases for both zero and suc are present. Then, it can split on the Vec argument, since the empty vector is already ruled out by instantiating n to a suc _.

  • Instance arguments resolution will now consider candidates which still expect hidden arguments. For example:

    record Eq (A : Set) : Set where
      field eq : A → A → Bool
    
    open Eq {{...}}
    
    eqFin : {n : ℕ} → Eq (Fin n)
    eqFin = record { eq = primEqFin }
    
    testFin : Bool
    testFin = eq fin1 fin2
    

    The type-checker will now resolve the instance argument of the eq function to eqFin {_}. This is only done for hidden arguments, not instance arguments, so that the instance search stays non-recursive.

  • Constraint solving: Upgraded Miller patterns to record patterns. [Issue #456]

    Agda now solves meta-variables that are applied to record patterns. A typical (but here, artificial) case is:

    record Sigma (A : Set)(B : A -> Set) : Set where
      constructor _,_
      field
        fst : A
        snd : B fst
    
    test : (A : Set)(B : A -> Set) ->
      let X : Sigma A B -> Sigma A B
          X = _
      in  (x : A)(y : B x) -> X (x , y) ≡ (x , y)
    test A B x y = refl
    

    This yields a constraint of the form

    _X A B (x , y) := t[x,y]
    

    (with t[x,y] = (x, y)) which is not a Miller pattern. However, Agda now solves this as

    _X A B z := t[fst z,snd z].
    
  • Changed: solving recursive constraints. [Issue #585]

    Until 2.3.0, Agda sometimes inferred values that did not pass the termination checker later, or would even make Agda loop. To prevent this, the occurs check now also looks into the definitions of the current mutual block, to avoid constructing recursive solutions. As a consequence, also terminating recursive solutions are no longer found automatically.

    This effects a programming pattern where the recursively computed type of a recursive function is left to Agda to solve.

    mutual
    
      T : D -> Set
      T pattern1 = _
      T pattern2 = _
    
      f : (d : D) -> T d
      f pattern1 = rhs1
      f pattern2 = rhs2
    

    This might no longer work from now on. See examples test/Fail/Issue585*.agda.

  • Less eager introduction of implicit parameters. [Issue #679]

    Until Agda 2.3.0, trailing hidden parameters were introduced eagerly on the left hand side of a definition. For instance, one could not write

    test : {A : Set} -> Set
    test = \ {A} -> A
    

    because internally, the hidden argument {A : Set} was added to the left-hand side, yielding

    test {_} = \ {A} -> A
    

    which raised a type error. Now, Agda only introduces the trailing implicit parameters it has to, in order to maintain uniform function arity. For instance, in

    test : Bool -> {A B C : Set} -> Set
    test true {A}      = A
    test false {B = B} = B
    

    Agda will introduce parameters A and B in all clauses, but not C, resulting in

    test : Bool -> {A B C : Set} -> Set
    test true  {A} {_}     = A
    test false {_} {B = B} = B
    

    Note that for checking where-clauses, still all hidden trailing parameters are in scope. For instance:

    id : {i : Level}{A : Set i} -> A -> A
    id = myId
      where myId : forall {A} -> A -> A
            myId x = x
    

    To be able to fill in the meta variable _1 in

    myId : {A : Set _1} -> A -> A
    

    the hidden parameter {i : Level} needs to be in scope.

    As a result of this more lazy introduction of implicit parameters, the following code now passes.

    data Unit : Set where
      unit : Unit
    
    T : Unit → Set
    T unit = {u : Unit} → Unit
    
    test : (u : Unit) → T u
    test unit with unit
    ... | _ = λ {v} → v
    

    Before, Agda would eagerly introduce the hidden parameter {v} as unnamed left-hand side parameter, leaving no way to refer to it.

    The related Issue #655 has also been addressed. It is now possible to make `synonym’ definitions

    name = expression
    

    even when the type of expression begins with a hidden quantifier. Simple example:

    id2 = id
    

    That resulted in unsolved metas until 2.3.0.

  • Agda detects unused arguments and ignores them during equality checking. [Issue #691, solves also Issue #44]

    Agda’s polarity checker now assigns ‘Nonvariant’ to arguments that are not actually used (except for absurd matches). If f’s first argument is Nonvariant, then f x is definitionally equal to f y regardless of x and y. It is similar to irrelevance, but does not require user annotation.

    For instance, unused module parameters do no longer get in the way:

    module M (x : Bool) where
    
      not : Bool → Bool
      not true  = false
      not false = true
    
    open M true
    open M false renaming (not to not′)
    
    test : (y : Bool) → not y ≡ not′ y
    test y = refl
    

    Matching against record or absurd patterns does not count as `use’, so we get some form of proof irrelevance:

    data ⊥ : Set where
    record ⊤ : Set where
      constructor trivial
    
    data Bool : Set where
      true false : Bool
    
    True : Bool → Set
    True true  = ⊤
    True false = ⊥
    
    fun : (b : Bool) → True b → Bool
    fun true  trivial = true
    fun false ()
    
    test : (b : Bool) → (x y : True b) → fun b x ≡ fun b y
    test b x y = refl
    

    More examples in test/Succeed/NonvariantPolarity.agda.

    Phantom arguments: Parameters of record and data types are considered `used’ even if they are not actually used. Consider:

    False : Nat → Set
    False zero    = ⊥
    False (suc n) = False n
    
    module Invariant where
      record Bla (n : Nat)(p : False n) : Set where
    
    module Nonvariant where
      Bla : (n : Nat) → False n → Set
      Bla n p = ⊤
    

    Even though record Bla does not use its parameters n and p, they are considered as used, allowing “phantom type” techniques.

    In contrast, the arguments of function Bla are recognized as unused. The following code type-checks if we open Invariant but leaves unsolved metas if we open Nonvariant.

    drop-suc : {n : Nat}{p : False n} → Bla (suc n) p → Bla n p
    drop-suc _ = _
    
    bla : (n : Nat) → {p : False n} → Bla n p → ⊥
    bla zero {()} b
    bla (suc n) b = bla n (drop-suc b)
    

    If Bla is considered invariant, the hidden argument in the recursive call can be inferred to be p. If it is considered non-variant, then Bla n X = Bla n p does not entail X = p and the hidden argument remains unsolved. Since bla does not actually use its hidden argument, its value is not important and it could be searched for. Unfortunately, polarity analysis of bla happens only after type checking, thus, the information that bla is non-variant in p is not available yet when meta-variables are solved. (See test/Fail/BrokenInferenceDueToNonvariantPolarity.agda)

  • Agda now expands simple definitions (one clause, terminating) to check whether a function is constructor headed. [Issue #747] For instance, the following now also works:

    MyPair : Set -> Set -> Set
    MyPair A B = Pair A B
    
    Vec : Set -> Nat -> Set
    Vec A zero    = Unit
    Vec A (suc n) = MyPair A (Vec A n)
    

    Here, Unit and Pair are data or record types.

Compiler backends

  • -Werror is now overridable.

    To enable compilation of Haskell modules containing warnings, the -Werror flag for the MAlonzo backend has been made overridable. If, for example, --ghc-flag=-Wwarn is passed when compiling, one can get away with things like:

    data PartialBool : Set where
      true : PartialBool
    
    {-# COMPILED_DATA PartialBool Bool True #-}
    

    The default behavior remains as it used to be and rejects the above program.

Tools

Emacs mode

  • Asynchronous Emacs mode.

    One can now use Emacs while a buffer is type-checked. If the buffer is edited while the type-checker runs, then syntax highlighting will not be updated when type-checking is complete.

  • Interactive syntax highlighting.

    The syntax highlighting is updated while a buffer is type-checked:

    • At first the buffer is highlighted in a somewhat crude way (without go-to-definition information for overloaded constructors).

    • If the highlighting level is “interactive”, then the piece of code that is currently being type-checked is highlighted as such. (The default is “non-interactive”.)

    • When a mutual block has been type-checked it is highlighted properly (this highlighting includes warnings for potential non-termination).

    The highlighting level can be controlled via the new configuration variable agda2-highlight-level.

  • Multiple case-splits can now be performed in one go.

    Consider the following example:

    _==_ : Bool → Bool → Bool
    b₁ == b₂ = {!!}
    

    If you split on b₁ b₂, then you get the following code:

    _==_ : Bool → Bool → Bool
    true == true = {!!}
    true == false = {!!}
    false == true = {!!}
    false == false = {!!}
    

    The order of the variables matters. Consider the following code:

    lookup : ∀ {a n} {A : Set a} → Vec A n → Fin n → A
    lookup xs i = {!!}
    

    If you split on xs i, then you get the following code:

    lookup : ∀ {a n} {A : Set a} → Vec A n → Fin n → A
    lookup [] ()
    lookup (x ∷ xs) zero = {!!}
    lookup (x ∷ xs) (suc i) = {!!}
    

    However, if you split on i xs, then you get the following code instead:

    lookup : ∀ {a n} {A : Set a} → Vec A n → Fin n → A
    lookup (x ∷ xs) zero = ?
    lookup (x ∷ xs) (suc i) = ?
    

    This code is rejected by Agda 2.3.0, but accepted by 2.3.2 thanks to improved coverage checking (see above).

  • The Emacs mode now presents information about which module is currently being type-checked.

  • New global menu entry: Information about the character at point.

    If this entry is selected, then information about the character at point is displayed, including (in many cases) information about how to type the character.

  • Commenting/uncommenting the rest of the buffer.

    One can now comment or uncomment the rest of the buffer by typing C-c C-x M-; or by selecting the menu entry Comment/uncomment the rest of the buffer”.

  • The Emacs mode now uses the Agda executable instead of GHCi.

    The *ghci* buffer has been renamed to *agda2*.

    A new configuration variable has been introduced: agda2-program-name, the name of the Agda executable (by default agda).

    The variable agda2-ghci-options has been replaced by agda2-program-args: extra arguments given to the Agda executable (by default none).

    If you want to limit Agda’s memory consumption you can add some arguments to agda2-program-args, for instance +RTS -M1.5G -RTS.

  • The Emacs mode no longer depends on haskell-mode.

    Users who have customised certain haskell-mode variables (such as haskell-ghci-program-args) may want to update their configuration.

LaTeX-backend

An experimental LaTeX-backend which does precise highlighting a la the HTML-backend and code alignment a la lhs2TeX has been added.

Here is a sample input literate Agda file:

\documentclass{article}

\usepackage{agda}

\begin{document}

The following module declaration will be hidden in the output.

\AgdaHide{
\begin{code}
module M where
\end{code}
}

Two or more spaces can be used to make the backend align stuff.

\begin{code}
data ℕ : Set where
  zero  : ℕ
  suc   : ℕ → ℕ

_+_ : ℕ → ℕ → ℕ
zero   + n = n
suc m  + n = suc (m + n)
\end{code}

\end{document}

To produce an output PDF issue the following commands:

agda --latex -i . <file>.lagda
pdflatex latex/<file>.tex

Only the top-most module is processed, like with lhs2tex and unlike with the HTML-backend. If you want to process imported modules you have to call agda --latex manually on each of those modules.

There are still issues related to formatting, see the bug tracker for more information:

https://code.google.com/p/agda/issues/detail?id=697

The default agda.sty might therefore change in backwards-incompatible ways, as work proceeds in trying to resolve those problems.

Implemented features:

  • Two or more spaces can be used to force alignment of things, like with lhs2tex. See example above.

  • The highlighting information produced by the type checker is used to generate the output. For example, the data declaration in the example above, produces:

    \AgdaKeyword{data} \AgdaDatatype{ℕ} \AgdaSymbol{:}
        \AgdaPrimitiveType{Set} \AgdaKeyword{where}
    

    These LaTeX commands are defined in agda.sty (which is imported by \usepackage{agda}) and cause the highlighting.

  • The LaTeX-backend checks if agda.sty is found by the LaTeX environment, if it isn’t a default agda.sty is copied from Agda’s data-dir into the working directory (and thus made available to the LaTeX environment).

    If the default agda.sty isn’t satisfactory (colors, fonts, spacing, etc) then the user can modify it and make put it somewhere where the LaTeX environment can find it. Hopefully most aspects should be modifiable via agda.sty rather than having to tweak the implementation.

  • --latex-dir can be used to change the default output directory.

Release notes for Agda 2 version 2.3.0

Language

  • New more liberal syntax for mutually recursive definitions.

    It is no longer necessary to use the mutual keyword to define mutually recursive functions or datatypes. Instead, it is enough to declare things before they are used. Instead of

    mutual
      f : A
      f = a[f, g]
    
      g : B[f]
      g = b[f, g]
    

    you can now write

    f : A
    g : B[f]
    f = a[f, g]
    g = b[f, g].
    

    With the new style you have more freedom in choosing the order in which things are type checked (previously type signatures were always checked before definitions). Furthermore you can mix arbitrary declarations, such as modules and postulates, with mutually recursive definitions.

    For data types and records the following new syntax is used to separate the declaration from the definition:

    -- Declaration.
    data Vec (A : Set) : Nat → Set  -- Note the absence of 'where'.
    
    -- Definition.
    data Vec A where
      []   : Vec A zero
      _::_ : {n : Nat} → A → Vec A n → Vec A (suc n)
    
    -- Declaration.
    record Sigma (A : Set) (B : A → Set) : Set
    
    -- Definition.
    record Sigma A B where
      constructor _,_
      field fst : A
            snd : B fst
    

    When making separated declarations/definitions private or abstract you should attach the private keyword to the declaration and the abstract keyword to the definition. For instance, a private, abstract function can be defined as

    private
      f : A
    abstract
      f = e
    

    Finally it may be worth noting that the old style of mutually recursive definitions is still supported (it basically desugars into the new style).

  • Pattern matching lambdas.

    Anonymous pattern matching functions can be defined using the syntax

    \ { p11 .. p1n -> e1 ; ... ; pm1 .. pmn -> em }
    

    (where, as usual, \ and -> can be replaced by λ and ). Internally this is translated into a function definition of the following form:

    .extlam p11 .. p1n = e1
    ...
    .extlam pm1 .. pmn = em
    

    This means that anonymous pattern matching functions are generative. For instance, refl will not be accepted as an inhabitant of the type

    (λ { true → true ; false → false }) ≡
    (λ { true → true ; false → false }),
    

    because this is equivalent to extlam1 ≡ extlam2 for some distinct fresh names extlam1 and extlam2.

    Currently the where and with constructions are not allowed in (the top-level clauses of) anonymous pattern matching functions.

    Examples:

    and : Bool → Bool → Bool
    and = λ { true x → x ; false _ → false }
    
    xor : Bool → Bool → Bool
    xor = λ { true  true  → false
            ; false false → false
            ; _     _     → true
            }
    
    fst : {A : Set} {B : A → Set} → Σ A B → A
    fst = λ { (a , b) → a }
    
    snd : {A : Set} {B : A → Set} (p : Σ A B) → B (fst p)
    snd = λ { (a , b) → b }
    
  • Record update syntax.

    Assume that we have a record type and a corresponding value:

    record MyRecord : Set where
      field
        a b c : ℕ
    
    old : MyRecord
    old = record { a = 1; b = 2; c = 3 }
    

    Then we can update (some of) the record value’s fields in the following way:

    new : MyRecord
    new = record old { a = 0; c = 5 }
    

    Here new normalises to record { a = 0; b = 2; c = 5 }. Any expression yielding a value of type MyRecord can be used instead of old.

    Record updating is not allowed to change types: the resulting value must have the same type as the original one, including the record parameters. Thus, the type of a record update can be inferred if the type of the original record can be inferred.

    The record update syntax is expanded before type checking. When the expression

    record old { upd-fields }
    

    is checked against a record type R, it is expanded to

    let r = old in record { new-fields },
    

    where old is required to have type R and new-fields is defined as follows: for each field x in R,

    • if x = e is contained in upd-fields then x = e is included in new-fields, and otherwise

    • if x is an explicit field then x = R.x r is included in new-fields, and

    • if x is an implicit or instance field, then it is omitted from new-fields.

    (Instance arguments are explained below.) The reason for treating implicit and instance fields specially is to allow code like the following:

    record R : Set where
      field
        {length} : ℕ
        vec      : Vec ℕ length
        -- More fields…
    
    xs : R
    xs = record { vec = 0 ∷ 1 ∷ 2 ∷ [] }
    
    ys = record xs { vec = 0 ∷ [] }
    

    Without the special treatment the last expression would need to include a new binding for length (for instance length = _).

  • Record patterns which do not contain data type patterns, but which do contain dot patterns, are no longer rejected.

  • When the --without-K flag is used literals are now treated as constructors.

  • Under-applied functions can now reduce.

    Consider the following definition:

    id : {A : Set} → A → A
    id x = x
    

    Previously the expression id would not reduce. This has been changed so that it now reduces to λ x → x. Usually this makes little difference, but it can be important in conjunction with with. See Issue #365 for an example.

  • Unused AgdaLight legacy syntax (x y : A; z v : B) for telescopes has been removed.

Universe polymorphism

  • Universe polymorphism is now enabled by default. Use --no-universe-polymorphism to disable it.

  • Universe levels are no longer defined as a data type.

    The basic level combinators can be introduced in the following way:

    postulate
      Level : Set
      zero  : Level
      suc   : Level → Level
      max   : Level → Level → Level
    
    {-# BUILTIN LEVEL     Level #-}
    {-# BUILTIN LEVELZERO zero  #-}
    {-# BUILTIN LEVELSUC  suc   #-}
    {-# BUILTIN LEVELMAX  max   #-}
    
  • The BUILTIN equality is now required to be universe-polymorphic.

  • trustMe is now universe-polymorphic.

Meta-variables and unification

  • Unsolved meta-variables are now frozen after every mutual block. This means that they cannot be instantiated by subsequent code. For instance,

    one : Nat
    one = _
    
    bla : one ≡ suc zero
    bla = refl
    

    leads to an error now, whereas previously it lead to the instantiation of _ with suc zero. If you want to make use of the old behaviour, put the two definitions in a mutual block.

    All meta-variables are unfrozen during interactive editing, so that the user can fill holes interactively. Note that type-checking of interactively given terms is not perfect: Agda sometimes refuses to load a file, even though no complaints were raised during the interactive construction of the file. This is because certain checks (for instance, positivity) are only invoked when a file is loaded.

  • Record types can now be inferred.

    If there is a unique known record type with fields matching the fields in a record expression, then the type of the expression will be inferred to be the record type applied to unknown parameters.

    If there is no known record type with the given fields the type checker will give an error instead of producing lots of unsolved meta-variables.

    Note that “known record type” refers to any record type in any imported module, not just types which are in scope.

  • The occurrence checker distinguishes rigid and strongly rigid occurrences [Reed, LFMTP 2009; Abel & Pientka, TLCA 2011].

    The completeness checker now accepts the following code:

    h : (n : Nat) → n ≡ suc n → Nat
    h n ()
    

    Internally this generates a constraint _n = suc _n where the meta-variable _n occurs strongly rigidly, i.e. on a constructor path from the root, in its own defining term tree. This is never solvable.

    Weakly rigid recursive occurrences may have a solution [Jason Reed’s PhD thesis, page 106]:

    test : (k : Nat) →
           let X : (Nat → Nat) → Nat
               X = _
           in
           (f : Nat → Nat) → X f ≡ suc (f (X (λ x → k)))
    test k f = refl
    

    The constraint _X k f = suc (f (_X k (λ x → k))) has the solution _X k f = suc (f (suc k)), despite the recursive occurrence of _X. Here _X is not strongly rigid, because it occurs under the bound variable f. Previously Agda rejected this code; now it instead complains about an unsolved meta-variable.

  • Equation constraints involving the same meta-variable in the head now trigger pruning [Pientka, PhD, Sec. 3.1.2; Abel & Pientka, TLCA 2011]. Example:

    same : let X : A → A → A → A × A
               X = _
           in {x y z : A} → X x y y ≡ (x , y)
                          × X x x y ≡ X x y y
    same = refl , refl
    

    The second equation implies that X cannot depend on its second argument. After pruning the first equation is linear and can be solved.

  • Instance arguments.

    A new type of hidden function arguments has been added: instance arguments. This new feature is based on influences from Scala’s implicits and Agda’s existing implicit arguments.

    Plain implicit arguments are marked by single braces: {…}. Instance arguments are instead marked by double braces: {{…}}. Example:

    postulate
      A : Set
      B : A → Set
      a : A
      f : {{a : A}} → B a
    

    Instead of the double braces you can use the symbols and , but these symbols must in many cases be surrounded by whitespace. (If you are using Emacs and the Agda input method, then you can conjure up the symbols by typing \{{ and \}}, respectively.)

    Instance arguments behave as ordinary implicit arguments, except for one important aspect: resolution of arguments which are not provided explicitly. For instance, consider the following code:

      test = f
    

    Here Agda will notice that f’s instance argument was not provided explicitly, and try to infer it. All definitions in scope at f’s call site, as well as all variables in the context, are considered. If exactly one of these names has the required type A, then the instance argument will be instantiated to this name.

    This feature can be used as an alternative to Haskell type classes. If we define

    record Eq (A : Set) : Set where
      field equal : A → A → Bool,
    

    then we can define the following projection:

    equal : {A : Set} {{eq : Eq A}} → A → A → Bool
    equal {{eq}} = Eq.equal eq
    

    Now consider the following expression:

    equal false false ∨ equal 3 4
    

    If the following Eq “instances” for Bool and are in scope, and no others, then the expression is accepted:

    eq-Bool : Eq Bool
    eq-Bool = record { equal = … }
    
    eq-ℕ : Eq ℕ
    eq-ℕ = record { equal = … }
    

    A shorthand notation is provided to avoid the need to define projection functions manually:

    module Eq-with-implicits = Eq {{...}}
    

    This notation creates a variant of Eq’s record module, where the main Eq argument is an instance argument instead of an explicit one. It is equivalent to the following definition:

    module Eq-with-implicits {A : Set} {{eq : Eq A}} = Eq eq
    

    Note that the short-hand notation allows you to avoid naming the “-with-implicits” module:

    open Eq {{...}}
    

    Instance argument resolution is not recursive. As an example, consider the following “parametrised instance”:

    eq-List : {A : Set} → Eq A → Eq (List A)
    eq-List {A} eq = record { equal = eq-List-A }
      where
      eq-List-A : List A → List A → Bool
      eq-List-A []       []       = true
      eq-List-A (a ∷ as) (b ∷ bs) = equal a b ∧ eq-List-A as bs
      eq-List-A _        _        = false
    

    Assume that the only Eq instances in scope are eq-List and eq-ℕ. Then the following code does not type-check:

    test = equal (1 ∷ 2 ∷ []) (3 ∷ 4 ∷ [])
    

    However, we can make the code work by constructing a suitable instance manually:

    test′ = equal (1 ∷ 2 ∷ []) (3 ∷ 4 ∷ [])
      where eq-List-ℕ = eq-List eq-ℕ
    

    By restricting the “instance search” to be non-recursive we avoid introducing a new, compile-time-only evaluation model to Agda.

    For more information about instance arguments, see Devriese & Piessens [ICFP 2011]. Some examples are also available in the examples/instance-arguments subdirectory of the Agda distribution.

Irrelevance

  • Dependent irrelevant function types.

    Some examples illustrating the syntax of dependent irrelevant function types:

    .(x y : A) → B    .{x y z : A} → B
    ∀ x .y → B        ∀ x .{y} {z} .v → B
    

    The declaration

    f : .(x : A) → B[x]
    f x = t[x]
    

    requires that x is irrelevant both in t[x] and in B[x]. This is possible if, for instance, B[x] = B′ x, with B′ : .A → Set.

    Dependent irrelevance allows us to define the eliminator for the Squash type:

    record Squash (A : Set) : Set where
      constructor squash
      field
        .proof : A
    
    elim-Squash : {A : Set} (P : Squash A → Set)
                  (ih : .(a : A) → P (squash a)) →
                  (a⁻ : Squash A) → P a⁻
    elim-Squash P ih (squash a) = ih a
    

    Note that this would not type-check with

    (ih : (a : A) -> P (squash a)).
    
  • Records with only irrelevant fields.

    The following now works:

    record IsEquivalence {A : Set} (_≈_ : A → A → Set) : Set where
      field
        .refl  : Reflexive _≈_
        .sym   : Symmetric _≈_
        .trans : Transitive _≈_
    
    record Setoid : Set₁ where
      infix 4 _≈_
      field
        Carrier        : Set
        _≈_            : Carrier → Carrier → Set
        .isEquivalence : IsEquivalence _≈_
    
      open IsEquivalence isEquivalence public
    

    Previously Agda complained about the application IsEquivalence isEquivalence, because isEquivalence is irrelevant and the IsEquivalence module expected a relevant argument. Now, when record modules are generated for records consisting solely of irrelevant arguments, the record parameter is made irrelevant:

    module IsEquivalence {A : Set} {_≈_ : A → A → Set}
                        .(r : IsEquivalence {A = A} _≈_) where
     …
    
  • Irrelevant things are no longer erased internally. This means that they are printed as ordinary terms, not as _ as before.

  • The new flag --experimental-irrelevance enables irrelevant universe levels and matching on irrelevant data when only one constructor is available. These features are very experimental and likely to change or disappear.

Reflection

  • The reflection API has been extended to mirror features like irrelevance, instance arguments and universe polymorphism, and to give (limited) access to definitions. For completeness all the builtins and primitives are listed below:

    -- Names.
    
    postulate Name : Set
    
    {-# BUILTIN QNAME Name #-}
    
    primitive
      -- Equality of names.
      primQNameEquality : Name → Name → Bool
    
    -- Is the argument visible (explicit), hidden (implicit), or an
    -- instance argument?
    
    data Visibility : Set where
      visible hidden instance : Visibility
    
    {-# BUILTIN HIDING   Visibility #-}
    {-# BUILTIN VISIBLE  visible    #-}
    {-# BUILTIN HIDDEN   hidden     #-}
    {-# BUILTIN INSTANCE instance   #-}
    
    -- Arguments can be relevant or irrelevant.
    
    data Relevance : Set where
      relevant irrelevant : Relevance
    
    {-# BUILTIN RELEVANCE  Relevance  #-}
    {-# BUILTIN RELEVANT   relevant   #-}
    {-# BUILTIN IRRELEVANT irrelevant #-}
    
    -- Arguments.
    
    data Arg A : Set where
      arg : (v : Visibility) (r : Relevance) (x : A) → Arg A
    
    {-# BUILTIN ARG    Arg #-}
    {-# BUILTIN ARGARG arg #-}
    
    -- Terms.
    
    mutual
      data Term : Set where
        -- Variable applied to arguments.
        var     : (x : ℕ) (args : List (Arg Term)) → Term
        -- Constructor applied to arguments.
        con     : (c : Name) (args : List (Arg Term)) → Term
        -- Identifier applied to arguments.
        def     : (f : Name) (args : List (Arg Term)) → Term
        -- Different kinds of λ-abstraction.
        lam     : (v : Visibility) (t : Term) → Term
        -- Pi-type.
        pi      : (t₁ : Arg Type) (t₂ : Type) → Term
        -- A sort.
        sort    : Sort → Term
        -- Anything else.
        unknown : Term
    
      data Type : Set where
        el : (s : Sort) (t : Term) → Type
    
      data Sort : Set where
        -- A Set of a given (possibly neutral) level.
        set     : (t : Term) → Sort
        -- A Set of a given concrete level.
        lit     : (n : ℕ) → Sort
        -- Anything else.
        unknown : Sort
    
    {-# BUILTIN AGDASORT            Sort    #-}
    {-# BUILTIN AGDATYPE            Type    #-}
    {-# BUILTIN AGDATERM            Term    #-}
    {-# BUILTIN AGDATERMVAR         var     #-}
    {-# BUILTIN AGDATERMCON         con     #-}
    {-# BUILTIN AGDATERMDEF         def     #-}
    {-# BUILTIN AGDATERMLAM         lam     #-}
    {-# BUILTIN AGDATERMPI          pi      #-}
    {-# BUILTIN AGDATERMSORT        sort    #-}
    {-# BUILTIN AGDATERMUNSUPPORTED unknown #-}
    {-# BUILTIN AGDATYPEEL          el      #-}
    {-# BUILTIN AGDASORTSET         set     #-}
    {-# BUILTIN AGDASORTLIT         lit     #-}
    {-# BUILTIN AGDASORTUNSUPPORTED unknown #-}
    
    postulate
      -- Function definition.
      Function  : Set
      -- Data type definition.
      Data-type : Set
      -- Record type definition.
      Record    : Set
    
    {-# BUILTIN AGDAFUNDEF    Function  #-}
    {-# BUILTIN AGDADATADEF   Data-type #-}
    {-# BUILTIN AGDARECORDDEF Record    #-}
    
    -- Definitions.
    
    data Definition : Set where
      function     : Function  → Definition
      data-type    : Data-type → Definition
      record′      : Record    → Definition
      constructor′ : Definition
      axiom        : Definition
      primitive′   : Definition
    
    {-# BUILTIN AGDADEFINITION                Definition   #-}
    {-# BUILTIN AGDADEFINITIONFUNDEF          function     #-}
    {-# BUILTIN AGDADEFINITIONDATADEF         data-type    #-}
    {-# BUILTIN AGDADEFINITIONRECORDDEF       record′      #-}
    {-# BUILTIN AGDADEFINITIONDATACONSTRUCTOR constructor′ #-}
    {-# BUILTIN AGDADEFINITIONPOSTULATE       axiom        #-}
    {-# BUILTIN AGDADEFINITIONPRIMITIVE       primitive′   #-}
    
    primitive
      -- The type of the thing with the given name.
      primQNameType        : Name → Type
      -- The definition of the thing with the given name.
      primQNameDefinition  : Name → Definition
      -- The constructors of the given data type.
      primDataConstructors : Data-type → List Name
    

    As an example the expression

    primQNameType (quote zero)
    

    is definitionally equal to

    el (lit 0) (def (quote ℕ) [])
    

    (if zero is a constructor of the data type ).

  • New keyword: unquote.

    The construction unquote t converts a representation of an Agda term to actual Agda code in the following way:

    1. The argument t must have type Term (see the reflection API above).

    2. The argument is normalised.

    3. The entire construction is replaced by the normal form, which is treated as syntax written by the user and type-checked in the usual way.

    Examples:

    test : unquote (def (quote ℕ) []) ≡ ℕ
    test = refl
    
    id : (A : Set) → A → A
    id = unquote (lam visible (lam visible (var 0 [])))
    
    id-ok : id ≡ (λ A (x : A) → x)
    id-ok = refl
    
  • New keyword: quoteTerm.

    The construction quoteTerm t is similar to quote n, but whereas quote is restricted to names n, quoteTerm accepts terms t. The construction is handled in the following way:

    1. The type of t is inferred. The term t must be type-correct.

    2. The term t is normalised.

    3. The construction is replaced by the Term representation (see the reflection API above) of the normal form. Any unsolved metavariables in the term are represented by the unknown term constructor.

    Examples:

    test₁ : quoteTerm (λ {A : Set} (x : A) → x) ≡
            lam hidden (lam visible (var 0 []))
    test₁ = refl
    
    -- Local variables are represented as de Bruijn indices.
    test₂ : (λ {A : Set} (x : A) → quoteTerm x) ≡ (λ x → var 0 [])
    test₂ = refl
    
    -- Terms are normalised before being quoted.
    test₃ : quoteTerm (0 + 0) ≡ con (quote zero) []
    test₃ = refl
    

Compiler backends

MAlonzo

  • The MAlonzo backend’s FFI now handles universe polymorphism in a better way.

    The translation of Agda types and kinds into Haskell now supports universe-polymorphic postulates. The core changes are that the translation of function types has been changed from

    T[[ Pi (x : A) B ]] =
      if A has a Haskell kind then
        forall x. () -> T[[ B ]]
      else if x in fv B then
        undef
      else
        T[[ A ]] -> T[[ B ]]
    

    into

    T[[ Pi (x : A) B ]] =
      if x in fv B then
        forall x. T[[ A ]] -> T[[ B ]]  -- Note: T[[A]] not Unit.
      else
        T[[ A ]] -> T[[ B ]],
    

    and that the translation of constants (postulates, constructors and literals) has been changed from

    T[[ k As ]] =
      if COMPILED_TYPE k T then
        T T[[ As ]]
      else
        undef
    

    into

    T[[ k As ]] =
      if COMPILED_TYPE k T then
        T T[[ As ]]
      else if COMPILED k E then
        ()
      else
        undef.
    

    For instance, assuming a Haskell definition

      type AgdaIO a b = IO b,
    

    we can set up universe-polymorphic IO in the following way:

    postulate
      IO     : ∀ {ℓ} → Set ℓ → Set ℓ
      return : ∀ {a} {A : Set a} → A → IO A
      _>>=_  : ∀ {a b} {A : Set a} {B : Set b} →
               IO A → (A → IO B) → IO B
    
    {-# COMPILED_TYPE IO AgdaIO              #-}
    {-# COMPILED return  (\_ _ -> return)    #-}
    {-# COMPILED _>>=_   (\_ _ _ _ -> (>>=)) #-}
    

    This is accepted because (assuming that the universe level type is translated to the Haskell unit type ())

    (\_ _ -> return)
      : forall a. () -> forall b. () -> b -> AgdaIO a b
      = T [[ ∀ {a} {A : Set a} → A → IO A ]]
    

    and

    (\_ _ _ _ -> (>>=))
      : forall a. () -> forall b. () ->
          forall c. () -> forall d. () ->
            AgdaIO a c -> (c -> AgdaIO b d) -> AgdaIO b d
      = T [[ ∀ {a b} {A : Set a} {B : Set b} →
               IO A → (A → IO B) → IO B ]].
    

Epic

  • New Epic backend pragma: STATIC.

    In the Epic backend, functions marked with the STATIC pragma will be normalised before compilation. Example usage:

    {-# STATIC power #-}
    
    power : ℕ → ℕ → ℕ
    power 0       x = 1
    power 1       x = x
    power (suc n) x = power n x * x
    

    Occurrences of power 4 x will be replaced by ((x * x) * x) * x.

  • Some new optimisations have been implemented in the Epic backend:

    • Removal of unused arguments.

    A worker/wrapper transformation is performed so that unused arguments can be removed by Epic’s inliner. For instance, the map function is transformed in the following way:

    map_wrap : (A B : Set) → (A → B) → List A → List B
    map_wrap A B f xs = map_work f xs
    
    map_work f []       = []
    map_work f (x ∷ xs) = f x ∷ map_work f xs
    

    If map_wrap is inlined (which it will be in any saturated call), then A and B disappear in the generated code.

    Unused arguments are found using abstract interpretation. The bodies of all functions in a module are inspected to decide which variables are used. The behaviour of postulates is approximated based on their types. Consider return, for instance:

    postulate return : {A : Set} → A → IO A
    

    The first argument of return can be removed, because it is of type Set and thus cannot affect the outcome of a program at runtime.

    • Injection detection.

    At runtime many functions may turn out to be inefficient variants of the identity function. This is especially true after forcing. Injection detection replaces some of these functions with more efficient versions. Example:

    inject : {n : ℕ} → Fin n → Fin (1 + n)
    inject {suc n} zero    = zero
    inject {suc n} (suc i) = suc (inject {n} i)
    

    Forcing removes the Fin constructors’ arguments, so this function is an inefficient identity function that can be replaced by the following one:

    inject {_} x = x
    

    To actually find this function, we make the induction hypothesis that inject is an identity function in its second argument and look at the branches of the function to decide if this holds.

    Injection detection also works over data type barriers. Example:

    forget : {A : Set} {n : ℕ} → Vec A n → List A
    forget []       = []
    forget (x ∷ xs) = x ∷ forget xs
    

    Given that the constructor tags (in the compiled Epic code) for Vec.[] and List.[] are the same, and that the tags for Vec._∷_ and List._∷_ are also the same, this is also an identity function. We can hence replace the definition with the following one:

    forget {_} xs = xs
    

    To get this to apply as often as possible, constructor tags are chosen after injection detection has been run, in a way to make as many functions as possible injections.

    Constructor tags are chosen once per source file, so it may be advantageous to define conversion functions like forget in the same module as one of the data types. For instance, if Vec.agda imports List.agda, then the forget function should be put in Vec.agda to ensure that vectors and lists get the same tags (unless some other injection function, which puts different constraints on the tags, is prioritised).

    • Smashing.

    This optimisation finds types whose values are inferable at runtime:

    • A data type with only one constructor where all fields are inferable is itself inferable.

    • Set ℓ is inferable (as it has no runtime representation).

    A function returning an inferable data type can be smashed, which means that it is replaced by a function which simply returns the inferred value.

    An important example of an inferable type is the usual propositional equality type (_≡_). Any function returning a propositional equality can simply return the reflexivity constructor directly without computing anything.

    This optimisation makes more arguments unused. It also makes the Epic code size smaller, which in turn speeds up compilation.

JavaScript

  • ECMAScript compiler backend.

    A new compiler backend is being implemented, targetting ECMAScript (also known as JavaScript), with the goal of allowing Agda programs to be run in browsers or other ECMAScript environments.

    The backend is still at an experimental stage: the core language is implemented, but many features are still missing.

    The ECMAScript compiler can be invoked from the command line using the flag --js:

    agda --js --compile-dir=<DIR> <FILE>.agda
    

    Each source <FILE>.agda is compiled into an ECMAScript target <DIR>/jAgda.<TOP-LEVEL MODULE NAME>.js. The compiler can also be invoked using the Emacs mode (the variable agda2-backend controls which backend is used).

    Note that ECMAScript is a strict rather than lazy language. Since Agda programs are total, this should not impact program semantics, but it may impact their space or time usage.

    ECMAScript does not support algebraic datatypes or pattern-matching. These features are translated to a use of the visitor pattern. For instance, the standard library’s List data type and null function are translated into the following code:

    exports["List"] = {};
    exports["List"]["[]"] = function (x0) {
        return x0["[]"]();
      };
    exports["List"]["_∷_"] = function (x0) {
        return function (x1) {
          return function (x2) {
            return x2["_∷_"](x0, x1);
          };
        };
      };
    
    exports["null"] = function (x0) {
        return function (x1) {
          return function (x2) {
            return x2({
              "[]": function () {
                return jAgda_Data_Bool["Bool"]["true"];
              },
              "_∷_": function (x3, x4) {
                return jAgda_Data_Bool["Bool"]["false"];
              }
            });
          };
        };
      };
    

    Agda records are translated to ECMAScript objects, preserving field names.

    Top-level Agda modules are translated to ECMAScript modules, following the common.js module specification. A top-level Agda module Foo.Bar is translated to an ECMAScript module jAgda.Foo.Bar.

    The ECMAScript compiler does not compile to Haskell, so the pragmas related to the Haskell FFI (IMPORT, COMPILED_DATA and COMPILED) are not used by the ECMAScript backend. Instead, there is a COMPILED_JS pragma which may be applied to any declaration. For postulates, primitives, functions and values, it gives the ECMAScript code to be emitted by the compiler. For data types, it gives a function which is applied to a value of that type, and a visitor object. For instance, a binding of natural numbers to ECMAScript integers (ignoring overflow errors) is:

    data ℕ : Set where
      zero : ℕ
      suc  : ℕ → ℕ
    
    {-# COMPILED_JS ℕ function (x,v) {
        if (x < 1) { return v.zero(); } else { return v.suc(x-1); }
      } #-}
    {-# COMPILED_JS zero 0 #-}
    {-# COMPILED_JS suc function (x) { return x+1; } #-}
    
    _+_ : ℕ → ℕ → ℕ
    zero  + n = n
    suc m + n = suc (m + n)
    
    {-# COMPILED_JS _+_ function (x) { return function (y) {
                          return x+y; };
      } #-}
    

    To allow FFI code to be optimised, the ECMAScript in a COMPILED_JS declaration is parsed, using a simple parser that recognises a pure functional subset of ECMAScript, consisting of functions, function applications, return, if-statements, if-expressions, side-effect-free binary operators (no precedence, left associative), side-effect-free prefix operators, objects (where all member names are quoted), field accesses, and string and integer literals. Modules may be imported using the require (<module-id>) syntax: any impure code, or code outside the supported fragment, can be placed in a module and imported.

Tools

  • New flag --safe, which can be used to type-check untrusted code.

    This flag disables postulates, primTrustMe, and “unsafe” OPTION pragmas, some of which are known to make Agda inconsistent.

    Rejected pragmas:

    --allow-unsolved-metas
    --experimental-irrelevance
    --guardedness-preserving-type-construtors
    --injective-type-constructors
    --no-coverage-check
    --no-positivity-check
    --no-termination-check
    --sized-types
    --type-in-type
    

    Note that, at the moment, it is not possible to define the universe level or coinduction primitives when --safe is used (because they must be introduced as postulates). This can be worked around by type-checking trusted files in a first pass, without using --safe, and then using --safe in a second pass. Modules which have already been type-checked are not re-type-checked just because --safe is used.

  • Dependency graphs.

    The new flag --dependency-graph=FILE can be used to generate a DOT file containing a module dependency graph. The generated file (FILE) can be rendered using a tool like dot.

  • The --no-unreachable-check flag has been removed.

  • Projection functions are highlighted as functions instead of as fields. Field names (in record definitions and record values) are still highlighted as fields.

  • Support for jumping to positions mentioned in the information buffer has been added.

  • The make install command no longer installs Agda globally (by default).

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:

    data _≡_ {A : Set} : A → A → Set where
      refl : ∀ x → x ≡ x
    

    Then the obvious implementation of the J rule is accepted:

    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:

    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:

    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:

    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:

    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

    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:

    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:

    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 ww. This means that

      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:

    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.

Release notes for Agda 2 version 2.2.8

Language

  • Record pattern matching.

    It is now possible to pattern match on named record constructors. Example:

    record Σ (A : Set) (B : A → Set) : Set where
      constructor _,_
      field
        proj₁ : A
        proj₂ : B proj₁
    
    map : {A B : Set} {P : A → Set} {Q : B → Set}
          (f : A → B) → (∀ {x} → P x → Q (f x)) →
          Σ A P → Σ B Q
    map f g (x , y) = (f x , g y)
    

    The clause above is internally translated into the following one:

    map f g p = (f (Σ.proj₁ p) , g (Σ.proj₂ p))
    

    Record patterns containing data type patterns are not translated. Example:

    add : ℕ × ℕ → ℕ
    add (zero  , n) = n
    add (suc m , n) = suc (add (m , n))
    

    Record patterns which do not contain data type patterns, but which do contain dot patterns, are currently rejected. Example:

    Foo : {A : Set} (p₁ p₂ : A × A) → proj₁ p₁ ≡ proj₁ p₂ → Set₁
    Foo (x , y) (.x , y′) refl = Set
    
  • Proof irrelevant function types.

    Agda now supports irrelevant non-dependent function types:

    f : .A → B
    

    This type implies that f does not depend computationally on its argument. One intended use case is data structures with embedded proofs, like sorted lists:

    postulate
      _≤_ : ℕ → ℕ → Set
      p₁  : 0 ≤ 1
      p₂  : 0 ≤ 1
    
    data SList (bound : ℕ) : Set where
      []    : SList bound
      scons : (head : ℕ) →
              .(head ≤ bound) →
              (tail : SList head) →
              SList bound
    

    The effect of the irrelevant type in the signature of scons is that scons’s second argument is never inspected after Agda has ensured that it has the right type. It is even thrown away, leading to smaller term sizes and hopefully some gain in efficiency. The type-checker ignores irrelevant arguments when checking equality, so two lists can be equal even if they contain different proofs:

    l₁ : SList 1
    l₁ = scons 0 p₁ []
    
    l₂ : SList 1
    l₂ = scons 0 p₂ []
    
    l₁≡l₂ : l₁ ≡ l₂
    l₁≡l₂ = refl
    

    Irrelevant arguments can only be used in irrelevant contexts. Consider the following subset type:

    data Subset (A : Set) (P : A → Set) : Set where
      _#_ : (elem : A) → .(P elem) → Subset A P
    

    The following two uses are fine:

    elimSubset : ∀ {A C : Set} {P} →
                 Subset A P → ((a : A) → .(P a) → C) → C
    elimSubset (a # p) k = k a p
    
    elem : {A : Set} {P : A → Set} → Subset A P → A
    elem (x # p) = x
    

    However, if we try to project out the proof component, then Agda complains that variable p is declared irrelevant, so it cannot be used here:

    prjProof : ∀ {A P} (x : Subset A P) → P (elem x)
    prjProof (a # p) = p
    

    Matching against irrelevant arguments is also forbidden, except in the case of irrefutable matches (record constructor patterns which have been translated away). For instance, the match against the pattern (p , q) here is accepted:

    elim₂ : ∀ {A C : Set} {P Q : A → Set} →
            Subset A (λ x → Σ (P x) (λ _ → Q x)) →
            ((a : A) → .(P a) → .(Q a) → C) → C
    elim₂ (a # (p , q)) k = k a p q
    

    Absurd matches () are also allowed.

    Note that record fields can also be irrelevant. Example:

    record Subset (A : Set) (P : A → Set) : Set where
      constructor _#_
      field
        elem   : A
        .proof : P elem
    

    Irrelevant fields are never in scope, neither inside nor outside the record. This means that no record field can depend on an irrelevant field, and furthermore projections are not defined for such fields. Irrelevant fields can only be accessed using pattern matching, as in elimSubset above.

    Irrelevant function types were added very recently, and have not been subjected to much experimentation yet, so do not be surprised if something is changed before the next release. For instance, dependent irrelevant function spaces (.(x : A) → B) might be added in the future.

  • Mixfix binders.

    It is now possible to declare user-defined syntax that binds identifiers. Example:

    postulate
      State  : Set → Set → Set
      put    : ∀ {S} → S → State S ⊤
      get    : ∀ {S} → State S S
      return : ∀ {A S} → A → State S A
      bind   : ∀ {A B S} → State S B → (B → State S A) → State S A
    
    syntax bind e₁ (λ x → e₂) = x ← e₁ , e₂
    
    increment : State ℕ ⊤
    increment = x ← get ,
                put (1 + x)
    

    The syntax declaration for bind implies that x is in scope in e₂, but not in e₁.

    You can give fixity declarations along with syntax declarations:

    infixr 40 bind
    syntax bind e₁ (λ x → e₂) = x ← e₁ , e₂
    

    The fixity applies to the syntax, not the name; syntax declarations are also restricted to ordinary, non-operator names. The following declaration is disallowed:

    syntax _==_ x y = x === y
    ```agda
    
    Syntax declarations must also be linear; the following declaration
    is disallowed:
    
    ```agda
    syntax wrong x = x + x
    

    Syntax declarations were added very recently, and have not been subjected to much experimentation yet, so do not be surprised if something is changed before the next release.

  • Prop has been removed from the language.

    The experimental sort Prop has been disabled. Any program using Prop should typecheck if Prop is replaced by Set₀. Note that Prop is still a keyword.

  • Injective type constructors off by default.

    Automatic injectivity of type constructors has been disabled (by default). To enable it, use the flag --injective-type-constructors, either on the command line or in an OPTIONS pragma. Note that this flag makes Agda anti-classical and possibly inconsistent:

    Agda with excluded middle is inconsistent http://thread.gmane.org/gmane.comp.lang.agda/1367

    See test/Succeed/InjectiveTypeConstructors.agda for an example.

  • Termination checker can count.

    There is a new flag --termination-depth=N accepting values N >= 1 (with N = 1 being the default) which influences the behavior of the termination checker. So far, the termination checker has only distinguished three cases when comparing the argument of a recursive call with the formal parameter of the callee.

    <: the argument is structurally smaller than the parameter

    =: they are equal

    ?: the argument is bigger or unrelated to the parameter

    This behavior, which is still the default (N = 1), will not recognise the following functions as terminating.

    mutual
    
       f : ℕ → ℕ
       f zero          = zero
       f (suc zero)    = zero
       f (suc (suc n)) = aux n
    
       aux : ℕ → ℕ
       aux m = f (suc m)
    

    The call graph

    f --(<)--> aux --(?)--> f
    

    yields a recursive call from f to f via aux where the relation of call argument to callee parameter is computed as “unrelated” (composition of < and ?).

    Setting N >= 2 allows a finer analysis: n has two constructors less than suc (suc n), and suc m has one more than m, so we get the call graph:

    f --(-2)--> aux --(+1)--> f
    

    The indirect call f --> f is now labeled with (-1), and the termination checker can recognise that the call argument is decreasing on this path.

    Setting the termination depth to N means that the termination checker counts decrease up to N and increase up to N-1. The default, N=1, means that no increase is counted, every increase turns to “unrelated”.

    In practice, examples like the one above sometimes arise when with is used. As an example, the program

    f : ℕ → ℕ
    f zero          = zero
    f (suc zero)    = zero
    f (suc (suc n)) with zero
    ... | _ = f (suc n)
    

    is internally represented as

    mutual
    
      f : ℕ → ℕ
      f zero          = zero
      f (suc zero)    = zero
      f (suc (suc n)) = aux n zero
    
      aux : ℕ → ℕ → ℕ
      aux m k = f (suc m)
    

    Thus, by default, the definition of f using with is not accepted by the termination checker, even though it looks structural (suc n is a subterm of suc suc n). Now, the termination checker is satisfied if the option --termination-depth=2 is used.

    Caveats:

    • This is an experimental feature, hopefully being replaced by something smarter in the near future.

    • Increasing the termination depth will quickly lead to very long termination checking times. So, use with care. Setting termination depth to 100 by habit, just to be on the safe side, is not a good idea!

    • Increasing termination depth only makes sense for linear data types such as and Size. For other types, increase cannot be recognised. For instance, consider a similar example with lists.

      data List : Set where
        nil  : List
        cons : ℕ → List → List
      
      mutual
        f : List → List
        f nil                  = nil
        f (cons x nil)         = nil
        f (cons x (cons y ys)) = aux y ys
      
        aux : ℕ → List → List
        aux z zs = f (cons z zs)
      

      Here the termination checker compares cons z zs to z and also to zs. In both cases, the result will be “unrelated”, no matter how high we set the termination depth. This is because when comparing cons z zs to zs, for instance, z is unrelated to zs, thus, cons z zs is also unrelated to zs. We cannot say it is just “one larger” since z could be a very large term. Note that this points to a weakness of untyped termination checking.

      To regain the benefit of increased termination depth, we need to index our lists by a linear type such as or Size. With termination depth 2, the above example is accepted for vectors instead of lists.

  • The codata keyword has been removed. To use coinduction, use the following new builtins: INFINITY, SHARP and FLAT. Example:

    {-# OPTIONS --universe-polymorphism #-}
    
    module Coinduction where
    
    open import Level
    
    infix 1000 ♯_
    
    postulate
      ∞  : ∀ {a} (A : Set a) → Set a
      ♯_ : ∀ {a} {A : Set a} → A → ∞ A
      ♭  : ∀ {a} {A : Set a} → ∞ A → A
    
    {-# BUILTIN INFINITY ∞  #-}
    {-# BUILTIN SHARP    ♯_ #-}
    {-# BUILTIN FLAT     ♭  #-}
    

    Note that (non-dependent) pattern matching on SHARP is no longer allowed.

    Note also that strange things might happen if you try to combine the pragmas above with COMPILED_TYPE, COMPILED_DATA or COMPILED pragmas, or if the pragmas do not occur right after the postulates.

    The compiler compiles the INFINITY builtin to nothing (more or less), so that the use of coinduction does not get in the way of FFI declarations:

    data Colist (A : Set) : Set where
      []  : Colist A
      _∷_ : (x : A) (xs : ∞ (Colist A)) → Colist A
    
    {-# COMPILED_DATA Colist [] [] (:) #-}
    
  • Infinite types.

    If the new flag --guardedness-preserving-type-constructors is used, then type constructors are treated as inductive constructors when we check productivity (but only in parameters, and only if they are used strictly positively or not at all). This makes examples such as the following possible:

    data Rec (A : ∞ Set) : Set where
      fold : ♭ A → Rec A
    
    -- Σ cannot be a record type below.
    
    data Σ (A : Set) (B : A → Set) : Set where
      _,_ : (x : A) → B x → Σ A B
    
    syntax Σ A (λ x → B) = Σ[ x ∶ A ] B
    
    -- Corecursive definition of the W-type.
    
    W : (A : Set) → (A → Set) → Set
    W A B = Rec (♯ (Σ[ x ∶ A ] (B x → W A B)))
    
    syntax W A (λ x → B) = W[ x ∶ A ] B
    
    sup : {A : Set} {B : A → Set} (x : A) (f : B x → W A B) → W A B
    sup x f = fold (x , f)
    
    W-rec : {A : Set} {B : A → Set}
            (P : W A B → Set) →
            (∀ {x} {f : B x → W A B} → (∀ y → P (f y)) → P (sup x f)) →
            ∀ x → P x
    W-rec P h (fold (x , f)) = h (λ y → W-rec P h (f y))
    
    -- Induction-recursion encoded as corecursion-recursion.
    
    data Label : Set where
      ′0 ′1 ′2 ′σ ′π ′w : Label
    
    mutual
    
      U : Set
      U = Σ Label U′
    
      U′ : Label → Set
      U′ ′0 = ⊤
      U′ ′1 = ⊤
      U′ ′2 = ⊤
      U′ ′σ = Rec (♯ (Σ[ a ∶ U ] (El a → U)))
      U′ ′π = Rec (♯ (Σ[ a ∶ U ] (El a → U)))
      U′ ′w = Rec (♯ (Σ[ a ∶ U ] (El a → U)))
    
      El : U → Set
      El (′0 , _)            = ⊥
      El (′1 , _)            = ⊤
      El (′2 , _)            = Bool
      El (′σ , fold (a , b)) = Σ[ x ∶ El a ]  El (b x)
      El (′π , fold (a , b)) =   (x : El a) → El (b x)
      El (′w , fold (a , b)) = W[ x ∶ El a ]  El (b x)
    
    U-rec : (P : ∀ u → El u → Set) →
            P (′1 , _) tt →
            P (′2 , _) true →
            P (′2 , _) false →
            (∀ {a b x y} →
             P a x → P (b x) y → P (′σ , fold (a , b)) (x , y)) →
            (∀ {a b f} →
             (∀ x → P (b x) (f x)) → P (′π , fold (a , b)) f) →
            (∀ {a b x f} →
             (∀ y → P (′w , fold (a , b)) (f y)) →
             P (′w , fold (a , b)) (sup x f)) →
            ∀ u (x : El u) → P u x
    U-rec P P1 P2t P2f Pσ Pπ Pw = rec
      where
      rec : ∀ u (x : El u) → P u x
      rec (′0 , _)            ()
      rec (′1 , _)            _              = P1
      rec (′2 , _)            true           = P2t
      rec (′2 , _)            false          = P2f
      rec (′σ , fold (a , b)) (x , y)        = Pσ (rec _ x) (rec _ y)
      rec (′π , fold (a , b)) f              = Pπ (λ x → rec _ (f x))
      rec (′w , fold (a , b)) (fold (x , f)) = Pw (λ y → rec _ (f y))
    

    The --guardedness-preserving-type-constructors extension is based on a rather operational understanding of /♯_; it’s not yet clear if this extension is consistent.

  • Qualified constructors.

    Constructors can now be referred to qualified by their data type. For instance, given

    data Nat : Set where
      zero : Nat
      suc  : Nat → Nat
    
    data Fin : Nat → Set where
      zero : ∀ {n} → Fin (suc n)
      suc  : ∀ {n} → Fin n → Fin (suc n)
    

    you can refer to the constructors unambiguously as Nat.zero, Nat.suc, Fin.zero, and Fin.suc (Nat and Fin are modules containing the respective constructors). Example:

    inj : (n m : Nat) → Nat.suc n ≡ suc m → n ≡ m
    inj .m m refl = refl
    

    Previously you had to write something like

    inj : (n m : Nat) → _≡_ {Nat} (suc n) (suc m) → n ≡ m
    

    to make the type checker able to figure out that you wanted the natural number suc in this case.

  • Reflection.

    There are two new constructs for reflection:

    • quoteGoal x in e

      In e the value of x will be a representation of the goal type (the type expected of the whole expression) as an element in a datatype of Agda terms (see below). For instance,

      example : ℕ
      example = quoteGoal x in {! at this point x = def (quote ℕ) [] !}
      
    • quote x : Name

      If x is the name of a definition (function, datatype, record, or a constructor), quote x gives you the representation of x as a value in the primitive type Name (see below).

    Quoted terms use the following BUILTINs and primitives (available from the standard library module Reflection):

    -- The type of Agda names.
    
    postulate Name : Set
    
    {-# BUILTIN QNAME Name #-}
    
    primitive primQNameEquality : Name → Name → Bool
    
    -- Arguments.
    
    Explicit? = Bool
    
    data Arg A : Set where
      arg : Explicit? → A → Arg A
    
    {-# BUILTIN ARG    Arg #-}
    {-# BUILTIN ARGARG arg #-}
    
    -- The type of Agda terms.
    
    data Term : Set where
      var     : ℕ → List (Arg Term) → Term
      con     : Name → List (Arg Term) → Term
      def     : Name → List (Arg Term) → Term
      lam     : Explicit? → Term → Term
      pi      : Arg Term → Term → Term
      sort    : Term
      unknown : Term
    
    {-# BUILTIN AGDATERM            Term    #-}
    {-# BUILTIN AGDATERMVAR         var     #-}
    {-# BUILTIN AGDATERMCON         con     #-}
    {-# BUILTIN AGDATERMDEF         def     #-}
    {-# BUILTIN AGDATERMLAM         lam     #-}
    {-# BUILTIN AGDATERMPI          pi      #-}
    {-# BUILTIN AGDATERMSORT        sort    #-}
    {-# BUILTIN AGDATERMUNSUPPORTED unknown #-}
    

    Reflection may be useful when working with internal decision procedures, such as the standard library’s ring solver.

  • Minor record definition improvement.

    The definition of a record type is now available when type checking record module definitions. This means that you can define things like the following:

    record Cat : Set₁ where
      field
        Obj  : Set
        _=>_ : Obj → Obj → Set
        -- ...
    
      -- not possible before:
      op : Cat
      op = record { Obj = Obj; _=>_ = λ A B → B => A }
    

Tools

  • The Goal type and context command now shows the goal type before the context, and the context is shown in reverse order. The Goal type, context and inferred type command has been modified in a similar way.

  • Show module contents command.

    Given a module name M the Emacs mode can now display all the top-level modules and names inside M, along with types for the names. The command is activated using C-c C-o or the menus.

  • Auto command.

    A command which searches for type inhabitants has been added. The command is invoked by pressing C-C C-a (or using the goal menu). There are several flags and parameters, e.g. -c which enables case-splitting in the search. For further information, see the Agda wiki:

    http://wiki.portal.chalmers.se/agda/pmwiki.php?n=Main.Auto

  • HTML generation is now possible for a module with unsolved meta-variables, provided that the --allow-unsolved-metas flag is used.

Release notes for Agda 2 version 2.2.6

Language

  • Universe polymorphism (experimental extension).

    To enable universe polymorphism give the flag --universe-polymorphism on the command line or (recommended) as an OPTIONS pragma.

    When universe polymorphism is enabled Set takes an argument which is the universe level. For instance, the type of universe polymorphic identity is

    id : {a : Level} {A : Set a} → A → A.
    

    The type Level is isomorphic to the unary natural numbers and should be specified using the BUILTINs LEVEL, LEVELZERO, and LEVELSUC:

    data Level : Set where
      zero : Level
      suc  : Level → Level
    
    {-# BUILTIN LEVEL     Level #-}
    {-# BUILTIN LEVELZERO zero  #-}
    {-# BUILTIN LEVELSUC  suc   #-}
    

    There is an additional BUILTIN LEVELMAX for taking the maximum of two levels:

    max : Level → Level → Level
    max  zero    m      = m
    max (suc n)  zero   = suc n
    max (suc n) (suc m) = suc (max n m)
    
    {-# BUILTIN LEVELMAX max #-}
    

    The non-polymorphic universe levels Set, Set₁ and so on are sugar for Set zero, Set (suc zero), etc.

    At present there is no automatic lifting of types from one level to another. It can still be done (rather clumsily) by defining types like the following one:

    data Lifted {a} (A : Set a) : Set (suc a) where
      lift : A → Lifted A
    

    However, it is likely that automatic lifting is introduced at some point in the future.

  • Multiple constructors, record fields, postulates or primitives can be declared using a single type signature:

    data Bool : Set where
      false true : Bool
    
    postulate
      A B : Set
    
  • Record fields can be implicit:

    record R : Set₁ where
      field
        {A}         : Set
        f           : A → A
        {B C} D {E} : Set
        g           : B → C → E
    

    By default implicit fields are not printed.

  • Record constructors can be defined:

    record Σ (A : Set) (B : A → Set) : Set where
      constructor _,_
      field
        proj₁ : A
        proj₂ : B proj₁
    

    In this example _,_ gets the type

     (proj₁ : A) → B proj₁ → Σ A B.
    

    For implicit fields the corresponding constructor arguments become implicit.

    Note that the constructor is defined in the outer scope, so any fixity declaration has to be given outside the record definition. The constructor is not in scope inside the record module.

    Note also that pattern matching for records has not been implemented yet.

  • BUILTIN hooks for equality.

    The data type

    data _≡_ {A : Set} (x : A) : A → Set where
      refl : x ≡ x
    

    can be specified as the builtin equality type using the following pragmas:

    {-# BUILTIN EQUALITY _≡_  #-}
    {-# BUILTIN REFL     refl #-}
    

    The builtin equality is used for the new rewrite construct and the primTrustMe primitive described below.

  • New rewrite construct.

    If eqn : a ≡ b, where _≡_ is the builtin equality (see above) you can now write

    f ps rewrite eqn = rhs
    

    instead of

      f ps with a | eqn
      ... | ._ | refl = rhs
    

    The rewrite construct has the effect of rewriting the goal and the context by the given equation (left to right).

    You can rewrite using several equations (in sequence) by separating them with vertical bars (|):

    f ps rewrite eqn₁ | eqn₂ | … = rhs
    

    It is also possible to add with-clauses after rewriting:

    f ps rewrite eqns with e
    ... | p = rhs
    

    Note that pattern matching happens before rewriting—if you want to rewrite and then do pattern matching you can use a with after the rewrite.

    See test/Succeed/Rewrite.agda for some examples.

  • A new primitive, primTrustMe, has been added:

      primTrustMe : {A : Set} {x y : A} → x ≡ y
    

    Here _≡_ is the builtin equality (see BUILTIN hooks for equality, above).

    If x and y are definitionally equal, then primTrustMe {x = x} {y = y} reduces to refl.

    Note that the compiler replaces all uses of primTrustMe with the REFL builtin, without any check for definitional equality. Incorrect uses of primTrustMe can potentially lead to segfaults or similar problems.

    For an example of the use of primTrustMe, see Data.String in version 0.3 of the standard library, where it is used to implement decidable equality on strings using the primitive boolean equality.

  • Changes to the syntax and semantics of IMPORT pragmas, which are used by the Haskell FFI. Such pragmas must now have the following form:

    {-# IMPORT <module name> #-}
    

    These pragmas are interpreted as qualified imports, so Haskell names need to be given qualified (unless they come from the Haskell prelude).

  • The horizontal tab character (U+0009) is no longer treated as white space.

  • Line pragmas are no longer supported.

  • The --include-path flag can no longer be used as a pragma.

  • The experimental and incomplete support for proof irrelevance has been disabled.

Tools

  • New intro command in the Emacs mode. When there is a canonical way of building something of the goal type (for instance, if the goal type is a pair), the goal can be refined in this way. The command works for the following goal types:

    • A data type where only one of its constructors can be used to construct an element of the goal type. (For instance, if the goal is a non-empty vector, a cons will be introduced.)

    • A record type. A record value will be introduced. Implicit fields will not be included unless showing of implicit arguments is switched on.

    • A function type. A lambda binding as many variables as possible will be introduced. The variable names will be chosen from the goal type if its normal form is a dependent function type, otherwise they will be variations on x. Implicit lambdas will only be inserted if showing of implicit arguments is switched on.

    This command can be invoked by using the refine command (C-c C-r) when the goal is empty. (The old behaviour of the refine command in this situation was to ask for an expression using the minibuffer.)

  • The Emacs mode displays Checked in the mode line if the current file type checked successfully without any warnings.

  • If a file F is loaded, and this file defines the module M, it is an error if F is not the file which defines M according to the include path.

    Note that the command-line tool and the Emacs mode define the meaning of relative include paths differently: the command-line tool interprets them relative to the current working directory, whereas the Emacs mode interprets them relative to the root directory of the current project. (As an example, if the module A.B.C is loaded from the file <some-path>/A/B/C.agda, then the root directory is <some-path>.)

  • It is an error if there are several files on the include path which match a given module name.

  • Interface files are relocatable. You can move around source trees as long as the include path is updated in a corresponding way. Note that a module M may be re-typechecked if its time stamp is strictly newer than that of the corresponding interface file (M.agdai).

  • Type-checking is no longer done when an up-to-date interface exists. (Previously the initial module was always type-checked.)

  • Syntax highlighting files for Emacs (.agda.el) are no longer used. The --emacs flag has been removed. (Syntax highlighting information is cached in the interface files.)

  • The Agate and Alonzo compilers have been retired. The options --agate, --alonzo and --malonzo have been removed.

  • The default directory for MAlonzo output is the project’s root directory. The --malonzo-dir flag has been renamed to --compile-dir.

  • Emacs mode: C-c C-x C-d no longer resets the type checking state. C-c C-x C-r can be used for a more complete reset. C-c C-x C-s (which used to reload the syntax highlighting information) has been removed. C-c C-l can be used instead.

  • The Emacs mode used to define some “abbrevs”, unless the user explicitly turned this feature off. The new default is not to add any abbrevs. The old default can be obtained by customising agda2-mode-abbrevs-use-defaults (a customisation buffer can be obtained by typing M-x customize-group agda2 RET after an Agda file has been loaded).

Release notes for Agda 2 version 2.2.4

Important changes since 2.2.2:

  • Change to the semantics of open import and open module. The declaration

    open import M <using/hiding/renaming>
    

    now translates to

    import A
    open A <using/hiding/renaming>
    

    instead of

    import A <using/hiding/renaming>
    open A
    

    The same translation is used for open module M = E …. Declarations involving the keywords as or public are changed in a corresponding way (as always goes with import, and public always with open).

    This change means that import directives do not affect the qualified names when open import/module is used. To get the old behaviour you can use the expanded version above.

  • Names opened publicly in parameterised modules no longer inherit the module parameters. Example:

    module A where
      postulate X : Set
    
    module B (Y : Set) where
      open A public
    

    In Agda 2.2.2 B.X has type (Y : Set) → Set, whereas in Agda 2.2.4 B.X has type Set.

  • Previously it was not possible to export a given constructor name through two different open public statements in the same module. This is now possible.

  • Unicode subscript digits are now allowed for the hierarchy of universes (Set₀, Set₁, …): Set₁ is equivalent to Set1.

Release notes for Agda 2 version 2.2.2

Tools

  • The --malonzodir option has been renamed to --malonzo-dir.

  • The output of agda --html is by default placed in a directory called html.

Infrastructure

  • The Emacs mode is included in the Agda Cabal package, and installed by cabal install. The recommended way to enable the Emacs mode is to include the following code in .emacs:

    (load-file (let ((coding-system-for-read 'utf-8))
                    (shell-command-to-string "agda-mode locate")))
    

Release notes for Agda 2 version 2.2.0

Important changes since 2.1.2 (which was released 2007-08-16):

Language

Tools

Libraries

Documentation

Infrastructure