idris-0.12: src/Idris/Elab/Clause.hs
{-|
Module : Idris.Elab.Clause
Description : Code to elaborate clauses.
Copyright :
License : BSD3
Maintainer : The Idris Community.
-}
{-# LANGUAGE PatternGuards #-}
module Idris.Elab.Clause where
import Idris.AbsSyntax
import Idris.ASTUtils
import Idris.DSL
import Idris.Error
import Idris.Delaborate
import Idris.Imports
import Idris.Elab.Term
import Idris.Coverage
import Idris.DataOpts
import Idris.Providers
import Idris.Primitives
import Idris.Inliner
import Idris.PartialEval
import Idris.Transforms
import Idris.DeepSeq
import Idris.Output (iputStrLn, pshow, iWarn, iRenderResult, sendHighlighting)
import IRTS.Lang
import Idris.Elab.AsPat
import Idris.Elab.Type
import Idris.Elab.Transform
import Idris.Elab.Utils
import Idris.Core.TT
import Idris.Core.Elaborate hiding (Tactic(..))
import Idris.Core.Evaluate
import Idris.Core.Execute
import Idris.Core.Typecheck
import Idris.Core.CaseTree
import Idris.Docstrings hiding (Unchecked)
import Util.Pretty hiding ((<$>))
import Prelude hiding (id, (.))
import Control.Category
import Control.Applicative hiding (Const)
import Control.DeepSeq
import Control.Monad
import Control.Monad.State.Strict as State
import qualified Control.Monad.State.Lazy as LState
import Data.List
import Data.Maybe
import Debug.Trace
import qualified Data.Map as Map
import qualified Data.Set as S
import qualified Data.Text as T
import Data.Char(isLetter, toLower)
import Data.List.Split (splitOn)
import Util.Pretty(pretty, text)
import Numeric
-- | Elaborate a collection of left-hand and right-hand pairs - that is, a
-- top-level definition.
elabClauses :: ElabInfo -> FC -> FnOpts -> Name -> [PClause] -> Idris ()
elabClauses info' fc opts n_in cs =
do let n = liftname info n_in
info = info' { elabFC = Just fc }
ctxt <- getContext
ist <- getIState
optimise <- getOptimise
let petrans = PETransform `elem` optimise
inacc <- map fst <$> fgetState (opt_inaccessible . ist_optimisation n)
-- Check n actually exists, with no definition yet
let tys = lookupTy n ctxt
let reflect = Reflection `elem` opts
checkUndefined n ctxt
unless (length tys > 1) $ do
fty <- case tys of
[] -> -- TODO: turn into a CAF if there's no arguments
-- question: CAFs in where blocks?
tclift $ tfail $ At fc (NoTypeDecl n)
[ty] -> return ty
let atys = map snd (getArgTys fty)
cs_elab <- mapM (elabClause info opts)
(zip [0..] cs)
ctxt <- getContext
-- pats_raw is the version we'll work with at compile time:
-- no simplification or PE
let (pats_in, cs_full) = unzip cs_elab
let pats_raw = map (simple_lhs ctxt) pats_in
logElab 3 $ "Elaborated patterns:\n" ++ show pats_raw
solveDeferred fc n
-- just ensure that the structure exists
fmodifyState (ist_optimisation n) id
addIBC (IBCOpt n)
ist <- getIState
ctxt <- getContext
-- Don't apply rules if this is a partial evaluation definition,
-- or we'll make something that just runs itself!
let tpats = case specNames opts of
Nothing -> transformPats ist pats_in
_ -> pats_in
-- If the definition is specialisable, this reduces the
-- RHS
pe_tm <- doPartialEval ist tpats
let pats_pe = if petrans
then map (simple_lhs ctxt) pe_tm
else pats_raw
let tcase = opt_typecase (idris_options ist)
-- Look for 'static' names and generate new specialised
-- definitions for them, as well as generating rewrite rules
-- for partially evaluated definitions
newrules <- if petrans
then mapM (\ e -> case e of
Left _ -> return []
Right (l, r) -> elabPE info fc n r) pats_pe
else return []
-- Redo transforms with the newly generated transformations, so
-- that the specialised application we've just made gets
-- used in place of the general one
ist <- getIState
let pats_transformed = if petrans
then transformPats ist pats_pe
else pats_pe
-- Summary of what's about to happen: Definitions go:
--
-- pats_in -> pats -> pdef -> pdef'
-- addCaseDef builds case trees from <pdef> and <pdef'>
-- pdef is the compile-time pattern definition.
-- This will get further inlined to help with totality checking.
let pdef = map (\(ns, lhs, rhs) -> (map fst ns, lhs, rhs)) $ map debind pats_raw
-- pdef_pe is the one which will get further optimised
-- for run-time, and, partially evaluated
let pdef_pe = map debind pats_transformed
logElab 5 $ "Initial typechecked patterns:\n" ++ show pats_raw
logElab 5 $ "Initial typechecked pattern def:\n" ++ show pdef
-- NOTE: Need to store original definition so that proofs which
-- rely on its structure aren't affected by any changes to the
-- inliner. Just use the inlined version to generate pdef' and to
-- help with later inlinings.
ist <- getIState
let pdef_inl = inlineDef ist pdef
numArgs <- tclift $ sameLength pdef
case specNames opts of
Just _ ->
do logElab 3 $ "Partially evaluated:\n" ++ show pats_pe
_ -> return ()
logElab 3 $ "Transformed:\n" ++ show pats_transformed
erInfo <- getErasureInfo <$> getIState
tree@(CaseDef scargs sc _) <- tclift $
simpleCase tcase (UnmatchedCase "Error") reflect CompileTime fc inacc atys pdef erInfo
cov <- coverage
pmissing <-
if cov && not (hasDefault pats_raw)
then do -- Generate clauses from the given possible cases
missing <- genClauses fc n (map getLHS pdef) cs_full
-- missing <- genMissing n scargs sc
missing' <- filterM (checkPossible info fc True n) missing
-- Filter out the ones which match one of the
-- given cases (including impossible ones)
let clhs = map getLHS pdef
logElab 2 $ "Must be unreachable:\n" ++
showSep "\n" (map showTmImpls missing') ++
"\nAgainst: " ++
showSep "\n" (map (\t -> showTmImpls (delab ist t)) (map getLHS pdef))
-- filter out anything in missing' which is
-- matched by any of clhs. This might happen since
-- unification may force a variable to take a
-- particular form, rather than force a case
-- to be impossible.
return (filter (noMatch ist clhs) missing')
else return []
let pcover = null pmissing
-- pdef' is the version that gets compiled for run-time,
-- so we start from the partially evaluated version
pdef_in' <- applyOpts $ map (\(ns, lhs, rhs) -> (map fst ns, lhs, rhs)) pdef_pe
ctxt <- getContext
let pdef' = map (simple_rt ctxt) pdef_in'
logElab 5 $ "After data structure transformations:\n" ++ show pdef'
ist <- getIState
let tot | pcover = Unchecked -- finish later
| AssertTotal `elem` opts = Total []
| PEGenerated `elem` opts = Generated
| otherwise = Partial NotCovering -- already know it's not total
case tree of
CaseDef _ _ [] -> return ()
CaseDef _ _ xs -> mapM_ (\x ->
iputStrLn $ show fc ++
":warning - Unreachable case: " ++
show (delab ist x)) xs
let knowncovering = (pcover && cov) || AssertTotal `elem` opts
let defaultcase = if knowncovering
then STerm Erased
else UnmatchedCase $ "*** " ++
show fc ++
":unmatched case in " ++ show n ++
" ***"
tree' <- tclift $ simpleCase tcase defaultcase reflect
RunTime fc inacc atys pdef' erInfo
logElab 3 $ "Unoptimised " ++ show n ++ ": " ++ show tree
logElab 3 $ "Optimised: " ++ show tree'
ctxt <- getContext
ist <- getIState
let opt = idris_optimisation ist
putIState (ist { idris_patdefs = addDef n (force pdef_pe, force pmissing)
(idris_patdefs ist) })
let caseInfo = CaseInfo (inlinable opts) (inlinable opts) (dictionary opts)
case lookupTyExact n ctxt of
Just ty ->
do ctxt' <- do ctxt <- getContext
tclift $
addCasedef n erInfo caseInfo
tcase defaultcase
reflect
(AssertTotal `elem` opts)
atys
inacc
pats_pe
pdef
pdef -- compile time
pdef_inl -- inlined
pdef' ty
ctxt
setContext ctxt'
addIBC (IBCDef n)
addDefinedName n
setTotality n tot
when (not reflect && PEGenerated `notElem` opts) $
do totcheck (fc, n)
defer_totcheck (fc, n)
when (tot /= Unchecked) $ addIBC (IBCTotal n tot)
i <- getIState
ctxt <- getContext
case lookupDef n ctxt of
(CaseOp _ _ _ _ _ cd : _) ->
let (scargs, sc) = cases_compiletime cd in
do let calls = map fst $ findCalls sc scargs
-- let scg = buildSCG i sc scargs
-- add SCG later, when checking totality
logElab 2 $ "Called names: " ++ show calls
-- if the definition is public, make sure
-- it only uses public names
nvis <- getFromHideList n
case nvis of
Just Public -> mapM_ (checkVisibility fc n Public Public) calls
_ -> return ()
addCalls n calls
addIBC (IBCCG n)
_ -> return ()
return ()
-- addIBC (IBCTotal n tot)
_ -> return ()
-- Check it's covering, if 'covering' option is used. Chase
-- all called functions, and fail if any of them are also
-- 'Partial NotCovering'
when (CoveringFn `elem` opts) $ checkAllCovering fc [] n n
where
noMatch i cs tm = all (\x -> case trim_matchClause i (delab' i x True True) tm of
Right _ -> False
Left miss -> True) cs
where
trim_matchClause i (PApp fcl fl ls) (PApp fcr fr rs)
= let args = min (length ls) (length rs) in
matchClause i (PApp fcl fl (take args ls))
(PApp fcr fr (take args rs))
checkUndefined n ctxt = case lookupDef n ctxt of
[] -> return ()
[TyDecl _ _] -> return ()
_ -> tclift $ tfail (At fc (AlreadyDefined n))
debind (Right (x, y)) = let (vs, x') = depat [] x
(_, y') = depat [] y in
(vs, x', y')
debind (Left x) = let (vs, x') = depat [] x in
(vs, x', Impossible)
depat acc (Bind n (PVar t) sc) = depat ((n, t) : acc) (instantiate (P Bound n t) sc)
depat acc x = (acc, x)
getPVs (Bind x (PVar _) tm) = let (vs, tm') = getPVs tm
in (x:vs, tm')
getPVs tm = ([], tm)
isPatVar vs (P Bound n _) = n `elem` vs
isPatVar _ _ = False
hasDefault cs | (Right (lhs, rhs) : _) <- reverse cs
, (pvs, tm) <- getPVs (explicitNames lhs)
, (f, args) <- unApply tm = all (isPatVar pvs) args
hasDefault _ = False
getLHS (_, l, _) = l
-- Simplify the left hand side of a definition, to remove any lets
-- that may have arisen during elaboration
simple_lhs ctxt (Right (x, y)) = Right (Idris.Core.Evaluate.simplify ctxt [] x, y)
simple_lhs ctxt t = t
simple_rt ctxt (p, x, y) = (p, x, force (uniqueBinders p
(rt_simplify ctxt [] y)))
specNames [] = Nothing
specNames (Specialise ns : _) = Just ns
specNames (_ : xs) = specNames xs
sameLength ((_, x, _) : xs)
= do l <- sameLength xs
let (f, as) = unApply x
if (null xs || l == length as) then return (length as)
else tfail (At fc (Msg "Clauses have differing numbers of arguments "))
sameLength [] = return 0
-- Partially evaluate, if the definition is marked as specialisable
doPartialEval ist pats =
case specNames opts of
Nothing -> return pats
Just ns -> case partial_eval (tt_ctxt ist) ns pats of
Just t -> return t
Nothing -> ierror (At fc (Msg "No specialisation achieved"))
-- | Find 'static' applications in a term and partially evaluate them.
-- Return any new transformation rules
elabPE :: ElabInfo -> FC -> Name -> Term -> Idris [(Term, Term)]
-- Don't go deeper than 5 nested partially evaluated definitions in one go
-- (make this configurable? It's a good limit for most cases, certainly for
-- interfaces and polymorphic definitions, but maybe not for DSLs and
-- interpreters in complicated cases.
-- Possibly only worry about the limit if we've specialised the same function
-- a number of times in one go.)
elabPE info fc caller r | pe_depth info > 5 = return []
elabPE info fc caller r =
do ist <- getIState
let sa = filter (\ap -> fst ap /= caller) $ getSpecApps ist [] r
rules <- mapM mkSpecialised sa
return $ concat rules
where
-- Make a specialised version of the application, and
-- add a PTerm level transformation rule, which is basically the
-- new definition in reverse (before specialising it).
-- RHS => LHS where implicit arguments are left blank in the
-- transformation.
-- Transformation rules are applied after every PClause elaboration
mkSpecialised :: (Name, [(PEArgType, Term)]) -> Idris [(Term, Term)]
mkSpecialised specapp_in = do
ist <- getIState
ctxt <- getContext
let (specTy, specapp) = getSpecTy ist specapp_in
let (n, newnm, specdecl) = getSpecClause ist specapp
let lhs = pe_app specdecl
let rhs = pe_def specdecl
let undef = case lookupDefExact newnm ctxt of
Nothing -> True
_ -> False
logElab 5 $ show (newnm, undef, map (concreteArg ist) (snd specapp))
idrisCatch
(if (undef && all (concreteArg ist) (snd specapp)) then do
cgns <- getAllNames n
-- on the RHS of the new definition, we should reduce
-- everything that's not itself static (because we'll
-- want to be a PE version of those next)
let cgns' = filter (\x -> x /= n &&
notStatic ist x) cgns
-- set small reduction limit on partial/productive things
let maxred = case lookupTotal n ctxt of
[Total _] -> 65536
[Productive] -> 16
_ -> 1
let opts = [Specialise ((if pe_simple specdecl
then map (\x -> (x, Nothing)) cgns'
else []) ++
(n, Just maxred) :
mapMaybe (specName (pe_simple specdecl))
(snd specapp))]
logElab 3 $ "Specialising application: " ++ show specapp
++ " in " ++ show caller ++
" with " ++ show opts
logElab 3 $ "New name: " ++ show newnm
logElab 3 $ "PE definition type : " ++ (show specTy)
++ "\n" ++ show opts
logElab 5 $ "PE definition " ++ show newnm ++ ":\n" ++
showSep "\n"
(map (\ (lhs, rhs) ->
(showTmImpls lhs ++ " = " ++
showTmImpls rhs)) (pe_clauses specdecl))
logElab 2 $ show n ++ " transformation rule: " ++
showTmImpls rhs ++ " ==> " ++ showTmImpls lhs
elabType info defaultSyntax emptyDocstring [] fc opts newnm NoFC specTy
let def = map (\(lhs, rhs) ->
let lhs' = mapPT hiddenToPH $ stripUnmatchable ist lhs in
PClause fc newnm lhs' [] rhs [])
(pe_clauses specdecl)
trans <- elabTransform info fc False rhs lhs
elabClauses (info {pe_depth = pe_depth info + 1}) fc
(PEGenerated:opts) newnm def
return [trans]
else return [])
-- if it doesn't work, just don't specialise. Could happen for lots
-- of valid reasons (e.g. local variables in scope which can't be
-- lifted out).
(\e -> do logElab 3 $ "Couldn't specialise: " ++ (pshow ist e)
return [])
hiddenToPH (PHidden _) = Placeholder
hiddenToPH x = x
specName simpl (ImplicitS, tm)
| (P Ref n _, _) <- unApply tm = Just (n, Just (if simpl then 1 else 0))
specName simpl (ExplicitS, tm)
| (P Ref n _, _) <- unApply tm = Just (n, Just (if simpl then 1 else 0))
specName simpl _ = Nothing
notStatic ist n = case lookupCtxtExact n (idris_statics ist) of
Just s -> not (or s)
_ -> True
concreteArg ist (ImplicitS, tm) = concreteTm ist tm
concreteArg ist (ExplicitS, tm) = concreteTm ist tm
concreteArg ist _ = True
concreteTm ist tm | (P _ n _, _) <- unApply tm =
case lookupTy n (tt_ctxt ist) of
[] -> False
_ -> True
concreteTm ist (Constant _) = True
concreteTm ist (Bind n (Lam _) sc) = True
concreteTm ist (Bind n (Pi _ _ _) sc) = True
concreteTm ist (Bind n (Let _ _) sc) = concreteTm ist sc
concreteTm ist _ = False
-- get the type of a specialised application
getSpecTy ist (n, args)
= case lookupTy n (tt_ctxt ist) of
[ty] -> let (specty_in, args') = specType args (explicitNames ty)
specty = normalise (tt_ctxt ist) [] (finalise specty_in)
t = mkPE_TyDecl ist args' (explicitNames specty) in
(t, (n, args'))
-- (normalise (tt_ctxt ist) [] (specType args ty))
_ -> error "Can't happen (getSpecTy)"
-- get the clause of a specialised application
getSpecClause ist (n, args)
= let newnm = sUN ("PE_" ++ show (nsroot n) ++ "_" ++
qhash 5381 (showSep "_" (map showArg args))) in
-- UN (show n ++ show (map snd args)) in
(n, newnm, mkPE_TermDecl ist newnm n args)
where showArg (ExplicitS, n) = qshow n
showArg (ImplicitS, n) = qshow n
showArg _ = ""
qshow (Bind _ _ _) = "fn"
qshow (App _ f a) = qshow f ++ qshow a
qshow (P _ n _) = show n
qshow (Constant c) = show c
qshow _ = ""
-- Simple but effective string hashing...
-- Keep it to 32 bits for readability/debuggability
qhash :: Int -> String -> String
qhash hash [] = showHex (abs hash `mod` 0xffffffff) ""
qhash hash (x:xs) = qhash (hash * 33 + fromEnum x) xs
-- | Checks if the clause is a possible left hand side.
checkPossible :: ElabInfo -> FC -> Bool -> Name -> PTerm -> Idris Bool
checkPossible info fc tcgen fname lhs_in
= do ctxt <- getContext
i <- getIState
let lhs = addImplPat i lhs_in
-- if the LHS type checks, it is possible
case elaborate (constraintNS info) ctxt (idris_datatypes i) (idris_name i) (sMN 0 "patLHS") infP initEState
(erun fc (buildTC i info ELHS [] fname
(allNamesIn lhs_in)
(infTerm lhs))) of
OK (ElabResult lhs' _ _ ctxt' newDecls highlights newGName, _) ->
do setContext ctxt'
processTacticDecls info newDecls
sendHighlighting highlights
updateIState $ \i -> i { idris_name = newGName }
let lhs_tm = orderPats (getInferTerm lhs')
case recheck (constraintNS info) ctxt' [] (forget lhs_tm) lhs_tm of
OK _ -> return True
err -> return False
-- if it's a recoverable error, the case may become possible
Error err -> if tcgen then return (recoverableCoverage ctxt err)
else return (validCoverageCase ctxt err ||
recoverableCoverage ctxt err)
findUnique :: Context -> Env -> Term -> [Name]
findUnique ctxt env (Bind n b sc)
= let rawTy = forgetEnv (map fst env) (binderTy b)
uniq = case check ctxt env rawTy of
OK (_, UType UniqueType) -> True
OK (_, UType NullType) -> True
OK (_, UType AllTypes) -> True
_ -> False in
if uniq then n : findUnique ctxt ((n, b) : env) sc
else findUnique ctxt ((n, b) : env) sc
findUnique _ _ _ = []
-- | Return the elaborated LHS/RHS, and the original LHS with implicits added
elabClause :: ElabInfo -> FnOpts -> (Int, PClause) ->
Idris (Either Term (Term, Term), PTerm)
elabClause info opts (_, PClause fc fname lhs_in [] PImpossible [])
= do let tcgen = Dictionary `elem` opts
i <- get
let lhs = addImpl [] i lhs_in
b <- checkPossible info fc tcgen fname lhs_in
case b of
True -> tclift $ tfail (At fc
(Msg $ show lhs_in ++ " is a valid case"))
False -> do ptm <- mkPatTm lhs_in
logElab 5 $ "Elaborated impossible case " ++ showTmImpls lhs ++
"\n" ++ show ptm
return (Left ptm, lhs)
elabClause info opts (cnum, PClause fc fname lhs_in_as withs rhs_in_as whereblock)
= do let tcgen = Dictionary `elem` opts
push_estack fname False
ctxt <- getContext
let (lhs_in, rhs_in) = desugarAs lhs_in_as rhs_in_as
-- Build the LHS as an "Infer", and pull out its type and
-- pattern bindings
i <- getIState
inf <- isTyInferred fname
-- Check if we have "with" patterns outside of "with" block
when (isOutsideWith lhs_in && (not $ null withs)) $
ierror (At fc (Elaborating "left hand side of " fname Nothing
(Msg "unexpected patterns outside of \"with\" block")))
-- get the parameters first, to pass through to any where block
let fn_ty = case lookupTy fname ctxt of
[t] -> t
_ -> error "Can't happen (elabClause function type)"
let fn_is = case lookupCtxt fname (idris_implicits i) of
[t] -> t
_ -> []
let norm_ty = normalise ctxt [] fn_ty
let params = getParamsInType i [] fn_is norm_ty
let tcparams = getTCParamsInType i [] fn_is norm_ty
let lhs = mkLHSapp $ stripLinear i $ stripUnmatchable i $
propagateParams i params norm_ty (allNamesIn lhs_in) (addImplPat i lhs_in)
-- let lhs = mkLHSapp $
-- propagateParams i params fn_ty (addImplPat i lhs_in)
logElab 10 (show (params, fn_ty) ++ " " ++ showTmImpls (addImplPat i lhs_in))
logElab 5 ("LHS: " ++ show opts ++ "\n" ++ show fc ++ " " ++ showTmImpls lhs)
logElab 4 ("Fixed parameters: " ++ show params ++ " from " ++ showTmImpls lhs_in ++
"\n" ++ show (fn_ty, fn_is))
((ElabResult lhs' dlhs [] ctxt' newDecls highlights newGName, probs, inj), _) <-
tclift $ elaborate (constraintNS info) ctxt (idris_datatypes i) (idris_name i) (sMN 0 "patLHS") infP initEState
(do res <- errAt "left hand side of " fname Nothing
(erun fc (buildTC i info ELHS opts fname
(allNamesIn lhs_in)
(infTerm lhs)))
probs <- get_probs
inj <- get_inj
return (res, probs, inj))
setContext ctxt'
processTacticDecls info newDecls
sendHighlighting highlights
updateIState $ \i -> i { idris_name = newGName }
when inf $ addTyInfConstraints fc (map (\(x,y,_,_,_,_,_) -> (x,y)) probs)
let lhs_tm = orderPats (getInferTerm lhs')
let lhs_ty = getInferType lhs'
let static_names = getStaticNames i lhs_tm
logElab 3 ("Elaborated: " ++ show lhs_tm)
logElab 3 ("Elaborated type: " ++ show lhs_ty)
logElab 5 ("Injective: " ++ show fname ++ " " ++ show inj)
-- If we're inferring metavariables in the type, don't recheck,
-- because we're only doing this to try to work out those metavariables
ctxt <- getContext
(clhs_c, clhsty) <- if not inf
then recheckC_borrowing False (PEGenerated `notElem` opts)
[] (constraintNS info) fc id [] lhs_tm
else return (lhs_tm, lhs_ty)
let clhs = Idris.Core.Evaluate.simplify ctxt [] clhs_c
let borrowed = borrowedNames [] clhs
-- These are the names we're not allowed to use on the RHS, because
-- they're UniqueTypes and borrowed from another function.
-- FIXME: There is surely a nicer way than this...
-- Issue #1615 on the Issue Tracker.
-- https://github.com/idris-lang/Idris-dev/issues/1615
when (not (null borrowed)) $
logElab 5 ("Borrowed names on LHS: " ++ show borrowed)
logElab 3 ("Normalised LHS: " ++ showTmImpls (delabMV i clhs))
rep <- useREPL
when rep $ do
addInternalApp (fc_fname fc) (fst . fc_start $ fc) (delabMV i clhs) -- TODO: Should use span instead of line and filename?
addIBC (IBCLineApp (fc_fname fc) (fst . fc_start $ fc) (delabMV i clhs))
logElab 5 ("Checked " ++ show clhs ++ "\n" ++ show clhsty)
-- Elaborate where block
ist <- getIState
ctxt <- getContext
windex <- getName
let decls = nub (concatMap declared whereblock)
let defs = nub (decls ++ concatMap defined whereblock)
let newargs_all = pvars ist lhs_tm
-- Unique arguments must be passed to the where block explicitly
-- (since we can't control "usage" easlily otherwise). Remove them
-- from newargs here
let uniqargs = findUnique ctxt [] lhs_tm
let newargs = filter (\(n,_) -> n `notElem` uniqargs) newargs_all
let winfo = (pinfo info newargs defs windex) { elabFC = Just fc }
let wb = map (mkStatic static_names) $
map (expandInstanceScope ist decorate newargs defs) $
map (expandParamsD False ist decorate newargs defs) whereblock
-- Split the where block into declarations with a type, and those
-- without
-- Elaborate those with a type *before* RHS, those without *after*
let (wbefore, wafter) = sepBlocks wb
logElab 5 $ "Where block:\n " ++ show wbefore ++ "\n" ++ show wafter
mapM_ (rec_elabDecl info EAll winfo) wbefore
-- Now build the RHS, using the type of the LHS as the goal.
i <- getIState -- new implicits from where block
logElab 5 (showTmImpls (expandParams decorate newargs defs (defs \\ decls) rhs_in))
let rhs = rhs_trans info $
addImplBoundInf i (map fst newargs_all) (defs \\ decls)
(expandParams decorate newargs defs (defs \\ decls) rhs_in)
logElab 2 $ "RHS: " ++ show (map fst newargs_all) ++ " " ++ showTmImpls rhs
ctxt <- getContext -- new context with where block added
logElab 5 "STARTING CHECK"
((rhs', defer, holes, is, probs, ctxt', newDecls, highlights, newGName), _) <-
tclift $ elaborate (constraintNS info) ctxt (idris_datatypes i) (idris_name i) (sMN 0 "patRHS") clhsty initEState
(do pbinds ist lhs_tm
-- proof search can use explicitly written names
mapM_ addPSname (allNamesIn lhs_in)
mapM_ setinj (nub (tcparams ++ inj))
setNextName
(ElabResult _ _ is ctxt' newDecls highlights newGName) <-
errAt "right hand side of " fname (Just clhsty)
(erun fc (build i winfo ERHS opts fname rhs))
errAt "right hand side of " fname (Just clhsty)
(erun fc $ psolve lhs_tm)
tt <- get_term
aux <- getAux
let (tm, ds) = runState (collectDeferred (Just fname)
(map fst $ case_decls aux) ctxt tt) []
probs <- get_probs
hs <- get_holes
return (tm, ds, hs, is, probs, ctxt', newDecls, highlights, newGName))
setContext ctxt'
processTacticDecls info newDecls
sendHighlighting highlights
updateIState $ \i -> i { idris_name = newGName }
when inf $ addTyInfConstraints fc (map (\(x,y,_,_,_,_,_) -> (x,y)) probs)
logElab 5 "DONE CHECK"
logElab 4 $ "---> " ++ show rhs'
when (not (null defer)) $ logElab 1 $ "DEFERRED " ++
show (map (\ (n, (_,_,t,_)) -> (n, t)) defer)
-- If there's holes, set the metavariables as undefinable
def' <- checkDef info fc (\n -> Elaborating "deferred type of " n Nothing) (null holes) defer
let def'' = map (\(n, (i, top, t, ns)) -> (n, (i, top, t, ns, False, null holes))) def'
addDeferred def''
mapM_ (\(n, _) -> addIBC (IBCDef n)) def''
when (not (null def')) $ do
mapM_ defer_totcheck (map (\x -> (fc, fst x)) def'')
-- Now the remaining deferred (i.e. no type declarations) clauses
-- from the where block
mapM_ (rec_elabDecl info EAll winfo) wafter
mapM_ (elabCaseBlock winfo opts) is
ctxt <- getContext
logElab 5 "Rechecking"
logElab 6 $ " ==> " ++ show (forget rhs')
(crhs, crhsty) -- if there's holes && deferred things, it's okay
-- but we'll need to freeze the definition and not
-- allow the deferred things to be definable
-- (this is just to allow users to inspect intermediate
-- things)
<- if (null holes || null def') && not inf
then recheckC_borrowing True (PEGenerated `notElem` opts)
borrowed (constraintNS info) fc id [] rhs'
else return (rhs', clhsty)
logElab 6 $ " ==> " ++ showEnvDbg [] crhsty ++ " against " ++ showEnvDbg [] clhsty
-- If there's holes, make sure this definition is frozen
when (not (null holes)) $ do
logElab 5 $ "Making " ++ show fname ++ " frozen due to " ++ show holes
setAccessibility fname Frozen
ctxt <- getContext
let constv = next_tvar ctxt
tit <- typeInType
case LState.runStateT (convertsC ctxt [] crhsty clhsty) (constv, []) of
OK (_, cs) -> when (PEGenerated `notElem` opts && not tit) $ do
addConstraints fc cs
mapM_ (\c -> addIBC (IBCConstraint fc c)) (snd cs)
logElab 6 $ "CONSTRAINTS ADDED: " ++ show cs ++ "\n" ++ show (clhsty, crhsty)
return ()
Error e -> ierror (At fc (CantUnify False (clhsty, Nothing) (crhsty, Nothing) e [] 0))
i <- getIState
checkInferred fc (delab' i crhs True True) rhs
-- if the function is declared '%error_reverse', or its type,
-- then we'll try running it in reverse to improve error messages
let (ret_fam, _) = unApply (getRetTy crhsty)
rev <- case ret_fam of
P _ rfamn _ ->
case lookupCtxt rfamn (idris_datatypes i) of
[TI _ _ dopts _ _] ->
return (DataErrRev `elem` dopts)
_ -> return False
_ -> return False
when (rev || ErrorReverse `elem` opts) $ do
addIBC (IBCErrRev (crhs, clhs))
addErrRev (crhs, clhs)
pop_estack
return (Right (clhs, crhs), lhs)
where
pinfo :: ElabInfo -> [(Name, PTerm)] -> [Name] -> Int -> ElabInfo
pinfo info ns ds i
= let newps = params info ++ ns
dsParams = map (\n -> (n, map fst newps)) ds
newb = addAlist dsParams (inblock info)
l = liftname info in
info { params = newps,
inblock = newb,
liftname = id -- (\n -> case lookupCtxt n newb of
-- Nothing -> n
-- _ -> MN i (show n)) . l
}
-- Find the variable names which appear under a 'Ownership.Read' so that
-- we know they can't be used on the RHS
borrowedNames :: [Name] -> Term -> [Name]
borrowedNames env (App _ (App _ (P _ (NS (UN lend) [owner]) _) _) arg)
| owner == txt "Ownership" &&
(lend == txt "lend" || lend == txt "Read") = getVs arg
where
getVs (V i) = [env!!i]
getVs (App _ f a) = nub $ getVs f ++ getVs a
getVs _ = []
borrowedNames env (App _ f a) = nub $ borrowedNames env f ++ borrowedNames env a
borrowedNames env (Bind n b sc) = nub $ borrowedB b ++ borrowedNames (n:env) sc
where borrowedB (Let t v) = nub $ borrowedNames env t ++ borrowedNames env v
borrowedB b = borrowedNames env (binderTy b)
borrowedNames _ _ = []
mkLHSapp t@(PRef _ _ _) = PApp fc t []
mkLHSapp t = t
decorate (NS x ns)
= NS (SN (WhereN cnum fname x)) ns
decorate x
= SN (WhereN cnum fname x)
sepBlocks bs = sepBlocks' [] bs where
sepBlocks' ns (d@(PTy _ _ _ _ _ n _ t) : bs)
= let (bf, af) = sepBlocks' (n : ns) bs in
(d : bf, af)
sepBlocks' ns (d@(PClauses _ _ n _) : bs)
| not (n `elem` ns) = let (bf, af) = sepBlocks' ns bs in
(bf, d : af)
sepBlocks' ns (b : bs) = let (bf, af) = sepBlocks' ns bs in
(b : bf, af)
sepBlocks' ns [] = ([], [])
-- term is not within "with" block
isOutsideWith :: PTerm -> Bool
isOutsideWith (PApp _ (PRef _ _ (SN (WithN _ _))) _) = False
isOutsideWith _ = True
elabClause info opts (_, PWith fc fname lhs_in withs wval_in pn_in withblock)
= do let tcgen = Dictionary `elem` opts
ctxt <- getContext
-- Build the LHS as an "Infer", and pull out its type and
-- pattern bindings
i <- getIState
-- get the parameters first, to pass through to any where block
let fn_ty = case lookupTy fname ctxt of
[t] -> t
_ -> error "Can't happen (elabClause function type)"
let fn_is = case lookupCtxt fname (idris_implicits i) of
[t] -> t
_ -> []
let params = getParamsInType i [] fn_is (normalise ctxt [] fn_ty)
let lhs = stripLinear i $ stripUnmatchable i $
propagateParams i params fn_ty (allNamesIn lhs_in)
(addImplPat i lhs_in)
logElab 2 ("LHS: " ++ show lhs)
(ElabResult lhs' dlhs [] ctxt' newDecls highlights newGName, _) <-
tclift $ elaborate (constraintNS info) ctxt (idris_datatypes i) (idris_name i) (sMN 0 "patLHS") infP initEState
(errAt "left hand side of with in " fname Nothing
(erun fc (buildTC i info ELHS opts fname
(allNamesIn lhs_in)
(infTerm lhs))) )
setContext ctxt'
processTacticDecls info newDecls
sendHighlighting highlights
updateIState $ \i -> i { idris_name = newGName }
ctxt <- getContext
let lhs_tm = orderPats (getInferTerm lhs')
let lhs_ty = getInferType lhs'
let ret_ty = getRetTy (explicitNames (normalise ctxt [] lhs_ty))
let static_names = getStaticNames i lhs_tm
logElab 5 (show lhs_tm ++ "\n" ++ show static_names)
(clhs, clhsty) <- recheckC (constraintNS info) fc id [] lhs_tm
logElab 5 ("Checked " ++ show clhs)
let bargs = getPBtys (explicitNames (normalise ctxt [] lhs_tm))
let wval = rhs_trans info $ addImplBound i (map fst bargs) wval_in
logElab 5 ("Checking " ++ showTmImpls wval)
-- Elaborate wval in this context
((wval', defer, is, ctxt', newDecls, highlights, newGName), _) <-
tclift $ elaborate (constraintNS info) ctxt (idris_datatypes i) (idris_name i) (sMN 0 "withRHS")
(bindTyArgs PVTy bargs infP) initEState
(do pbinds i lhs_tm
-- proof search can use explicitly written names
mapM_ addPSname (allNamesIn lhs_in)
setNextName
-- TODO: may want where here - see winfo abpve
(ElabResult _ d is ctxt' newDecls highlights newGName) <- errAt "with value in " fname Nothing
(erun fc (build i info ERHS opts fname (infTerm wval)))
erun fc $ psolve lhs_tm
tt <- get_term
return (tt, d, is, ctxt', newDecls, highlights, newGName))
setContext ctxt'
processTacticDecls info newDecls
sendHighlighting highlights
updateIState $ \i -> i { idris_name = newGName }
def' <- checkDef info fc iderr True defer
let def'' = map (\(n, (i, top, t, ns)) -> (n, (i, top, t, ns, False, True))) def'
addDeferred def''
mapM_ (elabCaseBlock info opts) is
logElab 5 ("Checked wval " ++ show wval')
ctxt <- getContext
(cwval, cwvalty) <- recheckC (constraintNS info) fc id [] (getInferTerm wval')
let cwvaltyN = explicitNames (normalise ctxt [] cwvalty)
let cwvalN = explicitNames (normalise ctxt [] cwval)
logElab 3 ("With type " ++ show cwvalty ++ "\nRet type " ++ show ret_ty)
-- We're going to assume the with type is not a function shortly,
-- so report an error if it is (you can't match on a function anyway
-- so this doesn't lose anything)
case getArgTys cwvaltyN of
[] -> return ()
(_:_) -> ierror $ At fc (WithFnType cwvalty)
let pvars = map fst (getPBtys cwvalty)
-- we need the unelaborated term to get the names it depends on
-- rather than a de Bruijn index.
let pdeps = usedNamesIn pvars i (delab i cwvalty)
let (bargs_pre, bargs_post) = split pdeps bargs []
let mpn = case pn_in of
Nothing -> Nothing
Just (n, nfc) -> Just (uniqueName n (map fst bargs))
-- Highlight explicit proofs
sendHighlighting [(fc, AnnBoundName n False) | (n, fc) <- maybeToList pn_in]
logElab 10 ("With type " ++ show (getRetTy cwvaltyN) ++
" depends on " ++ show pdeps ++ " from " ++ show pvars)
logElab 10 ("Pre " ++ show bargs_pre ++ "\nPost " ++ show bargs_post)
windex <- getName
-- build a type declaration for the new function:
-- (ps : Xs) -> (withval : cwvalty) -> (ps' : Xs') -> ret_ty
let wargval = getRetTy cwvalN
let wargtype = getRetTy cwvaltyN
let wargname = sMN windex "warg"
logElab 5 ("Abstract over " ++ show wargval ++ " in " ++ show wargtype)
let wtype = bindTyArgs (flip (Pi Nothing) (TType (UVar [] 0))) (bargs_pre ++
(wargname, wargtype) :
map (abstract wargname wargval wargtype) bargs_post ++
case mpn of
Just pn -> [(pn, mkApp (P Ref eqTy Erased)
[wargtype, wargtype,
P Bound wargname Erased, wargval])]
Nothing -> [])
(substTerm wargval (P Bound wargname wargtype) ret_ty)
logElab 3 ("New function type " ++ show wtype)
let wname = SN (WithN windex fname)
let imps = getImps wtype -- add to implicits context
putIState (i { idris_implicits = addDef wname imps (idris_implicits i) })
let statics = getStatics static_names wtype
logElab 5 ("Static positions " ++ show statics)
i <- getIState
putIState (i { idris_statics = addDef wname statics (idris_statics i) })
addIBC (IBCDef wname)
addIBC (IBCImp wname)
addIBC (IBCStatic wname)
def' <- checkDef info fc iderr True [(wname, (-1, Nothing, wtype, []))]
let def'' = map (\(n, (i, top, t, ns)) -> (n, (i, top, t, ns, False, True))) def'
addDeferred def''
-- in the subdecls, lhs becomes:
-- fname pats | wpat [rest]
-- ==> fname' ps wpat [rest], match pats against toplevel for ps
wb <- mapM (mkAuxC mpn wname lhs (map fst bargs_pre) (map fst bargs_post))
withblock
logElab 3 ("with block " ++ show wb)
-- propagate totality assertion to the new definitions
setFlags wname [Inlinable]
when (AssertTotal `elem` opts) $ setFlags wname [Inlinable, AssertTotal]
i <- getIState
let rhstrans' = updateWithTerm i mpn wname lhs (map fst bargs_pre) (map fst (bargs_post))
. rhs_trans info
mapM_ (rec_elabDecl info EAll (info { rhs_trans = rhstrans' })) wb
-- rhs becomes: fname' ps_pre wval ps_post Refl
let rhs = PApp fc (PRef fc [] wname)
(map (pexp . (PRef fc []) . fst) bargs_pre ++
pexp wval :
(map (pexp . (PRef fc []) . fst) bargs_post) ++
case mpn of
Nothing -> []
Just _ -> [pexp (PApp NoFC (PRef NoFC [] eqCon)
[ pimp (sUN "A") Placeholder False
, pimp (sUN "x") Placeholder False
])])
logElab 5 ("New RHS " ++ showTmImpls rhs)
ctxt <- getContext -- New context with block added
i <- getIState
((rhs', defer, is, ctxt', newDecls, highlights, newGName), _) <-
tclift $ elaborate (constraintNS info) ctxt (idris_datatypes i) (idris_name i) (sMN 0 "wpatRHS") clhsty initEState
(do pbinds i lhs_tm
setNextName
(ElabResult _ d is ctxt' newDecls highlights newGName) <-
erun fc (build i info ERHS opts fname rhs)
psolve lhs_tm
tt <- get_term
return (tt, d, is, ctxt', newDecls, highlights, newGName))
setContext ctxt'
processTacticDecls info newDecls
sendHighlighting highlights
updateIState $ \i -> i { idris_name = newGName }
def' <- checkDef info fc iderr True defer
let def'' = map (\(n, (i, top, t, ns)) -> (n, (i, top, t, ns, False, True))) def'
addDeferred def''
mapM_ (elabCaseBlock info opts) is
logElab 5 ("Checked RHS " ++ show rhs')
(crhs, crhsty) <- recheckC (constraintNS info) fc id [] rhs'
return (Right (clhs, crhs), lhs)
where
getImps (Bind n (Pi _ _ _) t) = pexp Placeholder : getImps t
getImps _ = []
mkAuxC pn wname lhs ns ns' (PClauses fc o n cs)
= do cs' <- mapM (mkAux pn wname lhs ns ns') cs
return $ PClauses fc o wname cs'
mkAuxC pn wname lhs ns ns' d = return d
mkAux pn wname toplhs ns ns' (PClause fc n tm_in (w:ws) rhs wheres)
= do i <- getIState
let tm = addImplPat i tm_in
logElab 2 ("Matching " ++ showTmImpls tm ++ " against " ++
showTmImpls toplhs)
case matchClause i toplhs tm of
Left (a,b) -> ifail $ show fc ++ ":with clause does not match top level"
Right mvars ->
do logElab 3 ("Match vars : " ++ show mvars)
lhs <- updateLHS n pn wname mvars ns ns' (fullApp tm) w
return $ PClause fc wname lhs ws rhs wheres
mkAux pn wname toplhs ns ns' (PWith fc n tm_in (w:ws) wval pn' withs)
= do i <- getIState
let tm = addImplPat i tm_in
logElab 2 ("Matching " ++ showTmImpls tm ++ " against " ++
showTmImpls toplhs)
withs' <- mapM (mkAuxC pn wname toplhs ns ns') withs
case matchClause i toplhs tm of
Left (a,b) -> trace ("matchClause: " ++ show a ++ " =/= " ++ show b) (ifail $ show fc ++ "with clause does not match top level")
Right mvars ->
do lhs <- updateLHS n pn wname mvars ns ns' (fullApp tm) w
return $ PWith fc wname lhs ws wval pn' withs'
mkAux pn wname toplhs ns ns' c
= ifail $ show fc ++ ":badly formed with clause"
addArg (PApp fc f args) w = PApp fc f (args ++ [pexp w])
addArg (PRef fc hls f) w = PApp fc (PRef fc hls f) [pexp w]
-- ns, arguments which don't depend on the with argument
-- ns', arguments which do
updateLHS n pn wname mvars ns_in ns_in' (PApp fc (PRef fc' hls' n') args) w
= let ns = map (keepMvar (map fst mvars) fc') ns_in
ns' = map (keepMvar (map fst mvars) fc') ns_in' in
return $ substMatches mvars $
PApp fc (PRef fc' [] wname)
(map pexp ns ++ pexp w : (map pexp ns') ++
case pn of
Nothing -> []
Just pnm -> [pexp (PRef fc [] pnm)])
updateLHS n pn wname mvars ns_in ns_in' tm w
= updateLHS n pn wname mvars ns_in ns_in' (PApp fc tm []) w
-- Only keep a var as a pattern variable in the with block if it's
-- matched in the top level pattern
keepMvar mvs fc v | v `elem` mvs = PRef fc [] v
| otherwise = Placeholder
updateWithTerm :: IState -> Maybe Name -> Name -> PTerm -> [Name] -> [Name] -> PTerm -> PTerm
updateWithTerm ist pn wname toplhs ns_in ns_in' tm
= mapPT updateApp tm
where
arity (PApp _ _ as) = length as
arity _ = 0
lhs_arity = arity toplhs
currentFn fname (PAlternative _ _ as)
| Just tm <- getApp as = tm
where getApp (tm@(PApp _ (PRef _ _ f) _) : as)
| f == fname = Just tm
getApp (_ : as) = getApp as
getApp [] = Nothing
currentFn _ tm = tm
updateApp wtm@(PWithApp fcw tm_in warg) =
let tm = currentFn fname tm_in in
case matchClause ist toplhs tm of
Left _ -> PElabError (Msg (show fc ++ ":with application does not match top level "))
Right mvars ->
let ns = map (keepMvar (map fst mvars) fcw) ns_in
ns' = map (keepMvar (map fst mvars) fcw) ns_in'
wty = lookupTyExact wname (tt_ctxt ist)
res = substMatches mvars $
PApp fcw (PRef fcw [] wname)
(map pexp ns ++ pexp warg : (map pexp ns') ++
case pn of
Nothing -> []
Just pnm -> [pexp (PRef fc [] pnm)]) in
case wty of
Nothing -> res -- can't happen!
Just ty -> addResolves ty res
updateApp tm = tm
addResolves ty (PApp fc f args) = PApp fc f (addResolvesArgs fc ty args)
addResolves ty tm = tm
-- if an argument's type is a type class, and is otherwise to
-- be inferred, then resolve it with instance search
-- This is something of a hack, because matching on the top level
-- application won't find this information for us
addResolvesArgs :: FC -> Term -> [PArg] -> [PArg]
addResolvesArgs fc (Bind n (Pi _ ty _) sc) (a : args)
| (P _ cn _, _) <- unApply ty,
getTm a == Placeholder
= case lookupCtxtExact cn (idris_classes ist) of
Just _ -> a { getTm = PResolveTC fc } : addResolvesArgs fc sc args
Nothing -> a : addResolvesArgs fc sc args
addResolvesArgs fc (Bind n (Pi _ ty _) sc) (a : args)
= a : addResolvesArgs fc sc args
addResolvesArgs fc _ args = args
fullApp (PApp _ (PApp fc f args) xs) = fullApp (PApp fc f (args ++ xs))
fullApp x = x
split [] rest pre = (reverse pre, rest)
split deps ((n, ty) : rest) pre
| n `elem` deps = split (deps \\ [n]) rest ((n, ty) : pre)
| otherwise = split deps rest ((n, ty) : pre)
split deps [] pre = (reverse pre, [])
abstract wn wv wty (n, argty) = (n, substTerm wv (P Bound wn wty) argty)
-- | Apply a transformation to all RHSes and nested RHSs
mapRHS :: (PTerm -> PTerm) -> PClause -> PClause
mapRHS f (PClause fc n lhs args rhs ws)
= PClause fc n lhs args (f rhs) (map (mapRHSdecl f) ws)
mapRHS f (PWith fc n lhs args warg prf ws)
= PWith fc n lhs args (f warg) prf (map (mapRHSdecl f) ws)
mapRHS f (PClauseR fc args rhs ws)
= PClauseR fc args (f rhs) (map (mapRHSdecl f) ws)
mapRHS f (PWithR fc args warg prf ws)
= PWithR fc args (f warg) prf (map (mapRHSdecl f) ws)
mapRHSdecl :: (PTerm -> PTerm) -> PDecl -> PDecl
mapRHSdecl f (PClauses fc opt n cs)
= PClauses fc opt n (map (mapRHS f) cs)
mapRHSdecl f t = t