diff options
Diffstat (limited to 'new-luxc/source/luxc/analyser')
-rw-r--r-- | new-luxc/source/luxc/analyser/case.lux | 294 | ||||
-rw-r--r-- | new-luxc/source/luxc/analyser/case/coverage.lux | 287 | ||||
-rw-r--r-- | new-luxc/source/luxc/analyser/common.lux | 7 | ||||
-rw-r--r-- | new-luxc/source/luxc/analyser/function.lux | 8 | ||||
-rw-r--r-- | new-luxc/source/luxc/analyser/inference.lux | 109 | ||||
-rw-r--r-- | new-luxc/source/luxc/analyser/procedure/common.lux | 3 | ||||
-rw-r--r-- | new-luxc/source/luxc/analyser/structure.lux | 429 | ||||
-rw-r--r-- | new-luxc/source/luxc/analyser/type.lux | 4 |
8 files changed, 641 insertions, 500 deletions
diff --git a/new-luxc/source/luxc/analyser/case.lux b/new-luxc/source/luxc/analyser/case.lux index f3eec6b6b..306618caf 100644 --- a/new-luxc/source/luxc/analyser/case.lux +++ b/new-luxc/source/luxc/analyser/case.lux @@ -15,25 +15,25 @@ (macro [code]) [type] (type ["TC" check])) - (luxc ["&" base] - (lang ["la" analysis]) - ["&;" env] - (analyser ["&;" common] - ["&;" structure]))) - -(type: #rec Coverage - #PartialC - (#BoolC Bool) - (#VariantC Nat (D;Dict Nat Coverage)) - (#SeqC Coverage Coverage) - (#AltC Coverage Coverage) - #TotalC) + (../.. ["&" base] + (lang ["la" analysis]) + ["&;" env]) + (.. ["&;" common] + ["&;" structure]) + (. ["&&;" coverage])) (def: (pattern-error type pattern) (-> Type Code Text) (format "Cannot match this type: " (%type type) "\n" " With this pattern: " (%code pattern))) +## Type-checking on the input value is done during the analysis of a +## "case" expression, to ensure that the patterns being used make +## sense for the type of the input value. +## Sometimes, that input value is complex, by depending on +## type-variables or quantifications. +## This function makes it easier for "case" analysis to properly +## type-check the input with respect to the patterns. (def: (simplify-case-type type) (-> Type (Lux Type)) (case type @@ -60,6 +60,22 @@ _ (:: Monad<Lux> wrap type))) +## This function handles several concerns at once, but it must be that +## way because those concerns are interleaved when doing +## pattern-matching and they cannot be separated. +## The pattern is analysed in order to get a general feel for what is +## expected of the input value. This, in turn, informs the +## type-checking of the input. +## A kind of "continuation" value is passed around which signifies +## what needs to be done _after_ analysing a pattern. +## In general, this is done to analyse the "body" expression +## associated to a particular pattern _in the context of_ said +## pattern. +## The reason why *context* is important is because patterns may bind +## values to local variables, which may in turn be referenced in the +## body expressions. +## That is why the body must be analysed in the context of the +## pattern, and not separately. (def: (analyse-pattern num-tags inputT pattern next) (All [a] (-> (Maybe Nat) Type Code (Lux a) (Lux [la;Pattern a]))) (case pattern @@ -143,10 +159,10 @@ (&;fail (pattern-error inputT pattern)) ))) - [cursor (#;Record pairs)] + [cursor (#;Record record)] (do Monad<Lux> - [pairs (&structure;normalize-record pairs) - [members recordT] (&structure;order-record pairs) + [record (&structure;normalize record) + [members recordT] (&structure;order record) _ (&;within-type-env (TC;check inputT recordT))] (analyse-pattern (#;Some (list;size members)) inputT [cursor (#;Tuple members)] next)) @@ -200,240 +216,6 @@ (&;fail (format "Unrecognized pattern syntax: " (%code pattern))) )) -(def: (analyse-branch analyse inputT pattern body) - (-> &;Analyser Type Code Code (Lux [la;Pattern la;Analysis])) - (analyse-pattern #;None inputT pattern (analyse body))) - -(do-template [<name> <tag>] - [(def: (<name> coverage) - (-> Coverage Bool) - (case coverage - (<tag> _) - true - - _ - false))] - - [total? #TotalC] - [alt? #AltC] - ) - -(def: (determine-coverage pattern) - (-> la;Pattern Coverage) - (case pattern - (^or (#la;BindP _) (^ (#la;TupleP (list)))) - #TotalC - - (^ (#la;TupleP (list singleton))) - (determine-coverage singleton) - - (#la;BoolP value) - (#BoolC value) - - (^or (#la;NatP _) (#la;IntP _) (#la;DegP _) - (#la;RealP _) (#la;CharP _) (#la;TextP _)) - #PartialC - - (#la;TupleP subs) - (loop [subs subs] - (case subs - #;Nil - #TotalC - - (#;Cons sub subs') - (let [post (recur subs')] - (if (total? post) - (determine-coverage sub) - (#SeqC (determine-coverage sub) - post))))) - - (#la;VariantP tag-id num-tags sub) - (#VariantC num-tags - (|> (D;new number;Hash<Nat>) - (D;put tag-id (determine-coverage sub)))))) - -(def: (xor left right) - (-> Bool Bool Bool) - (or (and left (not right)) - (and (not left) right))) - -(def: redundant-pattern - (R;Result Coverage) - (R;fail "Redundant pattern.")) - -(def: (flatten-alt coverage) - (-> Coverage (List Coverage)) - (case coverage - (#AltC left right) - (list& left (flatten-alt right)) - - _ - (list coverage))) - -(struct: _ (Eq Coverage) - (def: (= reference sample) - (case [reference sample] - [#TotalC #TotalC] - true - - [(#BoolC sideR) (#BoolC sideS)] - (B/= sideR sideS) - - [(#VariantC allR casesR) (#VariantC allS casesS)] - (and (n.= allR allS) - (:: (D;Eq<Dict> =) = casesR casesS)) - - [(#SeqC leftR rightR) (#SeqC leftS rightS)] - (and (= leftR leftS) - (= rightR rightS)) - - [(#AltC _) (#AltC _)] - (let [flatR (flatten-alt reference) - flatS (flatten-alt sample)] - (and (n.= (list;size flatR) (list;size flatS)) - (list;every? (function [[coverageR coverageS]] - (= coverageR coverageS)) - (list;zip2 flatR flatS)))) - - _ - false))) - -(open Eq<Coverage> "C/") - -(def: (merge-coverages addition so-far) - (-> Coverage Coverage (R;Result Coverage)) - (case [addition so-far] - ## The addition cannot possibly improve the coverage. - [_ #TotalC] - redundant-pattern - - ## The addition completes the coverage. - [#TotalC _] - (R/wrap #TotalC) - - [#PartialC #PartialC] - (R/wrap #PartialC) - - (^multi [(#BoolC sideA) (#BoolC sideSF)] - (xor sideA sideSF)) - (R/wrap #TotalC) - - [(#VariantC allA casesA) (#VariantC allSF casesSF)] - (cond (not (n.= allSF allA)) - (R;fail "Variants do not match.") - - (:: (D;Eq<Dict> Eq<Coverage>) = casesSF casesA) - redundant-pattern - - ## else - (do R;Monad<Result> - [casesM (foldM @ - (function [[tagA coverageA] casesSF'] - (case (D;get tagA casesSF') - (#;Some coverageSF) - (do @ - [coverageM (merge-coverages coverageA coverageSF)] - (wrap (D;put tagA coverageM casesSF'))) - - #;None - (wrap (D;put tagA coverageA casesSF')))) - casesSF (D;entries casesA))] - (wrap (if (let [case-coverages (D;values casesM)] - (and (n.= allSF (list;size case-coverages)) - (list;every? total? case-coverages))) - #TotalC - (#VariantC allSF casesM))))) - - [(#SeqC leftA rightA) (#SeqC leftSF rightSF)] - (case [(C/= leftSF leftA) (C/= rightSF rightA)] - ## There is nothing the addition adds to the coverage. - [true true] - redundant-pattern - - ## The 2 sequences cannot possibly be merged. - [false false] - (R/wrap (#AltC so-far addition)) - - ## Same prefix - [true false] - (do R;Monad<Result> - [rightM (merge-coverages rightA rightSF)] - (if (total? rightM) - (wrap leftSF) - (wrap (#SeqC leftSF rightM)))) - - ## Same suffix - [false true] - (do R;Monad<Result> - [leftM (merge-coverages leftA leftSF)] - (wrap (#SeqC leftM rightA)))) - - ## The left part will always match, so the addition is redundant. - (^multi [(#SeqC left right) single] - (C/= left single)) - redundant-pattern - - ## The right part is not necessary, since it can always match the left. - (^multi [single (#SeqC left right)] - (C/= left single)) - (R/wrap single) - - [_ (#AltC leftS rightS)] - (do R;Monad<Result> - [#let [fuse-once (: (-> Coverage (List Coverage) - (R;Result [(Maybe Coverage) - (List Coverage)])) - (function [coverage possibilities] - (loop [alts possibilities] - (case alts - #;Nil - (wrap [#;None (list coverage)]) - - (#;Cons alt alts') - (case (merge-coverages coverage alt) - (#R;Success altM) - (case altM - (#AltC _) - (do @ - [[success alts+] (recur alts')] - (wrap [success (#;Cons alt alts+)])) - - _ - (wrap [(#;Some altM) alts'])) - - (#R;Error error) - (R;fail error)) - ))))] - [success possibilities] (fuse-once addition (flatten-alt so-far))] - (loop [success success - possibilities possibilities] - (case success - (#;Some coverage') - (do @ - [[success' possibilities'] (fuse-once coverage' possibilities)] - (recur success' possibilities')) - - #;None - (case (list;reverse possibilities) - #;Nil - (R;fail "{ This is not supposed to happen... }") - - (#;Cons last prevs) - (wrap (L/fold (function [left right] (#AltC left right)) - last - prevs)))))) - - _ - (if (C/= so-far addition) - ## The addition cannot possibly improve the coverage. - redundant-pattern - ## There are now 2 alternative paths. - (R/wrap (#AltC so-far addition))))) - -(def: get-coverage - (-> [la;Pattern la;Analysis] Coverage) - (|>. product;left determine-coverage)) - (def: #export (analyse-case analyse input branches) (-> &;Analyser Code (List [Code Code]) (Lux la;Analysis)) (case branches @@ -444,17 +226,17 @@ (do Monad<Lux> [[inputT inputA] (&common;with-unknown-type (analyse input)) - outputH (analyse-branch analyse inputT patternH bodyH) + outputH (analyse-pattern #;None inputT patternH (analyse bodyH)) outputT (mapM @ (function [[patternT bodyT]] - (analyse-branch analyse inputT patternT bodyT)) + (analyse-pattern #;None inputT patternT (analyse bodyT))) branchesT) _ (case (foldM R;Monad<Result> - merge-coverages - (get-coverage outputH) - (L/map get-coverage outputT)) + &&coverage;merge + (|> outputH product;left &&coverage;determine) + (L/map (|>. product;left &&coverage;determine) outputT)) (#R;Success coverage) - (if (total? coverage) + (if (&&coverage;total? coverage) (wrap []) (&;fail "Pattern-matching is not total.")) diff --git a/new-luxc/source/luxc/analyser/case/coverage.lux b/new-luxc/source/luxc/analyser/case/coverage.lux new file mode 100644 index 000000000..754e555b2 --- /dev/null +++ b/new-luxc/source/luxc/analyser/case/coverage.lux @@ -0,0 +1,287 @@ +(;module: + lux + (lux (control monad + eq) + (data [bool "B/" Eq<Bool>] + [number] + ["R" result "R/" Monad<Result>] + (coll [list "L/" Fold<List>] + ["D" dict]))) + (luxc (lang ["la" analysis]))) + +## The coverage of a pattern-matching expression summarizes how well +## all the possible values of an input are being covered by the +## different patterns involved. +## Ideally, the pattern-matching has "total" coverage, which just +## means that every possible value can be matched by at least 1 +## pattern. +## Every other coverage is considered partial, and it would be valued +## as insuficient (since it could lead to runtime errors due to values +## not being handled by any pattern). +## The #Partial tag covers arbitrary partial coverages in a general +## way, while the other tags cover more specific cases for booleans +## and variants. +(type: #export #rec Coverage + #Partial + (#Bool Bool) + (#Variant Nat (D;Dict Nat Coverage)) + (#Seq Coverage Coverage) + (#Alt Coverage Coverage) + #Total) + +(def: #export (total? coverage) + (-> Coverage Bool) + (case coverage + (#Total _) + true + + _ + false)) + +(def: #export (determine pattern) + (-> la;Pattern Coverage) + (case pattern + ## Binding amounts to total coverage because any value can be + ## matched that way. + ## Unit [] amounts to total coverage because there is only one + ## possible value, so matching against it covers all cases. + (^or (#la;BindP _) (^ (#la;TupleP (list)))) + #Total + + (^ (#la;TupleP (list singleton))) + (determine singleton) + + ## Primitive patterns always have partial coverage because there + ## are too many possibilities as far as values go. + (^or (#la;NatP _) (#la;IntP _) (#la;DegP _) + (#la;RealP _) (#la;CharP _) (#la;TextP _)) + #Partial + + ## Bools are the exception, since there is only "true" and + ## "false", which means it is possible for boolean + ## pattern-matching to become total if complementary parts meet. + (#la;BoolP value) + (#Bool value) + + ## Tuple patterns can be total if there is totality for all of + ## their sub-patterns. + (#la;TupleP subs) + (loop [subs subs] + (case subs + #;Nil + #Total + + (#;Cons sub subs') + (let [post (recur subs')] + (if (total? post) + (determine sub) + (#Seq (determine sub) + post))))) + + ## Variant patterns can be shown to be total if all the possible + ## cases are handled totally. + (#la;VariantP tag-id num-tags sub) + (#Variant num-tags + (|> (D;new number;Hash<Nat>) + (D;put tag-id (determine sub)))))) + +(def: (xor left right) + (-> Bool Bool Bool) + (or (and left (not right)) + (and (not left) right))) + +## The coverage checker not only verifies that pattern-matching is +## total, but also that there are no redundant patterns. +## Redundant patterns will never be executed, since there will +## always be a pattern prior to them that would match the input. +## Because of that, the presence of redundant patterns is assumed to +## be a bug, likely due to programmer carelessness. +(def: redundant-pattern + (R;Result Coverage) + (R;fail "Redundant pattern.")) + +(def: (flatten-alt coverage) + (-> Coverage (List Coverage)) + (case coverage + (#Alt left right) + (list& left (flatten-alt right)) + + _ + (list coverage))) + +(struct: _ (Eq Coverage) + (def: (= reference sample) + (case [reference sample] + [#Total #Total] + true + + [(#Bool sideR) (#Bool sideS)] + (B/= sideR sideS) + + [(#Variant allR casesR) (#Variant allS casesS)] + (and (n.= allR allS) + (:: (D;Eq<Dict> =) = casesR casesS)) + + [(#Seq leftR rightR) (#Seq leftS rightS)] + (and (= leftR leftS) + (= rightR rightS)) + + [(#Alt _) (#Alt _)] + (let [flatR (flatten-alt reference) + flatS (flatten-alt sample)] + (and (n.= (list;size flatR) (list;size flatS)) + (list;every? (function [[coverageR coverageS]] + (= coverageR coverageS)) + (list;zip2 flatR flatS)))) + + _ + false))) + +(open Eq<Coverage> "C/") + +## After determining the coverage of each individual pattern, it is +## necessary to merge them all to figure out if the entire +## pattern-matching expression is total and whether it contains +## redundant patterns. +(def: #export (merge addition so-far) + (-> Coverage Coverage (R;Result Coverage)) + (case [addition so-far] + ## The addition cannot possibly improve the coverage. + [_ #Total] + redundant-pattern + + ## The addition completes the coverage. + [#Total _] + (R/wrap #Total) + + [#Partial #Partial] + (R/wrap #Partial) + + ## 2 boolean coverages are total if they compliment one another. + (^multi [(#Bool sideA) (#Bool sideSF)] + (xor sideA sideSF)) + (R/wrap #Total) + + [(#Variant allA casesA) (#Variant allSF casesSF)] + (cond (not (n.= allSF allA)) + (R;fail "Variants do not match.") + + (:: (D;Eq<Dict> Eq<Coverage>) = casesSF casesA) + redundant-pattern + + ## else + (do R;Monad<Result> + [casesM (foldM @ + (function [[tagA coverageA] casesSF'] + (case (D;get tagA casesSF') + (#;Some coverageSF) + (do @ + [coverageM (merge coverageA coverageSF)] + (wrap (D;put tagA coverageM casesSF'))) + + #;None + (wrap (D;put tagA coverageA casesSF')))) + casesSF (D;entries casesA))] + (wrap (if (let [case-coverages (D;values casesM)] + (and (n.= allSF (list;size case-coverages)) + (list;every? total? case-coverages))) + #Total + (#Variant allSF casesM))))) + + [(#Seq leftA rightA) (#Seq leftSF rightSF)] + (case [(C/= leftSF leftA) (C/= rightSF rightA)] + ## There is nothing the addition adds to the coverage. + [true true] + redundant-pattern + + ## The 2 sequences cannot possibly be merged. + [false false] + (R/wrap (#Alt so-far addition)) + + ## Same prefix + [true false] + (do R;Monad<Result> + [rightM (merge rightA rightSF)] + (if (total? rightM) + ## If all that follows is total, then it can be safely dropped + ## (since only the "left" part would influence whether the + ## merged coverage is total or not). + (wrap leftSF) + (wrap (#Seq leftSF rightM)))) + + ## Same suffix + [false true] + (do R;Monad<Result> + [leftM (merge leftA leftSF)] + (wrap (#Seq leftM rightA)))) + + ## The left part will always match, so the addition is redundant. + (^multi [(#Seq left right) single] + (C/= left single)) + redundant-pattern + + ## The right part is not necessary, since it can always match the left. + (^multi [single (#Seq left right)] + (C/= left single)) + (R/wrap single) + + ## When merging a new coverage against one based on Alt, it may be + ## that one of the many coverages in the Alt is complementary to + ## the new one, so effort must be made to fuse carefully, to match + ## the right coverages together. + ## If one of the Alt sub-coverages matches the new one, the cycle + ## must be repeated, in case the resulting coverage can now match + ## other ones in the original Alt. + ## This process must be repeated until no further productive + ## merges can be done. + [_ (#Alt leftS rightS)] + (do R;Monad<Result> + [#let [fuse-once (: (-> Coverage (List Coverage) + (R;Result [(Maybe Coverage) + (List Coverage)])) + (function [coverage possibilities] + (loop [alts possibilities] + (case alts + #;Nil + (wrap [#;None (list coverage)]) + + (#;Cons alt alts') + (case (merge coverage alt) + (#R;Success altM) + (case altM + (#Alt _) + (do @ + [[success alts+] (recur alts')] + (wrap [success (#;Cons alt alts+)])) + + _ + (wrap [(#;Some altM) alts'])) + + (#R;Error error) + (R;fail error)) + ))))] + [success possibilities] (fuse-once addition (flatten-alt so-far))] + (loop [success success + possibilities possibilities] + (case success + (#;Some coverage') + (do @ + [[success' possibilities'] (fuse-once coverage' possibilities)] + (recur success' possibilities')) + + #;None + (case (list;reverse possibilities) + #;Nil + (R;fail "{ This is not supposed to happen... }") + + (#;Cons last prevs) + (wrap (L/fold (function [left right] (#Alt left right)) + last + prevs)))))) + + _ + (if (C/= so-far addition) + ## The addition cannot possibly improve the coverage. + redundant-pattern + ## There are now 2 alternative paths. + (R/wrap (#Alt so-far addition))))) diff --git a/new-luxc/source/luxc/analyser/common.lux b/new-luxc/source/luxc/analyser/common.lux index 7a9e5dbf8..c1246d81c 100644 --- a/new-luxc/source/luxc/analyser/common.lux +++ b/new-luxc/source/luxc/analyser/common.lux @@ -30,3 +30,10 @@ output (body [id var]) _ (&;within-type-env (TC;delete-var id))] (wrap output))) + +(def: #export (variant-out-of-bounds-error type size tag) + (All [a] (-> Type Nat Nat (Lux a))) + (&;fail (format "Trying to create variant with tag beyond type's limitations." "\n" + " Tag: " (%i (nat-to-int tag)) "\n" + "Size: " (%i (nat-to-int size)) "\n" + "Type: " (%type type)))) diff --git a/new-luxc/source/luxc/analyser/function.lux b/new-luxc/source/luxc/analyser/function.lux index 394e65c4d..1aad8954e 100644 --- a/new-luxc/source/luxc/analyser/function.lux +++ b/new-luxc/source/luxc/analyser/function.lux @@ -62,7 +62,7 @@ (function [[output-id outputT]] (do @ [#let [funT (#;Function inputT outputT)] - =function (recur funT) + funA (recur funT) funT' (&;within-type-env (TC;clean output-id funT)) concrete-input? (&;within-type-env @@ -70,15 +70,17 @@ funT'' (if concrete-input? (&;within-type-env (TC;clean input-id funT')) - (wrap (#;UnivQ (list) (&inference;bind-var input-id +1 funT')))) + (wrap (type;univ-q +1 (&inference;replace-var input-id +1 funT')))) _ (&;within-type-env (TC;check expected funT''))] - (wrap =function)) + (wrap funA)) )))))) (#;Function inputT outputT) (<| (:: @ map (|>. #la;Function)) &;with-scope + ## Functions have access not only to their argument, but + ## also to themselves, through a local variable. (&env;with-local [func-name functionT]) (&env;with-local [arg-name inputT]) (&;with-expected-type outputT) diff --git a/new-luxc/source/luxc/analyser/inference.lux b/new-luxc/source/luxc/analyser/inference.lux index 824071ab3..11ec58eb3 100644 --- a/new-luxc/source/luxc/analyser/inference.lux +++ b/new-luxc/source/luxc/analyser/inference.lux @@ -10,16 +10,24 @@ (lang ["la" analysis #+ Analysis]) (analyser ["&;" common]))) -(def: #export (bind-var var-id bound-idx type) +## When doing inference, type-variables often need to be created in +## order to figure out which types are present in the expression being +## inferred. +## If a type-variable never gets bound/resolved to a type, then that +## means the expression can be generalized through universal +## quantification. +## When that happens, the type-variable must be replaced by an +## argument to the universally-quantified type. +(def: #export (replace-var var-id bound-idx type) (-> Nat Nat Type Type) (case type (#;Host name params) - (#;Host name (L/map (bind-var var-id bound-idx) params)) + (#;Host name (L/map (replace-var var-id bound-idx) params)) (^template [<tag>] (<tag> left right) - (<tag> (bind-var var-id bound-idx left) - (bind-var var-id bound-idx right))) + (<tag> (replace-var var-id bound-idx left) + (replace-var var-id bound-idx right))) ([#;Sum] [#;Product] [#;Function] @@ -32,18 +40,25 @@ (^template [<tag>] (<tag> env quantified) - (<tag> (L/map (bind-var var-id bound-idx) env) - (bind-var var-id (n.+ +2 bound-idx) quantified))) + (<tag> (L/map (replace-var var-id bound-idx) env) + (replace-var var-id (n.+ +2 bound-idx) quantified))) ([#;UnivQ] [#;ExQ]) (#;Named name unnamedT) (#;Named name - (bind-var var-id bound-idx unnamedT)) + (replace-var var-id bound-idx unnamedT)) _ type)) +## Type-inference works by applying some (potentially quantified) type +## to a sequence of values. +## Function types are used for this, although inference is not always +## done for function application (alternative uses may be records and +## tagged variants). +## But, so long as the type being used for the inference can be trated +## as a function type, this method of inference should work. (def: #export (apply-function analyse funcT args) (-> &;Analyser Type (List Code) (Lux [Type (List Analysis)])) (case args @@ -63,10 +78,12 @@ (do @ [? (&;within-type-env (TC;bound? var-id)) + ## Quantify over the type if genericity/parametricity + ## is discovered. outputT' (if ? (&;within-type-env (TC;clean var-id outputT)) - (wrap (#;UnivQ (list) (bind-var var-id +1 outputT))))] + (wrap (type;univ-q +1 (replace-var var-id +1 outputT))))] (wrap [outputT' argsA]))))) (#;ExQ _) @@ -75,6 +92,13 @@ TC;existential)] (apply-function analyse (assume (type;apply-type funcT exT)) args)) + ## Arguments are inferred back-to-front because, by convention, + ## Lux functions take the most important arguments *last*, which + ## means that the most information for doing proper inference is + ## located in the last arguments to a function call. + ## By inferring back-to-front, a lot of type-annotations can be + ## avoided in Lux code, since the inference algorithm can piece + ## things together more easily. (#;Function inputT outputT) (do Monad<Lux> [[outputT' args'A] (apply-function analyse outputT args') @@ -88,3 +112,72 @@ _ (&;fail (format "Cannot apply a non-function: " (%type funcT)))) )) + +## Turns a record type into the kind of function type suitable for inference. +(def: #export (record-inference-type type) + (-> Type (Lux Type)) + (case type + (#;Named name unnamedT) + (do Monad<Lux> + [unnamedT+ (record-inference-type unnamedT)] + (wrap (#;Named name unnamedT+))) + + (^template [<tag>] + (<tag> env bodyT) + (do Monad<Lux> + [bodyT+ (record-inference-type bodyT)] + (wrap (<tag> env bodyT+)))) + ([#;UnivQ] + [#;ExQ]) + + (#;Product _) + (:: Monad<Lux> wrap (type;function (type;flatten-tuple type) type)) + + _ + (&;fail (format "Not a record type: " (%type type))))) + +## Turns a variant type into the kind of function type suitable for inference. +(def: #export (variant-inference-type tag expected-size type) + (-> Nat Nat Type (Lux Type)) + (case type + (#;Named name unnamedT) + (do Monad<Lux> + [unnamedT+ (variant-inference-type tag expected-size unnamedT)] + (wrap (#;Named name unnamedT+))) + + (^template [<tag>] + (<tag> env bodyT) + (do Monad<Lux> + [bodyT+ (variant-inference-type tag expected-size bodyT)] + (wrap (<tag> env bodyT+)))) + ([#;UnivQ] + [#;ExQ]) + + (#;Sum _) + (let [cases (type;flatten-variant type) + actual-size (list;size cases) + boundary (n.dec expected-size)] + (cond (or (n.= expected-size actual-size) + (and (n.> expected-size actual-size) + (n.< boundary tag))) + (case (list;nth tag cases) + (#;Some caseT) + (:: Monad<Lux> wrap (type;function (list caseT) type)) + + #;None + (&common;variant-out-of-bounds-error type expected-size tag)) + + (n.< expected-size actual-size) + (&;fail (format "Variant type is smaller than expected." "\n" + "Expected: " (%i (nat-to-int expected-size)) "\n" + " Actual: " (%i (nat-to-int actual-size)))) + + (n.= boundary tag) + (let [caseT (type;variant (list;drop boundary cases))] + (:: Monad<Lux> wrap (type;function (list caseT) type))) + + ## else + (&common;variant-out-of-bounds-error type expected-size tag))) + + _ + (&;fail (format "Not a variant type: " (%type type))))) diff --git a/new-luxc/source/luxc/analyser/procedure/common.lux b/new-luxc/source/luxc/analyser/procedure/common.lux index 8a03f9cad..303cdc61c 100644 --- a/new-luxc/source/luxc/analyser/procedure/common.lux +++ b/new-luxc/source/luxc/analyser/procedure/common.lux @@ -71,6 +71,7 @@ (simple-proc proc (list fromT) toT)) ## [Analysers] +## "lux is" represents reference/pointer equality. (def: (analyse-lux-is proc) (-> Text Proc-Analyser) (function [analyse args] @@ -79,6 +80,8 @@ ((binary-operation varT varT Bool proc) analyse args))))) +## "lux try" provides a simple way to interact with the host platform's +## error-handling facilities. (def: (analyse-lux-try proc) (-> Text Proc-Analyser) (function [analyse args] diff --git a/new-luxc/source/luxc/analyser/structure.lux b/new-luxc/source/luxc/analyser/structure.lux index 9447ea059..f93534463 100644 --- a/new-luxc/source/luxc/analyser/structure.lux +++ b/new-luxc/source/luxc/analyser/structure.lux @@ -24,7 +24,109 @@ (analyser ["&;" common] ["&;" inference]))) -## [Analysers] +## Variants get analysed as binary sum types for the sake of semantic +## simplicity. +## This is because you can encode a variant of any size using just +## binary sums by nesting them. + +(do-template [<name> <side>] + [(def: (<name> inner) + (-> la;Analysis la;Analysis) + (#la;Sum (<side> inner)))] + + [sum-left #;Left] + [sum-right #;Right]) + +(def: (variant tag size temp value) + (-> Nat Nat Nat la;Analysis la;Analysis) + (if (n.= (n.dec size) tag) + (if (n.= +1 tag) + (sum-right value) + (L/fold (function;const sum-left) + (sum-right value) + (list;n.range +0 (n.- +2 tag)))) + (L/fold (function;const sum-left) + (case value + (#la;Sum _) + (#la;Case value (list [(#la;BindP temp) + (#la;Relative (#;Local temp))])) + + _ + value) + (list;n.range +0 tag)))) + +(def: #export (analyse-sum analyse tag valueC) + (-> &;Analyser Nat Code (Lux la;Analysis)) + (do Monad<Lux> + [expected macro;expected-type] + (&;with-stacked-errors + (function [_] (format "Invalid type for variant: " (%type expected))) + (case expected + (#;Sum _) + (let [flat (type;flatten-variant expected) + type-size (list;size flat)] + (case (list;nth tag flat) + (#;Some variant-type) + (do @ + [valueA (&;with-expected-type variant-type + (analyse valueC)) + temp &env;next-local] + (wrap (variant tag type-size temp valueA))) + + #;None + (&common;variant-out-of-bounds-error expected type-size tag))) + + (#;Named name unnamedT) + (&;with-expected-type unnamedT + (analyse-sum analyse tag valueC)) + + (#;Var id) + (do @ + [bound? (&;within-type-env + (TC;bound? id))] + (if bound? + (do @ + [expected' (&;within-type-env + (TC;read-var id))] + (&;with-expected-type expected' + (analyse-sum analyse tag valueC))) + ## Cannot do inference when the tag is numeric. + ## This is because there is no way of knowing how many + ## cases the inferred sum type would have. + (&;fail (format "Invalid type for variant: " (%type expected))))) + + (#;UnivQ _) + (do @ + [[var-id var] (&;within-type-env + TC;existential)] + (&;with-expected-type (assume (type;apply-type expected var)) + (analyse-sum analyse tag valueC))) + + (#;ExQ _) + (&common;with-var + (function [[var-id var]] + (&;with-expected-type (assume (type;apply-type expected var)) + (analyse-sum analyse tag valueC)))) + + _ + (&;fail ""))))) + +## Tuples get analysed into binary products for the sake of semantic +## simplicity, since products/pairs can encode tuples of any length +## through nesting. + +(def: (product members) + (-> (List la;Analysis) la;Analysis) + (case members + #;Nil + #la;Unit + + (#;Cons singleton #;Nil) + singleton + + (#;Cons left right) + (#la;Product left (product right)))) + (def: (analyse-typed-product analyse members) (-> &;Analyser (List Code) (Lux la;Analysis)) (do Monad<Lux> @@ -32,6 +134,8 @@ (loop [expected expected members members] (case [expected members] + ## If the type and the code are still ongoing, match each + ## sub-expression to its corresponding type. [(#;Product leftT rightT) (#;Cons leftC rightC)] (do @ [leftA (&;with-expected-type leftT @@ -39,10 +143,29 @@ rightA (recur rightT rightC)] (wrap (#la;Product leftA rightA))) + ## If the tuple runs out, whatever expression is the last gets + ## matched to the remaining type. [tailT (#;Cons tailC #;Nil)] (&;with-expected-type tailT (analyse tailC)) + ## If, however, the type runs out but there is still enough + ## tail, the remaining elements get packaged into another + ## tuple, and analysed through the intermediation of a + ## temporary local variable. + ## The reason for this is that it is assumed that the type of + ## the tuple represents the expectations of the user. + ## If the type is for a 3-tuple, but a 5-tuple is provided, it + ## is assumed that the user intended the following layout: + ## [0, 1, [2, 3, 4]] + ## but that, for whatever reason, it was written in a flat + ## way. + ## The reason why an intermediate variable is used is that if + ## the code was just re-written with just tuple nesting, the + ## resulting analysis would have undone the explicity nesting, + ## since Product nodes rely on nesting inherently, thereby + ## blurring the line between what was wanted (the separation) + ## and what was analysed. [tailT tailC] (do @ [g!tail (macro;gensym "tail")] @@ -52,73 +175,6 @@ (~ g!tail)))))) )))) -(def: #export (normalize-record pairs) - (-> (List [Code Code]) (Lux (List [Ident Code]))) - (mapM Monad<Lux> - (function [[key val]] - (case key - [_ (#;Tag key)] - (do Monad<Lux> - [key (macro;normalize key)] - (wrap [key val])) - - _ - (&;fail (format "Cannot use non-tag tokens in key positions in records: " (%code key))))) - pairs)) - -(def: #export (order-record pairs) - (-> (List [Ident Code]) (Lux [(List Code) Type])) - (case pairs - (#;Cons [head-k head-v] _) - (do Monad<Lux> - [head-k (macro;normalize head-k) - [_ tag-set recordT] (macro;resolve-tag head-k) - #let [size-record (list;size pairs) - size-ts (list;size tag-set)] - _ (if (n.= size-ts size-record) - (wrap []) - (&;fail (format "Record size does not match tag-set size." "\n" - "Expected: " (|> size-ts nat-to-int %i) "\n" - " Actual: " (|> size-record nat-to-int %i) "\n" - "For type: " (%type recordT)))) - #let [tuple-range (list;n.range +0 (n.dec size-ts)) - tag->idx (D;from-list ident;Hash<Ident> (list;zip2 tag-set tuple-range))] - idx->val (foldM @ - (function [[key val] idx->val] - (do @ - [key (macro;normalize key)] - (case (D;get key tag->idx) - #;None - (&;fail (format "Tag " (%code (code;tag key)) - " does not belong to tag-set for type " (%type recordT))) - - (#;Some idx) - (if (D;contains? idx idx->val) - (&;fail (format "Cannot repeat tag inside record: " (%code (code;tag key)))) - (wrap (D;put idx val idx->val)))))) - (: (D;Dict Nat Code) - (D;new number;Hash<Nat>)) - pairs) - #let [ordered-tuple (L/map (function [idx] - (assume (D;get idx idx->val))) - tuple-range)]] - (wrap [ordered-tuple recordT])) - - _ - (:: Monad<Lux> wrap [(list) Unit]))) - -(def: (tuple members) - (-> (List la;Analysis) la;Analysis) - (case members - #;Nil - #la;Unit - - (#;Cons singleton #;Nil) - singleton - - (#;Cons left right) - (#la;Product left (tuple right)))) - (def: #export (analyse-product analyse membersC) (-> &;Analyser (List Code) (Lux la;Analysis)) (do Monad<Lux> @@ -143,13 +199,14 @@ (TC;read-var id))] (&;with-expected-type expected' (analyse-product analyse membersC))) + ## Must do inference... (do @ [membersTA (mapM @ (|>. analyse &common;with-unknown-type) membersC) _ (&;within-type-env (TC;check expected (type;tuple (L/map product;left membersTA))))] - (wrap (tuple (L/map product;right membersTA)))))) + (wrap (product (L/map product;right membersTA)))))) (#;UnivQ _) (do @ @@ -168,183 +225,91 @@ (&;fail "") )))) -(def: (record-function-type type) - (-> Type (Lux Type)) - (case type - (#;Named name unnamedT) - (do Monad<Lux> - [unnamedT+ (record-function-type unnamedT)] - (wrap (#;Named name unnamedT+))) - - (^template [<tag>] - (<tag> env bodyT) - (do Monad<Lux> - [bodyT+ (record-function-type bodyT)] - (wrap (<tag> env bodyT+)))) - ([#;UnivQ] - [#;ExQ]) - - (#;Product _) - (:: Monad<Lux> wrap (type;function (type;flatten-tuple type) type)) - - _ - (&;fail (format "Not a record type: " (%type type))))) - -(def: (out-of-bounds-error type size tag) - (All [a] (-> Type Nat Nat (Lux a))) - (&;fail (format "Trying to create variant with tag beyond type's limitations." "\n" - " Tag: " (%i (nat-to-int tag)) "\n" - "Size: " (%i (nat-to-int size)) "\n" - "Type: " (%type type)))) - -(def: (variant-function-type tag expected-size type) - (-> Nat Nat Type (Lux Type)) - (case type - (#;Named name unnamedT) - (do Monad<Lux> - [unnamedT+ (variant-function-type tag expected-size unnamedT)] - (wrap (#;Named name unnamedT+))) - - (^template [<tag>] - (<tag> env bodyT) - (do Monad<Lux> - [bodyT+ (variant-function-type tag expected-size bodyT)] - (wrap (<tag> env bodyT+)))) - ([#;UnivQ] - [#;ExQ]) - - (#;Sum _) - (let [cases (type;flatten-variant type) - actual-size (list;size cases) - boundary (n.dec expected-size)] - (cond (or (n.= expected-size actual-size) - (and (n.> expected-size actual-size) - (n.< boundary tag))) - (case (list;nth tag cases) - (#;Some caseT) - (:: Monad<Lux> wrap (type;function (list caseT) type)) - - #;None - (out-of-bounds-error type expected-size tag)) - - (n.< expected-size actual-size) - (&;fail (format "Variant type is smaller than expected." "\n" - "Expected: " (%i (nat-to-int expected-size)) "\n" - " Actual: " (%i (nat-to-int actual-size)))) - - (n.= boundary tag) - (let [caseT (type;variant (list;drop boundary cases))] - (:: Monad<Lux> wrap (type;function (list caseT) type))) - - ## else - (out-of-bounds-error type expected-size tag))) - - _ - (&;fail (format "Not a variant type: " (%type type))))) - -(def: #export (analyse-record analyse members) - (-> &;Analyser (List [Code Code]) (Lux la;Analysis)) - (do Monad<Lux> - [members (normalize-record members) - [members recordT] (order-record members) - expectedT macro;expected-type - functionT (record-function-type recordT) - [inferredT membersA] (&inference;apply-function analyse functionT members) - _ (&;within-type-env - (TC;check expectedT inferredT))] - (wrap (tuple membersA)))) - -(do-template [<name> <side>] - [(def: (<name> inner) - (-> la;Analysis la;Analysis) - (#la;Sum (<side> inner)))] - - [sum-left #;Left] - [sum-right #;Right]) - -(def: (variant tag size temp value) - (-> Nat Nat Nat la;Analysis la;Analysis) - (if (n.= (n.dec size) tag) - (if (n.= +1 tag) - (sum-right value) - (L/fold (function;const sum-left) - (sum-right value) - (list;n.range +0 (n.- +2 tag)))) - (L/fold (function;const sum-left) - (case value - (#la;Sum _) - (#la;Case value (list [(#la;BindP temp) - (#la;Relative (#;Local temp))])) - - _ - value) - (list;n.range +0 tag)))) - (def: #export (analyse-tagged-sum analyse tag value) (-> &;Analyser Ident Code (Lux la;Analysis)) (do Monad<Lux> [tag (macro;normalize tag) [idx group variantT] (macro;resolve-tag tag) #let [case-size (list;size group)] - functionT (variant-function-type idx case-size variantT) - [inferredT valueA+] (&inference;apply-function analyse functionT (list value)) + inferenceT (&inference;variant-inference-type idx case-size variantT) + [inferredT valueA+] (&inference;apply-function analyse inferenceT (list value)) expectedT macro;expected-type _ (&;within-type-env (TC;check expectedT inferredT)) temp &env;next-local] (wrap (variant idx case-size temp (|> valueA+ list;head assume))))) -(def: #export (analyse-sum analyse tag valueC) - (-> &;Analyser Nat Code (Lux la;Analysis)) - (do Monad<Lux> - [expected macro;expected-type] - (&;with-stacked-errors - (function [_] (format "Invalid type for variant: " (%type expected))) - (case expected - (#;Sum _) - (let [flat (type;flatten-variant expected) - type-size (list;size flat)] - (case (list;nth tag flat) - (#;Some variant-type) - (do @ - [valueA (&;with-expected-type variant-type - (analyse valueC)) - temp &env;next-local] - (wrap (variant tag type-size temp valueA))) +## There cannot be any ambiguity or improper syntax when analysing +## records, so they must be normalized for further analysis. +## Normalization just means that all the tags get resolved to their +## canonical form (with their corresponding module identified). +(def: #export (normalize record) + (-> (List [Code Code]) (Lux (List [Ident Code]))) + (mapM Monad<Lux> + (function [[key val]] + (case key + [_ (#;Tag key)] + (do Monad<Lux> + [key (macro;normalize key)] + (wrap [key val])) - #;None - (out-of-bounds-error expected type-size tag))) + _ + (&;fail (format "Cannot use non-tag tokens in key positions in records: " (%code key))))) + record)) - (#;Named name unnamedT) - (&;with-expected-type unnamedT - (analyse-sum analyse tag valueC)) +## Lux already possesses the means to analyse tuples, so +## re-implementing the same functionality for records makes no sense. +## Records, thus, get transformed into tuples by ordering the elements. +(def: #export (order record) + (-> (List [Ident Code]) (Lux [(List Code) Type])) + (case record + ## empty-record = empty-tuple = unit = [] + #;Nil + (:: Monad<Lux> wrap [(list) Unit]) - (#;Var id) - (do @ - [bound? (&;within-type-env - (TC;bound? id))] - (if bound? - (do @ - [expected' (&;within-type-env - (TC;read-var id))] - (&;with-expected-type expected' - (analyse-sum analyse tag valueC))) - (&;fail (format "Invalid type for variant: " (%type expected))))) + (#;Cons [head-k head-v] _) + (do Monad<Lux> + [head-k (macro;normalize head-k) + [_ tag-set recordT] (macro;resolve-tag head-k) + #let [size-record (list;size record) + size-ts (list;size tag-set)] + _ (if (n.= size-ts size-record) + (wrap []) + (&;fail (format "Record size does not match tag-set size." "\n" + "Expected: " (|> size-ts nat-to-int %i) "\n" + " Actual: " (|> size-record nat-to-int %i) "\n" + "For type: " (%type recordT)))) + #let [tuple-range (list;n.range +0 (n.dec size-ts)) + tag->idx (D;from-list ident;Hash<Ident> (list;zip2 tag-set tuple-range))] + idx->val (foldM @ + (function [[key val] idx->val] + (do @ + [key (macro;normalize key)] + (case (D;get key tag->idx) + #;None + (&;fail (format "Tag " (%code (code;tag key)) + " does not belong to tag-set for type " (%type recordT))) - (#;UnivQ _) - (do @ - [[var-id var] (&;within-type-env - TC;existential)] - (&;with-expected-type (assume (type;apply-type expected var)) - (analyse-sum analyse tag valueC))) + (#;Some idx) + (if (D;contains? idx idx->val) + (&;fail (format "Cannot repeat tag inside record: " (%code (code;tag key)))) + (wrap (D;put idx val idx->val)))))) + (: (D;Dict Nat Code) + (D;new number;Hash<Nat>)) + record) + #let [ordered-tuple (L/map (function [idx] (assume (D;get idx idx->val))) + tuple-range)]] + (wrap [ordered-tuple recordT])) + )) - (#;ExQ _) - (&common;with-var - (function [[var-id var]] - (&;with-expected-type (assume (type;apply-type expected var)) - (analyse-sum analyse tag valueC)))) - - _ - (if (n.= +0 tag) - (analyse valueC) - (&;fail "")))))) +(def: #export (analyse-record analyse members) + (-> &;Analyser (List [Code Code]) (Lux la;Analysis)) + (do Monad<Lux> + [members (normalize members) + [members recordT] (order members) + expectedT macro;expected-type + inferenceT (&inference;record-inference-type recordT) + [inferredT membersA] (&inference;apply-function analyse inferenceT members) + _ (&;within-type-env + (TC;check expectedT inferredT))] + (wrap (product membersA)))) diff --git a/new-luxc/source/luxc/analyser/type.lux b/new-luxc/source/luxc/analyser/type.lux index 3b9b83245..1eb278d2a 100644 --- a/new-luxc/source/luxc/analyser/type.lux +++ b/new-luxc/source/luxc/analyser/type.lux @@ -6,7 +6,9 @@ (luxc ["&" base] (lang ["la" analysis #+ Analysis]))) -## [Analysers] +## These 2 analysers are somewhat special, since they require the +## means of evaluating Lux expressions at compile-time for the sake of +## computing Lux type values. (def: #export (analyse-check analyse eval type value) (-> &;Analyser &;Eval Code Code (Lux Analysis)) (do Monad<Lux> |