From 19d38211c33faf6d5fe01665982d696643f60051 Mon Sep 17 00:00:00 2001 From: Eduardo Julian Date: Sun, 20 May 2018 20:12:22 -0400 Subject: - Migrated pattern-matching analysis to stdlib. --- stdlib/source/lux/lang/analysis.lux | 89 +++--- stdlib/source/lux/lang/analysis/case.lux | 295 ++++++++++++++++++++ stdlib/source/lux/lang/analysis/case/coverage.lux | 322 ++++++++++++++++++++++ stdlib/source/lux/lang/analysis/structure.lux | 8 +- 4 files changed, 667 insertions(+), 47 deletions(-) create mode 100644 stdlib/source/lux/lang/analysis/case.lux create mode 100644 stdlib/source/lux/lang/analysis/case/coverage.lux (limited to 'stdlib/source') diff --git a/stdlib/source/lux/lang/analysis.lux b/stdlib/source/lux/lang/analysis.lux index 223f2fb29..0b48f803d 100644 --- a/stdlib/source/lux/lang/analysis.lux +++ b/stdlib/source/lux/lang/analysis.lux @@ -48,24 +48,15 @@ (#Constant Ident) (#Special (Special Text))) -(type: #export Variant +(type: #export (Variant a) {#lefts Nat #right? Bool - #value Analysis}) + #value a}) -(type: #export Tuple (List Analysis)) +(type: #export (Tuple a) (List a)) (type: #export Application [Analysis (List Analysis)]) -(do-template [ ] - [(def: - (-> Analysis Analysis) - (|>> #Sum #Structure))] - - [left #.Left] - [right #.Right] - ) - (def: (last? size tag) (-> Nat Tag Bool) (n/= (dec size) tag)) @@ -75,35 +66,47 @@ (let [identity (#Function (list) (#Variable (#Local +1)))] (#Apply value identity))) -(def: #export (sum size tag value) - (-> Nat Tag Analysis Analysis) - (if (last? size tag) - (if (n/= +1 tag) - (..right value) - (list/fold (function.const ..left) - (..right value) - (list.n/range +0 (n/- +2 tag)))) - (list/fold (function.const ..left) - (case value - (#Structure (#Sum _)) - (no-op value) - - _ - value) - (list.n/range +0 tag)))) - -(def: #export (product members) - (-> Tuple Analysis) - (case (list.reverse members) - #.Nil - (#Primitive #Unit) - - (#.Cons singleton #.Nil) - singleton - - (#.Cons last prevs) - (list/fold (function (_ left right) (#Structure (#Product left right))) - last prevs))) +(do-template [ ] + [(def: #export ( size tag value) + (-> Nat Tag ) + (let [left (function.const (|>> #.Left #Sum )) + right (|>> #.Right #Sum )] + (if (last? size tag) + (if (n/= +1 tag) + (right value) + (list/fold left + (right value) + (list.n/range +0 (n/- +2 tag)))) + (list/fold left + (case value + ( (#Sum _)) + ( value) + + _ + value) + (list.n/range +0 tag)))))] + + [sum-analysis Analysis #Structure no-op] + [sum-pattern Pattern #Complex id] + ) + +(do-template [ ] + [(def: #export ( members) + (-> (Tuple ) ) + (case (list.reverse members) + #.Nil + ( #Unit) + + (#.Cons singleton #.Nil) + singleton + + (#.Cons last prevs) + (list/fold (function (_ left right) ( (#Product left right))) + last prevs)))] + + [product-analysis Analysis #Primitive #Structure] + [product-pattern Pattern #Simple #Complex] + ) (def: #export (apply [func args]) (-> Application Analysis) @@ -113,7 +116,7 @@ (-> Code (Meta Analysis))) (def: #export (tuple analysis) - (-> Analysis Tuple) + (-> Analysis (Tuple Analysis)) (case analysis (#Structure (#Product left right)) (#.Cons left (tuple right)) @@ -122,7 +125,7 @@ (list analysis))) (def: #export (variant analysis) - (-> Analysis (Maybe Variant)) + (-> Analysis (Maybe (Variant Analysis))) (loop [lefts +0 variantA analysis] (case variantA diff --git a/stdlib/source/lux/lang/analysis/case.lux b/stdlib/source/lux/lang/analysis/case.lux new file mode 100644 index 000000000..3140a9d7e --- /dev/null +++ b/stdlib/source/lux/lang/analysis/case.lux @@ -0,0 +1,295 @@ +(.module: + [lux #- case] + (lux (control [monad #+ do] + ["ex" exception #+ exception:] + [equality #+ Eq]) + (data [bool] + [number] + [product] + ["e" error] + [maybe] + [text] + text/format + (coll [list "list/" Fold Monoid Functor])) + [function] + [macro] + (macro [code]) + [lang] + (lang [type] + (type ["tc" check]) + [".L" scope] + [".L" analysis #+ Pattern Analysis Analyser] + (analysis [".A" type] + [".A" structure] + (case [".A" coverage]))))) + +(exception: #export (cannot-match-type-with-pattern {type Type} {pattern Code}) + (ex.report ["Type" (%type type)] + ["Pattern" (%code pattern)])) + +(exception: #export (sum-type-has-no-case {case Nat} {type Type}) + (ex.report ["Case" (%n case)] + ["Type" (%type type)])) + +(exception: #export (unrecognized-pattern-syntax {pattern Code}) + (%code pattern)) + +(exception: #export (cannot-simplify-type-for-pattern-matching {type Type}) + (%type type)) + +(do-template [] + [(exception: #export ( {message Text}) + message)] + + [cannot-have-empty-branches] + [non-exhaustive-pattern-matching] + ) + +(def: (re-quantify envs baseT) + (-> (List (List Type)) Type Type) + (.case envs + #.Nil + baseT + + (#.Cons head tail) + (re-quantify tail (#.UnivQ head baseT)))) + +## 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 caseT) + (-> Type (Meta Type)) + (loop [envs (: (List (List Type)) + (list)) + caseT caseT] + (.case caseT + (#.Var id) + (do macro.Monad + [?caseT' (typeA.with-env + (tc.read id))] + (.case ?caseT' + (#.Some caseT') + (recur envs caseT') + + _ + (lang.throw cannot-simplify-type-for-pattern-matching caseT))) + + (#.Named name unnamedT) + (recur envs unnamedT) + + (#.UnivQ env unquantifiedT) + (recur (#.Cons env envs) unquantifiedT) + + (#.ExQ _) + (do macro.Monad + [[ex-id exT] (typeA.with-env + tc.existential)] + (recur envs (maybe.assume (type.apply (list exT) caseT)))) + + (#.Apply inputT funcT) + (.case funcT + (#.Var funcT-id) + (do macro.Monad + [funcT' (typeA.with-env + (do tc.Monad + [?funct' (tc.read funcT-id)] + (.case ?funct' + (#.Some funct') + (wrap funct') + + _ + (tc.throw cannot-simplify-type-for-pattern-matching caseT))))] + (recur envs (#.Apply inputT funcT'))) + + _ + (.case (type.apply (list inputT) funcT) + (#.Some outputT) + (recur envs outputT) + + #.None + (lang.throw cannot-simplify-type-for-pattern-matching caseT))) + + (#.Product _) + (|> caseT + type.flatten-tuple + (list/map (re-quantify envs)) + type.tuple + (:: macro.Monad wrap)) + + _ + (:: macro.Monad wrap (re-quantify envs caseT))))) + +(def: (analyse-primitive type inputT cursor output next) + (All [a] (-> Type Type Cursor Pattern (Meta a) (Meta [Pattern a]))) + (lang.with-cursor cursor + (do macro.Monad + [_ (typeA.with-env + (tc.check inputT type)) + outputA next] + (wrap [output outputA])))) + +## 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 (Meta a) (Meta [Pattern a]))) + (.case pattern + [cursor (#.Symbol ["" name])] + (lang.with-cursor cursor + (do macro.Monad + [outputA (scopeL.with-local [name inputT] + next) + idx scopeL.next-local] + (wrap [(#analysisL.Bind idx) outputA]))) + + (^template [ ] + [cursor ] + (analyse-primitive inputT cursor (#analysisL.Simple ) next)) + ([Bool (#.Bool pattern-value) (#analysisL.Bool pattern-value)] + [Nat (#.Nat pattern-value) (#analysisL.Nat pattern-value)] + [Int (#.Int pattern-value) (#analysisL.Int pattern-value)] + [Deg (#.Deg pattern-value) (#analysisL.Deg pattern-value)] + [Frac (#.Frac pattern-value) (#analysisL.Frac pattern-value)] + [Text (#.Text pattern-value) (#analysisL.Text pattern-value)] + [Top (#.Tuple #.Nil) #analysisL.Unit]) + + (^ [cursor (#.Tuple (list singleton))]) + (analyse-pattern #.None inputT singleton next) + + [cursor (#.Tuple sub-patterns)] + (lang.with-cursor cursor + (do macro.Monad + [inputT' (simplify-case-type inputT)] + (.case inputT' + (#.Product _) + (let [sub-types (type.flatten-tuple inputT') + num-sub-types (maybe.default (list.size sub-types) + num-tags) + num-sub-patterns (list.size sub-patterns) + matches (cond (n/< num-sub-types num-sub-patterns) + (let [[prefix suffix] (list.split (dec num-sub-patterns) sub-types)] + (list.zip2 (list/compose prefix (list (type.tuple suffix))) sub-patterns)) + + (n/> num-sub-types num-sub-patterns) + (let [[prefix suffix] (list.split (dec num-sub-types) sub-patterns)] + (list.zip2 sub-types (list/compose prefix (list (code.tuple suffix))))) + + ## (n/= num-sub-types num-sub-patterns) + (list.zip2 sub-types sub-patterns))] + (do @ + [[memberP+ thenA] (list/fold (: (All [a] + (-> [Type Code] (Meta [(List Pattern) a]) + (Meta [(List Pattern) a]))) + (function (_ [memberT memberC] then) + (do @ + [[memberP [memberP+ thenA]] ((:! (All [a] (-> (Maybe Nat) Type Code (Meta a) (Meta [Pattern a]))) + analyse-pattern) + #.None memberT memberC then)] + (wrap [(list& memberP memberP+) thenA])))) + (do @ + [nextA next] + (wrap [(list) nextA])) + (list.reverse matches))] + (wrap [(analysisL.product-pattern memberP+) + thenA]))) + + _ + (lang.throw cannot-match-type-with-pattern [inputT pattern]) + ))) + + [cursor (#.Record record)] + (do macro.Monad + [record (structureA.normalize record) + [members recordT] (structureA.order record) + _ (typeA.with-env + (tc.check inputT recordT))] + (analyse-pattern (#.Some (list.size members)) inputT [cursor (#.Tuple members)] next)) + + [cursor (#.Tag tag)] + (lang.with-cursor cursor + (analyse-pattern #.None inputT (` ((~ pattern))) next)) + + (^ [cursor (#.Form (list& [_ (#.Nat idx)] values))]) + (lang.with-cursor cursor + (do macro.Monad + [inputT' (simplify-case-type inputT)] + (.case inputT' + (#.Sum _) + (let [flat-sum (type.flatten-variant inputT') + size-sum (list.size flat-sum) + num-cases (maybe.default size-sum num-tags)] + (.case (list.nth idx flat-sum) + (^multi (#.Some case-type) + (n/< num-cases idx)) + (do macro.Monad + [[testP nextA] (if (and (n/> num-cases size-sum) + (n/= (dec num-cases) idx)) + (analyse-pattern #.None + (type.variant (list.drop (dec num-cases) flat-sum)) + (` [(~+ values)]) + next) + (analyse-pattern #.None case-type (` [(~+ values)]) next))] + (wrap [(analysisL.sum-pattern num-cases idx testP) + nextA])) + + _ + (lang.throw sum-type-has-no-case [idx inputT]))) + + _ + (lang.throw cannot-match-type-with-pattern [inputT pattern])))) + + (^ [cursor (#.Form (list& [_ (#.Tag tag)] values))]) + (lang.with-cursor cursor + (do macro.Monad + [tag (macro.normalize tag) + [idx group variantT] (macro.resolve-tag tag) + _ (typeA.with-env + (tc.check inputT variantT))] + (analyse-pattern (#.Some (list.size group)) inputT (` ((~ (code.nat idx)) (~+ values))) next))) + + _ + (lang.throw unrecognized-pattern-syntax pattern) + )) + +(def: #export (case analyse inputC branches) + (-> Analyser Code (List [Code Code]) (Meta Analysis)) + (.case branches + #.Nil + (lang.throw cannot-have-empty-branches "") + + (#.Cons [patternH bodyH] branchesT) + (do macro.Monad + [[inputT inputA] (typeA.with-inference + (analyse inputC)) + outputH (analyse-pattern #.None inputT patternH (analyse bodyH)) + outputT (monad.map @ + (function (_ [patternT bodyT]) + (analyse-pattern #.None inputT patternT (analyse bodyT))) + branchesT) + outputHC (|> outputH product.left coverageA.determine) + outputTC (monad.map @ (|>> product.left coverageA.determine) outputT) + _ (.case (monad.fold e.Monad coverageA.merge outputHC outputTC) + (#e.Success coverage) + (lang.assert non-exhaustive-pattern-matching "" + (coverageA.exhaustive? coverage)) + + (#e.Error error) + (lang.fail error))] + (wrap (#analysisL.Case inputA [outputH outputT]))))) diff --git a/stdlib/source/lux/lang/analysis/case/coverage.lux b/stdlib/source/lux/lang/analysis/case/coverage.lux new file mode 100644 index 000000000..da256206f --- /dev/null +++ b/stdlib/source/lux/lang/analysis/case/coverage.lux @@ -0,0 +1,322 @@ +(.module: + lux + (lux (control [monad #+ do] + ["ex" exception #+ exception:] + equality) + (data [bool "bool/" Eq] + [number] + ["e" error "error/" Monad] + [maybe] + text/format + (coll [list "list/" Fold] + (dictionary ["dict" unordered #+ Dict]))) + [macro "macro/" Monad] + [lang] + (lang [".L" analysis #+ Pattern Variant]))) + +(def: cases + (-> (Maybe Nat) Nat) + (|>> (maybe.default +0))) + +(def: (variant sum-side) + (-> (Either Pattern Pattern) (Variant Pattern)) + (loop [lefts +0 + variantP sum-side] + (case variantP + (#.Left valueP) + (case valueP + (#analysisL.Complex (#analysisL.Sum value-side)) + (recur (inc lefts) value-side) + + _ + {#analysisL.lefts lefts + #analysisL.right? false + #analysisL.value valueP}) + + (#.Right valueP) + {#analysisL.lefts lefts + #analysisL.right? true + #analysisL.value valueP}))) + +## 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 "exhaustive" 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 (Maybe Nat) (Dict Nat Coverage)) + (#Seq Coverage Coverage) + (#Alt Coverage Coverage) + #Exhaustive) + +(def: #export (exhaustive? coverage) + (-> Coverage Bool) + (case coverage + (#Exhaustive _) + true + + _ + false)) + +(def: #export (determine pattern) + (-> Pattern (Meta Coverage)) + (case pattern + (^or (#analysisL.Simple #analysisL.Unit) + (#analysisL.Bind _)) + (macro/wrap #Exhaustive) + + ## Primitive patterns always have partial coverage because there + ## are too many possibilities as far as values go. + (^template [] + (#analysisL.Simple ( _)) + (macro/wrap #Partial)) + ([#analysisL.Nat] + [#analysisL.Int] + [#analysisL.Deg] + [#analysisL.Frac] + [#analysisL.Text]) + + ## Bools are the exception, since there is only "true" and + ## "false", which means it is possible for boolean + ## pattern-matching to become exhaustive if complementary parts meet. + (#analysisL.Simple (#analysisL.Bool value)) + (macro/wrap (#Bool value)) + + ## Tuple patterns can be exhaustive if there is exhaustiveness for all of + ## their sub-patterns. + (#analysisL.Complex (#analysisL.Product [left right])) + (do macro.Monad + [left (determine left) + right (determine right)] + (case right + (#Exhaustive _) + (wrap left) + + _ + (wrap (#Seq left right)))) + + (#analysisL.Complex (#analysisL.Sum sum-side)) + (let [[variant-lefts variant-right? variant-value] (variant sum-side)] + ## Variant patterns can be shown to be exhaustive if all the possible + ## cases are handled exhaustively. + (do macro.Monad + [value-coverage (determine variant-value) + #let [variant-idx (if variant-right? + (inc variant-lefts) + variant-lefts)]] + (wrap (#Variant (if variant-right? + (#.Some variant-idx) + #.None) + (|> (dict.new number.Hash) + (dict.put variant-idx value-coverage)))))))) + +(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 +## exhaustive, 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 + (e.Error Coverage) + (e.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] + [#Exhaustive #Exhaustive] + true + + [(#Bool sideR) (#Bool sideS)] + (bool/= sideR sideS) + + [(#Variant allR casesR) (#Variant allS casesS)] + (and (n/= (cases allR) + (cases allS)) + (:: (dict.Eq =) = 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 "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 exhaustive and whether it contains +## redundant patterns. +(def: #export (merge addition so-far) + (-> Coverage Coverage (e.Error Coverage)) + (case [addition so-far] + ## The addition cannot possibly improve the coverage. + [_ #Exhaustive] + redundant-pattern + + ## The addition completes the coverage. + [#Exhaustive _] + (error/wrap #Exhaustive) + + [#Partial #Partial] + (error/wrap #Partial) + + ## 2 boolean coverages are exhaustive if they compliment one another. + (^multi [(#Bool sideA) (#Bool sideSF)] + (xor sideA sideSF)) + (error/wrap #Exhaustive) + + [(#Variant allA casesA) (#Variant allSF casesSF)] + (cond (not (n/= (cases allSF) (cases allA))) + (e.fail "Variants do not match.") + + (:: (dict.Eq Eq) = casesSF casesA) + redundant-pattern + + ## else + (do e.Monad + [casesM (monad.fold @ + (function (_ [tagA coverageA] casesSF') + (case (dict.get tagA casesSF') + (#.Some coverageSF) + (do @ + [coverageM (merge coverageA coverageSF)] + (wrap (dict.put tagA coverageM casesSF'))) + + #.None + (wrap (dict.put tagA coverageA casesSF')))) + casesSF (dict.entries casesA))] + (wrap (if (let [case-coverages (dict.values casesM)] + (and (n/= (cases allSF) (list.size case-coverages)) + (list.every? exhaustive? case-coverages))) + #Exhaustive + (#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] + (error/wrap (#Alt so-far addition)) + + ## Same prefix + [true false] + (do e.Monad + [rightM (merge rightA rightSF)] + (if (exhaustive? rightM) + ## If all that follows is exhaustive, then it can be safely dropped + ## (since only the "left" part would influence whether the + ## merged coverage is exhaustive or not). + (wrap leftSF) + (wrap (#Seq leftSF rightM)))) + + ## Same suffix + [false true] + (do e.Monad + [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)) + (error/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 e.Monad + [#let [fuse-once (: (-> Coverage (List Coverage) + (e.Error [(Maybe Coverage) + (List Coverage)])) + (function (_ coverage possibilities) + (loop [alts possibilities] + (case alts + #.Nil + (wrap [#.None (list coverage)]) + + (#.Cons alt alts') + (case (merge coverage alt) + (#e.Success altM) + (case altM + (#Alt _) + (do @ + [[success alts+] (recur alts')] + (wrap [success (#.Cons alt alts+)])) + + _ + (wrap [(#.Some altM) alts'])) + + (#e.Error error) + (e.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) + (#.Cons last prevs) + (wrap (list/fold (function (_ left right) (#Alt left right)) + last + prevs)) + + #.Nil + (undefined))))) + + _ + (if (C/= so-far addition) + ## The addition cannot possibly improve the coverage. + redundant-pattern + ## There are now 2 alternative paths. + (error/wrap (#Alt so-far addition))))) diff --git a/stdlib/source/lux/lang/analysis/structure.lux b/stdlib/source/lux/lang/analysis/structure.lux index cc185ebe9..8e3611e67 100644 --- a/stdlib/source/lux/lang/analysis/structure.lux +++ b/stdlib/source/lux/lang/analysis/structure.lux @@ -89,7 +89,7 @@ (do @ [valueA (typeA.with-type variant-type (analyse valueC))] - (wrap (analysis.sum type-size tag valueA))) + (wrap (analysis.sum-analysis type-size tag valueA))) #.None (lang.throw inferenceA.variant-tag-out-of-bounds [type-size tag expectedT]))) @@ -219,7 +219,7 @@ _ (typeA.with-env (tc.check expectedT (type.tuple (list/map product.left membersTA))))] - (wrap (analysis.product (list/map product.right membersTA)))))) + (wrap (analysis.product-analysis (list/map product.right membersTA)))))) (^template [ ] ( _) @@ -268,7 +268,7 @@ [#let [case-size (list.size group)] inferenceT (inferenceA.variant idx case-size variantT) [inferredT valueA+] (inferenceA.general analyse inferenceT (list valueC))] - (wrap (analysis.sum case-size idx (|> valueA+ list.head maybe.assume)))) + (wrap (analysis.sum-analysis case-size idx (|> valueA+ list.head maybe.assume)))) _ (..sum analyse idx valueC)))) @@ -352,7 +352,7 @@ (do @ [inferenceT (inferenceA.record recordT) [inferredT membersA] (inferenceA.general analyse inferenceT membersC)] - (wrap (analysis.product membersA))) + (wrap (analysis.product-analysis membersA))) _ (..product analyse membersC)))))) -- cgit v1.2.3