324 lines
8.9 KiB
OCaml
324 lines
8.9 KiB
OCaml
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(* The source calculus. *)
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module S = Top
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(* The target calculus. *)
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module T = C
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(* -------------------------------------------------------------------------- *)
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(* [interval i j f] constructs the list [[f i; f (i + 1); ...; f (j - 1)]]. *)
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let rec interval i j (f : int -> 'a) : 'a list =
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if i < j then
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f i :: interval (i + 1) j f
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else
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[]
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(* -------------------------------------------------------------------------- *)
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(* [index xs] constructs a list of pairs, where each element of [xs] is paired
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with its index. Indices are 0-based. *)
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let index (xs : 'a list) : (int * 'a) list =
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let n = List.length xs in
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let indices = interval 0 n (fun i -> i) in
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List.combine indices xs
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(* -------------------------------------------------------------------------- *)
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(* The number of fields of a block, not counting its tag. *)
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let block_num_fields b =
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match b with
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| S.Con (_, vs) ->
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List.length vs
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(* -------------------------------------------------------------------------- *)
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(* A simple-minded way of ensuring that every atom is printed as a
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distinct string is to concatenate the atom's hint and identity,
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with an underscore in between. This is guaranteed to rule out
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collisions. *)
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let var (x : S.variable) : T.ident =
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Printf.sprintf "%s_%d" (Atom.hint x) (Atom.identity x)
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let evar (x : S.variable) : T.expr =
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T.Name (var x)
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(* -------------------------------------------------------------------------- *)
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(* Predefined C types and functions. *)
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(* A universal type: every value is translated to a C value of type [univ].
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This is a union type (i.e., an untagged sum) of integers and pointers to
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memory blocks. *)
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let univ : T.type_spec =
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T.Named "univ"
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(* The type of integers. *)
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let int : T.type_spec =
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T.Named "int"
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(* The type [char] appears in the type of [main]. *)
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let char : T.type_spec =
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T.Named "char"
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let answer : T.type_spec =
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int
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(* Our functions never actually return, since they are tail recursive.
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We use [int] as their return type, since this is the return type of
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[main]. *)
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let exit : T.expr =
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T.Name "exit"
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let printf : T.expr =
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T.Name "printf"
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(* -------------------------------------------------------------------------- *)
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(* [declare x init] constructs a local variable declaration for a variable [x]
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of type [univ]. [x] is optionally initialized according to [init]. *)
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let declare (x : S.variable) (init : T.init option) : T.declaration =
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univ, None, [ T.Ident (var x), init ]
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(* -------------------------------------------------------------------------- *)
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(* Macro invocations. *)
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let macro m es : T.expr =
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(* We disguise a macro invocation as a procedure call. *)
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T.Call (T.Name m, es)
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(* -------------------------------------------------------------------------- *)
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(* Integer literals; conversions between [univ] and [int]. *)
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let iconst i : T.expr =
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T.Constant (Constant.Int64, string_of_int i)
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let to_int v : T.expr =
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macro "TO_INT" [ v ]
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(* This is an unsafe conversion, of course. *)
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let from_int v : T.expr =
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macro "FROM_INT" [ v ]
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(* -------------------------------------------------------------------------- *)
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(* The translation of values. *)
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let finish_op = function
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| S.OpAdd ->
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T.K.Add
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| S.OpSub ->
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T.K.Sub
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| S.OpMul ->
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T.K.Mult
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| S.OpDiv ->
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T.K.Div
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let rec finish_value (v : S.value) : T.expr =
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match v with
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| S.VVar x ->
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evar x
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| S.VLit i ->
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from_int (iconst i)
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| S.VBinOp (v1, op, v2) ->
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from_int (
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T.Op2 (
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finish_op op,
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to_int (finish_value v1),
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to_int (finish_value v2)
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)
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)
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let finish_values vs =
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List.map finish_value vs
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(* -------------------------------------------------------------------------- *)
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(* A macro for allocating a memory block. *)
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let alloc b : T.expr =
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T.Call (T.Name "ALLOC", [ iconst (block_num_fields b) ])
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(* -------------------------------------------------------------------------- *)
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(* Macros for reading and initializing the tag of a memory block. *)
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let read_tag (v : S.value) : T.expr =
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macro "GET_TAG" [ finish_value v ]
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let set_tag (x : S.variable) (tag : S.tag) : T.stmt =
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T.Expr (macro "SET_TAG" [ evar x; iconst tag ])
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(* -------------------------------------------------------------------------- *)
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(* Macros for reading and setting a field in a memory block. *)
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let read_field (v : S.value) (i : int) : T.expr =
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(* [i] is a 0-based field index. *)
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macro "GET_FIELD" [ finish_value v; iconst i ]
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let read_field (v : S.value) (i, x) (t : T.stmt list) : T.stmt list =
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(* [x] is a variable, which is declared and initialized with
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the content of the [i]th field of the block [v]. *)
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T.DeclStmt (declare x (Some (T.InitExpr (read_field v i)))) ::
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t
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let read_fields (v : S.value) xs (t : T.stmt list) : T.stmt list =
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(* [xs] are variables, which are declared and initialized with
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the contents of the fields of the block [v]. *)
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List.fold_right (read_field v) (index xs) t
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let set_field x i (v : S.value) : T.stmt =
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T.Expr (macro "SET_FIELD" [ evar x; iconst i; finish_value v ])
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(* -------------------------------------------------------------------------- *)
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(* A sequence of instructions for initializing a memory block. *)
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let init_block (x : S.variable) (b : S.block) : T.stmt list =
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match b with
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| S.Con (tag, vs) ->
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T.Comment "Initializing a memory block:" ::
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set_tag x tag ::
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List.mapi (set_field x) vs
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(* -------------------------------------------------------------------------- *)
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(* Function calls, as expressions and as statements. *)
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let ecall f args : T.expr =
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T.Call (f, args)
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let scall f args : T.stmt =
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T.Expr (ecall f args)
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(* -------------------------------------------------------------------------- *)
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(* The translation of terms. *)
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let rec finish_term (t : S.term) : C.stmt =
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match t with
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| S.Exit ->
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T.Compound [
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scall exit [ iconst 0 ]
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]
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| S.TailCall (f, vs) ->
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T.Return (Some (ecall (evar f) (finish_values vs)))
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| S.Print (v, t) ->
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T.Compound [
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scall printf [ T.Literal "%d\\n"; to_int (finish_value v) ];
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finish_term t
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]
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| S.LetVal (x, v1, t2) ->
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T.Compound [
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T.DeclStmt (declare x (Some (T.InitExpr (finish_value v1))));
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finish_term t2
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]
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| S.LetBlo (x, b1, t2) ->
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T.Compound (
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T.DeclStmt (declare x (Some (T.InitExpr (alloc b1)))) ::
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init_block x b1 @
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[ finish_term t2 ]
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)
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| S.Swi (v, bs) ->
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T.Switch (
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read_tag v,
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finish_branches v bs,
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default
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)
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and default : T.stmt =
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(* This default [switch] branch should never be taken. *)
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T.Compound [
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scall printf [ T.Literal "Oops! A nonexistent case has been taken.\\n" ];
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scall exit [ iconst 42 ];
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]
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and finish_branches v bs =
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List.map (finish_branch v) bs
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and finish_branch v (S.Branch (tag, xs, t)) : T.expr * T.stmt =
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iconst tag,
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T.Compound (read_fields v xs [finish_term t])
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(* -------------------------------------------------------------------------- *)
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(* Function declarations. *)
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(* We distinguish the function [main], whose type is imposed by the C standard,
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and ordinary functions, whose parameters have type [univ]. *)
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(* A parameter of an ordinary function has type [univ]. *)
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let param (x : S.variable) : T.param =
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univ, T.Ident (var x)
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(* A declaration of an ordinary function. *)
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let declare_ordinary_function f xs : T.declaration =
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answer, None, [ T.Function (None, T.Ident (var f), List.map param xs), None ]
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(* The declaration of the main function. *)
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let declare_main_function : T.declaration =
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let params = [
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int, T.Ident "argc";
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char, T.Pointer (T.Pointer (T.Ident "argv"))
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] in
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int, None, [ T.Function (None, T.Ident "main", params), None ]
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(* -------------------------------------------------------------------------- *)
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(* A function definition. *)
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type decl_or_fun =
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T.declaration_or_function
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let define (decl : T.declaration) (t : S.term) : decl_or_fun =
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T.Function (
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[], (* no comments *)
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false, (* not inlined *)
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decl,
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T.Compound [finish_term t]
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)
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let define_ordinary_function (S.Fun (f, xs, t)) : decl_or_fun =
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define (declare_ordinary_function f xs) t
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let define_main_function (t : S.term) : decl_or_fun =
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define declare_main_function t
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(* -------------------------------------------------------------------------- *)
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(* Because all functions are mutually recursive, their definitions must be
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preceded with their prototypes. *)
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let prototype (f : decl_or_fun) : decl_or_fun =
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match f with
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| T.Function (_, _, declaration, _) ->
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T.Decl ([], declaration)
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| T.Decl _ ->
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assert false
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let prototypes (fs : decl_or_fun list) : decl_or_fun list =
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List.map prototype fs @
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fs
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(* -------------------------------------------------------------------------- *)
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(* The translation of a complete program. *)
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let finish_program (S.Prog (decls, main) : S.program) : T.program =
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prototypes (
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define_main_function main ::
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List.map define_ordinary_function decls
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)
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