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|
(** Define base utilities for the extraction *)
open Pure
open TranslateCore
module C = Contexts
module RegionVarId = T.RegionVarId
module F = Format
(** The local logger *)
let log = L.pure_to_extract_log
type region_group_info = {
id : RegionGroupId.id;
(** The id of the region group.
Note that a simple way of generating unique names for backward
functions is to use the region group ids.
*)
region_names : string option list;
(** The names of the region variables included in this group.
Note that names are not always available...
*)
}
module StringSet = Collections.MakeSet (Collections.OrderedString)
module StringMap = Collections.MakeMap (Collections.OrderedString)
type name = Names.name
type type_name = Names.type_name
type global_name = Names.global_name
type fun_name = Names.fun_name
(** Characterizes a declaration.
Is in particular useful to derive the proper keywords to introduce the
declarations/definitions.
*)
type decl_kind =
| SingleNonRec
(** A single, non-recursive definition.
F*: [let x = ...]
Coq: [Definition x := ...]
*)
| SingleRec
(** A single, recursive definition.
F*: [let rec x = ...]
Coq: [Fixpoint x := ...]
*)
| MutRecFirst
(** The first definition of a group of mutually-recursive definitions.
F*: [type x0 = ... and x1 = ...]
Coq: [Fixpoint x0 := ... with x1 := ...]
*)
| MutRecInner
(** An inner definition in a group of mutually-recursive definitions. *)
| MutRecLast
(** The last definition in a group of mutually-recursive definitions.
We need this because in some theorem provers like Coq, we need to
delimit group of mutually recursive definitions (in particular, we
need to insert an end delimiter).
*)
| Assumed
(** An assumed definition.
F*: [assume val x]
Coq: [Axiom x : Type.]
*)
| Declared
(** Declare a type in an interface or a module signature.
Rem.: for now, in Coq, we don't declare module signatures: we
thus assume the corresponding declarations.
F*: [val x : Type0]
Coq: [Axiom x : Type.]
*)
(** Return [true] if the declaration is the last from its group of declarations.
We need this because in some provers (e.g., Coq), we need to delimit the
end of a (group of) definition(s) (in Coq: with a ".").
*)
let decl_is_last_from_group (kind : decl_kind) : bool =
match kind with
| SingleNonRec | SingleRec | MutRecLast | Assumed | Declared -> true
| MutRecFirst | MutRecInner -> false
let decl_is_from_rec_group (kind : decl_kind) : bool =
match kind with
| SingleNonRec | Assumed | Declared -> false
| SingleRec | MutRecFirst | MutRecInner | MutRecLast -> true
let decl_is_from_mut_rec_group (kind : decl_kind) : bool =
match kind with
| SingleNonRec | SingleRec | Assumed | Declared -> false
| MutRecFirst | MutRecInner | MutRecLast -> true
let decl_is_first_from_group (kind : decl_kind) : bool =
match kind with
| SingleNonRec | SingleRec | MutRecFirst | Assumed | Declared -> true
| MutRecLast | MutRecInner -> false
(** Return [true] if the declaration is not the last from its group of declarations.
We need this because in some provers (e.g., HOL4), we need to delimit
the inner declarations (with `/\` for instance).
*)
let decl_is_not_last_from_group (kind : decl_kind) : bool =
not (decl_is_last_from_group kind)
(* TODO: this should a module we give to a functor! *)
type type_decl_kind = Enum | Struct
(** A formatter's role is twofold:
1. Come up with name suggestions.
For instance, provided some information about a function (its basename,
information about the region group, etc.) it should come up with an
appropriate name for the forward/backward function.
It can of course apply many transformations, like changing to camel case/
snake case, adding prefixes/suffixes, etc.
2. Format some specific terms, like constants.
*)
type formatter = {
bool_name : string;
char_name : string;
int_name : integer_type -> string;
str_name : string;
type_decl_kind_to_qualif :
decl_kind -> type_decl_kind option -> string option;
(** Compute the qualified for a type definition/declaration.
For instance: "type", "and", etc.
Remark: can return [None] for some backends like HOL4.
*)
fun_decl_kind_to_qualif : decl_kind -> string option;
(** Compute the qualified for a function definition/declaration.
For instance: "let", "let rec", "and", etc.
Remark: can return [None] for some backends like HOL4.
*)
field_name : name -> FieldId.id -> string option -> string;
(** Inputs:
- type name
- field id
- field name
Note that fields don't always have names, but we still need to
generate some names if we want to extract the structures to records...
We might want to extract such structures to tuples, later, but field
access then causes trouble because not all provers accept syntax like
[x.3] where [x] is a tuple.
*)
variant_name : name -> string -> string;
(** Inputs:
- type name
- variant name
*)
struct_constructor : name -> string;
(** Structure constructors are used when constructing structure values.
For instance, in F*:
{[
type pair = { x : nat; y : nat }
let p : pair = Mkpair 0 1
]}
Inputs:
- type name
*)
type_name : type_name -> string;
(** Provided a basename, compute a type name. *)
global_name : global_name -> string;
(** Provided a basename, compute a global name. *)
fun_name :
fun_name ->
int ->
LoopId.id option ->
int ->
region_group_info option ->
bool * int ->
string;
(** Compute the name of a regular (non-assumed) function.
Inputs:
- function basename (TODO: shouldn't appear for assumed functions?...)
- number of loops in the function (useful to check if we need to use
indices to derive unique names for the loops for instance - if there is
exactly one loop, we don't need to use indices)
- loop id (if pertinent)
- number of region groups
- region group information in case of a backward function
([None] if forward function)
- pair:
- do we generate the forward function (it may have been filtered)?
- the number of *extracted backward functions* (same comment as for
the number of loops)
The number of extracted backward functions if not necessarily
equal to the number of region groups, because we may have
filtered some of them.
TODO: use the fun id for the assumed functions.
*)
termination_measure_name :
A.FunDeclId.id -> fun_name -> int -> LoopId.id option -> string;
(** Generates the name of the termination measure used to prove/reason about
termination. The generated code uses this clause where needed,
but its body must be defined by the user.
F* and Lean only.
Inputs:
- function id: this is especially useful to identify whether the
function is an assumed function or a local function
- function basename
- the number of loops in the parent function. This is used for
the same purpose as in {!field:fun_name}.
- loop identifier, if this is for a loop
*)
decreases_proof_name :
A.FunDeclId.id -> fun_name -> int -> LoopId.id option -> string;
(** Generates the name of the proof used to prove/reason about
termination. The generated code uses this clause where needed,
but its body must be defined by the user.
Lean only.
Inputs:
- function id: this is especially useful to identify whether the
function is an assumed function or a local function
- function basename
- the number of loops in the parent function. This is used for
the same purpose as in {!field:fun_name}.
- loop identifier, if this is for a loop
*)
opaque_pre : unit -> string;
(** The prefix to use for opaque definitions.
We need this because for some backends like Lean and Coq, we group
opaque definitions in module signatures, meaning that using those
definitions requires to prefix them with a module parameter name (such
as "opaque_defs.").
For instance, if we have an opaque function [f : int -> int], which
is used by the non-opaque function [g], we would generate (in Coq):
{[
(* The module signature declaring the opaque definitions *)
module type OpaqueDefs = {
f_fwd : int -> int
... (* Other definitions *)
}
(* The definitions generated for the non-opaque definitions *)
module Funs (opaque: OpaqueDefs) = {
let g ... =
...
opaque_defs.f_fwd
...
}
]}
Upon using [f] in [g], we don't directly use the the name "f_fwd",
but prefix it with the "opaque_defs." identifier.
*)
var_basename : StringSet.t -> string option -> ty -> string;
(** Generates a variable basename.
Inputs:
- the set of names used in the context so far
- the basename we got from the symbolic execution, if we have one
- the type of the variable (can be useful for heuristics, in order
not to always use "x" for instance, whenever naming anonymous
variables)
Note that once the formatter generated a basename, we add an index
if necessary to prevent name clashes: the burden of name clashes checks
is thus on the caller's side.
*)
type_var_basename : StringSet.t -> string -> string;
(** Generates a type variable basename. *)
append_index : string -> int -> string;
(** Appends an index to a name - we use this to generate unique
names: when doing so, the role of the formatter is just to concatenate
indices to names, the responsability of finding a proper index is
delegated to helper functions.
*)
extract_primitive_value : F.formatter -> bool -> primitive_value -> unit;
(** Format a constant value.
Inputs:
- formatter
- [inside]: if [true], the value should be wrapped in parentheses
if it is made of an application (ex.: [U32 3])
- the constant value
*)
extract_unop :
(bool -> texpression -> unit) ->
F.formatter ->
bool ->
unop ->
texpression ->
unit;
(** Format a unary operation
Inputs:
- a formatter for expressions (called on the argument of the unop)
- extraction context (see below)
- formatter
- expression formatter
- [inside]
- unop
- argument
*)
extract_binop :
(bool -> texpression -> unit) ->
F.formatter ->
bool ->
E.binop ->
integer_type ->
texpression ->
texpression ->
unit;
(** Format a binary operation
Inputs:
- a formatter for expressions (called on the arguments of the binop)
- extraction context (see below)
- formatter
- expression formatter
- [inside]
- binop
- argument 0
- argument 1
*)
}
(** We use identifiers to look for name clashes *)
type id =
| GlobalId of A.GlobalDeclId.id
| FunId of fun_id
| TerminationMeasureId of (A.fun_id * LoopId.id option)
(** The definition which provides the decreases/termination measure.
We insert calls to this clause to prove/reason about termination:
the body of those clauses must be defined by the user, in the
proper files.
More specifically:
- in F*, this is the content of the [decreases] clause.
Example:
========
{[
let rec sum (ls : list nat) : Tot nat (decreases ls) = ...
]}
- in Lean, this is the content of the [termination_by] clause.
*)
| DecreasesProofId of (A.fun_id * LoopId.id option)
(** The definition which provides the decreases/termination proof.
We insert calls to this clause to prove/reason about termination:
the body of those clauses must be defined by the user, in the
proper files.
More specifically:
- F* doesn't use this.
- in Lean, this is the tactic used by the [decreases_by] annotations.
*)
| TypeId of type_id
| StructId of type_id
(** We use this when we manipulate the names of the structure
constructors.
For instance, in F*:
{[
type pair = { x: nat; y : nat }
let p : pair = Mkpair 0 1
]}
*)
| VariantId of type_id * VariantId.id
(** If often happens that variant names must be unique (it is the case in
F* ) which is why we register them here.
*)
| FieldId of type_id * FieldId.id
(** If often happens that in the case of structures, the field names
must be unique (it is the case in F* ) which is why we register
them here.
*)
| TypeVarId of TypeVarId.id
| VarId of VarId.id
| UnknownId
(** Used for stored various strings like keywords, definitions which
should always be in context, etc. and which can't be linked to one
of the above.
*)
[@@deriving show, ord]
module IdOrderedType = struct
type t = id
let compare = compare_id
let to_string = show_id
let pp_t = pp_id
let show_t = show_id
end
module IdMap = Collections.MakeMap (IdOrderedType)
module IdSet = Collections.MakeSet (IdOrderedType)
(** The names map stores the mappings from names to identifiers and vice-versa.
We use it for lookups (during the translation) and to check for name clashes.
[id_to_string] is for debugging.
*)
type names_map = {
id_to_name : string IdMap.t;
name_to_id : id StringMap.t;
(** The name to id map is used to look for name clashes, and generate nice
debugging messages: if there is a name clash, it is useful to know
precisely which identifiers are mapped to the same name...
*)
names_set : StringSet.t;
opaque_ids : IdSet.t;
(** The set of opaque definitions.
See {!formatter.opaque_pre} for detailed explanations about why
we need to know which definitions are opaque to compute names.
Also note that the opaque ids don't contain the ids of the assumed
definitions. In practice, assumed definitions are opaque_defs. However, they
are not grouped in the opaque module, meaning we never need to
prefix them (with, say, "opaque_defs."): we thus consider them as non-opaque
with regards to the names map.
*)
}
let names_map_add (id_to_string : id -> string) (is_opaque : bool) (id : id)
(name : string) (nm : names_map) : names_map =
(* Check if there is a clash *)
(match StringMap.find_opt name nm.name_to_id with
| None -> () (* Ok *)
| Some clash ->
(* There is a clash: print a nice debugging message for the user *)
let id1 = "\n- " ^ id_to_string clash in
let id2 = "\n- " ^ id_to_string id in
let err =
"Name clash detected: the following identifiers are bound to the same \
name \"" ^ name ^ "\":" ^ id1 ^ id2
in
log#serror err;
raise (Failure err));
(* Sanity check *)
assert (not (StringSet.mem name nm.names_set));
(* Insert *)
let id_to_name = IdMap.add id name nm.id_to_name in
let name_to_id = StringMap.add name id nm.name_to_id in
let names_set = StringSet.add name nm.names_set in
let opaque_ids =
if is_opaque then IdSet.add id nm.opaque_ids else nm.opaque_ids
in
{ id_to_name; name_to_id; names_set; opaque_ids }
let names_map_add_assumed_type (id_to_string : id -> string) (id : assumed_ty)
(name : string) (nm : names_map) : names_map =
let is_opaque = false in
names_map_add id_to_string is_opaque (TypeId (Assumed id)) name nm
let names_map_add_assumed_struct (id_to_string : id -> string) (id : assumed_ty)
(name : string) (nm : names_map) : names_map =
let is_opaque = false in
names_map_add id_to_string is_opaque (StructId (Assumed id)) name nm
let names_map_add_assumed_variant (id_to_string : id -> string)
(id : assumed_ty) (variant_id : VariantId.id) (name : string)
(nm : names_map) : names_map =
let is_opaque = false in
names_map_add id_to_string is_opaque
(VariantId (Assumed id, variant_id))
name nm
let names_map_add_function (id_to_string : id -> string) (is_opaque : bool)
(fid : fun_id) (name : string) (nm : names_map) : names_map =
names_map_add id_to_string is_opaque (FunId fid) name nm
(** Make a (variable) basename unique (by adding an index).
We do this in an inefficient manner (by testing all indices starting from
0) but it shouldn't be a bottleneck.
Also note that at some point, we thought about trying to reuse names of
variables which are not used anymore, like here:
{[
let x = ... in
...
let x0 = ... in // We could use the name "x" if [x] is not used below
...
]}
However it is a good idea to keep things as they are for F*: as F* is
designed for extrinsic proofs, a proof about a function follows this
function's structure. The consequence is that we often end up
copy-pasting function bodies. As in the proofs (in assertions and
when calling lemmas) we often need to talk about the "past" (i.e.,
previous values), it is very useful to generate code where all variable
names are assigned at most once.
[append]: function to append an index to a string
*)
let basename_to_unique (names_set : StringSet.t)
(append : string -> int -> string) (basename : string) : string =
let rec gen (i : int) : string =
let s = append basename i in
if StringSet.mem s names_set then gen (i + 1) else s
in
if StringSet.mem basename names_set then gen 0 else basename
(** Extraction context.
Note that the extraction context contains information coming from the
LLBC AST (not only the pure AST). This is useful for naming, for instance:
we use the region information to generate the names of the backward
functions, etc.
*)
type extraction_ctx = {
trans_ctx : trans_ctx;
names_map : names_map;
fmt : formatter;
indent_incr : int;
(** The indent increment we insert whenever we need to indent more *)
use_opaque_pre : bool;
(** Do we use the "opaque_defs." prefix for the opaque definitions?
Opaque function definitions might refer opaque types: if we are in the
opaque module, we musn't use the "opaque_defs." prefix, otherwise we
use it.
Also see {!names_map.opaque_ids}.
*)
}
(** Debugging function, used when communicating name collisions to the user,
and also to print ids for internal debugging (in case of lookup miss for
instance).
*)
let id_to_string (id : id) (ctx : extraction_ctx) : string =
let global_decls = ctx.trans_ctx.global_context.global_decls in
let fun_decls = ctx.trans_ctx.fun_context.fun_decls in
let type_decls = ctx.trans_ctx.type_context.type_decls in
(* TODO: factorize the pretty-printing with what is in PrintPure *)
let get_type_name (id : type_id) : string =
match id with
| AdtId id ->
let def = TypeDeclId.Map.find id type_decls in
Print.name_to_string def.name
| Assumed aty -> show_assumed_ty aty
| Tuple -> raise (Failure "Unreachable")
in
match id with
| GlobalId gid ->
let name = (A.GlobalDeclId.Map.find gid global_decls).name in
"global name: " ^ Print.global_name_to_string name
| FunId fid -> (
match fid with
| FromLlbc (fid, lp_id, rg_id) ->
let fun_name =
match fid with
| Regular fid ->
Print.fun_name_to_string
(A.FunDeclId.Map.find fid fun_decls).name
| Assumed aid -> A.show_assumed_fun_id aid
in
let lp_kind =
match lp_id with
| None -> ""
| Some lp_id -> "loop " ^ LoopId.to_string lp_id ^ ", "
in
let fwd_back_kind =
match rg_id with
| None -> "forward"
| Some rg_id -> "backward " ^ RegionGroupId.to_string rg_id
in
"fun name (" ^ lp_kind ^ fwd_back_kind ^ "): " ^ fun_name
| Pure fid -> PrintPure.pure_assumed_fun_id_to_string fid)
| DecreasesProofId (fid, lid) ->
let fun_name =
match fid with
| Regular fid ->
Print.fun_name_to_string (A.FunDeclId.Map.find fid fun_decls).name
| Assumed aid -> A.show_assumed_fun_id aid
in
let loop =
match lid with
| None -> ""
| Some lid -> ", loop: " ^ LoopId.to_string lid
in
"decreases proof for function: " ^ fun_name ^ loop
| TerminationMeasureId (fid, lid) ->
let fun_name =
match fid with
| Regular fid ->
Print.fun_name_to_string (A.FunDeclId.Map.find fid fun_decls).name
| Assumed aid -> A.show_assumed_fun_id aid
in
let loop =
match lid with
| None -> ""
| Some lid -> ", loop: " ^ LoopId.to_string lid
in
"termination measure for function: " ^ fun_name ^ loop
| TypeId id -> "type name: " ^ get_type_name id
| StructId id -> "struct constructor of: " ^ get_type_name id
| VariantId (id, variant_id) ->
let variant_name =
match id with
| Tuple -> raise (Failure "Unreachable")
| Assumed Result ->
if variant_id = result_return_id then "@result::Return"
else if variant_id = result_fail_id then "@result::Fail"
else raise (Failure "Unreachable")
| Assumed Error ->
if variant_id = error_failure_id then "@error::Failure"
else if variant_id = error_out_of_fuel_id then "@error::OutOfFuel"
else raise (Failure "Unreachable")
| Assumed Option ->
if variant_id = option_some_id then "@option::Some"
else if variant_id = option_none_id then "@option::None"
else raise (Failure "Unreachable")
| Assumed (State | Vec | Fuel) -> raise (Failure "Unreachable")
| AdtId id -> (
let def = TypeDeclId.Map.find id type_decls in
match def.kind with
| Struct _ | Opaque -> raise (Failure "Unreachable")
| Enum variants ->
let variant = VariantId.nth variants variant_id in
Print.name_to_string def.name ^ "::" ^ variant.variant_name)
in
"variant name: " ^ variant_name
| FieldId (id, field_id) ->
let field_name =
match id with
| Tuple -> raise (Failure "Unreachable")
| Assumed (State | Result | Error | Fuel | Option) ->
raise (Failure "Unreachable")
| Assumed Vec ->
(* We can't directly have access to the fields of a vector *)
raise (Failure "Unreachable")
| AdtId id -> (
let def = TypeDeclId.Map.find id type_decls in
match def.kind with
| Enum _ | Opaque -> raise (Failure "Unreachable")
| Struct fields ->
let field = FieldId.nth fields field_id in
let field_name =
match field.field_name with
| None -> FieldId.to_string field_id
| Some name -> name
in
Print.name_to_string def.name ^ "." ^ field_name)
in
"field name: " ^ field_name
| UnknownId -> "keyword"
| TypeVarId id -> "type_var_id: " ^ TypeVarId.to_string id
| VarId id -> "var_id: " ^ VarId.to_string id
let ctx_add (is_opaque : bool) (id : id) (name : string) (ctx : extraction_ctx)
: extraction_ctx =
(* The id_to_string function to print nice debugging messages if there are
* collisions *)
let id_to_string (id : id) : string = id_to_string id ctx in
let names_map = names_map_add id_to_string is_opaque id name ctx.names_map in
{ ctx with names_map }
(** [with_opaque_pre]: if [true] and the definition is opaque, add the opaque prefix *)
let ctx_get (with_opaque_pre : bool) (id : id) (ctx : extraction_ctx) : string =
match IdMap.find_opt id ctx.names_map.id_to_name with
| Some s ->
let is_opaque = IdSet.mem id ctx.names_map.opaque_ids in
if with_opaque_pre && is_opaque then ctx.fmt.opaque_pre () ^ s else s
| None ->
log#serror ("Could not find: " ^ id_to_string id ctx);
raise Not_found
let ctx_get_global (with_opaque_pre : bool) (id : A.GlobalDeclId.id)
(ctx : extraction_ctx) : string =
ctx_get with_opaque_pre (GlobalId id) ctx
let ctx_get_function (with_opaque_pre : bool) (id : fun_id)
(ctx : extraction_ctx) : string =
ctx_get with_opaque_pre (FunId id) ctx
let ctx_get_local_function (with_opaque_pre : bool) (id : A.FunDeclId.id)
(lp : LoopId.id option) (rg : RegionGroupId.id option)
(ctx : extraction_ctx) : string =
ctx_get_function with_opaque_pre (FromLlbc (Regular id, lp, rg)) ctx
let ctx_get_type (with_opaque_pre : bool) (id : type_id) (ctx : extraction_ctx)
: string =
assert (id <> Tuple);
ctx_get with_opaque_pre (TypeId id) ctx
let ctx_get_local_type (with_opaque_pre : bool) (id : TypeDeclId.id)
(ctx : extraction_ctx) : string =
ctx_get_type with_opaque_pre (AdtId id) ctx
let ctx_get_assumed_type (id : assumed_ty) (ctx : extraction_ctx) : string =
(* In practice, the assumed types are opaque. However, assumed types
are never grouped in the opaque module, meaning we never need to
prefix them: we thus consider them as non-opaque with regards to the
names map.
*)
let is_opaque = false in
ctx_get_type is_opaque (Assumed id) ctx
let ctx_get_var (id : VarId.id) (ctx : extraction_ctx) : string =
let is_opaque = false in
ctx_get is_opaque (VarId id) ctx
let ctx_get_type_var (id : TypeVarId.id) (ctx : extraction_ctx) : string =
let is_opaque = false in
ctx_get is_opaque (TypeVarId id) ctx
let ctx_get_field (type_id : type_id) (field_id : FieldId.id)
(ctx : extraction_ctx) : string =
let is_opaque = false in
ctx_get is_opaque (FieldId (type_id, field_id)) ctx
let ctx_get_struct (with_opaque_pre : bool) (def_id : type_id)
(ctx : extraction_ctx) : string =
ctx_get with_opaque_pre (StructId def_id) ctx
let ctx_get_variant (def_id : type_id) (variant_id : VariantId.id)
(ctx : extraction_ctx) : string =
let is_opaque = false in
ctx_get is_opaque (VariantId (def_id, variant_id)) ctx
let ctx_get_decreases_proof (def_id : A.FunDeclId.id)
(loop_id : LoopId.id option) (ctx : extraction_ctx) : string =
let is_opaque = false in
ctx_get is_opaque (DecreasesProofId (Regular def_id, loop_id)) ctx
let ctx_get_termination_measure (def_id : A.FunDeclId.id)
(loop_id : LoopId.id option) (ctx : extraction_ctx) : string =
let is_opaque = false in
ctx_get is_opaque (TerminationMeasureId (Regular def_id, loop_id)) ctx
(** Generate a unique type variable name and add it to the context *)
let ctx_add_type_var (basename : string) (id : TypeVarId.id)
(ctx : extraction_ctx) : extraction_ctx * string =
let is_opaque = false in
let name = ctx.fmt.type_var_basename ctx.names_map.names_set basename in
let name =
basename_to_unique ctx.names_map.names_set ctx.fmt.append_index name
in
let ctx = ctx_add is_opaque (TypeVarId id) name ctx in
(ctx, name)
(** See {!ctx_add_type_var} *)
let ctx_add_type_vars (vars : (string * TypeVarId.id) list)
(ctx : extraction_ctx) : extraction_ctx * string list =
List.fold_left_map
(fun ctx (name, id) -> ctx_add_type_var name id ctx)
ctx vars
(** Generate a unique variable name and add it to the context *)
let ctx_add_var (basename : string) (id : VarId.id) (ctx : extraction_ctx) :
extraction_ctx * string =
let is_opaque = false in
let name =
basename_to_unique ctx.names_map.names_set ctx.fmt.append_index basename
in
let ctx = ctx_add is_opaque (VarId id) name ctx in
(ctx, name)
(** See {!ctx_add_var} *)
let ctx_add_vars (vars : var list) (ctx : extraction_ctx) :
extraction_ctx * string list =
List.fold_left_map
(fun ctx (v : var) ->
let name = ctx.fmt.var_basename ctx.names_map.names_set v.basename v.ty in
ctx_add_var name v.id ctx)
ctx vars
let ctx_add_type_params (vars : type_var list) (ctx : extraction_ctx) :
extraction_ctx * string list =
List.fold_left_map
(fun ctx (var : type_var) -> ctx_add_type_var var.name var.index ctx)
ctx vars
let ctx_add_type_decl_struct (def : type_decl) (ctx : extraction_ctx) :
extraction_ctx * string =
assert (match def.kind with Struct _ -> true | _ -> false);
let is_opaque = false in
let cons_name = ctx.fmt.struct_constructor def.name in
let ctx = ctx_add is_opaque (StructId (AdtId def.def_id)) cons_name ctx in
(ctx, cons_name)
let ctx_add_type_decl (def : type_decl) (ctx : extraction_ctx) : extraction_ctx
=
let is_opaque = def.kind = Opaque in
let def_name = ctx.fmt.type_name def.name in
let ctx = ctx_add is_opaque (TypeId (AdtId def.def_id)) def_name ctx in
ctx
let ctx_add_field (def : type_decl) (field_id : FieldId.id) (field : field)
(ctx : extraction_ctx) : extraction_ctx * string =
let is_opaque = false in
let name = ctx.fmt.field_name def.name field_id field.field_name in
let ctx = ctx_add is_opaque (FieldId (AdtId def.def_id, field_id)) name ctx in
(ctx, name)
let ctx_add_fields (def : type_decl) (fields : (FieldId.id * field) list)
(ctx : extraction_ctx) : extraction_ctx * string list =
List.fold_left_map
(fun ctx (vid, v) -> ctx_add_field def vid v ctx)
ctx fields
let ctx_add_variant (def : type_decl) (variant_id : VariantId.id)
(variant : variant) (ctx : extraction_ctx) : extraction_ctx * string =
let is_opaque = false in
let name = ctx.fmt.variant_name def.name variant.variant_name in
(* Add the type name prefix for Lean *)
let name =
if !Config.backend = Lean then
let type_name = ctx.fmt.type_name def.name in
type_name ^ "." ^ name
else name
in
let ctx =
ctx_add is_opaque (VariantId (AdtId def.def_id, variant_id)) name ctx
in
(ctx, name)
let ctx_add_variants (def : type_decl)
(variants : (VariantId.id * variant) list) (ctx : extraction_ctx) :
extraction_ctx * string list =
List.fold_left_map
(fun ctx (vid, v) -> ctx_add_variant def vid v ctx)
ctx variants
let ctx_add_struct (def : type_decl) (ctx : extraction_ctx) :
extraction_ctx * string =
assert (match def.kind with Struct _ -> true | _ -> false);
let is_opaque = false in
let name = ctx.fmt.struct_constructor def.name in
let ctx = ctx_add is_opaque (StructId (AdtId def.def_id)) name ctx in
(ctx, name)
let ctx_add_decreases_proof (def : fun_decl) (ctx : extraction_ctx) :
extraction_ctx =
let is_opaque = false in
let name =
ctx.fmt.decreases_proof_name def.def_id def.basename def.num_loops
def.loop_id
in
ctx_add is_opaque
(DecreasesProofId (Regular def.def_id, def.loop_id))
name ctx
let ctx_add_termination_measure (def : fun_decl) (ctx : extraction_ctx) :
extraction_ctx =
let is_opaque = false in
let name =
ctx.fmt.termination_measure_name def.def_id def.basename def.num_loops
def.loop_id
in
ctx_add is_opaque
(TerminationMeasureId (Regular def.def_id, def.loop_id))
name ctx
let ctx_add_global_decl_and_body (def : A.global_decl) (ctx : extraction_ctx) :
extraction_ctx =
(* TODO: update once the body id can be an option *)
let is_opaque = false in
let name = ctx.fmt.global_name def.name in
let decl = GlobalId def.def_id in
let body = FunId (FromLlbc (Regular def.body_id, None, None)) in
let ctx = ctx_add is_opaque decl (name ^ "_c") ctx in
let ctx = ctx_add is_opaque body (name ^ "_body") ctx in
ctx
let ctx_add_fun_decl (trans_group : bool * pure_fun_translation)
(def : fun_decl) (ctx : extraction_ctx) : extraction_ctx =
(* Sanity check: the function should not be a global body - those are handled
* separately *)
assert (not def.is_global_decl_body);
(* Lookup the LLBC def to compute the region group information *)
let def_id = def.def_id in
let llbc_def =
A.FunDeclId.Map.find def_id ctx.trans_ctx.fun_context.fun_decls
in
let sg = llbc_def.signature in
let num_rgs = List.length sg.regions_hierarchy in
let keep_fwd, (_, backs) = trans_group in
let num_backs = List.length backs in
let rg_info =
match def.back_id with
| None -> None
| Some rg_id ->
let rg = T.RegionGroupId.nth sg.regions_hierarchy rg_id in
let regions =
List.map
(fun rid -> T.RegionVarId.nth sg.region_params rid)
rg.regions
in
let region_names =
List.map (fun (r : T.region_var) -> r.name) regions
in
Some { id = rg_id; region_names }
in
let is_opaque = def.body = None in
(* Add the function name *)
let def_name =
ctx.fmt.fun_name def.basename def.num_loops def.loop_id num_rgs rg_info
(keep_fwd, num_backs)
in
ctx_add is_opaque
(FunId (FromLlbc (A.Regular def_id, def.loop_id, def.back_id)))
def_name ctx
type names_map_init = {
keywords : string list;
assumed_adts : (assumed_ty * string) list;
assumed_structs : (assumed_ty * string) list;
assumed_variants : (assumed_ty * VariantId.id * string) list;
assumed_llbc_functions :
(A.assumed_fun_id * RegionGroupId.id option * string) list;
assumed_pure_functions : (pure_assumed_fun_id * string) list;
}
(** Initialize a names map with a proper set of keywords/names coming from the
target language/prover. *)
let initialize_names_map (fmt : formatter) (init : names_map_init) : names_map =
let int_names = List.map fmt.int_name T.all_int_types in
let keywords =
List.concat
[
[ fmt.bool_name; fmt.char_name; fmt.str_name ]; int_names; init.keywords;
]
in
let names_set = StringSet.of_list keywords in
let name_to_id =
StringMap.of_list (List.map (fun x -> (x, UnknownId)) keywords)
in
let opaque_ids = IdSet.empty in
(* We fist initialize [id_to_name] as empty, because the id of a keyword is [UnknownId].
* Also note that we don't need this mapping for keywords: we insert keywords only
* to check collisions. *)
let id_to_name = IdMap.empty in
let nm = { id_to_name; name_to_id; names_set; opaque_ids } in
(* For debugging - we are creating bindings for assumed types and functions, so
* it is ok if we simply use the "show" function (those aren't simply identified
* by numbers) *)
let id_to_string = show_id in
(* Then we add:
* - the assumed types
* - the assumed struct constructors
* - the assumed variants
* - the assumed functions
*)
let nm =
List.fold_left
(fun nm (type_id, name) ->
names_map_add_assumed_type id_to_string type_id name nm)
nm init.assumed_adts
in
let nm =
List.fold_left
(fun nm (type_id, name) ->
names_map_add_assumed_struct id_to_string type_id name nm)
nm init.assumed_structs
in
let nm =
List.fold_left
(fun nm (type_id, variant_id, name) ->
names_map_add_assumed_variant id_to_string type_id variant_id name nm)
nm init.assumed_variants
in
let assumed_functions =
List.map
(fun (fid, rg, name) -> (FromLlbc (A.Assumed fid, None, rg), name))
init.assumed_llbc_functions
@ List.map (fun (fid, name) -> (Pure fid, name)) init.assumed_pure_functions
in
let nm =
(* In practice, the assumed function are opaque. However, assumed functions
are never grouped in the opaque module, meaning we never need to
prefix them: we thus consider them as non-opaque with regards to the
names map.
*)
let is_opaque = false in
List.fold_left
(fun nm (fid, name) ->
names_map_add_function id_to_string is_opaque fid name nm)
nm assumed_functions
in
(* Return *)
nm
let compute_type_decl_name (fmt : formatter) (def : type_decl) : string =
fmt.type_name def.name
(** Helper function: generate a suffix for a function name, i.e., generates
a suffix like "_loop", "loop1", etc. to append to a function name.
*)
let default_fun_loop_suffix (num_loops : int) (loop_id : LoopId.id option) :
string =
match loop_id with
| None -> ""
| Some loop_id ->
(* If this is for a loop, generally speaking, we append the loop index.
If this function admits only one loop, we omit it. *)
if num_loops = 1 then "_loop" else "_loop" ^ LoopId.to_string loop_id
(** A helper function: generates a function suffix from a region group
information.
TODO: move all those helpers.
*)
let default_fun_suffix (num_loops : int) (loop_id : LoopId.id option)
(num_region_groups : int) (rg : region_group_info option)
((keep_fwd, num_backs) : bool * int) : string =
let lp_suff = default_fun_loop_suffix num_loops loop_id in
(* There are several cases:
- [rg] is [Some]: this is a forward function:
- we add "_fwd"
- [rg] is [None]: this is a backward function:
- this function has one extracted backward function:
- if the forward function has been filtered, we add "_fwd_back":
the forward function is useless, so the unique backward function
takes its place, in a way
- otherwise we add "_back"
- this function has several backward functions: we add "_back" and an
additional suffix to identify the precise backward function
Note that we always add a suffix (in case there are no region groups,
we could not add the "_fwd" suffix) to prevent name clashes between
definitions (in particular between type and function definitions).
*)
let rg_suff =
match rg with
| None -> "_fwd"
| Some rg ->
assert (num_region_groups > 0 && num_backs > 0);
if num_backs = 1 then
(* Exactly one backward function *)
if not keep_fwd then "_fwd_back" else "_back"
else if
(* Several region groups/backward functions:
- if all the regions in the group have names, we use those names
- otherwise we use an index
*)
List.for_all Option.is_some rg.region_names
then
(* Concatenate the region names *)
"_back" ^ String.concat "" (List.map Option.get rg.region_names)
else (* Use the region index *)
"_back" ^ RegionGroupId.to_string rg.id
in
lp_suff ^ rg_suff
|