package ocaml-base-compiler
Utility functions for the Flambda intermediate language.
Access functions
val find_declaration :
Closure_id.t ->
Flambda.function_declarations ->
Flambda.function_declarationfind_declaration f decl raises Not_found if f is not in decl.
val find_declaration_variable :
Closure_id.t ->
Flambda.function_declarations ->
Variable.tfind_declaration_variable f decl raises Not_found if f is not in decl.
val find_free_variable :
Var_within_closure.t ->
Flambda.set_of_closures ->
Variable.tfind_free_variable v clos raises Not_found if c is not in clos.
Utility functions
val function_arity : Flambda.function_declaration -> intval variables_bound_by_the_closure :
Closure_id.t ->
Flambda.function_declarations ->
Variable.Set.tVariables "bound by a closure" are those variables free in the corresponding function's body that are neither:
- bound as parameters of that function; nor
- bound by the
letbinding that introduces the function declaration(s). In particular, iff,gandhare being introduced by a simultaneous, possibly mutually-recursiveletbinding then none off,gorhare bound in any of the closures forf,gandh.
If can_be_merged f1 f2 is true, it is safe to merge switch branches containing f1 and f2.
val description_of_toplevel_node : Flambda.t -> stringval make_closure_declaration :
is_classic_mode:bool ->
id:Variable.t ->
body:Flambda.t ->
params:Parameter.t list ->
Flambda.tval toplevel_substitution :
Variable.t Variable.Map.t ->
Flambda.expr ->
Flambda.exprval toplevel_substitution_named :
Variable.t Variable.Map.t ->
Flambda.named ->
Flambda.namedval bind :
bindings:(Variable.t * Flambda.named) list ->
body:Flambda.t ->
Flambda.tbind [var1, expr1; ...; varN, exprN] body binds using Immutable Let expressions the given (var, expr) pairs around the body.
val name_expr : name:Internal_variable_names.t -> Flambda.named -> Flambda.tval name_expr_from_var : var:Variable.t -> Flambda.named -> Flambda.tval initialize_symbols :
Flambda.program ->
(Symbol.t * Tag.t * Flambda.t list) listval imported_symbols : Flambda.program -> Symbol.Set.tval needed_import_symbols : Flambda.program -> Symbol.Set.tval introduce_needed_import_symbols : Flambda.program -> Flambda.programval root_symbol : Flambda.program -> Symbol.tval might_raise_static_exn : Flambda.named -> Static_exception.t -> boolReturns true iff the given term might raise the given static exception.
val make_closure_map : Flambda.program -> Set_of_closures_id.t Closure_id.Map.tCreates a map from closure IDs to set_of_closure IDs by iterating over all sets of closures in the given program.
val all_lifted_constants :
Flambda.program ->
(Symbol.t * Flambda.constant_defining_value) listThe definitions of all constants that have been lifted out to Let_symbol or Let_rec_symbol constructions.
val all_lifted_constants_as_map :
Flambda.program ->
Flambda.constant_defining_value Symbol.Map.tLike all_lifted_constant_symbols, but returns a map instead of a list.
val all_lifted_constant_sets_of_closures :
Flambda.program ->
Set_of_closures_id.Set.tThe identifiers of all constant sets of closures that have been lifted out to Let_symbol or Let_rec_symbol constructions.
val all_lifted_constant_closures : Flambda.program -> Closure_id.Set.tval all_sets_of_closures : Flambda.program -> Flambda.set_of_closures listAll sets of closures in the given program (whether or not bound to a symbol.)
val all_sets_of_closures_map :
Flambda.program ->
Flambda.set_of_closures Set_of_closures_id.Map.tval substitute_read_symbol_field_for_variables :
(Symbol.t * int list) Variable.Map.t ->
Flambda.t ->
Flambda.tmodule Switch_storer : sig ... endFor the compilation of switch statements.
val fun_vars_referenced_in_decls :
Flambda.function_declarations ->
closure_symbol:(Closure_id.t -> Symbol.t) ->
Variable.Set.t Variable.Map.tWithin a set of function declarations there is a set of function bodies, each of which may (or may not) reference one of the other functions in the same set. Initially such intra-set references are by Vars (known as "fun_var"s) but if the function is lifted by Lift_constants then the references will be translated to Symbols. This means that optimization passes that need to identify whether a given "fun_var" (i.e. a key in the funs map in a value of type function_declarations) is used in one of the function bodies need to examine the free_symbols as well as the free_variables members of function_declarations. This function makes that process easier by computing all used "fun_var"s in the bodies of the given set of function declarations, including the cases where the references are Symbols. The returned value is a map from "fun_var"s to the "fun_var"s (if any) used in the body of the function associated with that "fun_var".
val closures_required_by_entry_point :
entry_point:Closure_id.t ->
closure_symbol:(Closure_id.t -> Symbol.t) ->
Flambda.function_declarations ->
Variable.Set.tComputes the set of closure_id in the set of closures that are required used (transitively) the entry_point
val all_functions_parameters : Flambda.function_declarations -> Variable.Set.tval all_free_symbols : Flambda.function_declarations -> Symbol.Set.tval contains_stub : Flambda.function_declarations -> boolval clean_projections :
which_variables:Flambda.specialised_to Variable.Map.t ->
Flambda.specialised_to Variable.Map.tval projection_to_named : Projection.t -> Flambda.namedval parameters_specialised_to_the_same_variable :
function_decls:Flambda.function_declarations ->
specialised_args:Flambda.specialised_to Variable.Map.t ->
specialised_to_same_as list Variable.Map.tFor each parameter in a given set of function declarations and the usual specialised-args mapping, determine which other parameters are specialised to the same variable as that parameter. The result is presented as a map from fun_vars to lists, corresponding componentwise to the usual params list in the corresponding function declaration.