#lang racket (require rackunit) (require syntax/location) (require (for-syntax syntax/location)) ;; The simply-typed lambda calculus, with: ;; - sums, products, recursive types, ascryption ;; - bidirectional typechecking ;; - impredicative references built on a levels system ;; - explicit level stratification syntax ;; - automatic level collection ;; ;; This system is impredicative. It can be made predicative by tweaking ;; the sections of the code labeled with "KNOB". (define-syntax-rule (print msg) (eprintf "~a~%" msg)) (define-syntax-rule (dbg body) (let ([res body]) (eprintf "[~a:~a] ~v = ~a~%" (syntax-source-file-name #'body) (syntax-line #'body) 'body res) res)) (define-syntax-rule (err msg) (error 'error (format "[~a:~a] ~a" (syntax-source-file-name #'msg) (syntax-line #'msg) msg))) (define-syntax (todo stx) (with-syntax ([src (syntax-source-file-name stx)] [line (syntax-line stx)]) #'(error 'todo (format "[~a:~a] unimplemented" src line)))) (define (any? proc lst) (foldl (λ (x acc) (if (proc x) #t acc)) #f lst)) (define (all? proc lst) (foldl (λ (x acc) (if (proc x) acc #f)) #t lst)) ;; Whether a given level is a syntactically valid level. ;; This does not account for context, and so all symbols are valid levels. (define (level? level) (match level [n #:when (natural? n) #t] ; Symbols are only valid if previously bound (by `level`). ; We can't check that here, however. [s #:when (symbol? s) #t] ; Levels may be a list of symbols, or a list of symbols followed by a natural. [`(+ ,l ... ,n) #:when (natural? n) (all? (λ (s) (symbol? s)) l)] [`(+ ,l ...) (all? (λ (s) (symbol? s)) l)] [_ #f])) ;; Whether a given type is a syntactically valid type. ;; This does not account for context, and so all symbols are valid types. (define (type? type) (match type [(or 'Unit 'Bool 'Nat) #t] ; Symbols are only valid if previously bound (by `type` or `μ`). ; We can't check that here, however. [s #:when (symbol? s) #t] [`(Ref ,t) (type? t)] [(or `(,t1 × ,t2) `(,t1 ⊕ ,t2)) (and (type? t1) (type? t2))] [`(,t1 → ,l ,t2) (and (type? t1) (level? l) (type? t2))] [`(μ ,x ,t) (and (symbol? x) (type? t))] [_ #f])) ;; Whether a given expression is a syntactically valid expression. ;; This does not account for context, and so all symbols are valid exprs. (define (expr? expr) (match expr ['sole #t] [n #:when (natural? n) #t] [b #:when (boolean? b) #t] ; Symbols are only valid if previously bound by `λ` or `case`. ; We can't check that here, however. [s #:when (symbol? s) #t] [`(,e : ,t) (and (expr? e) (type? t))] [`(type ,t1 ,t2 ,e) (and (type? t1) (type? t2) (expr? e))] ; Note that level must only introduce new variables as levels. [`(level ,l ,e) (and (symbol? l) (expr? e))] ; Kind of want to call ⇑ :: on analogy with : [`(,e ⇑ ,l) (and (expr? e) (level? l))] [(or `(new ,e) `(! ,e)) (expr? e)] ; [`(ptr ,a) (symbol? a)] [`(set ,e1 ,e2) (and (expr? e1) (expr? e2))] [`(inc ,e) (expr? e)] [`(if ,c ,e1 ,e2) (and (expr? c) (expr? e1) (expr? e2))] [`(pair ,e1 ,e2) (and (expr? e1) (expr? e2))] [(or `(car ,e) `(cdr ,e)) (expr? e)] [(or `(inl ,e) `(inr ,e)) (expr? e)] [`(case ,c (,x1 ⇒ ,e1) (,x2 ⇒ ,e2)) (and (symbol? x1) (symbol? x2) (expr? c) (expr? e1) (expr? e2))] [(or `(fold ,e) `(unfold ,e)) (expr? e)] [`(λ (,x : ,t) ,e) (and (symbol? x) (type? t) (expr? e))] [`(,e1 ,e2) (and (expr? e1) (expr? e2))] [_ #f])) ;; Whether a term is a value or a computation. What's that little rhyme about this again? ;; A value is, a computation/expr/term does? (define (value? expr) (match expr ['sole #t] [n #:when (natural? n) #t] [b #:when (boolean? b) #t] ; [`(,v : ,t) (and (expr? v) (type? t))] ; [`(type ,t1 ,t2 ,b) ; (and (type? t1) (type? t2) (value? v))] ; [(or `(level ,l ,v) `(,v ⇑ ,l)) ; (and (level? l) (value? v))] [`(ptr ,l ,a) (and (level? l) (symbol? a))] [`(pair ,v1 ,v2) (and (value? v1) (value? v2))] [(or `(inl ,v) `(inr ,v)) (value? v)] ; [(or `(fold ,v) `(unfold ,v)) (value? v)] [`(λ (,x : ,t) ,e ,env) (and (symbol? x) (type? t) (expr? e) (dict? env))] [_ #f])) (define (ptr? expr) (match expr [`(ptr ,l ,a) (and (level? l) (symbol? a))] [_ #f])) ;; Creates a new multiset from a list. (define/contract (list->multiset l) (-> list? dict?) (foldl (λ (x acc) (if (dict-has-key? acc x) (dict-set acc x (+ (dict-ref acc x) 1)) (dict-set acc x 1))) #hash() l)) ;; Creates a new list from a multiset. (define/contract (multiset->list m) (-> dict? list?) (foldl (λ (x acc) (append acc (build-list (dict-ref m x) (λ (_) x)))) '() (dict-keys m))) ;; Adds a symbol to a multiset. (define/contract (multiset-add m1 s) (-> dict? symbol? dict?) (if (dict-has-key? m1 s) (dict-set m1 s (+ (dict-ref m1 s) 1)) (dict-set m1 s 1))) ;; Queries two multisets for equality. (define/contract (multiset-eq m1 m2) (-> dict? dict? boolean?) (if (equal? (length m1) (length m2)) #f (foldl (λ (x acc) (if (and acc (dict-has-key? m1 x)) (equal? (dict-ref m1 x) (dict-ref m2 x)) acc)) #t (dict-keys m2)))) ;; Unions two multisets. Shared members take the maximum count of each other. (define/contract (multiset-union m1 m2) (-> dict? dict? dict?) (foldl (λ (x acc) (if (dict-has-key? acc x) (dict-set acc x (max (dict-ref acc x) (dict-ref m2 x))) (dict-set acc x (dict-ref m2 x)))) m1 (dict-keys m2))) ;; Intersects two multisets. Shared members take the minimum count of each other. (define/contract (multiset-intersect m1 m2) (-> dict? dict? dict?) (foldl (λ (x acc) (if (dict-has-key? m1 x) (dict-set acc x (min (dict-ref m1 x) (dict-ref m2 x))) acc)) #hash() (dict-keys m2))) ;; Checks if a level is at its "base" form. (define/contract (level-base? l) (-> level? boolean?) (match l [n #:when (natural? n) (zero? n)] [s #:when (symbol? s) #t] [`(+ ,s ... ,n) #:when (natural? n) (zero? n)] ; should be avoided [`(+ ,s ...) #t])) ;; Syntactic equality between levels is not trivial. ;; This helper function defines it. (define/contract (level-eq? l1 l2) (-> level? level? boolean?) (match* (l1 l2) [(n1 n2) #:when (and (natural? n1) (natural? n2)) (equal? n1 n2)] [(`(+ ,s1 ... ,n1) `(+ ,s2 ... ,n2)) #:when (and (natural? n1) (natural? n2)) (and (equal? n1 n2) (level-eq? `(+ ,@s1) `(+ ,@s2)))] [(`(+ ,s1 ...) `(+ ,s2 ...)) (multiset-eq (list->multiset s1) (list->multiset s2))] [(_ _) #f])) ;; Levels can carry natural numbers, and so we define a stratification between them. ;; Note: this returns FALSE if the levels are incomparable (i.e. (level-geq 'a 'b)) (define/contract (level-geq? l1 l2) (-> level? level? boolean?) (match* (l1 l2) [(n1 n2) #:when (and (natural? n1) (natural? n2)) (>= n1 n2)] [(s1 s2) #:when (and (symbol? s1) (symbol? s2)) (equal? s1 s2)] [(`(+ ,s1 ... ,n1) `(+ ,s2 ... ,n2)) #:when (and (natural? n1) (natural? n2)) (and (level-eq? `(+ ,@s1) `(+ ,@s2)) (level-geq? n1 n2))] [(`(+ ,s1 ... ,n) `(+ ,s2 ...)) #:when (natural? n) (level-eq? `(+ ,@s1) `(+ ,@s2))] [(`(+ ,s1 ...) `(+ ,s2 ...)) (multiset-eq (list->multiset s1) (multiset-intersect (list->multiset s1) (list->multiset s2)))] [(_ _) #f])) ;; We define a maximum of two levels. ;; This can return one of the two levels or an entirely new level. (define/contract (level-max l1 l2) (-> level? level? level?) (match* (l1 l2) [(n1 n2) #:when (and (natural? n1) (natural? n2)) (max n1 n2)] [(s1 s2) #:when (and (symbol? s1) (symbol? s2)) (if (equal? s1 s2) s1 `(+ ,s1 ,s2))] [(`(+ ,s1 ... ,n1) `(+ ,s2 ... ,n2)) #:when (and (natural? n1) (natural? n2)) (if (equal? s1 s2) `(+ ,@s1 ,(max n1 n2)) (level-union `(+ ,@s1) `(+ ,@s2)))] [(`(+ ,s1 ... ,n) `(+ ,s2 ...)) #:when (natural? n) (if (level-geq? s1 s2) `(+ ,@s1 ,n) (level-union `(+ ,@s1) `(+ ,@s2)))] [(`(+ ,s1 ...) `(+ ,s2 ... ,n)) #:when (natural? n) (if (level-geq? s2 s1) `(+ ,@s2 ,n) (level-union `(+ ,@s1) `(+ ,@s2)))] [(`(+ ,s ... ,n1) n2) #:when (and (natural? n1) (natural? n2)) `(+ ,s ... ,n1)] [(n1 `(+ ,s ... ,n2)) #:when (and (natural? n1) (natural? n2)) `(+ ,s ... ,n2)] [(`(+ ,s ...) n) #:when (natural? n) `(+ ,@s ,n)] [(n `(+ ,s ...)) #:when (natural? n) `(+ ,@s ,n)] [(`(+ ,s1 ...) `(+ ,s2 ...)) (level-union `(+ ,@s1) `(+ ,@s2))])) ;; A helper function to perform the union of levels. (define/contract (level-union l1 l2) (-> level-base? level-base? level-base?) (match* (l1 l2) [(0 l) l] [(l 0) l] [(`(+ ,s1 ...) `(+ ,s2 ...)) `(+ ,@(multiset->list (multiset-union (list->multiset s1) (list->multiset s2))))])) ;; We define addition in terms of our syntactic constructs. (define/contract (level-add l1 l2) (-> level? level? level?) (match* (l1 l2) [(n1 n2) #:when (and (natural? n1) (natural? n2)) (+ n1 n2)] [(s1 s2) #:when (and (symbol? s1) (symbol? s2)) `(+ ,s1 ,s2)] [(`(+ ,s1 ... ,n1) `(+ ,s2 ... ,n2)) #:when (and (natural? n1) (natural? n2)) (level-add (level-add `(+ ,@s1) `(+ ,@s2)) (+ n1 n2))] [(`(+ ,s1 ... ,n) `(+ ,s2 ...)) #:when (natural? n) (level-add (level-add `(+ ,@s1) `(+ ,@s2)) n)] [(`(+ ,s1 ...) `(+ ,s2 ... ,n)) #:when (natural? n) (level-add (level-add `(+ ,@s1) `(+ ,@s2)) n)] [(`(+ ,s ... ,n1) n2) #:when (and (natural? n1) (natural? n2)) `(+ ,@s ,(+ n1 n2))] [(n1 `(+ ,s ... ,n2)) #:when (and (natural? n1) (natural? n2)) `(+ ,@s ,(+ n1 n2))] [(`(+ ,s ...) n) #:when (natural? n) `(+ ,@s ,n)] [(n `(+ ,s ...)) #:when (natural? n) `(+ ,@s ,n)] [(`(+ ,s1 ...) `(+ ,s2 ...)) `(+ ,@s1 ,@s2)])) ;; Decrements a level by 1. ;; ASSUMPTION: the level is not a base level (i.e. there is some n to dec) (define/contract (level-dec l) (-> level? level?) (match l [n #:when (and (natural? n) (not (zero? n))) (- n 1)] [`(+ ,s ... 1) `(+ ,@s)] [`(+ ,s ... ,n) #:when (and (natural? n) (not (zero? n))) `(+ ,@s ,(- n 1))] [_ (err (format "attempting to decrement base level ~a" l))])) ;; Returns the "base" form of a level. (define/contract (level-base l) (-> level? level?) (match l [n #:when (natural? n) 0] [s #:when (symbol? s) s] [`(+ ,s ... ,n) #:when (natural? n) `(+ ,@s)] [`(+ ,s ...) `(+ ,@s)])) ;; Returns the "offset" portion of a level. (define/contract (level-offset l) (-> level? level?) (match l [n #:when (natural? n) n] [s #:when (symbol? s) 0] [`(+ ,s ... ,n) #:when (natural? n) n] [`(+ ,s ...) 0])) ;; Infers the level of a (well-formed) type in a context. ;; We need the context for type ascryption, and μ-types. ;; Otherwise, levels are syntactically inferred. ;; ASSUMPTION: the type is well-formed in the given context (i.e. all symbols bound). ;; This is not checked via contracts due to (presumably) massive performance overhead. (define/contract (level-type t Γ) (-> type? dict? level?) (match t [(or 'Unit 'Bool 'Nat) 0] [s #:when (symbol? s) 0] ; HACK: μ-type variables, not in Γ [`(Ref ,t) ; KNOB (let ([l (level-type t Γ)]) (if (level-base? l) l (level-add l 1)))] [(or `(,t1 × ,t2) `(,t1 ⊕ ,t2)) (level-max (level-type t1 Γ) (level-type t2 Γ))] [`(,t1 → ,l ,t2) ; KNOB (if (and (level-geq? l (level-type t1 Γ)) (level-geq? l (level-type t2 Γ))) l (err (format "annotated level ~a is less than inferred levels ~a and ~a!")))] [`(μ ,x ,t) (level-type t (dict-set Γ x `(μ ,x ,t)))])) ;; Infers the level of a (well-formed) expression. (define/contract (level-expr e Γ) (-> expr? dict? level?) (match e ['sole 0] [n #:when (natural? n) 0] [b #:when (boolean? b) 0] [x #:when (dict-has-key? Γ x) ; free variables (level-type (expand-whnf (dict-ref Γ x) Γ) Γ)] [s #:when (symbol? s) 0] ; local variables [`(,e : ,t) (let ([l1 (level-expr e Γ)] [l2 (level-type t Γ)]) (if (level-geq? l1 l2) l1 (err (format "annotated level ~a is less than inferred level ~a!" l1 l2))))] [`(type ,t1 ,t2 ,e) (level-expr e (dict-set Γ `(type ,t1) t2))] [`(level ,l ,e) ; NOTE: is this correct? (level-expr e Γ)] [`(,e ⇑ ,l) (level-add l (level-expr e Γ))] [`(new ,e) ; KNOB (let ([l (level-expr e Γ)]) (if (level-base? l) l (level-add l 1)))] [`(if ,c ,e1 ,e2) (level-max (level-expr c Γ) (level-max (level-expr e1 Γ) (level-expr e2 Γ)))] [`(case ,c (,x1 ⇒ ,e1) (,x2 ⇒ ,e2)) (level-max (level-expr c Γ) ; support shadowing (level-max (level-expr e1 (dict-remove Γ x1)) (level-expr e2 (dict-remove Γ x2))))] [`(λ (,x : ,_) ,e) ; support shadowing (level-expr e (dict-remove Γ x))] [(or `(! ,e)`(inc ,e) `(car ,e) `(cdr ,e) `(inl ,e) `(inr ,e) `(fold ,e) `(unfold ,e)) (level-expr e Γ)] [(or `(set ,e1 ,e2) `(pair ,e1 ,e2) `(,e1 ,e2)) (level-max (level-expr e1 Γ) (level-expr e2 Γ))])) ;; Whether a given type is a semantically valid type. ;; We assume any type in Γ is semantically valid. ;; Otherwise, we would infinitely recurse re: μ. (define/contract (well-formed? t Γ) (-> type? dict? boolean?) (match t [(or 'Unit 'Bool 'Nat) #t] [s #:when (symbol? s) (dict-has-key? Γ `(type s))] [`(Ref ,t) (well-formed? t Γ)] [(or `(,t1 × ,t2) `(,t1 ⊕ ,t2)) (and (well-formed? t1 Γ) (well-formed? t2 Γ))] [`(,t1 → ,l ,t2) (and (dict-has-key? Γ `(level ,l)) (well-formed? t1 Γ) (well-formed? t2 Γ))] [`(μ ,x ,t) ; check: this might infinitely recurse?? (well-formed? t (dict-set Γ `(type ,x) `(μ ,x ,t)))])) ;; Whether a given type at a given level is semantically valid. (define/contract (well-kinded? t l Γ) (-> type? level? dict? boolean?) (match t [(or 'Unit 'Bool 'Nat) (level-geq? l 0)] [s #:when (symbol? s) (if (dict-has-key? `(type ,s)) (well-kinded? (dict-ref Γ `(type ,t))) #f)] [`(Ref ,t) ; FIXME: this is not entirely correct. hrm. (if (level-base? l) (well-kinded? t l Γ) (well-kinded? t (level-dec l) Γ))] [(or `(,t1 × ,t2) `(,t1 ⊕ ,t2)) (and (well-kinded? t1 l Γ) (well-kinded? t1 l Γ))] [`(,t1 → ,k ,t2) (and (level-geq? l k) (well-kinded? t1 k Γ) (well-kinded? t2 k Γ))] [`(μ ,x ,t) ; HACK (well-kinded? t l (dict-set Γ `(type ,x) 'Unit))])) ;; Whether a given structure is the heap, in our model. ;; This is a quite useless function and is just here to note the model of the heap. ;; Our heap is a Dict[Level, List[Dict[Addr, Expr]]]. In other words: ;; - the heap is first stratified by algebraic levels, i.e. α, β, α+β, etc ;; - those heaps are then stratified by n: the level as a natural number. ;; - this is (define (heap? heap) (match heap [`((,level-var . (,subheap ...)) ...) (and (all? (λ (l) (level? l)) level-var) (all? (λ (n) (dict? n)) subheap))] [_ #f])) ;; Extends a list to have at least n+1 elements. Takes a default-generating procedure. (define/contract (list-extend l n default) (-> list? natural? procedure? list?) (if (>= n (length l)) (build-list (+ n 1) (λ (k) (if (< k (length l)) (list-ref l k) (default)))) l)) ;; Models the allocation of an (unsized) memory pointer at an arbitrary heap level. (define/contract (alloc! Σ l) (-> dict? level? ptr?) (let ([addr (gensym)] [base (level-base l)] [offset (level-offset l)]) (if (dict-has-key? Σ base) (let ([base-heap (dict-ref Σ base)]) (if (>= offset (length base-heap)) (dict-set! Σ base ; FIXME: we probably should error if location is occupied (let ([offset-heap (make-hash)]) (dict-set! offset-heap addr 'null) ; FIXME: probably should not be null (list-set (list-extend base-heap offset make-hash) offset offset-heap))) (let ([offset-heap (list-ref base-heap offset)]) (dict-set! offset-heap addr 'null)))) (dict-set! Σ base (let ([offset-heap (make-hash)]) (dict-set! offset-heap addr 'null) (list-set (build-list (+ offset 1) (λ (_) (make-hash))) offset offset-heap)))) `(ptr ,l ,addr))) ;; Updates the heap given a pointer to a memory location and a value. (define/contract (write! Σ p v) (-> dict? ptr? value? ptr?) (match p [`(ptr ,l ,a) (let ([base (level-base l)] [offset (level-offset l)]) (if (dict-has-key? Σ base) (let ([base-heap (dict-ref Σ base)]) (if (< offset (length base-heap)) (dict-set! (list-ref base-heap offset) a v) (err (format "writing to invalid memory location ~a!" p)))) (err (format "writing to invalid memory location ~a!" p))))]) p) ;; Returns the corresponding value of a pointer to a memory location on the heap. (define/contract (read! Σ p) (-> dict? ptr? value?) (match p [`(ptr ,l ,a) (let ([base (level-base l)] [offset (level-offset l)]) (if (dict-has-key? Σ base) (let ([base-heap (dict-ref Σ base)]) (if (< offset (length base-heap)) (dict-ref (list-ref base-heap offset) a) (err (format "reading from invalid memory location ~a!" p)))) (err (format "reading from invalid memory location ~a!" p))))])) ;; Models the deallocation of all memory locations of level `l` or higher. ;; For complexity and performance purposes, we only support deallocating base levels. (define/contract (dealloc! Σ l) (-> dict? level-base? void?) (for-each (λ (key) (if (level-geq? key l) (dict-remove! Σ key) (void))) (dict-keys Σ))) ;; Whether two types are equivalent in a context. ;; We define equivalence as equivalence up to α-renaming. (define/contract (equiv-type t1 t2 Γ) (-> type? type? dict? boolean?) (equiv-type-core t1 t2 Γ Γ)) (define (equiv-type-core t1 t2 Γ1 Γ2) (match* (t1 t2) ; bound identifiers: if a key exists in the context, look it up [(x1 x2) #:when (dict-has-key? Γ1 `(type ,x1)) (equiv-type-core (dict-ref Γ1 `(type ,x1)) x2 Γ1 Γ2)] [(x1 x2) #:when (dict-has-key? Γ2 `(type ,x2)) (equiv-type-core x1 (dict-ref Γ2 `(type ,x2)) Γ1 Γ2)] ; recursive types: self-referential names can be arbitrary [(`(μ ,x1 ,t1) `(μ ,x2 ,t2)) (let ([name gensym]) (equiv-type-core t1 t2 (dict-set Γ1 `(type ,x1) name) (dict-set Γ2 `(type ,x2) name)))] ; check for syntactic equivalence on remaining forms [(`(,l1 ...) `(,l2 ...)) (foldl (λ (x1 x2 acc) (if (equiv-type-core x1 x2 Γ1 Γ2) acc #f)) #t l1 l2)] [(v1 v2) (equal? v1 v2)])) ;; Whether two expressions are equivalent in a context. ;; We define equivalence as equivalence up to α-renaming. ; (define/contract (equiv-expr e1 e2 Γ) (-> expr? expr? dict? boolean?) ; (equiv-expr-core e1 e2 Γ Γ)) ; (define (equiv-expr-core e1 e2 Γ1 Γ2) ; (match* (e1 e2))) ;; Expands a type alias into weak-head normal form, for literal matching. (define/contract (expand-whnf t Γ) (-> type? dict? type?) (if (dict-has-key? Γ `(type ,t)) (expand-whnf (dict-ref Γ `(type ,t)) Γ) t)) ;; Replaces all references to a type alias with another alias. (define/contract (replace-type type key value) (-> type? type? type? type?) (match type ; Do not accidentally replace shadowed bindings [`(μ ,x _) #:when (equal? x key) type] [`(,e ...) `(,@(map (λ (x) (replace-type x key value)) e))] [x #:when (equal? x key) value] [v v])) ;; Evaluates an expression to a value. ;; Follows the call-by-value evaluation strategy. (define/contract (call-by-value expr) (-> expr? value?) (cbv-core expr #hash() (make-hash))) (define (cbv-core expr Γ Σ) ; ℓ (match expr ['sole 'sole] [n #:when (natural? n) n] [b #:when (boolean? b) b] [p #:when (dict-has-key? Σ p) p] [x #:when (dict-has-key? Γ x) (dict-ref Γ x)] [`(,e : ,t) (cbv-core e Γ Σ)] [`(type ,t1 ,t2 ,e) (cbv-core e (dict-set Γ `(type ,t1) t2) Σ)] ; The (level ...) syntax introduces new level *variables*. [`(level ,l ,e) (let ([v (cbv-core e (dict-set Γ `(level ,l) 'level) Σ)]) (dealloc! Σ l) v)] ; they are then freed at the end of scope [`(,e ⇑ ,l) (cbv-core e Γ Σ)] [`(new ,e) (let ([p (alloc! Σ (level-expr e Γ))]) (write! Σ p (cbv-core e Γ Σ)))] [`(! ,e) (match (cbv-core e Γ Σ) [`(ptr ,l ,a) (read! Σ `(ptr ,l ,a))] [e (err (format "attempting to deref unknown expression ~a, expected ptr" e))])] [`(set ,e1 ,e2) ; FIXME: we do NOT check levels before writing here (match (cbv-core e1 Γ Σ) [`(ptr ,l ,a) (write! Σ `(ptr ,l ,a) (cbv-core e2 Γ Σ))] [e (err (format "attempting to write to unknown expression ~a, expected ptr" e))])] [`(inc ,e) (match (cbv-core e Γ Σ) [n #:when (natural? n) (+ n 1)] [e (err (format "incrementing an unknown value ~a" e))])] [`(if ,c ,e1 ,e2) (match (cbv-core c Γ Σ) ['#t (cbv-core e1 Γ Σ)] ['#f (cbv-core e2 Γ Σ)] [e (err (format "calling if on unknown expression ~a" e))])] [`(pair ,e1 ,e2) `(pair ,(cbv-core e1 Γ Σ) ,(cbv-core e2 Γ Σ))] [`(car ,e) (match (cbv-core e Γ Σ) [`(pair ,e1 ,e2) e1] [e (err (format "calling car on unknown expression ~a" e))])] [`(cdr ,e) (match (cbv-core e Γ Σ) [`(pair ,e1 ,e2) e2] [e (err (format "calling cdr on unknown expression ~a" e))])] [`(inl ,e) `(inl ,(cbv-core e Γ Σ))] [`(inr ,e) `(inr ,(cbv-core e Γ Σ))] [`(case ,e (,x1 ⇒ ,e1) (,x2 ⇒ ,e2)) (match (cbv-core e Γ Σ) [`(inl ,e) (cbv-core e1 (dict-set Γ x1 e) Σ)] [`(inr ,e) (cbv-core e2 (dict-set Γ x2 e) Σ)] [e (err (format "calling case on unknown expression ~a" e))])] [`(fold ,e) `(fold ,(cbv-core e Γ Σ))] [`(unfold ,e) (match (cbv-core e Γ Σ) [`(fold ,e) e] [e (err (format "attempting to unfold unknown expression ~a" e))])] [`(λ (,x : ,t) ,e) `(λ (,x : ,t) ,e ,Γ)] [`(,e1 ,e2) (match (cbv-core e1 Γ Σ) [`(λ (,x : ,t) ,e1 ,env) (cbv-core e1 (dict-set env x (cbv-core e2 Γ Σ)) Σ)] [e1 (err (format "attempting to interpret arg ~a applied to unknown expression ~a" e2 e1))])] [e (err (format "attempting to interpret unknown expression ~a" e))])) ;; Checks that an expression is of a type, and returns #t or #f, or a bubbled-up error. ;; `with` must be a type in weak-head normal form for structural matching. (define/contract (check expr with) (-> expr? type? boolean?) (check-core expr with #hash())) (define (check-core expr with Γ) (match expr ['sole 'Unit] [n #:when (natural? n) 'Nat] [b #:when (boolean? b) 'Bool] ; We expand into weak-head normal form as the binding may be whatever. [x #:when (dict-has-key? Γ x) (expand-whnf (dict-ref Γ x) Γ)] [`(type ,t1 ,t2 ,e) (check-core e with (dict-set Γ `(type ,t1) t2))] [`(level ,l ,e) ; We add the level to the context just to note it is valid. (check-core e with (dict-set Γ `(level ,l) 'level))] [`(new ,e) (match with [`(Ref ,t) (check-core e t Γ)] [_ #f])] [`(! ,e) (check-core e `(Ref ,with) Γ)] [`(if ,c ,e1 ,e2) (and (check-core c 'Bool Γ) (check-core e1 with Γ) (check-core e2 with Γ))] [`(pair ,e1 ,e2) (match with [`(,t1 × ,t2) (and (check-core e1 t1 Γ) (check-core e2 t2 Γ))] [_ #f])] [`(inl ,e) (match with [`(,t1 ⊕ ,t2) (check-core e t1 Γ)] [_ #f])] [`(inr ,e) (match with [`(,t1 ⊕ ,t2) (check-core e t2 Γ)] [_ #f])] ; We do not technically need case in check form. ; We keep it here to avoid needing type annotations on `c`. [`(case ,c (,x1 ⇒ ,e1) (,x2 ⇒ ,e2)) (match (infer-core c Γ) [`(,a1 ⊕ ,a2) (and (check-core e1 with (dict-set Γ x1 a1)) (check-core e2 with (dict-set Γ x2 a2)))] [_ #f])] [`(fold ,e) (match with [`(μ ,x ,t) (check-core e t (dict-set Γ `(type ,x) `(μ ,x ,t)))] [_ #f])] [`(λ (,x : ,t) ,e) (match with [`(,t1 → ,l ,t2) ; KNOB (and (equiv-type t t1 Γ) (check-core e t2 (dict-set Γ x t)) (> l (level-expr e (dict-set Γ x t1))))] [`(,t1 → ,t2) (err (format "missing level annotation on function type"))] [_ #f])] [_ (equiv-type (infer-core expr Γ) with Γ)])) ;; Infers a type from a given expression, if possible. Errors out otherwise. ;; Returns a type in weak-head normal form for structural matching. (define/contract (infer expr) (-> expr? type?) (infer-core expr #hash())) ;; Γ is our context: a dictionary from symbols to types??? i forget actually ;; note: our context plays many roles. (define (infer-core expr Γ) (match expr ['sole 'Unit] [n #:when (natural? n) 'Nat] [b #:when (boolean? b) 'Bool] ; We expand into weak-head normal form as the binding may be to another binding. [x #:when (dict-has-key? Γ x) (expand-whnf (dict-ref Γ x) Γ)] [`(type ,t1 ,t2 ,e) (infer-core e (dict-set Γ `(type ,t1) t2))] [`(,e : ,t) (if (check-core e (expand-whnf t Γ) Γ) (expand-whnf t Γ) (err (format "expression ~a is not of annotated type ~a" e t)))] [`(level ,l ,e) ; We add the level to the context just to note it is valid. (infer-core e (dict-set Γ `(level ,l) 'level))] [`(,e ⇑ ,l) ; We retrieve the level from the context to check it is valid. (if (dict-has-key? Γ `(level ,(level-base l))) (infer-core e Γ) (err (format "level ~a not found in context, was it introduced?")))] [`(new ,e) `(Ref ,(infer-core e Γ))] [`(ptr ,a) (err (format "cannot infer type from raw pointer ~a" `(ptr ,a)))] [`(! ,e) (match (infer-core e Γ) [`(Ref ,t) t] [t (err (format "attempting to deref term ~a of type ~a" e t))])] [`(set ,e1 ,e2) ; FIXME: this does not account for explicit allocation syntax! (match (infer-core e1 Γ) ; should we check levels? [`(Ref ,t) (if (check-core e2 t Γ) 'Unit (err (format "attempting to update ~a: ~a with term ~a: ~a of differing type" e1 t e2 (infer-core e2 Γ))))] [t (err (format "attempting to update non-reference ~a: ~a" e1 t))])] [`(inc ,e) (if (check-core e 'Nat Γ) 'Nat (err (format "calling inc on incorrect type ~a, expected Nat" (infer-core e Γ))))] [`(if ,c ,e1 ,e2) (if (check-core c 'Bool Γ) (let ([t (infer-core e1 Γ)]) (if (check-core e2 t Γ) t (err (format "if ~a is not of consistent type!" `(if Bool ,t ,(infer-core e2 Γ)))))) (err (format "if ~a has incorrect type ~a on condition, expected Bool" c (infer-core c Γ))))] [`(pair ,e1 ,e2) `(,(infer-core e1 Γ) × ,(infer-core e2 Γ))] [`(car ,e) (match (infer-core e Γ) [`(,t1 × ,t2) t1] [t (err (format "calling car on incorrect type ~a, expected a product" t))])] [`(cdr ,e) (match (infer-core e Γ) [`(,t1 × ,t2) t2] [t (err (format "calling cdr on incorrect type ~a, expected a product" t))])] [`(inl ,e) (err (format "unable to infer the type of a raw inl"))] [`(inr ,e) (err (format "unable to infer the type of a raw inr"))] [`(case ,c (,x1 ⇒ ,e1) (,x2 ⇒ ,e2)) (match (infer-core c Γ) [`(,a1 ⊕ ,a2) (let ([b1 (infer-core e1 (dict-set Γ x1 a1))] [b2 (infer-core e2 (dict-set Γ x2 a2))]) (if (equiv-type b1 b2 Γ) b1 (err (format "case ~a is not of consistent type!" `(case (,a1 ⊕ ,a2) (,x1 ⇒ ,b1) (,x2 ⇒ ,b2))))))] [t (err (format "case has incorrect type ~a on condition, expected a sum" t))])] [`(unfold ,e) (match (infer-core e Γ) [`(μ ,x ,t) (replace-type t x `(μ ,x ,t))] [t (err (format "expected ~a to be of recursive type, got ~a" e t))])] [`(λ (,x : ,t1) ,e) ; KNOB (let* ([t2 (infer-core e (dict-set Γ x t1))] [t1 (expand-whnf t1 Γ)] [l (+ 1 (level-expr e (dict-set Γ x t1)))]) `(,t1 → ,l ,t2))] [`(,e1 ,e2) (match (infer-core e1 Γ) [`(,t1 → ,l ,t2) ; should we check levels here? probably redundant (if (check-core e2 t1 Γ) t2 (err (format "inferred argument type ~a does not match arg ~a of type ~a" t1 e2 (infer-core e2 Γ))))] [`(,t1 → ,t2) (err (format "missing level annotation on function type"))] [t (err (format "expected → type on application body, got ~a" t))])] [_ (err (format "attempting to infer an unknown expression ~a" expr))])) ;; Define aliases from higher-level constructs to lower-level core forms. (define (desugar expr) (match expr ; convenient aliases ['⟨⟩ 'sole] [`(ref ,e) (desugar `(new ,e))] [`(deref ,e) (desugar `(! ,e))] [`(,e :: ,k) (desugar `(,e ⇑ ,k))] ; set-with-continuation [`(set ,e1 ,e2 ,in) (desugar `(let (_ : Unit) (set ,e1 ,e2) ,in))] ; many forms of let. this lets us elide many typing annotations [`(let (,id : (,a → ,k ,b)) (λ (,x : ,a) ,e) ,in) (desugar `((λ (,id : (,a → ,k ,b)) ,in) (λ (,x : ,a) ,e)))] [`(let (,id : (,a → ,k ,b)) (λ ,x ,e) ,in) (desugar `((λ (,id : (,a → ,k ,b)) ,in) (λ (,x : ,a) ,e)))] [`(let (,id : (,a → ,b)) (λ (,x : ,a) ,e) ,in) (desugar `((λ (,id : (,a → ,b)) ,in) (λ (,x : ,a) ,e)))] [`(let (,id : (,a → ,b)) (λ ,x ,e) ,in) (desugar `((λ (,id : (,a → ,b)) ,in) (λ (,x : ,a) ,e)))] [`(let ,x (,e : ,t) ,in) (desugar `((λ (,x : ,t) ,in) (,e : ,t)))] [`(let ,x ,e ,in) (desugar `((λ ,x ,in) ,e))] [`(let ,x ,e) (desugar `(let ,x ,e sole))] ; desugar all remaining constructions [`(,e ...) `(,@(map desugar e))] [e e])) ;; (type DoublyLinkedList (μ Self ((Nat × ((Ref Self) × (Ref Self))) ⊕ Unit))) (check-equal? (call-by-value (desugar ' (let (next : ((μ Self ((Nat × ((Ref Self) × (Ref Self))) ⊕ Unit)) → 1 (μ Self ((Nat × ((Ref Self) × (Ref Self))) ⊕ Unit)))) (λ (self : (μ Self ((Nat × ((Ref Self) × (Ref Self))) ⊕ Unit))) (case (unfold self) (some ⇒ (! (cdr (cdr some)))) (none ⇒ (fold (inr sole))))) (let (my_list : (μ Self ((Nat × ((Ref Self) × (Ref Self))) ⊕ Unit))) (fold (inl (pair 413 (pair (new (inr sole)) (new (inr sole)))))) (next my_list))))) '(inr sole)) (check-equal? (infer (desugar ' (type DoublyLinkedList (μ Self ((Nat × ((Ref Self) × (Ref Self))) ⊕ Unit)) (λ (self : DoublyLinkedList) (case (unfold self) (some ⇒ ((! (cdr (cdr some))) : DoublyLinkedList)) (none ⇒ ((fold (inr sole)) : DoublyLinkedList))))))) '((μ Self ((Nat × ((Ref Self) × (Ref Self))) ⊕ Unit)) → 1 (μ Self ((Nat × ((Ref Self) × (Ref Self))) ⊕ Unit)))) (check-true (equiv-type (infer (desugar ' (type DoublyLinkedList (μ Self ((Nat × ((Ref Self) × (Ref Self))) ⊕ Unit)) (λ (self : DoublyLinkedList) (case (unfold self) (some ⇒ (! (cdr (cdr some)))) (none ⇒ ((fold (inr sole)) : DoublyLinkedList))))))) '(DoublyLinkedList → 1 DoublyLinkedList) #hash(((type DoublyLinkedList) . (μ Self ((Nat × ((Ref Self) × (Ref Self))) ⊕ Unit)))))) (check-true (check (desugar ' (type DoublyLinkedList (μ Self ((Nat × ((Ref Self) × (Ref Self))) ⊕ Unit)) (let (get : (DoublyLinkedList → 1 (Nat ⊕ Unit))) (λ self (case (unfold self) (some ⇒ (inl (car some))) (none ⇒ (inr sole)))) (let (prev : (DoublyLinkedList → 1 DoublyLinkedList)) (λ self (case (unfold self) (some ⇒ (! (car (cdr some)))) (none ⇒ ((fold (inr sole)) : DoublyLinkedList)))) (let (next : (DoublyLinkedList → 1 DoublyLinkedList)) (λ self (case (unfold self) (some ⇒ (! (cdr (cdr some)))) (none ⇒ ((fold (inr sole)) : DoublyLinkedList)))) (let (my_list : DoublyLinkedList) (fold (inl (pair 413 (pair (new ((fold (inr sole)) : DoublyLinkedList)) (new ((fold (inr sole)) : DoublyLinkedList)))))) (prev my_list))))))) 'DoublyLinkedList))