%% -*- erlang-indent-level: 2 -*-
%%
%% Licensed under the Apache License, Version 2.0 (the "License");
%% you may not use this file except in compliance with the License.
%% You may obtain a copy of the License at
%%
%% http://www.apache.org/licenses/LICENSE-2.0
%%
%% Unless required by applicable law or agreed to in writing, software
%% distributed under the License is distributed on an "AS IS" BASIS,
%% WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
%% See the License for the specific language governing permissions and
%% limitations under the License.
%%
%% @copyright 2000-2003 Richard Carlsson, 2006-2009 Tobias Lindahl
%% @author Richard Carlsson <[email protected]>
%% @author Tobias Lindahl <[email protected]>
%% @author Kostis Sagonas <[email protected]>
%% @author Manouk Manoukian
%% @doc Provides a representation of Erlang types.
%% The initial author of this file is Richard Carlsson (2000-2004).
%% In July 2006, the type representation was totally re-designed by
%% Tobias Lindahl. This is the representation which is used currently.
%% In late 2008, Manouk Manoukian and Kostis Sagonas added support for
%% opaque types to the structure-based representation of types.
%% During February and March 2009, Kostis Sagonas significantly
%% cleaned up the type representation and added spec declarations.
-module(erl_types).
-export([any_none/1,
any_none_or_unit/1,
lookup_record/3,
max/2,
min/2,
number_max/1, number_max/2,
number_min/1, number_min/2,
t_abstract_records/2,
t_any/0,
t_arity/0,
t_atom/0,
t_atom/1,
t_atoms/1,
t_atom_vals/1, t_atom_vals/2,
t_binary/0,
t_bitstr/0,
t_bitstr/2,
t_bitstr_base/1,
t_bitstr_concat/1,
t_bitstr_concat/2,
t_bitstr_match/2,
t_bitstr_unit/1,
t_bitstrlist/0,
t_boolean/0,
t_byte/0,
t_char/0,
t_collect_vars/1,
t_cons/0,
t_cons/2,
t_cons_hd/1, t_cons_hd/2,
t_cons_tl/1, t_cons_tl/2,
t_contains_opaque/1, t_contains_opaque/2,
t_decorate_with_opaque/3,
t_elements/1,
t_find_opaque_mismatch/3,
t_find_unknown_opaque/3,
t_fixnum/0,
t_non_neg_fixnum/0,
t_pos_fixnum/0,
t_float/0,
t_var_names/1,
t_form_to_string/1,
t_from_form/6,
t_from_form_without_remote/3,
t_from_form_check_remote/4,
t_check_record_fields/6,
t_from_range/2,
t_from_range_unsafe/2,
t_from_term/1,
t_fun/0,
t_fun/1,
t_fun/2,
t_fun_args/1, t_fun_args/2,
t_fun_arity/1, t_fun_arity/2,
t_fun_range/1, t_fun_range/2,
t_has_opaque_subtype/2,
t_has_var/1,
t_identifier/0,
%% t_improper_list/2,
t_inf/1,
t_inf/2,
t_inf/3,
t_inf_lists/2,
t_inf_lists/3,
t_integer/0,
t_integer/1,
t_non_neg_integer/0,
t_pos_integer/0,
t_integers/1,
t_iodata/0,
t_iolist/0,
t_is_any/1,
t_is_atom/1, t_is_atom/2,
t_is_any_atom/2, t_is_any_atom/3,
t_is_binary/1, t_is_binary/2,
t_is_bitstr/1, t_is_bitstr/2,
t_is_bitwidth/1,
t_is_boolean/1, t_is_boolean/2,
t_is_byte/1,
t_is_char/1,
t_is_cons/1, t_is_cons/2,
t_is_equal/2,
t_is_fixnum/1,
t_is_float/1, t_is_float/2,
t_is_fun/1, t_is_fun/2,
t_is_identifier/1,
t_is_instance/2,
t_is_integer/1, t_is_integer/2,
t_is_list/1,
t_is_map/1,
t_is_map/2,
t_is_matchstate/1,
t_is_nil/1, t_is_nil/2,
t_is_non_neg_integer/1,
t_is_none/1,
t_is_none_or_unit/1,
t_is_number/1, t_is_number/2,
t_is_opaque/1, t_is_opaque/2,
t_is_pid/1, t_is_pid/2,
t_is_port/1, t_is_port/2,
t_is_maybe_improper_list/1, t_is_maybe_improper_list/2,
t_is_reference/1, t_is_reference/2,
t_is_singleton/1,
t_is_singleton/2,
t_is_string/1,
t_is_subtype/2,
t_is_tuple/1, t_is_tuple/2,
t_is_unit/1,
t_is_var/1,
t_limit/2,
t_list/0,
t_list/1,
t_list_elements/1, t_list_elements/2,
t_list_termination/1, t_list_termination/2,
t_map/0,
t_map/1,
t_map/3,
t_map_entries/2, t_map_entries/1,
t_map_def_key/2, t_map_def_key/1,
t_map_def_val/2, t_map_def_val/1,
t_map_get/2, t_map_get/3,
t_map_is_key/2, t_map_is_key/3,
t_map_update/2, t_map_update/3,
t_map_pairwise_merge/4,
t_map_put/2, t_map_put/3,
t_matchstate/0,
t_matchstate/2,
t_matchstate_present/1,
t_matchstate_slot/2,
t_matchstate_slots/1,
t_matchstate_update_present/2,
t_matchstate_update_slot/3,
t_mfa/0,
t_module/0,
t_nil/0,
t_node/0,
t_none/0,
t_nonempty_list/0,
t_nonempty_list/1,
t_nonempty_string/0,
t_number/0,
t_number/1,
t_number_vals/1, t_number_vals/2,
t_opaque_from_records/1,
t_opaque_structure/1,
t_pid/0,
t_port/0,
t_maybe_improper_list/0,
%% t_maybe_improper_list/2,
t_product/1,
t_reference/0,
t_singleton_to_term/2,
t_string/0,
t_struct_from_opaque/2,
t_subst/2,
t_subtract/2,
t_subtract_list/2,
t_sup/1,
t_sup/2,
t_timeout/0,
t_to_string/1,
t_to_string/2,
t_to_tlist/1,
t_tuple/0,
t_tuple/1,
t_tuple_args/1, t_tuple_args/2,
t_tuple_size/1, t_tuple_size/2,
t_tuple_sizes/1,
t_tuple_subtypes/1,
t_tuple_subtypes/2,
t_unify/2,
t_unit/0,
t_unopaque/1, t_unopaque/2,
t_var/1,
t_var_name/1,
t_widen_to_number/1,
%% t_assign_variables_to_subtype/2,
type_is_defined/4,
record_field_diffs_to_string/2,
subst_all_vars_to_any/1,
lift_list_to_pos_empty/1, lift_list_to_pos_empty/2,
is_opaque_type/2,
is_erl_type/1,
atom_to_string/1,
var_table__new/0,
cache__new/0
]).
-compile({no_auto_import,[min/2,max/2,map_get/2]}).
-export_type([erl_type/0, opaques/0, type_table/0,
var_table/0, cache/0]).
%%-define(DEBUG, true).
-ifdef(DEBUG).
-define(debug(__A), __A).
-else.
-define(debug(__A), ok).
-endif.
%%=============================================================================
%%
%% Definition of the type structure
%%
%%=============================================================================
%%-----------------------------------------------------------------------------
%% Limits
%%
-define(REC_TYPE_LIMIT, 2).
-define(EXPAND_DEPTH, 16).
-define(EXPAND_LIMIT, 10000).
-define(TUPLE_TAG_LIMIT, 5).
-define(TUPLE_ARITY_LIMIT, 8).
-define(SET_LIMIT, 13).
-define(MAX_BYTE, 255).
-define(MAX_CHAR, 16#10ffff).
-define(UNIT_MULTIPLIER, 8).
-define(TAG_IMMED1_SIZE, 4).
-define(BITS, (erlang:system_info(wordsize) * 8) - ?TAG_IMMED1_SIZE).
-define(MAX_TUPLE_SIZE, (1 bsl 10)).
%%-----------------------------------------------------------------------------
%% Type tags and qualifiers
%%
-define(atom_tag, atom).
-define(binary_tag, binary).
-define(function_tag, function).
-define(identifier_tag, identifier).
-define(list_tag, list).
-define(map_tag, map).
-define(matchstate_tag, matchstate).
-define(nil_tag, nil).
-define(number_tag, number).
-define(opaque_tag, opaque).
-define(product_tag, product).
-define(tuple_set_tag, tuple_set).
-define(tuple_tag, tuple).
-define(union_tag, union).
-define(var_tag, var).
-type tag() :: ?atom_tag | ?binary_tag | ?function_tag | ?identifier_tag
| ?list_tag | ?map_tag | ?matchstate_tag | ?nil_tag | ?number_tag
| ?opaque_tag | ?product_tag
| ?tuple_tag | ?tuple_set_tag | ?union_tag | ?var_tag.
-define(float_qual, float).
-define(integer_qual, integer).
-define(nonempty_qual, nonempty).
-define(pid_qual, pid).
-define(port_qual, port).
-define(reference_qual, reference).
-define(unknown_qual, unknown).
-type qual() :: ?float_qual | ?integer_qual | ?nonempty_qual | ?pid_qual
| ?port_qual | ?reference_qual | ?unknown_qual | {_, _}.
%%-----------------------------------------------------------------------------
%% The type representation
%%
-define(any, any).
-define(none, none).
-define(unit, unit).
%% Generic constructor - elements can be many things depending on the tag.
-record(c, {tag :: tag(),
elements = [] :: term(),
qualifier = ?unknown_qual :: qual()}).
-opaque erl_type() :: ?any | ?none | ?unit | #c{}.
%%-----------------------------------------------------------------------------
%% Auxiliary types and convenient macros
%%
-type parse_form() :: erl_parse:abstract_type().
-type rng_elem() :: 'pos_inf' | 'neg_inf' | integer().
-record(int_set, {set :: [integer()]}).
-record(int_rng, {from :: rng_elem(), to :: rng_elem()}).
%% Note: the definition of #opaque{} was changed to 'mod' and 'name';
%% it used to be an ordsets of {Mod, Name} pairs. The Dialyzer version
%% was updated to 2.7 due to this change.
-record(opaque, {mod :: module(), name :: atom(),
args = [] :: [erl_type()], struct :: erl_type()}).
-define(atom(Set), #c{tag=?atom_tag, elements=Set}).
-define(bitstr(Unit, Base), #c{tag=?binary_tag, elements=[Unit,Base]}).
-define(float, ?number(?any, ?float_qual)).
-define(function(Domain, Range), #c{tag=?function_tag,
elements=[Domain, Range]}).
-define(identifier(Types), #c{tag=?identifier_tag, elements=Types}).
-define(integer(Types), ?number(Types, ?integer_qual)).
-define(int_range(From, To), ?integer(#int_rng{from=From, to=To})).
-define(int_set(Set), ?integer(#int_set{set=Set})).
-define(list(Types, Term, Size), #c{tag=?list_tag, elements=[Types,Term],
qualifier=Size}).
-define(nil, #c{tag=?nil_tag}).
-define(nonempty_list(Types, Term),?list(Types, Term, ?nonempty_qual)).
-define(number(Set, Qualifier), #c{tag=?number_tag, elements=Set,
qualifier=Qualifier}).
-define(map(Pairs,DefKey,DefVal),
#c{tag=?map_tag, elements={Pairs,DefKey,DefVal}}).
-define(opaque(Optypes), #c{tag=?opaque_tag, elements=Optypes}).
-define(product(Types), #c{tag=?product_tag, elements=Types}).
-define(tuple(Types, Arity, Qual), #c{tag=?tuple_tag, elements=Types,
qualifier={Arity, Qual}}).
-define(tuple_set(Tuples), #c{tag=?tuple_set_tag, elements=Tuples}).
-define(var(Id), #c{tag=?var_tag, elements=Id}).
-define(matchstate(P, Slots), #c{tag=?matchstate_tag, elements=[P,Slots]}).
-define(any_matchstate, ?matchstate(t_bitstr(), ?any)).
-define(byte, ?int_range(0, ?MAX_BYTE)).
-define(char, ?int_range(0, ?MAX_CHAR)).
-define(integer_pos, ?int_range(1, pos_inf)).
-define(integer_non_neg, ?int_range(0, pos_inf)).
-define(integer_neg, ?int_range(neg_inf, -1)).
-type opaques() :: [erl_type()] | 'universe'.
-type file_line() :: {file:name(), erl_anno:line()}.
-type record_key() :: {'record', atom()}.
-type type_key() :: {'type' | 'opaque', mfa()}.
-type field() :: {atom(), erl_parse:abstract_expr(), erl_type()}.
-type record_value() :: {file_line(),
[{RecordSize :: non_neg_integer(), [field()]}]}.
-type type_value() :: {{module(), file_line(),
erl_parse:abstract_type(), ArgNames :: [atom()]},
erl_type()}.
-type type_table() :: #{record_key() | type_key() =>
record_value() | type_value()}.
-opaque var_table() :: #{atom() => erl_type()}.
%%-----------------------------------------------------------------------------
%% Unions
%%
-define(union(List), #c{tag=?union_tag, elements=[_,_,_,_,_,_,_,_,_,_]=List}).
-define(atom_union(T), ?union([T,?none,?none,?none,?none,?none,?none,?none,?none,?none])).
-define(bitstr_union(T), ?union([?none,T,?none,?none,?none,?none,?none,?none,?none,?none])).
-define(function_union(T), ?union([?none,?none,T,?none,?none,?none,?none,?none,?none,?none])).
-define(identifier_union(T), ?union([?none,?none,?none,T,?none,?none,?none,?none,?none,?none])).
-define(list_union(T), ?union([?none,?none,?none,?none,T,?none,?none,?none,?none,?none])).
-define(number_union(T), ?union([?none,?none,?none,?none,?none,T,?none,?none,?none,?none])).
-define(tuple_union(T), ?union([?none,?none,?none,?none,?none,?none,T,?none,?none,?none])).
-define(matchstate_union(T), ?union([?none,?none,?none,?none,?none,?none,?none,T,?none,?none])).
-define(opaque_union(T), ?union([?none,?none,?none,?none,?none,?none,?none,?none,T,?none])).
-define(map_union(T), ?union([?none,?none,?none,?none,?none,?none,?none,?none,?none,T])).
-define(integer_union(T), ?number_union(T)).
-define(float_union(T), ?number_union(T)).
-define(nil_union(T), ?list_union(T)).
%%=============================================================================
%%
%% Primitive operations such as type construction and type tests
%%
%%=============================================================================
%%-----------------------------------------------------------------------------
%% Top and bottom
%%
-spec t_any() -> erl_type().
t_any() ->
?any.
-spec t_is_any(erl_type()) -> boolean().
t_is_any(Type) ->
do_opaque(Type, 'universe', fun is_any/1).
is_any(?any) -> true;
is_any(_) -> false.
-spec t_none() -> erl_type().
t_none() ->
?none.
-spec t_is_none(erl_type()) -> boolean().
t_is_none(?none) -> true;
t_is_none(_) -> false.
%%-----------------------------------------------------------------------------
%% Opaque types
%%
-spec t_opaque(module(), atom(), [_], erl_type()) -> erl_type().
t_opaque(Mod, Name, Args, Struct) ->
O = #opaque{mod = Mod, name = Name, args = Args, struct = Struct},
?opaque(set_singleton(O)).
-spec t_is_opaque(erl_type(), [erl_type()]) -> boolean().
t_is_opaque(?opaque(_) = Type, Opaques) ->
not is_opaque_type(Type, Opaques);
t_is_opaque(_Type, _Opaques) -> false.
-spec t_is_opaque(erl_type()) -> boolean().
t_is_opaque(?opaque(_)) -> true;
t_is_opaque(_) -> false.
-spec t_has_opaque_subtype(erl_type(), opaques()) -> boolean().
t_has_opaque_subtype(Type, Opaques) ->
do_opaque(Type, Opaques, fun has_opaque_subtype/1).
has_opaque_subtype(?union(Ts)) ->
lists:any(fun t_is_opaque/1, Ts);
has_opaque_subtype(T) ->
t_is_opaque(T).
-spec t_opaque_structure(erl_type()) -> erl_type().
t_opaque_structure(?opaque(Elements)) ->
t_sup([Struct || #opaque{struct = Struct} <- ordsets:to_list(Elements)]).
-spec t_contains_opaque(erl_type()) -> boolean().
t_contains_opaque(Type) ->
t_contains_opaque(Type, []).
%% Returns 'true' iff there is an opaque type that is *not* one of
%% the types of the second argument.
-spec t_contains_opaque(erl_type(), [erl_type()]) -> boolean().
t_contains_opaque(?any, _Opaques) -> false;
t_contains_opaque(?none, _Opaques) -> false;
t_contains_opaque(?unit, _Opaques) -> false;
t_contains_opaque(?atom(_Set), _Opaques) -> false;
t_contains_opaque(?bitstr(_Unit, _Base), _Opaques) -> false;
t_contains_opaque(?float, _Opaques) -> false;
t_contains_opaque(?function(Domain, Range), Opaques) ->
t_contains_opaque(Domain, Opaques)
orelse t_contains_opaque(Range, Opaques);
t_contains_opaque(?identifier(_Types), _Opaques) -> false;
t_contains_opaque(?int_range(_From, _To), _Opaques) -> false;
t_contains_opaque(?int_set(_Set), _Opaques) -> false;
t_contains_opaque(?integer(_Types), _Opaques) -> false;
t_contains_opaque(?list(Type, Tail, _), Opaques) ->
t_contains_opaque(Type, Opaques) orelse t_contains_opaque(Tail, Opaques);
t_contains_opaque(?map(_, _, _) = Map, Opaques) ->
list_contains_opaque(map_all_types(Map), Opaques);
t_contains_opaque(?matchstate(_P, _Slots), _Opaques) -> false;
t_contains_opaque(?nil, _Opaques) -> false;
t_contains_opaque(?number(_Set, _Tag), _Opaques) -> false;
t_contains_opaque(?opaque(_)=T, Opaques) ->
not is_opaque_type(T, Opaques)
orelse t_contains_opaque(t_opaque_structure(T));
t_contains_opaque(?product(Types), Opaques) ->
list_contains_opaque(Types, Opaques);
t_contains_opaque(?tuple(?any, _, _), _Opaques) -> false;
t_contains_opaque(?tuple(Types, _, _), Opaques) ->
list_contains_opaque(Types, Opaques);
t_contains_opaque(?tuple_set(_Set) = T, Opaques) ->
list_contains_opaque(t_tuple_subtypes(T), Opaques);
t_contains_opaque(?union(List), Opaques) ->
list_contains_opaque(List, Opaques);
t_contains_opaque(?var(_Id), _Opaques) -> false.
-spec list_contains_opaque([erl_type()], [erl_type()]) -> boolean().
list_contains_opaque(List, Opaques) ->
lists:any(fun(E) -> t_contains_opaque(E, Opaques) end, List).
%% t_find_opaque_mismatch/2 of two types should only be used if their
%% t_inf is t_none() due to some opaque type violation. However,
%% 'error' is returned if a structure mismatch is found.
%%
%% The first argument of the function is the pattern and its second
%% argument the type we are matching against the pattern.
-spec t_find_opaque_mismatch(erl_type(), erl_type(), [erl_type()]) ->
'error' | {'ok', erl_type(), erl_type()}.
t_find_opaque_mismatch(T1, T2, Opaques) ->
try t_find_opaque_mismatch(T1, T2, T2, Opaques)
catch throw:error -> error
end.
t_find_opaque_mismatch(?any, _Type, _TopType, _Opaques) -> error;
t_find_opaque_mismatch(?none, _Type, _TopType, _Opaques) -> throw(error);
t_find_opaque_mismatch(?list(T1, Tl1, _), ?list(T2, Tl2, _), TopType, Opaques) ->
t_find_opaque_mismatch_ordlists([T1, Tl1], [T2, Tl2], TopType, Opaques);
t_find_opaque_mismatch(T1, ?opaque(_) = T2, TopType, Opaques) ->
case is_opaque_type(T2, Opaques) of
false ->
case t_is_opaque(T1) andalso compatible_opaque_types(T1, T2) =/= [] of
true -> error;
false -> {ok, TopType, T2}
end;
true ->
t_find_opaque_mismatch(T1, t_opaque_structure(T2), TopType, Opaques)
end;
t_find_opaque_mismatch(?opaque(_) = T1, T2, TopType, Opaques) ->
%% The generated message is somewhat misleading:
case is_opaque_type(T1, Opaques) of
false ->
case t_is_opaque(T2) andalso compatible_opaque_types(T1, T2) =/= [] of
true -> error;
false -> {ok, TopType, T1}
end;
true ->
t_find_opaque_mismatch(t_opaque_structure(T1), T2, TopType, Opaques)
end;
t_find_opaque_mismatch(?product(T1), ?product(T2), TopType, Opaques) ->
t_find_opaque_mismatch_ordlists(T1, T2, TopType, Opaques);
t_find_opaque_mismatch(?tuple(T1, Arity, _), ?tuple(T2, Arity, _),
TopType, Opaques) ->
t_find_opaque_mismatch_ordlists(T1, T2, TopType, Opaques);
t_find_opaque_mismatch(?tuple(_, _, _) = T1, ?tuple_set(_) = T2,
TopType, Opaques) ->
Tuples1 = t_tuple_subtypes(T1),
Tuples2 = t_tuple_subtypes(T2),
t_find_opaque_mismatch_lists(Tuples1, Tuples2, TopType, Opaques);
t_find_opaque_mismatch(T1, ?union(U2), TopType, Opaques) ->
t_find_opaque_mismatch_lists([T1], U2, TopType, Opaques);
t_find_opaque_mismatch(T1, T2, _TopType, Opaques) ->
case t_is_none(t_inf(T1, T2, Opaques)) of
false -> error;
true -> throw(error)
end.
t_find_opaque_mismatch_ordlists(L1, L2, TopType, Opaques) ->
List = lists:zipwith(fun(T1, T2) ->
t_find_opaque_mismatch(T1, T2, TopType, Opaques)
end, L1, L2),
t_find_opaque_mismatch_list(List).
t_find_opaque_mismatch_lists(L1, L2, _TopType, Opaques) ->
List = [try t_find_opaque_mismatch(T1, T2, T2, Opaques)
catch throw:error -> error
end || T1 <- L1, T2 <- L2],
t_find_opaque_mismatch_list(List).
t_find_opaque_mismatch_list([]) -> throw(error);
t_find_opaque_mismatch_list([H|T]) ->
case H of
{ok, _T1, _T2} -> H;
error -> t_find_opaque_mismatch_list(T)
end.
-spec t_find_unknown_opaque(erl_type(), erl_type(), opaques()) ->
[pos_integer()].
%% The nice thing about using two types and t_inf() as compared to
%% calling t_contains_opaque/2 is that the traversal stops when
%% there is a mismatch which means that unknown opaque types "below"
%% the mismatch are not found.
t_find_unknown_opaque(_T1, _T2, 'universe') -> [];
t_find_unknown_opaque(T1, T2, Opaques) ->
try t_inf(T1, T2, {match, Opaques}) of
_ -> []
catch throw:{pos, Ns} -> Ns
end.
-spec t_decorate_with_opaque(erl_type(), erl_type(), [erl_type()]) -> erl_type().
%% The first argument can contain opaque types. The second argument
%% is assumed to be taken from the contract.
t_decorate_with_opaque(T1, T2, Opaques) ->
case
Opaques =:= [] orelse t_is_equal(T1, T2) orelse not t_contains_opaque(T2)
of
true -> T1;
false ->
T = t_inf(T1, T2),
case t_contains_opaque(T) of
false -> T1;
true ->
R = decorate(T1, T, Opaques),
?debug(case catch
not t_is_equal(t_unopaque(R), t_unopaque(T1))
orelse
t_is_equal(T1, T) andalso not t_is_equal(T1, R)
of
false -> ok;
_ ->
io:format("T1 = ~p,\n", [T1]),
io:format("T2 = ~p,\n", [T2]),
io:format("O = ~p,\n", [Opaques]),
io:format("erl_types:t_decorate_with_opaque(T1,T2,O).\n"),
throw({error, "Failed to handle opaque types"})
end),
R
end
end.
decorate(Type, ?none, _Opaques) -> Type;
decorate(?function(Domain, Range), ?function(D, R), Opaques) ->
?function(decorate(Domain, D, Opaques), decorate(Range, R, Opaques));
decorate(?list(Types, Tail, Size), ?list(Ts, Tl, _Sz), Opaques) ->
?list(decorate(Types, Ts, Opaques), decorate(Tail, Tl, Opaques), Size);
decorate(?product(Types), ?product(Ts), Opaques) ->
?product(list_decorate(Types, Ts, Opaques));
decorate(?tuple(_, _, _)=T, ?tuple(?any, _, _), _Opaques) -> T;
decorate(?tuple(?any, _, _)=T, ?tuple(_, _, _), _Opaques) -> T;
decorate(?tuple(Types, Arity, Tag), ?tuple(Ts, Arity, _), Opaques) ->
?tuple(list_decorate(Types, Ts, Opaques), Arity, Tag);
decorate(?tuple_set(List), ?tuple(_, Arity, _) = T, Opaques) ->
decorate_tuple_sets(List, [{Arity, [T]}], Opaques);
decorate(?tuple_set(List), ?tuple_set(L), Opaques) ->
decorate_tuple_sets(List, L, Opaques);
decorate(?union(List), T, Opaques) when T =/= ?any ->
?union(L) = force_union(T),
union_decorate(List, L, Opaques);
decorate(T, ?union(L), Opaques) when T =/= ?any ->
?union(List) = force_union(T),
union_decorate(List, L, Opaques);
decorate(Type, ?opaque(_)=T, Opaques) ->
decorate_with_opaque(Type, T, Opaques);
decorate(Type, _T, _Opaques) -> Type.
%% Note: it is important that #opaque.struct is a subtype of the
%% opaque type.
decorate_with_opaque(Type, ?opaque(Set2), Opaques) ->
case decoration(set_to_list(Set2), Type, Opaques, [], false) of
{[], false} -> Type;
{List, All} when List =/= [] ->
NewType = sup_opaque(List),
case All of
true -> NewType;
false -> t_sup(NewType, Type)
end
end.
decoration([#opaque{struct = S} = Opaque|OpaqueTypes], Type, Opaques,
NewOpaqueTypes0, All) ->
IsOpaque = is_opaque_type2(Opaque, Opaques),
I = t_inf(Type, S),
case not IsOpaque orelse t_is_none(I) of
true -> decoration(OpaqueTypes, Type, Opaques, NewOpaqueTypes0, All);
false ->
NewI = decorate(I, S, Opaques),
NewOpaque = combine(NewI, [Opaque]),
NewAll = All orelse t_is_equal(I, Type),
NewOpaqueTypes = NewOpaque ++ NewOpaqueTypes0,
decoration(OpaqueTypes, Type, Opaques, NewOpaqueTypes, NewAll)
end;
decoration([], _Type, _Opaques, NewOpaqueTypes, All) ->
{NewOpaqueTypes, All}.
-spec list_decorate([erl_type()], [erl_type()], opaques()) -> [erl_type()].
list_decorate(List, L, Opaques) ->
[decorate(Elem, E, Opaques) || {Elem, E} <- lists:zip(List, L)].
union_decorate(U1, U2, Opaques) ->
Union = union_decorate(U1, U2, Opaques, 0, []),
[A,B,F,I,L,N,T,M,_,Map] = U1,
[_,_,_,_,_,_,_,_,Opaque,_] = U2,
List = [A,B,F,I,L,N,T,M,Map],
DecList = [Dec ||
E <- List,
not t_is_none(E),
not t_is_none(Dec = decorate(E, Opaque, Opaques))],
t_sup([Union|DecList]).
union_decorate([?none|Left1], [_|Left2], Opaques, N, Acc) ->
union_decorate(Left1, Left2, Opaques, N, [?none|Acc]);
union_decorate([T1|Left1], [?none|Left2], Opaques, N, Acc) ->
union_decorate(Left1, Left2, Opaques, N+1, [T1|Acc]);
union_decorate([T1|Left1], [T2|Left2], Opaques, N, Acc) ->
union_decorate(Left1, Left2, Opaques, N+1, [decorate(T1, T2, Opaques)|Acc]);
union_decorate([], [], _Opaques, N, Acc) ->
if N =:= 0 -> ?none;
N =:= 1 ->
[Type] = [T || T <- Acc, T =/= ?none],
Type;
N >= 2 -> ?union(lists:reverse(Acc))
end.
decorate_tuple_sets(List, L, Opaques) ->
decorate_tuple_sets(List, L, Opaques, []).
decorate_tuple_sets([{Arity, Tuples}|List], [{Arity, Ts}|L], Opaques, Acc) ->
DecTs = decorate_tuples_in_sets(Tuples, Ts, Opaques),
decorate_tuple_sets(List, L, Opaques, [{Arity, DecTs}|Acc]);
decorate_tuple_sets([ArTup|List], L, Opaques, Acc) ->
decorate_tuple_sets(List, L, Opaques, [ArTup|Acc]);
decorate_tuple_sets([], _L, _Opaques, Acc) ->
?tuple_set(lists:reverse(Acc)).
decorate_tuples_in_sets([?tuple(Elements, _, ?any)], Ts, Opaques) ->
NewList = [list_decorate(Elements, Es, Opaques) || ?tuple(Es, _, _) <- Ts],
case t_sup([t_tuple(Es) || Es <- NewList]) of
?tuple_set([{_Arity, Tuples}]) -> Tuples;
?tuple(_, _, _)=Tuple -> [Tuple]
end;
decorate_tuples_in_sets(Tuples, Ts, Opaques) ->
decorate_tuples_in_sets(Tuples, Ts, Opaques, []).
decorate_tuples_in_sets([?tuple(Elements, Arity, Tag1) = T1|Tuples] = L1,
[?tuple(Es, Arity, Tag2)|Ts] = L2, Opaques, Acc) ->
if
Tag1 < Tag2 -> decorate_tuples_in_sets(Tuples, L2, Opaques, [T1|Acc]);
Tag1 > Tag2 -> decorate_tuples_in_sets(L1, Ts, Opaques, Acc);
Tag1 =:= Tag2 ->
NewElements = list_decorate(Elements, Es, Opaques),
NewAcc = [?tuple(NewElements, Arity, Tag1)|Acc],
decorate_tuples_in_sets(Tuples, Ts, Opaques, NewAcc)
end;
decorate_tuples_in_sets([T1|Tuples], L2, Opaques, Acc) ->
decorate_tuples_in_sets(Tuples, L2, Opaques, [T1|Acc]);
decorate_tuples_in_sets([], _L, _Opaques, Acc) ->
lists:reverse(Acc).
-spec t_opaque_from_records(type_table()) -> [erl_type()].
t_opaque_from_records(RecMap) ->
OpaqueRecMap =
maps:filter(fun(Key, _Value) ->
case Key of
{opaque, _Name, _Arity} -> true;
_ -> false
end
end, RecMap),
OpaqueTypeMap =
maps:map(fun({opaque, Name, _Arity},
{{Module, _FileLine, _Form, ArgNames}, _Type}) ->
%% Args = args_to_types(ArgNames),
%% List = lists:zip(ArgNames, Args),
%% TmpVarTab = maps:to_list(List),
%% Rep = t_from_form(Type, RecDict, TmpVarTab),
Rep = t_any(), % not used for anything right now
Args = [t_any() || _ <- ArgNames],
t_opaque(Module, Name, Args, Rep)
end, OpaqueRecMap),
[OpaqueType || {_Key, OpaqueType} <- maps:to_list(OpaqueTypeMap)].
%% Decompose opaque instances of type arg2 to structured types, in arg1
%% XXX: Same as t_unopaque
-spec t_struct_from_opaque(erl_type(), [erl_type()]) -> erl_type().
t_struct_from_opaque(?function(Domain, Range), Opaques) ->
?function(t_struct_from_opaque(Domain, Opaques),
t_struct_from_opaque(Range, Opaques));
t_struct_from_opaque(?list(Types, Term, Size), Opaques) ->
?list(t_struct_from_opaque(Types, Opaques),
t_struct_from_opaque(Term, Opaques), Size);
t_struct_from_opaque(?opaque(_) = T, Opaques) ->
case is_opaque_type(T, Opaques) of
true -> t_opaque_structure(T);
false -> T
end;
t_struct_from_opaque(?product(Types), Opaques) ->
?product(list_struct_from_opaque(Types, Opaques));
t_struct_from_opaque(?tuple(?any, _, _) = T, _Opaques) -> T;
t_struct_from_opaque(?tuple(Types, Arity, Tag), Opaques) ->
?tuple(list_struct_from_opaque(Types, Opaques), Arity, Tag);
t_struct_from_opaque(?tuple_set(Set), Opaques) ->
NewSet = [{Sz, [t_struct_from_opaque(T, Opaques) || T <- Tuples]}
|| {Sz, Tuples} <- Set],
?tuple_set(NewSet);
t_struct_from_opaque(?union(List), Opaques) ->
t_sup(list_struct_from_opaque(List, Opaques));
t_struct_from_opaque(Type, _Opaques) -> Type.
list_struct_from_opaque(Types, Opaques) ->
[t_struct_from_opaque(Type, Opaques) || Type <- Types].
%%-----------------------------------------------------------------------------
%% Unit type. Signals non termination.
%%
-spec t_unit() -> erl_type().
t_unit() ->
?unit.
-spec t_is_unit(erl_type()) -> boolean().
t_is_unit(?unit) -> true;
t_is_unit(_) -> false.
-spec t_is_none_or_unit(erl_type()) -> boolean().
t_is_none_or_unit(?none) -> true;
t_is_none_or_unit(?unit) -> true;
t_is_none_or_unit(_) -> false.
%%-----------------------------------------------------------------------------
%% Atoms and the derived type boolean
%%
-spec t_atom() -> erl_type().
t_atom() ->
?atom(?any).
-spec t_atom(atom()) -> erl_type().
t_atom(A) when is_atom(A) ->
?atom(set_singleton(A)).
-spec t_atoms([atom()]) -> erl_type().
t_atoms(List) when is_list(List) ->
t_sup([t_atom(A) || A <- List]).
-spec t_atom_vals(erl_type()) -> 'unknown' | [atom(),...].
t_atom_vals(Type) ->
t_atom_vals(Type, 'universe').
-spec t_atom_vals(erl_type(), opaques()) -> 'unknown' | [atom(),...].
t_atom_vals(Type, Opaques) ->
do_opaque(Type, Opaques, fun atom_vals/1).
atom_vals(?atom(?any)) -> unknown;
atom_vals(?atom(Set)) -> set_to_list(Set);
atom_vals(?opaque(_)) -> unknown;
atom_vals(Other) ->
?atom(_) = Atm = t_inf(t_atom(), Other),
atom_vals(Atm).
-spec t_is_atom(erl_type()) -> boolean().
t_is_atom(Type) ->
t_is_atom(Type, 'universe').
-spec t_is_atom(erl_type(), opaques()) -> boolean().
t_is_atom(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_atom1/1).
is_atom1(?atom(_)) -> true;
is_atom1(_) -> false.
-spec t_is_any_atom(atom(), erl_type()) -> boolean().
t_is_any_atom(Atom, SomeAtomsType) ->
t_is_any_atom(Atom, SomeAtomsType, 'universe').
-spec t_is_any_atom(atom(), erl_type(), opaques()) -> boolean().
t_is_any_atom(Atom, SomeAtomsType, Opaques) ->
do_opaque(SomeAtomsType, Opaques,
fun(AtomsType) -> is_any_atom(Atom, AtomsType) end).
is_any_atom(Atom, ?atom(?any)) when is_atom(Atom) -> false;
is_any_atom(Atom, ?atom(Set)) when is_atom(Atom) ->
set_is_singleton(Atom, Set);
is_any_atom(Atom, _) when is_atom(Atom) -> false.
%%------------------------------------
-spec t_is_boolean(erl_type()) -> boolean().
t_is_boolean(Type) ->
t_is_boolean(Type, 'universe').
-spec t_is_boolean(erl_type(), opaques()) -> boolean().
t_is_boolean(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_boolean/1).
-spec t_boolean() -> erl_type().
t_boolean() ->
?atom(set_from_list([false, true])).
is_boolean(?atom(?any)) -> false;
is_boolean(?atom(Set)) ->
case set_size(Set) of
1 -> set_is_element(true, Set) orelse set_is_element(false, Set);
2 -> set_is_element(true, Set) andalso set_is_element(false, Set);
N when is_integer(N), N > 2 -> false
end;
is_boolean(_) -> false.
%%-----------------------------------------------------------------------------
%% Binaries
%%
-spec t_binary() -> erl_type().
t_binary() ->
?bitstr(8, 0).
-spec t_is_binary(erl_type()) -> boolean().
t_is_binary(Type) ->
t_is_binary(Type, 'universe').
-spec t_is_binary(erl_type(), opaques()) -> boolean().
t_is_binary(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_binary/1).
is_binary(?bitstr(U, B)) ->
((U rem 8) =:= 0) andalso ((B rem 8) =:= 0);
is_binary(_) -> false.
%%-----------------------------------------------------------------------------
%% Bitstrings
%%
-spec t_bitstr() -> erl_type().
t_bitstr() ->
?bitstr(1, 0).
-spec t_bitstr(non_neg_integer(), non_neg_integer()) -> erl_type().
t_bitstr(U, B) ->
NewB =
if
U =:= 0 -> B;
B >= (U * (?UNIT_MULTIPLIER + 1)) ->
(B rem U) + U * ?UNIT_MULTIPLIER;
true ->
B
end,
?bitstr(U, NewB).
-spec t_bitstr_unit(erl_type()) -> non_neg_integer().
t_bitstr_unit(?bitstr(U, _)) -> U.
-spec t_bitstr_base(erl_type()) -> non_neg_integer().
t_bitstr_base(?bitstr(_, B)) -> B.
-spec t_bitstr_concat([erl_type()]) -> erl_type().
t_bitstr_concat(List) ->
t_bitstr_concat_1(List, t_bitstr(0, 0)).
t_bitstr_concat_1([T|Left], Acc) ->
t_bitstr_concat_1(Left, t_bitstr_concat(Acc, T));
t_bitstr_concat_1([], Acc) ->
Acc.
-spec t_bitstr_concat(erl_type(), erl_type()) -> erl_type().
t_bitstr_concat(T1, T2) ->
T1p = t_inf(t_bitstr(), T1),
T2p = t_inf(t_bitstr(), T2),
bitstr_concat(t_unopaque(T1p), t_unopaque(T2p)).
-spec t_bitstr_match(erl_type(), erl_type()) -> erl_type().
t_bitstr_match(T1, T2) ->
T1p = t_inf(t_bitstr(), T1),
T2p = t_inf(t_bitstr(), T2),
bitstr_match(t_unopaque(T1p), t_unopaque(T2p)).
-spec t_is_bitstr(erl_type()) -> boolean().
t_is_bitstr(Type) ->
t_is_bitstr(Type, 'universe').
-spec t_is_bitstr(erl_type(), opaques()) -> boolean().
t_is_bitstr(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_bitstr/1).
is_bitstr(?bitstr(_, _)) -> true;
is_bitstr(_) -> false.
%%-----------------------------------------------------------------------------
%% Matchstates
%%
-spec t_matchstate() -> erl_type().
t_matchstate() ->
?any_matchstate.
-spec t_matchstate(erl_type(), non_neg_integer()) -> erl_type().
t_matchstate(Init, 0) ->
?matchstate(Init, Init);
t_matchstate(Init, Max) when is_integer(Max) ->
Slots = [Init|[?none || _ <- lists:seq(1, Max)]],
?matchstate(Init, t_product(Slots)).
-spec t_is_matchstate(erl_type()) -> boolean().
t_is_matchstate(?matchstate(_, _)) -> true;
t_is_matchstate(_) -> false.
-spec t_matchstate_present(erl_type()) -> erl_type().
t_matchstate_present(Type) ->
case t_inf(t_matchstate(), Type) of
?matchstate(P, _) -> P;
_ -> ?none
end.
-spec t_matchstate_slot(erl_type(), non_neg_integer()) -> erl_type().
t_matchstate_slot(Type, Slot) ->
RealSlot = Slot + 1,
case t_inf(t_matchstate(), Type) of
?matchstate(_, ?any) -> ?any;
?matchstate(_, ?product(Vals)) when length(Vals) >= RealSlot ->
lists:nth(RealSlot, Vals);
?matchstate(_, ?product(_)) ->
?none;
?matchstate(_, SlotType) when RealSlot =:= 1 ->
SlotType;
_ ->
?none
end.
-spec t_matchstate_slots(erl_type()) -> erl_type().
t_matchstate_slots(?matchstate(_, Slots)) ->
Slots.
-spec t_matchstate_update_present(erl_type(), erl_type()) -> erl_type().
t_matchstate_update_present(New, Type) ->
case t_inf(t_matchstate(), Type) of
?matchstate(_, Slots) ->
?matchstate(New, Slots);
_ -> ?none
end.
-spec t_matchstate_update_slot(erl_type(), erl_type(), non_neg_integer()) -> erl_type().
t_matchstate_update_slot(New, Type, Slot) ->
RealSlot = Slot + 1,
case t_inf(t_matchstate(), Type) of
?matchstate(Pres, Slots) ->
NewSlots =
case Slots of
?any ->
?any;
?product(Vals) when length(Vals) >= RealSlot ->
NewTuple = setelement(RealSlot, list_to_tuple(Vals), New),
NewVals = tuple_to_list(NewTuple),
?product(NewVals);
?product(_) ->
?none;
_ when RealSlot =:= 1 ->
New;
_ ->
?none
end,
?matchstate(Pres, NewSlots);
_ ->
?none
end.
%%-----------------------------------------------------------------------------
%% Functions
%%
-spec t_fun() -> erl_type().
t_fun() ->
?function(?any, ?any).
-spec t_fun(erl_type()) -> erl_type().
t_fun(Range) ->
?function(?any, Range).
-spec t_fun([erl_type()] | arity(), erl_type()) -> erl_type().
t_fun(Domain, Range) when is_list(Domain) ->
?function(?product(Domain), Range);
t_fun(Arity, Range) when is_integer(Arity), 0 =< Arity, Arity =< 255 ->
?function(?product(lists:duplicate(Arity, ?any)), Range).
-spec t_fun_args(erl_type()) -> 'unknown' | [erl_type()].
t_fun_args(Type) ->
t_fun_args(Type, 'universe').
-spec t_fun_args(erl_type(), opaques()) -> 'unknown' | [erl_type()].
t_fun_args(Type, Opaques) ->
do_opaque(Type, Opaques, fun fun_args/1).
fun_args(?function(?any, _)) ->
unknown;
fun_args(?function(?product(Domain), _)) when is_list(Domain) ->
Domain.
-spec t_fun_arity(erl_type()) -> 'unknown' | non_neg_integer().
t_fun_arity(Type) ->
t_fun_arity(Type, 'universe').
-spec t_fun_arity(erl_type(), opaques()) -> 'unknown' | non_neg_integer().
t_fun_arity(Type, Opaques) ->
do_opaque(Type, Opaques, fun fun_arity/1).
fun_arity(?function(?any, _)) ->
unknown;
fun_arity(?function(?product(Domain), _)) ->
length(Domain).
-spec t_fun_range(erl_type()) -> erl_type().
t_fun_range(Type) ->
t_fun_range(Type, 'universe').
-spec t_fun_range(erl_type(), opaques()) -> erl_type().
t_fun_range(Type, Opaques) ->
do_opaque(Type, Opaques, fun fun_range/1).
fun_range(?function(_, Range)) ->
Range.
-spec t_is_fun(erl_type()) -> boolean().
t_is_fun(Type) ->
t_is_fun(Type, 'universe').
-spec t_is_fun(erl_type(), opaques()) -> boolean().
t_is_fun(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_fun/1).
is_fun(?function(_, _)) -> true;
is_fun(_) -> false.
%%-----------------------------------------------------------------------------
%% Identifiers. Includes ports, pids and refs.
%%
-spec t_identifier() -> erl_type().
t_identifier() ->
?identifier(?any).
-spec t_is_identifier(erl_type()) -> boolean().
t_is_identifier(?identifier(_)) -> true;
t_is_identifier(_) -> false.
%%------------------------------------
-spec t_port() -> erl_type().
t_port() ->
?identifier(set_singleton(?port_qual)).
-spec t_is_port(erl_type()) -> boolean().
t_is_port(Type) ->
t_is_port(Type, 'universe').
-spec t_is_port(erl_type(), opaques()) -> boolean().
t_is_port(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_port1/1).
is_port1(?identifier(?any)) -> false;
is_port1(?identifier(Set)) -> set_is_singleton(?port_qual, Set);
is_port1(_) -> false.
%%------------------------------------
-spec t_pid() -> erl_type().
t_pid() ->
?identifier(set_singleton(?pid_qual)).
-spec t_is_pid(erl_type()) -> boolean().
t_is_pid(Type) ->
t_is_pid(Type, 'universe').
-spec t_is_pid(erl_type(), opaques()) -> boolean().
t_is_pid(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_pid1/1).
is_pid1(?identifier(?any)) -> false;
is_pid1(?identifier(Set)) -> set_is_singleton(?pid_qual, Set);
is_pid1(_) -> false.
%%------------------------------------
-spec t_reference() -> erl_type().
t_reference() ->
?identifier(set_singleton(?reference_qual)).
-spec t_is_reference(erl_type()) -> boolean().
t_is_reference(Type) ->
t_is_reference(Type, 'universe').
-spec t_is_reference(erl_type(), opaques()) -> boolean().
t_is_reference(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_reference1/1).
is_reference1(?identifier(?any)) -> false;
is_reference1(?identifier(Set)) -> set_is_singleton(?reference_qual, Set);
is_reference1(_) -> false.
%%-----------------------------------------------------------------------------
%% Numbers are divided into floats, integers, chars and bytes.
%%
-spec t_number() -> erl_type().
t_number() ->
?number(?any, ?unknown_qual).
-spec t_number(integer()) -> erl_type().
t_number(X) when is_integer(X) ->
t_integer(X).
-spec t_is_number(erl_type()) -> boolean().
t_is_number(Type) ->
t_is_number(Type, 'universe').
-spec t_is_number(erl_type(), opaques()) -> boolean().
t_is_number(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_number/1).
is_number(?number(_, _)) -> true;
is_number(_) -> false.
%% Currently, the type system collapses all floats to ?float and does
%% not keep any information about their values. As a result, the list
%% that this function returns contains only integers.
-spec t_number_vals(erl_type()) -> 'unknown' | [integer(),...].
t_number_vals(Type) ->
t_number_vals(Type, 'universe').
-spec t_number_vals(erl_type(), opaques()) -> 'unknown' | [integer(),...].
t_number_vals(Type, Opaques) ->
do_opaque(Type, Opaques, fun number_vals/1).
number_vals(?int_set(Set)) -> set_to_list(Set);
number_vals(?number(_, _)) -> unknown;
number_vals(?opaque(_)) -> unknown;
number_vals(Other) ->
Inf = t_inf(Other, t_number()),
false = t_is_none(Inf), % sanity check
number_vals(Inf).
%%------------------------------------
-spec t_float() -> erl_type().
t_float() ->
?float.
-spec t_is_float(erl_type()) -> boolean().
t_is_float(Type) ->
t_is_float(Type, 'universe').
-spec t_is_float(erl_type(), opaques()) -> boolean().
t_is_float(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_float1/1).
is_float1(?float) -> true;
is_float1(_) -> false.
%%------------------------------------
-spec t_integer() -> erl_type().
t_integer() ->
?integer(?any).
-spec t_integer(integer()) -> erl_type().
t_integer(I) when is_integer(I) ->
?int_set(set_singleton(I)).
-spec t_integers([integer()]) -> erl_type().
t_integers(List) when is_list(List) ->
t_sup([t_integer(I) || I <- List]).
-spec t_is_integer(erl_type()) -> boolean().
t_is_integer(Type) ->
t_is_integer(Type, 'universe').
-spec t_is_integer(erl_type(), opaques()) -> boolean().
t_is_integer(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_integer1/1).
is_integer1(?integer(_)) -> true;
is_integer1(_) -> false.
%%------------------------------------
-spec t_byte() -> erl_type().
t_byte() ->
?byte.
-spec t_is_byte(erl_type()) -> boolean().
t_is_byte(?int_range(neg_inf, _)) -> false;
t_is_byte(?int_range(_, pos_inf)) -> false;
t_is_byte(?int_range(From, To))
when is_integer(From), From >= 0, is_integer(To), To =< ?MAX_BYTE -> true;
t_is_byte(?int_set(Set)) ->
(set_min(Set) >= 0) andalso (set_max(Set) =< ?MAX_BYTE);
t_is_byte(_) -> false.
%%------------------------------------
-spec t_char() -> erl_type().
t_char() ->
?char.
-spec t_is_char(erl_type()) -> boolean().
t_is_char(?int_range(neg_inf, _)) -> false;
t_is_char(?int_range(_, pos_inf)) -> false;
t_is_char(?int_range(From, To))
when is_integer(From), From >= 0, is_integer(To), To =< ?MAX_CHAR -> true;
t_is_char(?int_set(Set)) ->
(set_min(Set) >= 0) andalso (set_max(Set) =< ?MAX_CHAR);
t_is_char(_) -> false.
%%-----------------------------------------------------------------------------
%% Lists
%%
-spec t_cons() -> erl_type().
t_cons() ->
?nonempty_list(?any, ?any).
%% Note that if the tail argument can be a list, we must collapse the
%% content of the list to include both the content of the tail list
%% and the head of the cons. If for example the tail argument is any()
%% then there can be any list in the tail and the content of the
%% returned list must be any().
-spec t_cons(erl_type(), erl_type()) -> erl_type().
t_cons(?none, _) -> ?none;
t_cons(_, ?none) -> ?none;
t_cons(?unit, _) -> ?none;
t_cons(_, ?unit) -> ?none;
t_cons(Hd, ?nil) ->
?nonempty_list(Hd, ?nil);
t_cons(Hd, ?list(Contents, Termination, _)) ->
?nonempty_list(t_sup(Contents, Hd), Termination);
t_cons(Hd, Tail) ->
case cons_tail(t_inf(Tail, t_maybe_improper_list())) of
?list(Contents, Termination, _Size) ->
%% Collapse the list part of the termination but keep the
%% non-list part intact.
NewTermination = t_sup(t_subtract(Tail, t_maybe_improper_list()),
Termination),
?nonempty_list(t_sup(Hd, Contents), NewTermination);
?nil -> ?nonempty_list(Hd, Tail);
?none -> ?nonempty_list(Hd, Tail);
?unit -> ?none
end.
cons_tail(Type) ->
do_opaque(Type, 'universe', fun(T) -> T end).
-spec t_is_cons(erl_type()) -> boolean().
t_is_cons(Type) ->
t_is_cons(Type, 'universe').
-spec t_is_cons(erl_type(), opaques()) -> boolean().
t_is_cons(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_cons/1).
is_cons(?nonempty_list(_, _)) -> true;
is_cons(_) -> false.
-spec t_cons_hd(erl_type()) -> erl_type().
t_cons_hd(Type) ->
t_cons_hd(Type, 'universe').
-spec t_cons_hd(erl_type(), opaques()) -> erl_type().
t_cons_hd(Type, Opaques) ->
do_opaque(Type, Opaques, fun cons_hd/1).
cons_hd(?nonempty_list(Contents, _Termination)) -> Contents.
-spec t_cons_tl(erl_type()) -> erl_type().
t_cons_tl(Type) ->
t_cons_tl(Type, 'universe').
-spec t_cons_tl(erl_type(), opaques()) -> erl_type().
t_cons_tl(Type, Opaques) ->
do_opaque(Type, Opaques, fun cons_tl/1).
cons_tl(?nonempty_list(_Contents, Termination) = T) ->
t_sup(Termination, T).
-spec t_nil() -> erl_type().
t_nil() ->
?nil.
-spec t_is_nil(erl_type()) -> boolean().
t_is_nil(Type) ->
t_is_nil(Type, 'universe').
-spec t_is_nil(erl_type(), opaques()) -> boolean().
t_is_nil(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_nil/1).
is_nil(?nil) -> true;
is_nil(_) -> false.
-spec t_list() -> erl_type().
t_list() ->
?list(?any, ?nil, ?unknown_qual).
-spec t_list(erl_type()) -> erl_type().
t_list(?none) -> ?none;
t_list(?unit) -> ?none;
t_list(Contents) ->
?list(Contents, ?nil, ?unknown_qual).
-spec t_list_elements(erl_type()) -> erl_type().
t_list_elements(Type) ->
t_list_elements(Type, 'universe').
-spec t_list_elements(erl_type(), opaques()) -> erl_type().
t_list_elements(Type, Opaques) ->
do_opaque(Type, Opaques, fun list_elements/1).
list_elements(?list(Contents, _, _)) -> Contents;
list_elements(?nil) -> ?none.
-spec t_list_termination(erl_type(), opaques()) -> erl_type().
t_list_termination(Type, Opaques) ->
do_opaque(Type, Opaques, fun t_list_termination/1).
-spec t_list_termination(erl_type()) -> erl_type().
t_list_termination(?nil) -> ?nil;
t_list_termination(?list(_, Term, _)) -> Term.
-spec t_is_list(erl_type()) -> boolean().
t_is_list(?list(_Contents, ?nil, _)) -> true;
t_is_list(?nil) -> true;
t_is_list(_) -> false.
-spec t_nonempty_list() -> erl_type().
t_nonempty_list() ->
t_cons(?any, ?nil).
-spec t_nonempty_list(erl_type()) -> erl_type().
t_nonempty_list(Type) ->
t_cons(Type, ?nil).
-spec t_nonempty_string() -> erl_type().
t_nonempty_string() ->
t_nonempty_list(t_char()).
-spec t_string() -> erl_type().
t_string() ->
t_list(t_char()).
-spec t_is_string(erl_type()) -> boolean().
t_is_string(X) ->
t_is_list(X) andalso t_is_char(t_list_elements(X)).
-spec t_maybe_improper_list() -> erl_type().
t_maybe_improper_list() ->
?list(?any, ?any, ?unknown_qual).
%% Should only be used if you know what you are doing. See t_cons/2
-spec t_maybe_improper_list(erl_type(), erl_type()) -> erl_type().
t_maybe_improper_list(_Content, ?unit) -> ?none;
t_maybe_improper_list(?unit, _Termination) -> ?none;
t_maybe_improper_list(Content, Termination) ->
%% Safety check: would be nice to have but does not work with remote types
%% true = t_is_subtype(t_nil(), Termination),
?list(Content, Termination, ?unknown_qual).
-spec t_is_maybe_improper_list(erl_type()) -> boolean().
t_is_maybe_improper_list(Type) ->
t_is_maybe_improper_list(Type, 'universe').
-spec t_is_maybe_improper_list(erl_type(), opaques()) -> boolean().
t_is_maybe_improper_list(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_maybe_improper_list/1).
is_maybe_improper_list(?list(_, _, _)) -> true;
is_maybe_improper_list(?nil) -> true;
is_maybe_improper_list(_) -> false.
%% %% Should only be used if you know what you are doing. See t_cons/2
%% -spec t_improper_list(erl_type(), erl_type()) -> erl_type().
%%
%% t_improper_list(?unit, _Termination) -> ?none;
%% t_improper_list(_Content, ?unit) -> ?none;
%% t_improper_list(Content, Termination) ->
%% %% Safety check: would be nice to have but does not work with remote types
%% %% false = t_is_subtype(t_nil(), Termination),
%% ?list(Content, Termination, ?any).
-spec lift_list_to_pos_empty(erl_type(), opaques()) -> erl_type().
lift_list_to_pos_empty(Type, Opaques) ->
do_opaque(Type, Opaques, fun lift_list_to_pos_empty/1).
-spec lift_list_to_pos_empty(erl_type()) -> erl_type().
lift_list_to_pos_empty(?nil) -> ?nil;
lift_list_to_pos_empty(?list(Content, Termination, _)) ->
?list(Content, Termination, ?unknown_qual).
-spec t_widen_to_number(erl_type()) -> erl_type().
%% Widens integers and floats to t_number().
%% Used by erl_bif_types:key_comparison_fail().
t_widen_to_number(?any) -> ?any;
t_widen_to_number(?none) -> ?none;
t_widen_to_number(?unit) -> ?unit;
t_widen_to_number(?atom(_Set) = T) -> T;
t_widen_to_number(?bitstr(_Unit, _Base) = T) -> T;
t_widen_to_number(?float) -> t_number();
t_widen_to_number(?function(Domain, Range)) ->
?function(t_widen_to_number(Domain), t_widen_to_number(Range));
t_widen_to_number(?identifier(_Types) = T) -> T;
t_widen_to_number(?int_range(_From, _To)) -> t_number();
t_widen_to_number(?int_set(_Set)) -> t_number();
t_widen_to_number(?integer(_Types)) -> t_number();
t_widen_to_number(?list(Type, Tail, Size)) ->
?list(t_widen_to_number(Type), t_widen_to_number(Tail), Size);
t_widen_to_number(?map(Pairs, DefK, DefV)) ->
L = [{t_widen_to_number(K), MNess, t_widen_to_number(V)} ||
{K, MNess, V} <- Pairs],
t_map(L, t_widen_to_number(DefK), t_widen_to_number(DefV));
t_widen_to_number(?matchstate(_P, _Slots) = T) -> T;
t_widen_to_number(?nil) -> ?nil;
t_widen_to_number(?number(_Set, _Tag)) -> t_number();
t_widen_to_number(?opaque(Set)) ->
L = [Opaque#opaque{struct = t_widen_to_number(S)} ||
#opaque{struct = S} = Opaque <- set_to_list(Set)],
?opaque(ordsets:from_list(L));
t_widen_to_number(?product(Types)) ->
?product(list_widen_to_number(Types));
t_widen_to_number(?tuple(?any, _, _) = T) -> T;
t_widen_to_number(?tuple(Types, Arity, Tag)) ->
?tuple(list_widen_to_number(Types), Arity, Tag);
t_widen_to_number(?tuple_set(_) = Tuples) ->
t_sup([t_widen_to_number(T) || T <- t_tuple_subtypes(Tuples)]);
t_widen_to_number(?union(List)) ->
?union(list_widen_to_number(List));
t_widen_to_number(?var(_Id)= T) -> T.
list_widen_to_number(List) ->
[t_widen_to_number(E) || E <- List].
%%-----------------------------------------------------------------------------
%% Maps
%%
%% Representation:
%% ?map(Pairs, DefaultKey, DefaultValue)
%%
%% Pairs is a sorted dictionary of types with a mandatoriness tag on each pair
%% (t_map_dict()). DefaultKey and DefaultValue are plain types.
%%
%% A map M belongs to this type iff
%% For each pair {KT, mandatory, VT} in Pairs, there exists a pair {K, V} in M
%% such that K \in KT and V \in VT.
%% For each pair {KT, optional, VT} in Pairs, either there exists no key K in
%% M s.t. K in KT, or there exists a pair {K, V} in M such that K \in KT and
%% V \in VT.
%% For each remaining pair {K, V} in M (where remaining means that there is no
%% key KT in Pairs s.t. K \in KT), K \in DefaultKey and V \in DefaultValue.
%%
%% Invariants:
%% * The keys in Pairs are singleton types.
%% * The values of Pairs must not be unit, and may only be none if the
%% mandatoriness tag is 'optional'.
%% * There is no pair {K, 'optional', V} in Pairs s.t.
%% K is a subtype of DefaultKey and V is equal to DefaultValue.
%% * DefaultKey must be the empty type iff DefaultValue is the empty type.
%% * DefaultKey must not be a singleton type.
%% * For every key K in Pairs, DefaultKey - K must not be representable; i.e.
%% t_subtract(DefaultKey, K) must return DefaultKey.
%% * For every pair {K, 'optional', ?none} in Pairs, K must be a subtype of
%% DefaultKey.
%% * Pairs must be sorted and not contain any duplicate keys.
%%
%% These invariants ensure that equal map types are represented by equal terms.
-define(mand, mandatory).
-define(opt, optional).
-type t_map_mandatoriness() :: ?mand | ?opt.
-type t_map_pair() :: {erl_type(), t_map_mandatoriness(), erl_type()}.
-type t_map_dict() :: [t_map_pair()].
-spec t_map() -> erl_type().
t_map() ->
t_map([], t_any(), t_any()).
-spec t_map([{erl_type(), erl_type()}]) -> erl_type().
t_map(L) ->
lists:foldl(fun t_map_put/2, t_map(), L).
-spec t_map(t_map_dict(), erl_type(), erl_type()) -> erl_type().
t_map(Pairs0, DefK0, DefV0) ->
DefK1 = lists:foldl(fun({K,_,_},Acc)->t_subtract(Acc,K)end, DefK0, Pairs0),
{DefK2, DefV1} =
case t_is_none_or_unit(DefK1) orelse t_is_none_or_unit(DefV0) of
true -> {?none, ?none};
false -> {DefK1, DefV0}
end,
{Pairs1, DefK, DefV}
= case is_singleton_type(DefK2) of
true -> {mapdict_insert({DefK2, ?opt, DefV1}, Pairs0), ?none, ?none};
false -> {Pairs0, DefK2, DefV1}
end,
Pairs = normalise_map_optionals(Pairs1, DefK, DefV),
%% Validate invariants of the map representation.
%% Since we needed to iterate over the arguments in order to normalise anyway,
%% we might as well save us some future pain and do this even without
%% define(DEBUG, true).
try
validate_map_elements(Pairs)
catch error:badarg -> error(badarg, [Pairs0,DefK0,DefV0])
end,
case map_pairs_are_none(Pairs) of
true -> ?none;
false -> ?map(Pairs, DefK, DefV)
end.
normalise_map_optionals([], _, _) -> [];
normalise_map_optionals([E={K,?opt,?none}|T], DefK, DefV) ->
Diff = t_subtract(DefK, K),
case t_is_subtype(K, DefK) andalso DefK =:= Diff of
true -> [E|normalise_map_optionals(T, DefK, DefV)];
false -> normalise_map_optionals(T, Diff, DefV)
end;
normalise_map_optionals([E={K,?opt,V}|T], DefK, DefV) ->
case t_is_equal(V, DefV) andalso t_is_subtype(K, DefK) of
true -> normalise_map_optionals(T, DefK, DefV);
false -> [E|normalise_map_optionals(T, DefK, DefV)]
end;
normalise_map_optionals([E|T], DefK, DefV) ->
[E|normalise_map_optionals(T, DefK, DefV)].
validate_map_elements([{K1,_,_}|Rest=[{K2,_,_}|_]]) ->
case is_singleton_type(K1) andalso K1 < K2 of
false -> error(badarg);
true -> validate_map_elements(Rest)
end;
validate_map_elements([{K,_,_}]) ->
case is_singleton_type(K) of
false -> error(badarg);
true -> true
end;
validate_map_elements([]) -> true.
map_pairs_are_none([]) -> false;
map_pairs_are_none([{_,?mand,?none}|_]) -> true;
map_pairs_are_none([_|Ps]) -> map_pairs_are_none(Ps).
-spec t_is_map(erl_type()) -> boolean().
t_is_map(Type) ->
t_is_map(Type, 'universe').
-spec t_is_map(erl_type(), opaques()) -> boolean().
t_is_map(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_map1/1).
is_map1(?map(_, _, _)) -> true;
is_map1(_) -> false.
-spec t_map_entries(erl_type()) -> t_map_dict().
t_map_entries(M) ->
t_map_entries(M, 'universe').
-spec t_map_entries(erl_type(), opaques()) -> t_map_dict().
t_map_entries(M, Opaques) ->
do_opaque(M, Opaques, fun map_entries/1).
map_entries(?map(Pairs,_,_)) ->
Pairs.
-spec t_map_def_key(erl_type()) -> erl_type().
t_map_def_key(M) ->
t_map_def_key(M, 'universe').
-spec t_map_def_key(erl_type(), opaques()) -> erl_type().
t_map_def_key(M, Opaques) ->
do_opaque(M, Opaques, fun map_def_key/1).
map_def_key(?map(_,DefK,_)) ->
DefK.
-spec t_map_def_val(erl_type()) -> erl_type().
t_map_def_val(M) ->
t_map_def_val(M, 'universe').
-spec t_map_def_val(erl_type(), opaques()) -> erl_type().
t_map_def_val(M, Opaques) ->
do_opaque(M, Opaques, fun map_def_val/1).
map_def_val(?map(_,_,DefV)) ->
DefV.
-spec mapdict_store(t_map_pair(), t_map_dict()) -> t_map_dict().
mapdict_store(E={K,_,_}, [{K,_,_}|T]) -> [E|T];
mapdict_store(E1={K1,_,_}, [E2={K2,_,_}|T]) when K1 > K2 ->
[E2|mapdict_store(E1, T)];
mapdict_store(E={_,_,_}, T) -> [E|T].
-spec mapdict_insert(t_map_pair(), t_map_dict()) -> t_map_dict().
mapdict_insert(E={K,_,_}, D=[{K,_,_}|_]) -> error(badarg, [E, D]);
mapdict_insert(E1={K1,_,_}, [E2={K2,_,_}|T]) when K1 > K2 ->
[E2|mapdict_insert(E1, T)];
mapdict_insert(E={_,_,_}, T) -> [E|T].
-type map_pairwise_merge_fun() :: fun((erl_type(),
t_map_mandatoriness(), erl_type(),
t_map_mandatoriness(), erl_type())
-> t_map_pair() | false).
-spec t_map_pairwise_merge(map_pairwise_merge_fun(), erl_type(), erl_type(),
opaques()) -> t_map_dict().
t_map_pairwise_merge(F, MapA, MapB, Opaques) ->
do_opaque(MapA, Opaques,
fun(UMapA) ->
do_opaque(MapB, Opaques,
fun(UMapB) ->
map_pairwise_merge(F, UMapA, UMapB)
end)
end).
%% Merges the pairs of two maps together. Missing pairs become (?opt, DefV) or
%% (?opt, ?none), depending on whether K \in DefK.
-spec map_pairwise_merge(map_pairwise_merge_fun(), erl_type(), erl_type())
-> t_map_dict().
map_pairwise_merge(F, ?map(APairs, ADefK, ADefV),
?map(BPairs, BDefK, BDefV)) ->
map_pairwise_merge(F, APairs, ADefK, ADefV, BPairs, BDefK, BDefV).
map_pairwise_merge(_, [], _, _, [], _, _) -> [];
map_pairwise_merge(F, As0, ADefK, ADefV, Bs0, BDefK, BDefV) ->
{K1, AMNess1, AV1, As1, BMNess1, BV1, Bs1} =
case {As0, Bs0} of
{[{K,AMNess,AV}|As], [{K, BMNess,BV}|Bs]} ->
{K, AMNess, AV, As, BMNess, BV, Bs};
{[{K,AMNess,AV}|As], [{BK,_, _ }|_]=Bs} when K < BK ->
{K, AMNess, AV, As, ?opt, mapmerge_otherv(K, BDefK, BDefV), Bs};
{As, [{K, BMNess,BV}|Bs]} ->
{K, ?opt, mapmerge_otherv(K, ADefK, ADefV), As, BMNess, BV, Bs};
{[{K,AMNess,AV}|As], []=Bs} ->
{K, AMNess, AV, As, ?opt, mapmerge_otherv(K, BDefK, BDefV), Bs}
end,
MK = K1, %% Rename to make clear that we are matching below
case F(K1, AMNess1, AV1, BMNess1, BV1) of
false -> map_pairwise_merge(F,As1,ADefK,ADefV,Bs1,BDefK,BDefV);
{MK,_,_}=M -> [M|map_pairwise_merge(F,As1,ADefK,ADefV,Bs1,BDefK,BDefV)]
end.
%% Folds over the pairs in two maps simultaneously in reverse key order. Missing
%% pairs become (?opt, DefV) or (?opt, ?none), depending on whether K \in DefK.
-spec map_pairwise_merge_foldr(fun((erl_type(),
t_map_mandatoriness(), erl_type(),
t_map_mandatoriness(), erl_type(),
Acc) -> Acc),
Acc, erl_type(), erl_type()) -> Acc.
map_pairwise_merge_foldr(F, AccIn, ?map(APairs, ADefK, ADefV),
?map(BPairs, BDefK, BDefV)) ->
map_pairwise_merge_foldr(F, AccIn, APairs, ADefK, ADefV, BPairs, BDefK, BDefV).
map_pairwise_merge_foldr(_, Acc, [], _, _, [], _, _) -> Acc;
map_pairwise_merge_foldr(F, AccIn, As0, ADefK, ADefV, Bs0, BDefK, BDefV) ->
{K1, AMNess1, AV1, As1, BMNess1, BV1, Bs1} =
case {As0, Bs0} of
{[{K,AMNess,AV}|As], [{K,BMNess,BV}|Bs]} ->
{K, AMNess, AV, As, BMNess, BV, Bs};
{[{K,AMNess,AV}|As], [{BK,_, _ }|_]=Bs} when K < BK ->
{K, AMNess, AV, As, ?opt, mapmerge_otherv(K, BDefK, BDefV), Bs};
{As, [{K,BMNess,BV}|Bs]} ->
{K, ?opt, mapmerge_otherv(K, ADefK, ADefV), As, BMNess, BV, Bs};
{[{K,AMNess,AV}|As], []=Bs} ->
{K, AMNess, AV, As, ?opt, mapmerge_otherv(K, BDefK, BDefV), Bs}
end,
F(K1, AMNess1, AV1, BMNess1, BV1,
map_pairwise_merge_foldr(F,AccIn,As1,ADefK,ADefV,Bs1,BDefK,BDefV)).
%% By observing that a missing pair in a map is equivalent to an optional pair,
%% with ?none or DefV value, depending on whether K \in DefK, we can simplify
%% merging by denormalising the map pairs temporarily, removing all 'false'
%% cases, at the cost of the creation of more tuples:
mapmerge_otherv(K, ODefK, ODefV) ->
case t_inf(K, ODefK) of
?none -> ?none;
_KOrOpaque -> ODefV
end.
-spec t_map_put({erl_type(), erl_type()}, erl_type()) -> erl_type().
t_map_put(KV, Map) ->
t_map_put(KV, Map, 'universe').
-spec t_map_put({erl_type(), erl_type()}, erl_type(), opaques()) -> erl_type().
t_map_put(KV, Map, Opaques) ->
do_opaque(Map, Opaques, fun(UM) -> map_put(KV, UM, Opaques) end).
%% Key and Value are *not* unopaqued, but the map is
map_put(_, ?none, _) -> ?none;
map_put(_, ?unit, _) -> ?none;
map_put({Key, Value}, ?map(Pairs,DefK,DefV), Opaques) ->
case t_is_none_or_unit(Key) orelse t_is_none_or_unit(Value) of
true -> ?none;
false ->
case is_singleton_type(Key) of
true ->
t_map(mapdict_store({Key, ?mand, Value}, Pairs), DefK, DefV);
false ->
t_map([{K, MNess, case t_is_none(t_inf(K, Key, Opaques)) of
true -> V;
false -> t_sup(V, Value)
end} || {K, MNess, V} <- Pairs],
t_sup(DefK, Key),
t_sup(DefV, Value))
end
end.
-spec t_map_update({erl_type(), erl_type()}, erl_type()) -> erl_type().
t_map_update(KV, Map) ->
t_map_update(KV, Map, 'universe').
-spec t_map_update({erl_type(), erl_type()}, erl_type(), opaques()) -> erl_type().
t_map_update(_, ?none, _) -> ?none;
t_map_update(_, ?unit, _) -> ?none;
t_map_update(KV={Key, _}, M, Opaques) ->
case t_is_subtype(t_atom('true'), t_map_is_key(Key, M, Opaques)) of
false -> ?none;
true -> t_map_put(KV, M, Opaques)
end.
-spec t_map_get(erl_type(), erl_type()) -> erl_type().
t_map_get(Key, Map) ->
t_map_get(Key, Map, 'universe').
-spec t_map_get(erl_type(), erl_type(), opaques()) -> erl_type().
t_map_get(Key, Map, Opaques) ->
do_opaque(Map, Opaques,
fun(UM) ->
do_opaque(Key, Opaques, fun(UK) -> map_get(UK, UM) end)
end).
map_get(_, ?none) -> ?none;
map_get(_, ?unit) -> ?none;
map_get(Key, ?map(Pairs, DefK, DefV)) ->
DefRes =
case t_do_overlap(DefK, Key) of
false -> t_none();
true -> DefV
end,
case is_singleton_type(Key) of
false ->
lists:foldl(fun({K, _, V}, Res) ->
case t_do_overlap(K, Key) of
false -> Res;
true -> t_sup(Res, V)
end
end, DefRes, Pairs);
true ->
case lists:keyfind(Key, 1, Pairs) of
false -> DefRes;
{_, _, ValType} -> ValType
end
end.
-spec t_map_is_key(erl_type(), erl_type()) -> erl_type().
t_map_is_key(Key, Map) ->
t_map_is_key(Key, Map, 'universe').
-spec t_map_is_key(erl_type(), erl_type(), opaques()) -> erl_type().
t_map_is_key(Key, Map, Opaques) ->
do_opaque(Map, Opaques,
fun(UM) ->
do_opaque(Key, Opaques, fun(UK) -> map_is_key(UK, UM) end)
end).
map_is_key(_, ?none) -> ?none;
map_is_key(_, ?unit) -> ?none;
map_is_key(Key, ?map(Pairs, DefK, _DefV)) ->
case is_singleton_type(Key) of
true ->
case lists:keyfind(Key, 1, Pairs) of
{Key, ?mand, _} -> t_atom(true);
{Key, ?opt, ?none} -> t_atom(false);
{Key, ?opt, _} -> t_boolean();
false ->
case t_do_overlap(DefK, Key) of
false -> t_atom(false);
true -> t_boolean()
end
end;
false ->
case t_do_overlap(DefK, Key)
orelse lists:any(fun({_,_,?none}) -> false;
({K,_,_}) -> t_do_overlap(K, Key)
end, Pairs)
of
true -> t_boolean();
false -> t_atom(false)
end
end.
%%-----------------------------------------------------------------------------
%% Tuples
%%
-spec t_tuple() -> erl_type().
t_tuple() ->
?tuple(?any, ?any, ?any).
-spec t_tuple(non_neg_integer() | [erl_type()]) -> erl_type().
t_tuple(N) when is_integer(N), N > ?MAX_TUPLE_SIZE ->
t_tuple();
t_tuple(N) when is_integer(N) ->
?tuple(lists:duplicate(N, ?any), N, ?any);
t_tuple(List) ->
case any_none_or_unit(List) of
true -> t_none();
false ->
Arity = length(List),
case get_tuple_tags(List) of
[Tag] -> ?tuple(List, Arity, Tag); %% Tag can also be ?any here
TagList ->
SortedTagList = lists:sort(TagList),
Tuples = [?tuple([T|tl(List)], Arity, T) || T <- SortedTagList],
?tuple_set([{Arity, Tuples}])
end
end.
-spec get_tuple_tags([erl_type()]) -> [erl_type(),...].
get_tuple_tags([Tag|_]) ->
do_opaque(Tag, 'universe', fun tuple_tags/1);
get_tuple_tags(_) -> [?any].
tuple_tags(?atom(?any)) -> [?any];
tuple_tags(?atom(Set)) ->
case set_size(Set) > ?TUPLE_TAG_LIMIT of
true -> [?any];
false -> [t_atom(A) || A <- set_to_list(Set)]
end;
tuple_tags(_) -> [?any].
%% to be used for a tuple with known types for its arguments (not ?any)
-spec t_tuple_args(erl_type()) -> [erl_type()].
t_tuple_args(Type) ->
t_tuple_args(Type, 'universe').
%% to be used for a tuple with known types for its arguments (not ?any)
-spec t_tuple_args(erl_type(), opaques()) -> [erl_type()].
t_tuple_args(Type, Opaques) ->
do_opaque(Type, Opaques, fun tuple_args/1).
tuple_args(?tuple(Args, _, _)) when is_list(Args) -> Args.
%% to be used for a tuple with a known size (not ?any)
-spec t_tuple_size(erl_type()) -> non_neg_integer().
t_tuple_size(Type) ->
t_tuple_size(Type, 'universe').
%% to be used for a tuple with a known size (not ?any)
-spec t_tuple_size(erl_type(), opaques()) -> non_neg_integer().
t_tuple_size(Type, Opaques) ->
do_opaque(Type, Opaques, fun tuple_size1/1).
tuple_size1(?tuple(_, Size, _)) when is_integer(Size) -> Size.
-spec t_tuple_sizes(erl_type()) -> 'unknown' | [non_neg_integer(),...].
t_tuple_sizes(Type) ->
do_opaque(Type, 'universe', fun tuple_sizes/1).
tuple_sizes(?tuple(?any, ?any, ?any)) -> unknown;
tuple_sizes(?tuple(_, Size, _)) when is_integer(Size) -> [Size];
tuple_sizes(?tuple_set(List)) -> [Size || {Size, _} <- List].
-spec t_tuple_subtypes(erl_type(), opaques()) ->
'unknown' | [erl_type(),...].
t_tuple_subtypes(Type, Opaques) ->
Fun = fun(?tuple_set(List)) ->
t_tuple_subtypes_tuple_list(List, Opaques);
(?opaque(_)) -> unknown;
(T) -> t_tuple_subtypes(T)
end,
do_opaque(Type, Opaques, Fun).
t_tuple_subtypes_tuple_list(List, Opaques) ->
lists:append([t_tuple_subtypes_list(Tuples, Opaques) ||
{_Size, Tuples} <- List]).
t_tuple_subtypes_list(List, Opaques) ->
ListOfLists = [t_tuple_subtypes(E, Opaques) || E <- List, E =/= ?none],
lists:append([L || L <- ListOfLists, L =/= 'unknown']).
-spec t_tuple_subtypes(erl_type()) -> 'unknown' | [erl_type(),...].
%% XXX. Not the same as t_tuple_subtypes(T, 'universe')...
t_tuple_subtypes(?tuple(?any, ?any, ?any)) -> unknown;
t_tuple_subtypes(?tuple(_, _, _) = T) -> [T];
t_tuple_subtypes(?tuple_set(List)) ->
lists:append([Tuples || {_Size, Tuples} <- List]).
-spec t_is_tuple(erl_type()) -> boolean().
t_is_tuple(Type) ->
t_is_tuple(Type, 'universe').
-spec t_is_tuple(erl_type(), opaques()) -> boolean().
t_is_tuple(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_tuple1/1).
is_tuple1(?tuple(_, _, _)) -> true;
is_tuple1(?tuple_set(_)) -> true;
is_tuple1(_) -> false.
%%-----------------------------------------------------------------------------
%% Non-primitive types, including some handy syntactic sugar types
%%
-spec t_bitstrlist() -> erl_type().
t_bitstrlist() ->
t_iolist(1, t_bitstr()).
-spec t_arity() -> erl_type().
t_arity() ->
t_from_range(0, 255). % was t_byte().
-spec t_pos_integer() -> erl_type().
t_pos_integer() ->
t_from_range(1, pos_inf).
-spec t_non_neg_integer() -> erl_type().
t_non_neg_integer() ->
t_from_range(0, pos_inf).
-spec t_is_non_neg_integer(erl_type()) -> boolean().
t_is_non_neg_integer(?integer(_) = T) ->
t_is_subtype(T, t_non_neg_integer());
t_is_non_neg_integer(_) -> false.
-spec t_neg_integer() -> erl_type().
t_neg_integer() ->
t_from_range(neg_inf, -1).
-spec t_fixnum() -> erl_type().
t_fixnum() ->
t_integer(). % Gross over-approximation
-spec t_pos_fixnum() -> erl_type().
t_pos_fixnum() ->
t_pos_integer(). % Gross over-approximation
-spec t_non_neg_fixnum() -> erl_type().
t_non_neg_fixnum() ->
t_non_neg_integer(). % Gross over-approximation
-spec t_mfa() -> erl_type().
t_mfa() ->
t_tuple([t_atom(), t_atom(), t_arity()]).
-spec t_module() -> erl_type().
t_module() ->
t_atom().
-spec t_node() -> erl_type().
t_node() ->
t_atom().
-spec t_iodata() -> erl_type().
t_iodata() ->
t_sup(t_iolist(), t_binary()).
-spec t_iolist() -> erl_type().
t_iolist() ->
t_iolist(1, t_binary()).
%% Added a second argument which currently is t_binary() | t_bitstr()
-spec t_iolist(non_neg_integer(), erl_type()) -> erl_type().
t_iolist(N, T) when N > 0 ->
t_maybe_improper_list(t_sup([t_iolist(N-1, T), T, t_byte()]),
t_sup(T, t_nil()));
t_iolist(0, T) ->
t_maybe_improper_list(t_any(), t_sup(T, t_nil())).
-spec t_timeout() -> erl_type().
t_timeout() ->
t_sup(t_non_neg_integer(), t_atom('infinity')).
%%------------------------------------
%% ?none is allowed in products. A product of size 1 is not a product.
-spec t_product([erl_type()]) -> erl_type().
t_product([T]) -> T;
t_product(Types) when is_list(Types) ->
?product(Types).
%% This function is intended to be the inverse of the one above.
%% It should NOT be used with ?any, ?none or ?unit as input argument.
-spec t_to_tlist(erl_type()) -> [erl_type()].
t_to_tlist(?product(Types)) -> Types;
t_to_tlist(T) when T =/= ?any orelse T =/= ?none orelse T =/= ?unit -> [T].
%%------------------------------------
-spec t_var(atom() | integer()) -> erl_type().
t_var(Atom) when is_atom(Atom) -> ?var(Atom);
t_var(Int) when is_integer(Int) -> ?var(Int).
-spec t_is_var(erl_type()) -> boolean().
t_is_var(?var(_)) -> true;
t_is_var(_) -> false.
-spec t_var_name(erl_type()) -> atom() | integer().
t_var_name(?var(Id)) -> Id.
-spec t_has_var(erl_type()) -> boolean().
t_has_var(?var(_)) -> true;
t_has_var(?function(Domain, Range)) ->
t_has_var(Domain) orelse t_has_var(Range);
t_has_var(?list(Contents, Termination, _)) ->
t_has_var(Contents) orelse t_has_var(Termination);
t_has_var(?product(Types)) -> t_has_var_list(Types);
t_has_var(?tuple(?any, ?any, ?any)) -> false;
t_has_var(?tuple(Elements, _, _)) ->
t_has_var_list(Elements);
t_has_var(?tuple_set(_) = T) ->
t_has_var_list(t_tuple_subtypes(T));
t_has_var(?map(_, DefK, _)= Map) ->
t_has_var_list(map_all_values(Map)) orelse
t_has_var(DefK);
t_has_var(?opaque(Set)) ->
%% Assume variables in 'args' are also present i 'struct'
t_has_var_list([O#opaque.struct || O <- set_to_list(Set)]);
t_has_var(?union(List)) ->
t_has_var_list(List);
t_has_var(_) -> false.
-spec t_has_var_list([erl_type()]) -> boolean().
t_has_var_list([T|Ts]) ->
t_has_var(T) orelse t_has_var_list(Ts);
t_has_var_list([]) -> false.
-spec t_collect_vars(erl_type()) -> [erl_type()].
t_collect_vars(T) ->
Vs = t_collect_vars(T, maps:new()),
[V || {V, _} <- maps:to_list(Vs)].
-type ctab() :: #{erl_type() => 'any'}.
-spec t_collect_vars(erl_type(), ctab()) -> ctab().
t_collect_vars(?var(_) = Var, Acc) ->
maps:put(Var, any, Acc);
t_collect_vars(?function(Domain, Range), Acc) ->
Acc1 = t_collect_vars(Domain, Acc),
t_collect_vars(Range, Acc1);
t_collect_vars(?list(Contents, Termination, _), Acc) ->
Acc1 = t_collect_vars(Contents, Acc),
t_collect_vars(Termination, Acc1);
t_collect_vars(?product(Types), Acc) ->
t_collect_vars_list(Types, Acc);
t_collect_vars(?tuple(?any, ?any, ?any), Acc) ->
Acc;
t_collect_vars(?tuple(Types, _, _), Acc) ->
t_collect_vars_list(Types, Acc);
t_collect_vars(?tuple_set(_) = TS, Acc) ->
t_collect_vars_list(t_tuple_subtypes(TS), Acc);
t_collect_vars(?map(_, DefK, _) = Map, Acc0) ->
Acc = t_collect_vars_list(map_all_values(Map), Acc0),
t_collect_vars(DefK, Acc);
t_collect_vars(?opaque(Set), Acc) ->
%% Assume variables in 'args' are also present i 'struct'
t_collect_vars_list([O#opaque.struct || O <- set_to_list(Set)], Acc);
t_collect_vars(?union(List), Acc) ->
t_collect_vars_list(List, Acc);
t_collect_vars(_, Acc) ->
Acc.
t_collect_vars_list([T|Ts], Acc0) ->
Acc = t_collect_vars(T, Acc0),
t_collect_vars_list(Ts, Acc);
t_collect_vars_list([], Acc) -> Acc.
%%=============================================================================
%%
%% Type construction from Erlang terms.
%%
%%=============================================================================
%%-----------------------------------------------------------------------------
%% Make a type from a term. No type depth is enforced.
%%
-spec t_from_term(term()) -> erl_type().
t_from_term([H|T]) -> t_cons(t_from_term(H), t_from_term(T));
t_from_term([]) -> t_nil();
t_from_term(T) when is_atom(T) -> t_atom(T);
t_from_term(T) when is_bitstring(T) -> t_bitstr(0, erlang:bit_size(T));
t_from_term(T) when is_float(T) -> t_float();
t_from_term(T) when is_function(T) ->
{arity, Arity} = erlang:fun_info(T, arity),
t_fun(Arity, t_any());
t_from_term(T) when is_integer(T) -> t_integer(T);
t_from_term(T) when is_map(T) ->
Pairs = [{t_from_term(K), ?mand, t_from_term(V)}
|| {K, V} <- maps:to_list(T)],
{Stons, Rest} = lists:partition(fun({K,_,_}) -> is_singleton_type(K) end,
Pairs),
{DefK, DefV}
= lists:foldl(fun({K,_,V},{AK,AV}) -> {t_sup(K,AK), t_sup(V,AV)} end,
{t_none(), t_none()}, Rest),
t_map(lists:keysort(1, Stons), DefK, DefV);
t_from_term(T) when is_pid(T) -> t_pid();
t_from_term(T) when is_port(T) -> t_port();
t_from_term(T) when is_reference(T) -> t_reference();
t_from_term(T) when is_tuple(T) ->
t_tuple([t_from_term(E) || E <- tuple_to_list(T)]).
%%-----------------------------------------------------------------------------
%% Integer types from a range.
%%-----------------------------------------------------------------------------
%%-define(USE_UNSAFE_RANGES, true).
-spec t_from_range(rng_elem(), rng_elem()) -> erl_type().
-ifdef(USE_UNSAFE_RANGES).
t_from_range(X, Y) ->
t_from_range_unsafe(X, Y).
-else.
t_from_range(pos_inf, pos_inf) -> ?integer_pos;
t_from_range(neg_inf, neg_inf) -> ?integer_neg;
t_from_range(neg_inf, pos_inf) -> t_integer();
t_from_range(neg_inf, Y) when is_integer(Y), Y < 0 -> ?integer_neg;
t_from_range(neg_inf, Y) when is_integer(Y), Y >= 0 -> t_integer();
t_from_range(X, pos_inf) when is_integer(X), X >= 1 -> ?integer_pos;
t_from_range(X, pos_inf) when is_integer(X), X >= 0 -> ?integer_non_neg;
t_from_range(X, pos_inf) when is_integer(X), X < 0 -> t_integer();
t_from_range(X, Y) when is_integer(X), is_integer(Y), X > Y -> t_none();
t_from_range(X, Y) when is_integer(X), is_integer(Y) ->
case ((Y - X) < ?SET_LIMIT) of
true -> t_integers(lists:seq(X, Y));
false ->
case X >= 0 of
false ->
if Y < 0 -> ?integer_neg;
true -> t_integer()
end;
true ->
if Y =< ?MAX_BYTE, X >= 1 -> ?int_range(1, ?MAX_BYTE);
Y =< ?MAX_BYTE -> t_byte();
Y =< ?MAX_CHAR, X >= 1 -> ?int_range(1, ?MAX_CHAR);
Y =< ?MAX_CHAR -> t_char();
X >= 1 -> ?integer_pos;
X >= 0 -> ?integer_non_neg
end
end
end;
t_from_range(pos_inf, neg_inf) -> t_none().
-endif.
-spec t_from_range_unsafe(rng_elem(), rng_elem()) -> erl_type().
t_from_range_unsafe(pos_inf, pos_inf) -> ?integer_pos;
t_from_range_unsafe(neg_inf, neg_inf) -> ?integer_neg;
t_from_range_unsafe(neg_inf, pos_inf) -> t_integer();
t_from_range_unsafe(neg_inf, Y) -> ?int_range(neg_inf, Y);
t_from_range_unsafe(X, pos_inf) -> ?int_range(X, pos_inf);
t_from_range_unsafe(X, Y) when is_integer(X), is_integer(Y), X =< Y ->
if (Y - X) < ?SET_LIMIT -> t_integers(lists:seq(X, Y));
true -> ?int_range(X, Y)
end;
t_from_range_unsafe(X, Y) when is_integer(X), is_integer(Y) -> t_none();
t_from_range_unsafe(pos_inf, neg_inf) -> t_none().
-spec t_is_fixnum(erl_type()) -> boolean().
t_is_fixnum(?int_range(neg_inf, _)) -> false;
t_is_fixnum(?int_range(_, pos_inf)) -> false;
t_is_fixnum(?int_range(From, To)) ->
is_fixnum(From) andalso is_fixnum(To);
t_is_fixnum(?int_set(Set)) ->
is_fixnum(set_min(Set)) andalso is_fixnum(set_max(Set));
t_is_fixnum(_) -> false.
-spec is_fixnum(integer()) -> boolean().
is_fixnum(N) when is_integer(N) ->
Bits = ?BITS,
(N =< ((1 bsl (Bits - 1)) - 1)) andalso (N >= -(1 bsl (Bits - 1))).
infinity_geq(pos_inf, _) -> true;
infinity_geq(_, pos_inf) -> false;
infinity_geq(_, neg_inf) -> true;
infinity_geq(neg_inf, _) -> false;
infinity_geq(A, B) -> A >= B.
-spec t_is_bitwidth(erl_type()) -> boolean().
t_is_bitwidth(?int_range(neg_inf, _)) -> false;
t_is_bitwidth(?int_range(_, pos_inf)) -> false;
t_is_bitwidth(?int_range(From, To)) ->
infinity_geq(From, 0) andalso infinity_geq(?BITS, To);
t_is_bitwidth(?int_set(Set)) ->
infinity_geq(set_min(Set), 0) andalso infinity_geq(?BITS, set_max(Set));
t_is_bitwidth(_) -> false.
-spec number_min(erl_type()) -> rng_elem().
number_min(Type) ->
number_min(Type, 'universe').
-spec number_min(erl_type(), opaques()) -> rng_elem().
number_min(Type, Opaques) ->
do_opaque(Type, Opaques, fun number_min2/1).
number_min2(?int_range(From, _)) -> From;
number_min2(?int_set(Set)) -> set_min(Set);
number_min2(?number(?any, _Tag)) -> neg_inf.
-spec number_max(erl_type()) -> rng_elem().
number_max(Type) ->
number_max(Type, 'universe').
-spec number_max(erl_type(), opaques()) -> rng_elem().
number_max(Type, Opaques) ->
do_opaque(Type, Opaques, fun number_max2/1).
number_max2(?int_range(_, To)) -> To;
number_max2(?int_set(Set)) -> set_max(Set);
number_max2(?number(?any, _Tag)) -> pos_inf.
%% -spec int_range(rgn_elem(), rng_elem()) -> erl_type().
%%
%% int_range(neg_inf, pos_inf) -> t_integer();
%% int_range(neg_inf, To) -> ?int_range(neg_inf, To);
%% int_range(From, pos_inf) -> ?int_range(From, pos_inf);
%% int_range(From, To) when From =< To -> t_from_range(From, To);
%% int_range(From, To) when To < From -> ?none.
in_range(_, ?int_range(neg_inf, pos_inf)) -> true;
in_range(X, ?int_range(From, pos_inf)) -> X >= From;
in_range(X, ?int_range(neg_inf, To)) -> X =< To;
in_range(X, ?int_range(From, To)) -> (X >= From) andalso (X =< To).
-spec min(rng_elem(), rng_elem()) -> rng_elem().
min(neg_inf, _) -> neg_inf;
min(_, neg_inf) -> neg_inf;
min(pos_inf, Y) -> Y;
min(X, pos_inf) -> X;
min(X, Y) when X =< Y -> X;
min(_, Y) -> Y.
-spec max(rng_elem(), rng_elem()) -> rng_elem().
max(neg_inf, Y) -> Y;
max(X, neg_inf) -> X;
max(pos_inf, _) -> pos_inf;
max(_, pos_inf) -> pos_inf;
max(X, Y) when X =< Y -> Y;
max(X, _) -> X.
expand_range_from_set(Range = ?int_range(From, To), Set) ->
Min = min(set_min(Set), From),
Max = max(set_max(Set), To),
if From =:= Min, To =:= Max -> Range;
true -> t_from_range(Min, Max)
end.
%%=============================================================================
%%
%% Lattice operations
%%
%%=============================================================================
%%-----------------------------------------------------------------------------
%% Supremum
%%
-spec t_sup([erl_type()]) -> erl_type().
t_sup([]) -> ?none;
t_sup(Ts) ->
case lists:any(fun is_any/1, Ts) of
true -> ?any;
false ->
t_sup1(Ts, [])
end.
t_sup1([H1, H2|T], L) ->
t_sup1(T, [t_sup(H1, H2)|L]);
t_sup1([T], []) -> subst_all_vars_to_any(T);
t_sup1(Ts, L) ->
t_sup1(Ts++L, []).
-spec t_sup(erl_type(), erl_type()) -> erl_type().
t_sup(?any, _) -> ?any;
t_sup(_, ?any) -> ?any;
t_sup(?none, T) -> T;
t_sup(T, ?none) -> T;
t_sup(?unit, T) -> T;
t_sup(T, ?unit) -> T;
t_sup(T, T) -> subst_all_vars_to_any(T);
t_sup(?var(_), _) -> ?any;
t_sup(_, ?var(_)) -> ?any;
t_sup(?atom(Set1), ?atom(Set2)) ->
?atom(set_union(Set1, Set2));
t_sup(?bitstr(U1, B1), ?bitstr(U2, B2)) ->
t_bitstr(gcd(gcd(U1, U2), abs(B1-B2)), lists:min([B1, B2]));
t_sup(?function(Domain1, Range1), ?function(Domain2, Range2)) ->
%% The domain is either a product or any.
?function(t_sup(Domain1, Domain2), t_sup(Range1, Range2));
t_sup(?identifier(Set1), ?identifier(Set2)) ->
?identifier(set_union(Set1, Set2));
t_sup(?opaque(Set1), ?opaque(Set2)) ->
sup_opaque(set_to_list(ordsets:union(Set1, Set2)));
%%Disallow unions with opaque types
%%t_sup(T1=?opaque(_,_,_), T2) ->
%% io:format("Debug: t_sup executed with args ~w and ~w~n",[T1, T2]), ?none;
%%t_sup(T1, T2=?opaque(_,_,_)) ->
%% io:format("Debug: t_sup executed with args ~w and ~w~n",[T1, T2]), ?none;
t_sup(?matchstate(Pres1, Slots1), ?matchstate(Pres2, Slots2)) ->
?matchstate(t_sup(Pres1, Pres2), t_sup(Slots1, Slots2));
t_sup(?nil, ?nil) -> ?nil;
t_sup(?nil, ?list(Contents, Termination, _)) ->
?list(Contents, t_sup(?nil, Termination), ?unknown_qual);
t_sup(?list(Contents, Termination, _), ?nil) ->
?list(Contents, t_sup(?nil, Termination), ?unknown_qual);
t_sup(?list(Contents1, Termination1, Size1),
?list(Contents2, Termination2, Size2)) ->
NewSize =
case {Size1, Size2} of
{?unknown_qual, ?unknown_qual} -> ?unknown_qual;
{?unknown_qual, ?nonempty_qual} -> ?unknown_qual;
{?nonempty_qual, ?unknown_qual} -> ?unknown_qual;
{?nonempty_qual, ?nonempty_qual} -> ?nonempty_qual
end,
NewContents = t_sup(Contents1, Contents2),
NewTermination = t_sup(Termination1, Termination2),
TmpList = t_cons(NewContents, NewTermination),
case NewSize of
?nonempty_qual -> TmpList;
?unknown_qual ->
?list(FinalContents, FinalTermination, _) = TmpList,
?list(FinalContents, FinalTermination, ?unknown_qual)
end;
t_sup(?number(_, _), ?number(?any, ?unknown_qual) = T) -> T;
t_sup(?number(?any, ?unknown_qual) = T, ?number(_, _)) -> T;
t_sup(?float, ?float) -> ?float;
t_sup(?float, ?integer(_)) -> t_number();
t_sup(?integer(_), ?float) -> t_number();
t_sup(?integer(?any) = T, ?integer(_)) -> T;
t_sup(?integer(_), ?integer(?any) = T) -> T;
t_sup(?int_set(Set1), ?int_set(Set2)) ->
case set_union(Set1, Set2) of
?any ->
t_from_range(min(set_min(Set1), set_min(Set2)),
max(set_max(Set1), set_max(Set2)));
Set -> ?int_set(Set)
end;
t_sup(?int_range(From1, To1), ?int_range(From2, To2)) ->
t_from_range(min(From1, From2), max(To1, To2));
t_sup(Range = ?int_range(_, _), ?int_set(Set)) ->
expand_range_from_set(Range, Set);
t_sup(?int_set(Set), Range = ?int_range(_, _)) ->
expand_range_from_set(Range, Set);
t_sup(?product(Types1), ?product(Types2)) ->
L1 = length(Types1),
L2 = length(Types2),
if L1 =:= L2 -> ?product(t_sup_lists(Types1, Types2));
true -> ?any
end;
t_sup(?product(_), _) ->
?any;
t_sup(_, ?product(_)) ->
?any;
t_sup(?tuple(?any, ?any, ?any) = T, ?tuple(_, _, _)) -> T;
t_sup(?tuple(_, _, _), ?tuple(?any, ?any, ?any) = T) -> T;
t_sup(?tuple(?any, ?any, ?any) = T, ?tuple_set(_)) -> T;
t_sup(?tuple_set(_), ?tuple(?any, ?any, ?any) = T) -> T;
t_sup(?tuple(Elements1, Arity, Tag1) = T1,
?tuple(Elements2, Arity, Tag2) = T2) ->
if Tag1 =:= Tag2 -> t_tuple(t_sup_lists(Elements1, Elements2));
Tag1 =:= ?any -> t_tuple(t_sup_lists(Elements1, Elements2));
Tag2 =:= ?any -> t_tuple(t_sup_lists(Elements1, Elements2));
Tag1 < Tag2 -> ?tuple_set([{Arity, [T1, T2]}]);
Tag1 > Tag2 -> ?tuple_set([{Arity, [T2, T1]}])
end;
t_sup(?tuple(_, Arity1, _) = T1, ?tuple(_, Arity2, _) = T2) ->
sup_tuple_sets([{Arity1, [T1]}], [{Arity2, [T2]}]);
t_sup(?tuple_set(List1), ?tuple_set(List2)) ->
sup_tuple_sets(List1, List2);
t_sup(?tuple_set(List1), T2 = ?tuple(_, Arity, _)) ->
sup_tuple_sets(List1, [{Arity, [T2]}]);
t_sup(?tuple(_, Arity, _) = T1, ?tuple_set(List2)) ->
sup_tuple_sets([{Arity, [T1]}], List2);
t_sup(?map(_, ADefK, ADefV) = A, ?map(_, BDefK, BDefV) = B) ->
Pairs =
map_pairwise_merge(
fun(K, MNess, V1, MNess, V2) -> {K, MNess, t_sup(V1, V2)};
(K, _, V1, _, V2) -> {K, ?opt, t_sup(V1, V2)}
end, A, B),
t_map(Pairs, t_sup(ADefK, BDefK), t_sup(ADefV, BDefV));
t_sup(T1, T2) ->
?union(U1) = force_union(T1),
?union(U2) = force_union(T2),
sup_union(U1, U2).
sup_opaque([]) -> ?none;
sup_opaque(List) ->
L = sup_opaq(List),
?opaque(ordsets:from_list(L)).
sup_opaq(L0) ->
L1 = [{{Mod,Name,Args}, T} ||
#opaque{mod = Mod, name = Name, args = Args}=T <- L0],
F = family(L1),
[supl(Ts) || {_, Ts} <- F].
supl([O]) -> O;
supl(Ts) -> supl(Ts, t_none()).
supl([#opaque{struct = S}=O|L], S0) ->
S1 = t_sup(S, S0),
case L =:= [] of
true -> O#opaque{struct = S1};
false -> supl(L, S1)
end.
-spec t_sup_lists([erl_type()], [erl_type()]) -> [erl_type()].
t_sup_lists([T1|Left1], [T2|Left2]) ->
[t_sup(T1, T2)|t_sup_lists(Left1, Left2)];
t_sup_lists([], []) ->
[].
sup_tuple_sets(L1, L2) ->
TotalArities = ordsets:union([Arity || {Arity, _} <- L1],
[Arity || {Arity, _} <- L2]),
if length(TotalArities) > ?TUPLE_ARITY_LIMIT -> t_tuple();
true ->
case sup_tuple_sets(L1, L2, []) of
[{_Arity, [OneTuple = ?tuple(_, _, _)]}] -> OneTuple;
List -> ?tuple_set(List)
end
end.
sup_tuple_sets([{Arity, Tuples1}|Left1], [{Arity, Tuples2}|Left2], Acc) ->
NewAcc = [{Arity, sup_tuples_in_set(Tuples1, Tuples2)}|Acc],
sup_tuple_sets(Left1, Left2, NewAcc);
sup_tuple_sets([{Arity1, _} = T1|Left1] = L1,
[{Arity2, _} = T2|Left2] = L2, Acc) ->
if Arity1 < Arity2 -> sup_tuple_sets(Left1, L2, [T1|Acc]);
Arity1 > Arity2 -> sup_tuple_sets(L1, Left2, [T2|Acc])
end;
sup_tuple_sets([], L2, Acc) -> lists:reverse(Acc, L2);
sup_tuple_sets(L1, [], Acc) -> lists:reverse(Acc, L1).
sup_tuples_in_set([?tuple(_, _, ?any) = T], L) ->
[t_tuple(sup_tuple_elements([T|L]))];
sup_tuples_in_set(L, [?tuple(_, _, ?any) = T]) ->
[t_tuple(sup_tuple_elements([T|L]))];
sup_tuples_in_set(L1, L2) ->
FoldFun = fun(?tuple(_, _, Tag), AccTag) -> t_sup(Tag, AccTag) end,
TotalTag0 = lists:foldl(FoldFun, ?none, L1),
TotalTag = lists:foldl(FoldFun, TotalTag0, L2),
case TotalTag of
?atom(?any) ->
%% We will reach the set limit. Widen now.
[t_tuple(sup_tuple_elements(L1 ++ L2))];
?atom(Set) ->
case set_size(Set) > ?TUPLE_TAG_LIMIT of
true ->
%% We will reach the set limit. Widen now.
[t_tuple(sup_tuple_elements(L1 ++ L2))];
false ->
%% We can go on and build the tuple set.
sup_tuples_in_set(L1, L2, [])
end
end.
sup_tuple_elements([?tuple(Elements, _, _)|L]) ->
lists:foldl(fun (?tuple(Es, _, _), Acc) -> t_sup_lists(Es, Acc) end,
Elements, L).
sup_tuples_in_set([?tuple(Elements1, Arity, Tag1) = T1|Left1] = L1,
[?tuple(Elements2, Arity, Tag2) = T2|Left2] = L2, Acc) ->
if
Tag1 < Tag2 -> sup_tuples_in_set(Left1, L2, [T1|Acc]);
Tag1 > Tag2 -> sup_tuples_in_set(L1, Left2, [T2|Acc]);
Tag2 =:= Tag2 -> NewElements = t_sup_lists(Elements1, Elements2),
NewAcc = [?tuple(NewElements, Arity, Tag1)|Acc],
sup_tuples_in_set(Left1, Left2, NewAcc)
end;
sup_tuples_in_set([], L2, Acc) -> lists:reverse(Acc, L2);
sup_tuples_in_set(L1, [], Acc) -> lists:reverse(Acc, L1).
sup_union(U1, U2) ->
sup_union(U1, U2, 0, []).
sup_union([?none|Left1], [?none|Left2], N, Acc) ->
sup_union(Left1, Left2, N, [?none|Acc]);
sup_union([T1|Left1], [T2|Left2], N, Acc) ->
sup_union(Left1, Left2, N+1, [t_sup(T1, T2)|Acc]);
sup_union([], [], N, Acc) ->
if N =:= 0 -> ?none;
N =:= 1 ->
[Type] = [T || T <- Acc, T =/= ?none],
Type;
N =:= length(Acc) -> ?any;
true -> ?union(lists:reverse(Acc))
end.
force_union(T = ?atom(_)) -> ?atom_union(T);
force_union(T = ?bitstr(_, _)) -> ?bitstr_union(T);
force_union(T = ?function(_, _)) -> ?function_union(T);
force_union(T = ?identifier(_)) -> ?identifier_union(T);
force_union(T = ?list(_, _, _)) -> ?list_union(T);
force_union(T = ?nil) -> ?list_union(T);
force_union(T = ?number(_, _)) -> ?number_union(T);
force_union(T = ?opaque(_)) -> ?opaque_union(T);
force_union(T = ?map(_,_,_)) -> ?map_union(T);
force_union(T = ?tuple(_, _, _)) -> ?tuple_union(T);
force_union(T = ?tuple_set(_)) -> ?tuple_union(T);
force_union(T = ?matchstate(_, _)) -> ?matchstate_union(T);
force_union(T = ?union(_)) -> T.
%%-----------------------------------------------------------------------------
%% An attempt to write the inverse operation of t_sup/1 -- XXX: INCOMPLETE !!
%%
-spec t_elements(erl_type()) -> [erl_type()].
t_elements(?none) -> [];
t_elements(?unit) -> [];
t_elements(?any = T) -> [T];
t_elements(?nil = T) -> [T];
t_elements(?atom(?any) = T) -> [T];
t_elements(?atom(Atoms)) ->
[t_atom(A) || A <- Atoms];
t_elements(?bitstr(_, _) = T) -> [T];
t_elements(?function(_, _) = T) -> [T];
t_elements(?identifier(?any) = T) -> [T];
t_elements(?identifier(IDs)) ->
[?identifier([T]) || T <- IDs];
t_elements(?list(_, _, _) = T) -> [T];
t_elements(?number(_, _) = T) ->
case T of
?number(?any, ?unknown_qual) ->
[?float, ?integer(?any)];
?float -> [T];
?integer(?any) -> [T];
?int_range(_, _) -> [T];
?int_set(Set) ->
[t_integer(I) || I <- Set]
end;
t_elements(?opaque(_) = T) ->
do_elements(T);
t_elements(?map(_,_,_) = T) -> [T];
t_elements(?tuple(_, _, _) = T) -> [T];
t_elements(?tuple_set(_) = TS) ->
case t_tuple_subtypes(TS) of
unknown -> [];
Elems -> Elems
end;
t_elements(?union(_) = T) ->
do_elements(T);
t_elements(?var(_)) -> [?any]. %% yes, vars exist -- what else to do here?
%% t_elements(T) ->
%% io:format("T_ELEMENTS => ~p\n", [T]).
do_elements(Type0) ->
case do_opaque(Type0, 'universe', fun(T) -> T end) of
?union(List) -> lists:append([t_elements(T) || T <- List]);
Type -> t_elements(Type)
end.
%%-----------------------------------------------------------------------------
%% Infimum
%%
-spec t_inf([erl_type()]) -> erl_type().
t_inf([H1, H2|T]) ->
case t_inf(H1, H2) of
?none -> ?none;
NewH -> t_inf([NewH|T])
end;
t_inf([H]) -> H;
t_inf([]) -> ?none.
-spec t_inf(erl_type(), erl_type()) -> erl_type().
t_inf(T1, T2) ->
t_inf(T1, T2, 'universe').
%% 'match' should be used from t_find_unknown_opaque() only
-type t_inf_opaques() :: opaques() | {'match', [erl_type() | 'universe']}.
-spec t_inf(erl_type(), erl_type(), t_inf_opaques()) -> erl_type().
t_inf(?var(_), ?var(_), _Opaques) -> ?any;
t_inf(?var(_), T, _Opaques) -> subst_all_vars_to_any(T);
t_inf(T, ?var(_), _Opaques) -> subst_all_vars_to_any(T);
t_inf(?any, T, _Opaques) -> subst_all_vars_to_any(T);
t_inf(T, ?any, _Opaques) -> subst_all_vars_to_any(T);
t_inf(?none, _, _Opaques) -> ?none;
t_inf(_, ?none, _Opaques) -> ?none;
t_inf(?unit, _, _Opaques) -> ?unit; % ?unit cases should appear below ?none
t_inf(_, ?unit, _Opaques) -> ?unit;
t_inf(T, T, _Opaques) -> subst_all_vars_to_any(T);
t_inf(?atom(Set1), ?atom(Set2), _) ->
case set_intersection(Set1, Set2) of
?none -> ?none;
NewSet -> ?atom(NewSet)
end;
t_inf(?bitstr(U1, B1), ?bitstr(0, B2), _Opaques) ->
if B2 >= B1 andalso (B2-B1) rem U1 =:= 0 -> t_bitstr(0, B2);
true -> ?none
end;
t_inf(?bitstr(0, B1), ?bitstr(U2, B2), _Opaques) ->
if B1 >= B2 andalso (B1-B2) rem U2 =:= 0 -> t_bitstr(0, B1);
true -> ?none
end;
t_inf(?bitstr(U1, B1), ?bitstr(U1, B1), _Opaques) ->
t_bitstr(U1, B1);
t_inf(?bitstr(U1, B1), ?bitstr(U2, B2), _Opaques) when U2 > U1 ->
inf_bitstr(U2, B2, U1, B1);
t_inf(?bitstr(U1, B1), ?bitstr(U2, B2), _Opaques) ->
inf_bitstr(U1, B1, U2, B2);
t_inf(?function(Domain1, Range1), ?function(Domain2, Range2), Opaques) ->
case t_inf(Domain1, Domain2, Opaques) of
?none -> ?none;
Domain -> ?function(Domain, t_inf(Range1, Range2, Opaques))
end;
t_inf(?identifier(Set1), ?identifier(Set2), _Opaques) ->
case set_intersection(Set1, Set2) of
?none -> ?none;
Set -> ?identifier(Set)
end;
t_inf(?map(_, ADefK, ADefV) = A, ?map(_, BDefK, BDefV) = B, _Opaques) ->
%% Because it simplifies the anonymous function, we allow Pairs to temporarily
%% contain mandatory pairs with none values, since all such cases should
%% result in a none result.
Pairs =
map_pairwise_merge(
%% For optional keys in both maps, when the infinimum is none, we have
%% essentially concluded that K must not be a key in the map.
fun(K, ?opt, V1, ?opt, V2) -> {K, ?opt, t_inf(V1, V2)};
%% When a key is optional in one map, but mandatory in another, it
%% becomes mandatory in the infinumum
(K, _, V1, _, V2) -> {K, ?mand, t_inf(V1, V2)}
end, A, B),
t_map(Pairs, t_inf(ADefK, BDefK), t_inf(ADefV, BDefV));
t_inf(?matchstate(Pres1, Slots1), ?matchstate(Pres2, Slots2), _Opaques) ->
?matchstate(t_inf(Pres1, Pres2), t_inf(Slots1, Slots2));
t_inf(?nil, ?nil, _Opaques) -> ?nil;
t_inf(?nil, ?nonempty_list(_, _), _Opaques) ->
?none;
t_inf(?nonempty_list(_, _), ?nil, _Opaques) ->
?none;
t_inf(?nil, ?list(_Contents, Termination, _), Opaques) ->
t_inf(?nil, t_unopaque(Termination), Opaques);
t_inf(?list(_Contents, Termination, _), ?nil, Opaques) ->
t_inf(?nil, t_unopaque(Termination), Opaques);
t_inf(?list(Contents1, Termination1, Size1),
?list(Contents2, Termination2, Size2), Opaques) ->
case t_inf(Termination1, Termination2, Opaques) of
?none -> ?none;
Termination ->
case t_inf(Contents1, Contents2, Opaques) of
?none ->
%% If none of the lists are nonempty, then the infimum is nil.
case (Size1 =:= ?unknown_qual) andalso (Size2 =:= ?unknown_qual) of
true -> t_nil();
false -> ?none
end;
Contents ->
Size =
case {Size1, Size2} of
{?unknown_qual, ?unknown_qual} -> ?unknown_qual;
{?unknown_qual, ?nonempty_qual} -> ?nonempty_qual;
{?nonempty_qual, ?unknown_qual} -> ?nonempty_qual;
{?nonempty_qual, ?nonempty_qual} -> ?nonempty_qual
end,
?list(Contents, Termination, Size)
end
end;
t_inf(?number(_, _) = T1, ?number(_, _) = T2, _Opaques) ->
case {T1, T2} of
{T, T} -> T;
{_, ?number(?any, ?unknown_qual)} -> T1;
{?number(?any, ?unknown_qual), _} -> T2;
{?float, ?integer(_)} -> ?none;
{?integer(_), ?float} -> ?none;
{?integer(?any), ?integer(_)} -> T2;
{?integer(_), ?integer(?any)} -> T1;
{?int_set(Set1), ?int_set(Set2)} ->
case set_intersection(Set1, Set2) of
?none -> ?none;
Set -> ?int_set(Set)
end;
{?int_range(From1, To1), ?int_range(From2, To2)} ->
t_from_range(max(From1, From2), min(To1, To2));
{Range = ?int_range(_, _), ?int_set(Set)} ->
%% io:format("t_inf range, set args ~p ~p ~n", [T1, T2]),
Ans2 =
case set_filter(fun(X) -> in_range(X, Range) end, Set) of
?none -> ?none;
NewSet -> ?int_set(NewSet)
end,
%% io:format("Ans2 ~p ~n", [Ans2]),
Ans2;
{?int_set(Set), ?int_range(_, _) = Range} ->
case set_filter(fun(X) -> in_range(X, Range) end, Set) of
?none -> ?none;
NewSet -> ?int_set(NewSet)
end
end;
t_inf(?product(Types1), ?product(Types2), Opaques) ->
L1 = length(Types1),
L2 = length(Types2),
if L1 =:= L2 -> ?product(t_inf_lists(Types1, Types2, Opaques));
true -> ?none
end;
t_inf(?product(_), _, _Opaques) ->
?none;
t_inf(_, ?product(_), _Opaques) ->
?none;
t_inf(?tuple(?any, ?any, ?any), ?tuple(_, _, _) = T, _Opaques) ->
subst_all_vars_to_any(T);
t_inf(?tuple(_, _, _) = T, ?tuple(?any, ?any, ?any), _Opaques) ->
subst_all_vars_to_any(T);
t_inf(?tuple(?any, ?any, ?any), ?tuple_set(_) = T, _Opaques) ->
subst_all_vars_to_any(T);
t_inf(?tuple_set(_) = T, ?tuple(?any, ?any, ?any), _Opaques) ->
subst_all_vars_to_any(T);
t_inf(?tuple(Elements1, Arity, _Tag1), ?tuple(Elements2, Arity, _Tag2), Opaques) ->
case t_inf_lists_strict(Elements1, Elements2, Opaques) of
bottom -> ?none;
NewElements -> t_tuple(NewElements)
end;
t_inf(?tuple_set(List1), ?tuple_set(List2), Opaques) ->
inf_tuple_sets(List1, List2, Opaques);
t_inf(?tuple_set(List), ?tuple(_, Arity, _) = T, Opaques) ->
inf_tuple_sets(List, [{Arity, [T]}], Opaques);
t_inf(?tuple(_, Arity, _) = T, ?tuple_set(List), Opaques) ->
inf_tuple_sets(List, [{Arity, [T]}], Opaques);
%% be careful: here and in the next clause T can be ?opaque
t_inf(?union(U1), T, Opaques) ->
?union(U2) = force_union(T),
inf_union(U1, U2, Opaques);
t_inf(T, ?union(U2), Opaques) ->
?union(U1) = force_union(T),
inf_union(U1, U2, Opaques);
t_inf(?opaque(Set1), ?opaque(Set2), Opaques) ->
inf_opaque(Set1, Set2, Opaques);
t_inf(?opaque(_) = T1, T2, Opaques) ->
inf_opaque1(T2, T1, 1, Opaques);
t_inf(T1, ?opaque(_) = T2, Opaques) ->
inf_opaque1(T1, T2, 2, Opaques);
%% and as a result, the cases for ?opaque should appear *after* ?union
t_inf(#c{}, #c{}, _) ->
?none.
inf_opaque1(T1, ?opaque(Set2)=T2, Pos, Opaques) ->
case Opaques =:= 'universe' orelse inf_is_opaque_type(T2, Pos, Opaques) of
false -> ?none;
true ->
List2 = set_to_list(Set2),
case inf_collect(T1, List2, Opaques, []) of
[] -> ?none;
OpL -> ?opaque(ordsets:from_list(OpL))
end
end.
inf_is_opaque_type(T, Pos, {match, Opaques}) ->
is_opaque_type(T, Opaques) orelse throw({pos, [Pos]});
inf_is_opaque_type(T, _Pos, Opaques) ->
is_opaque_type(T, Opaques).
inf_collect(T1, [T2|List2], Opaques, OpL) ->
#opaque{struct = S2} = T2,
case t_inf(T1, S2, Opaques) of
?none -> inf_collect(T1, List2, Opaques, OpL);
Inf ->
Op = T2#opaque{struct = Inf},
inf_collect(T1, List2, Opaques, [Op|OpL])
end;
inf_collect(_T1, [], _Opaques, OpL) ->
OpL.
combine(S, T1, T2) ->
case is_compat_opaque_names(T1, T2) of
true -> combine(S, [T1]);
false -> combine(S, [T1, T2])
end.
combine(?opaque(Set), Ts) ->
[comb2(O, T) || O <- Set, T <- Ts];
combine(S, Ts) ->
[T#opaque{struct = S} || T <- Ts].
comb2(O, T) ->
case is_compat_opaque_names(O, T) of
true -> O;
false -> T#opaque{struct = ?opaque(set_singleton(O))}
end.
%% Combining two lists this way can be very time consuming...
%% Note: two parameterized opaque types are not the same if their
%% actual parameters differ
inf_opaque(Set1, Set2, Opaques) ->
List1 = inf_look_up(Set1, Opaques),
List2 = inf_look_up(Set2, Opaques),
List0 = [combine(Inf, T1, T2) ||
{Is1, T1} <- List1,
{Is2, T2} <- List2,
not t_is_none(Inf = inf_opaque_types(Is1, T1, Is2, T2, Opaques))],
List = lists:append(List0),
sup_opaque(List).
%% Optimization: do just one lookup.
inf_look_up(Set, Opaques) ->
[{Opaques =:= 'universe' orelse inf_is_opaque_type2(T, Opaques), T} ||
T <- set_to_list(Set)].
inf_is_opaque_type2(T, {match, Opaques}) ->
is_opaque_type2(T, Opaques);
inf_is_opaque_type2(T, Opaques) ->
is_opaque_type2(T, Opaques).
inf_opaque_types(IsOpaque1, T1, IsOpaque2, T2, Opaques) ->
#opaque{struct = S1}=T1,
#opaque{struct = S2}=T2,
case
Opaques =:= 'universe' orelse is_compat_opaque_names(T1, T2)
of
true -> t_inf(S1, S2, Opaques);
false ->
case {IsOpaque1, IsOpaque2} of
{true, true} -> t_inf(S1, S2, Opaques);
{true, false} -> t_inf(S1, ?opaque(set_singleton(T2)), Opaques);
{false, true} -> t_inf(?opaque(set_singleton(T1)), S2, Opaques);
{false, false} when element(1, Opaques) =:= match ->
throw({pos, [1, 2]});
{false, false} -> t_none()
end
end.
compatible_opaque_types(?opaque(Es1), ?opaque(Es2)) ->
[{O1, O2} || O1 <- Es1, O2 <- Es2, is_compat_opaque_names(O1, O2)].
is_compat_opaque_names(Opaque1, Opaque2) ->
#opaque{mod = Mod1, name = Name1, args = Args1} = Opaque1,
#opaque{mod = Mod2, name = Name2, args = Args2} = Opaque2,
case {{Mod1, Name1, Args1}, {Mod2, Name2, Args2}} of
{ModNameArgs, ModNameArgs} -> true;
{{Mod, Name, Args1}, {Mod, Name, Args2}} ->
is_compat_args(Args1, Args2);
_ -> false
end.
is_compat_args([A1|Args1], [A2|Args2]) ->
is_compat_arg(A1, A2) andalso is_compat_args(Args1, Args2);
is_compat_args([], []) -> true;
is_compat_args(_, _) -> false.
-spec is_compat_arg(erl_type(), erl_type()) -> boolean().
%% The intention is that 'true' is to be returned iff one of the
%% arguments is a specialization of the other argument in the sense
%% that every type is a specialization of any(). For example, {_,_} is
%% a specialization of any(), but not of tuple(). Does not handle
%% variables, but any() and unions (sort of). However, the
%% implementation is more relaxed as any() is compatible to anything.
is_compat_arg(T, T) -> true;
is_compat_arg(_, ?any) -> true;
is_compat_arg(?any, _) -> true;
is_compat_arg(?function(Domain1, Range1), ?function(Domain2, Range2)) ->
(is_compat_arg(Domain1, Domain2) andalso
is_compat_arg(Range1, Range2));
is_compat_arg(?list(Contents1, Termination1, Size1),
?list(Contents2, Termination2, Size2)) ->
(Size1 =:= Size2 andalso
is_compat_arg(Contents1, Contents2) andalso
is_compat_arg(Termination1, Termination2));
is_compat_arg(?product(Types1), ?product(Types2)) ->
is_compat_list(Types1, Types2);
is_compat_arg(?map(Pairs1, DefK1, DefV1), ?map(Pairs2, DefK2, DefV2)) ->
{Ks1, _, Vs1} = lists:unzip3(Pairs1),
{Ks2, _, Vs2} = lists:unzip3(Pairs2),
Key1 = t_sup([DefK1 | Ks1]),
Key2 = t_sup([DefK2 | Ks2]),
case is_compat_arg(Key1, Key2) of
true ->
Value1 = t_sup([DefV1 | Vs1]),
Value2 = t_sup([DefV2 | Vs2]),
is_compat_arg(Value1, Value2);
false ->
false
end;
is_compat_arg(?tuple(?any, ?any, ?any), ?tuple(_, _, _)) -> false;
is_compat_arg(?tuple(_, _, _), ?tuple(?any, ?any, ?any)) -> false;
is_compat_arg(?tuple(Elements1, Arity, _),
?tuple(Elements2, Arity, _)) when Arity =/= ?any ->
is_compat_list(Elements1, Elements2);
is_compat_arg(?tuple_set([{Arity, List}]),
?tuple(Elements2, Arity, _)) when Arity =/= ?any ->
is_compat_list(sup_tuple_elements(List), Elements2);
is_compat_arg(?tuple(Elements1, Arity, _),
?tuple_set([{Arity, List}])) when Arity =/= ?any ->
is_compat_list(Elements1, sup_tuple_elements(List));
is_compat_arg(?tuple_set(List1), ?tuple_set(List2)) ->
try
is_compat_list_list([sup_tuple_elements(T) || {_Arity, T} <- List1],
[sup_tuple_elements(T) || {_Arity, T} <- List2])
catch _:_ -> false
end;
is_compat_arg(?opaque(_) = T1, T2) ->
is_compat_arg(t_opaque_structure(T1), T2);
is_compat_arg(T1, ?opaque(_) = T2) ->
is_compat_arg(T1, t_opaque_structure(T2));
is_compat_arg(?union(List1)=T1, ?union(List2)=T2) ->
case is_compat_union2(T1, T2) of
{yes, Type1, Type2} -> is_compat_arg(Type1, Type2);
no -> is_compat_list(List1, List2)
end;
is_compat_arg(?union(List), T2) ->
case unify_union(List) of
{yes, Type} -> is_compat_arg(Type, T2);
no -> false
end;
is_compat_arg(T1, ?union(List)) ->
case unify_union(List) of
{yes, Type} -> is_compat_arg(T1, Type);
no -> false
end;
is_compat_arg(?var(_), _) -> exit(error);
is_compat_arg(_, ?var(_)) -> exit(error);
is_compat_arg(?none, _) -> false;
is_compat_arg(_, ?none) -> false;
is_compat_arg(?unit, _) -> false;
is_compat_arg(_, ?unit) -> false;
is_compat_arg(#c{}, #c{}) -> false.
is_compat_list_list(LL1, LL2) ->
length(LL1) =:= length(LL2) andalso is_compat_list_list1(LL1, LL2).
is_compat_list_list1([], []) -> true;
is_compat_list_list1([L1|LL1], [L2|LL2]) ->
is_compat_list(L1, L2) andalso is_compat_list_list1(LL1, LL2).
is_compat_list(L1, L2) ->
length(L1) =:= length(L2) andalso is_compat_list1(L1, L2).
is_compat_list1([], []) -> true;
is_compat_list1([T1|L1], [T2|L2]) ->
is_compat_arg(T1, T2) andalso is_compat_list1(L1, L2).
is_compat_union2(?union(List1)=T1, ?union(List2)=T2) ->
case {unify_union(List1), unify_union(List2)} of
{{yes, Type1}, {yes, Type2}} -> {yes, Type1, Type2};
{{yes, Type1}, no} -> {yes, Type1, T2};
{no, {yes, Type2}} -> {yes, T1, Type2};
{no, no} -> no
end.
-spec t_inf_lists([erl_type()], [erl_type()]) -> [erl_type()].
t_inf_lists(L1, L2) ->
t_inf_lists(L1, L2, 'universe').
-spec t_inf_lists([erl_type()], [erl_type()], t_inf_opaques()) -> [erl_type()].
t_inf_lists(L1, L2, Opaques) ->
t_inf_lists(L1, L2, [], Opaques).
-spec t_inf_lists([erl_type()], [erl_type()], [erl_type()], [erl_type()]) -> [erl_type()].
t_inf_lists([T1|Left1], [T2|Left2], Acc, Opaques) ->
t_inf_lists(Left1, Left2, [t_inf(T1, T2, Opaques)|Acc], Opaques);
t_inf_lists([], [], Acc, _Opaques) ->
lists:reverse(Acc).
%% Infimum of lists with strictness.
%% If any element is the ?none type, the value 'bottom' is returned.
-spec t_inf_lists_strict([erl_type()], [erl_type()], [erl_type()]) -> 'bottom' | [erl_type()].
t_inf_lists_strict(L1, L2, Opaques) ->
t_inf_lists_strict(L1, L2, [], Opaques).
-spec t_inf_lists_strict([erl_type()], [erl_type()], [erl_type()], [erl_type()]) -> 'bottom' | [erl_type()].
t_inf_lists_strict([T1|Left1], [T2|Left2], Acc, Opaques) ->
case t_inf(T1, T2, Opaques) of
?none -> bottom;
T -> t_inf_lists_strict(Left1, Left2, [T|Acc], Opaques)
end;
t_inf_lists_strict([], [], Acc, _Opaques) ->
lists:reverse(Acc).
inf_tuple_sets(L1, L2, Opaques) ->
case inf_tuple_sets(L1, L2, [], Opaques) of
[] -> ?none;
[{_Arity, [?tuple(_, _, _) = OneTuple]}] -> OneTuple;
List -> ?tuple_set(List)
end.
inf_tuple_sets([{Arity, Tuples1}|Ts1], [{Arity, Tuples2}|Ts2], Acc, Opaques) ->
case inf_tuples_in_sets(Tuples1, Tuples2, Opaques) of
[] -> inf_tuple_sets(Ts1, Ts2, Acc, Opaques);
[?tuple_set([{Arity, NewTuples}])] ->
inf_tuple_sets(Ts1, Ts2, [{Arity, NewTuples}|Acc], Opaques);
NewTuples -> inf_tuple_sets(Ts1, Ts2, [{Arity, NewTuples}|Acc], Opaques)
end;
inf_tuple_sets([{Arity1, _}|Ts1] = L1, [{Arity2, _}|Ts2] = L2, Acc, Opaques) ->
if Arity1 < Arity2 -> inf_tuple_sets(Ts1, L2, Acc, Opaques);
Arity1 > Arity2 -> inf_tuple_sets(L1, Ts2, Acc, Opaques)
end;
inf_tuple_sets([], _, Acc, _Opaques) -> lists:reverse(Acc);
inf_tuple_sets(_, [], Acc, _Opaques) -> lists:reverse(Acc).
inf_tuples_in_sets([?tuple(Elements1, _, ?any)], L2, Opaques) ->
NewList = [t_inf_lists_strict(Elements1, Elements2, Opaques)
|| ?tuple(Elements2, _, _) <- L2],
[t_tuple(Es) || Es <- NewList, Es =/= bottom];
inf_tuples_in_sets(L1, [?tuple(Elements2, _, ?any)], Opaques) ->
NewList = [t_inf_lists_strict(Elements1, Elements2, Opaques)
|| ?tuple(Elements1, _, _) <- L1],
[t_tuple(Es) || Es <- NewList, Es =/= bottom];
inf_tuples_in_sets(L1, L2, Opaques) ->
inf_tuples_in_sets2(L1, L2, [], Opaques).
inf_tuples_in_sets2([?tuple(Elements1, Arity, Tag)|Ts1],
[?tuple(Elements2, Arity, Tag)|Ts2], Acc, Opaques) ->
case t_inf_lists_strict(Elements1, Elements2, Opaques) of
bottom -> inf_tuples_in_sets2(Ts1, Ts2, Acc, Opaques);
NewElements ->
inf_tuples_in_sets2(Ts1, Ts2, [?tuple(NewElements, Arity, Tag)|Acc],
Opaques)
end;
inf_tuples_in_sets2([?tuple(_, _, Tag1)|Ts1] = L1,
[?tuple(_, _, Tag2)|Ts2] = L2, Acc, Opaques) ->
if Tag1 < Tag2 -> inf_tuples_in_sets2(Ts1, L2, Acc, Opaques);
Tag1 > Tag2 -> inf_tuples_in_sets2(L1, Ts2, Acc, Opaques)
end;
inf_tuples_in_sets2([], _, Acc, _Opaques) -> lists:reverse(Acc);
inf_tuples_in_sets2(_, [], Acc, _Opaques) -> lists:reverse(Acc).
inf_union(U1, U2, Opaques) ->
OpaqueFun =
fun(Union1, Union2, InfFun) ->
[_,_,_,_,_,_,_,_,Opaque,_] = Union1,
[A,B,F,I,L,N,T,M,_,Map] = Union2,
List = [A,B,F,I,L,N,T,M,Map],
inf_union_collect(List, Opaque, InfFun, [], [])
end,
{O1, ThrowList1} =
OpaqueFun(U1, U2, fun(E, Opaque) -> t_inf(Opaque, E, Opaques) end),
{O2, ThrowList2}
= OpaqueFun(U2, U1, fun(E, Opaque) -> t_inf(E, Opaque, Opaques) end),
{Union, ThrowList3} = inf_union(U1, U2, 0, [], [], Opaques),
ThrowList = lists:merge3(ThrowList1, ThrowList2, ThrowList3),
case t_sup([O1, O2, Union]) of
?none when ThrowList =/= [] -> throw({pos, lists:usort(ThrowList)});
Sup -> Sup
end.
inf_union_collect([], _Opaque, _InfFun, InfList, ThrowList) ->
{t_sup(InfList), lists:usort(ThrowList)};
inf_union_collect([?none|L], Opaque, InfFun, InfList, ThrowList) ->
inf_union_collect(L, Opaque, InfFun, [?none|InfList], ThrowList);
inf_union_collect([E|L], Opaque, InfFun, InfList, ThrowList) ->
try InfFun(E, Opaque)of
Inf ->
inf_union_collect(L, Opaque, InfFun, [Inf|InfList], ThrowList)
catch throw:{pos, Ns} ->
inf_union_collect(L, Opaque, InfFun, InfList, Ns ++ ThrowList)
end.
inf_union([?none|Left1], [?none|Left2], N, Acc, ThrowList, Opaques) ->
inf_union(Left1, Left2, N, [?none|Acc], ThrowList, Opaques);
inf_union([T1|Left1], [T2|Left2], N, Acc, ThrowList, Opaques) ->
try t_inf(T1, T2, Opaques) of
?none -> inf_union(Left1, Left2, N, [?none|Acc], ThrowList, Opaques);
T -> inf_union(Left1, Left2, N+1, [T|Acc], ThrowList, Opaques)
catch throw:{pos, Ns} ->
inf_union(Left1, Left2, N, [?none|Acc], Ns ++ ThrowList, Opaques)
end;
inf_union([], [], N, Acc, ThrowList, _Opaques) ->
if N =:= 0 -> {?none, ThrowList};
N =:= 1 ->
[Type] = [T || T <- Acc, T =/= ?none],
{Type, ThrowList};
N >= 2 -> {?union(lists:reverse(Acc)), ThrowList}
end.
inf_bitstr(U1, B1, U2, B2) ->
GCD = gcd(U1, U2),
case (B2-B1) rem GCD of
0 ->
U = (U1*U2) div GCD,
B = findfirst(0, 0, U1, B1, U2, B2),
t_bitstr(U, B);
_ ->
?none
end.
findfirst(N1, N2, U1, B1, U2, B2) ->
Val1 = U1*N1+B1,
Val2 = U2*N2+B2,
if Val1 =:= Val2 ->
Val1;
Val1 > Val2 ->
findfirst(N1, N2+1, U1, B1, U2, B2);
Val1 < Val2 ->
findfirst(N1+1, N2, U1, B1, U2, B2)
end.
%%-----------------------------------------------------------------------------
%% Substitution of variables
%%
-type subst_table() :: #{any() => erl_type()}.
-spec t_subst(erl_type(), subst_table()) -> erl_type().
t_subst(T, Map) ->
case t_has_var(T) of
true -> t_subst_aux(T, Map);
false -> T
end.
-spec subst_all_vars_to_any(erl_type()) -> erl_type().
subst_all_vars_to_any(T) ->
t_subst(T, #{}).
t_subst_aux(?var(Id), Map) ->
case maps:find(Id, Map) of
error -> ?any;
{ok, Type} -> Type
end;
t_subst_aux(?list(Contents, Termination, Size), Map) ->
case t_subst_aux(Contents, Map) of
?none -> ?none;
NewContents ->
%% Be careful here to make the termination collapse if necessary.
case t_subst_aux(Termination, Map) of
?nil -> ?list(NewContents, ?nil, Size);
?any -> ?list(NewContents, ?any, Size);
Other ->
?list(NewContents2, NewTermination, _) = t_cons(NewContents, Other),
?list(NewContents2, NewTermination, Size)
end
end;
t_subst_aux(?function(Domain, Range), Map) ->
?function(t_subst_aux(Domain, Map), t_subst_aux(Range, Map));
t_subst_aux(?product(Types), Map) ->
?product([t_subst_aux(T, Map) || T <- Types]);
t_subst_aux(?tuple(?any, ?any, ?any) = T, _Map) ->
T;
t_subst_aux(?tuple(Elements, _Arity, _Tag), Map) ->
t_tuple([t_subst_aux(E, Map) || E <- Elements]);
t_subst_aux(?tuple_set(_) = TS, Map) ->
t_sup([t_subst_aux(T, Map) || T <- t_tuple_subtypes(TS)]);
t_subst_aux(?map(Pairs, DefK, DefV), Map) ->
t_map([{K, MNess, t_subst_aux(V, Map)} || {K, MNess, V} <- Pairs],
t_subst_aux(DefK, Map), t_subst_aux(DefV, Map));
t_subst_aux(?opaque(Es), Map) ->
List = [Opaque#opaque{args = [t_subst_aux(Arg, Map) || Arg <- Args],
struct = t_subst_aux(S, Map)} ||
Opaque = #opaque{args = Args, struct = S} <- set_to_list(Es)],
?opaque(ordsets:from_list(List));
t_subst_aux(?union(List), Map) ->
?union([t_subst_aux(E, Map) || E <- List]);
t_subst_aux(T, _Map) ->
T.
%%-----------------------------------------------------------------------------
%% Unification
%%
-type t_unify_ret() :: {erl_type(), [{_, erl_type()}]}.
-spec t_unify(erl_type(), erl_type()) -> t_unify_ret().
t_unify(T1, T2) ->
{T, VarMap} = t_unify(T1, T2, #{}),
{t_subst(T, VarMap), lists:keysort(1, maps:to_list(VarMap))}.
t_unify(?var(Id) = T, ?var(Id), VarMap) ->
{T, VarMap};
t_unify(?var(Id1) = T, ?var(Id2), VarMap) ->
case maps:find(Id1, VarMap) of
error ->
case maps:find(Id2, VarMap) of
error -> {T, VarMap#{Id2 => T}};
{ok, Type} -> t_unify(T, Type, VarMap)
end;
{ok, Type1} ->
case maps:find(Id2, VarMap) of
error -> {Type1, VarMap#{Id2 => T}};
{ok, Type2} -> t_unify(Type1, Type2, VarMap)
end
end;
t_unify(?var(Id), Type, VarMap) ->
case maps:find(Id, VarMap) of
error -> {Type, VarMap#{Id => Type}};
{ok, VarType} -> t_unify(VarType, Type, VarMap)
end;
t_unify(Type, ?var(Id), VarMap) ->
case maps:find(Id, VarMap) of
error -> {Type, VarMap#{Id => Type}};
{ok, VarType} -> t_unify(VarType, Type, VarMap)
end;
t_unify(?function(Domain1, Range1), ?function(Domain2, Range2), VarMap) ->
{Domain, VarMap1} = t_unify(Domain1, Domain2, VarMap),
{Range, VarMap2} = t_unify(Range1, Range2, VarMap1),
{?function(Domain, Range), VarMap2};
t_unify(?list(Contents1, Termination1, Size),
?list(Contents2, Termination2, Size), VarMap) ->
{Contents, VarMap1} = t_unify(Contents1, Contents2, VarMap),
{Termination, VarMap2} = t_unify(Termination1, Termination2, VarMap1),
{?list(Contents, Termination, Size), VarMap2};
t_unify(?product(Types1), ?product(Types2), VarMap) ->
{Types, VarMap1} = unify_lists(Types1, Types2, VarMap),
{?product(Types), VarMap1};
t_unify(?tuple(?any, ?any, ?any) = T, ?tuple(?any, ?any, ?any), VarMap) ->
{T, VarMap};
t_unify(?tuple(Elements1, Arity, _),
?tuple(Elements2, Arity, _), VarMap) when Arity =/= ?any ->
{NewElements, VarMap1} = unify_lists(Elements1, Elements2, VarMap),
{t_tuple(NewElements), VarMap1};
t_unify(?tuple_set([{Arity, _}]) = T1,
?tuple(_, Arity, _) = T2, VarMap) when Arity =/= ?any ->
unify_tuple_set_and_tuple1(T1, T2, VarMap);
t_unify(?tuple(_, Arity, _) = T1,
?tuple_set([{Arity, _}]) = T2, VarMap) when Arity =/= ?any ->
unify_tuple_set_and_tuple2(T1, T2, VarMap);
t_unify(?tuple_set(List1) = T1, ?tuple_set(List2) = T2, VarMap) ->
try
unify_lists(lists:append([T || {_Arity, T} <- List1]),
lists:append([T || {_Arity, T} <- List2]), VarMap)
of
{Tuples, NewVarMap} -> {t_sup(Tuples), NewVarMap}
catch _:_ -> throw({mismatch, T1, T2})
end;
t_unify(?map(_, ADefK, ADefV) = A, ?map(_, BDefK, BDefV) = B, VarMap0) ->
{DefK, VarMap1} = t_unify(ADefK, BDefK, VarMap0),
{DefV, VarMap2} = t_unify(ADefV, BDefV, VarMap1),
{Pairs, VarMap} =
map_pairwise_merge_foldr(
fun(K, MNess, V1, MNess, V2, {Pairs0, VarMap3}) ->
%% We know that the keys unify and do not contain variables, or they
%% would not be singletons
%% TODO: Should V=?none (known missing keys) be handled special?
{V, VarMap4} = t_unify(V1, V2, VarMap3),
{[{K,MNess,V}|Pairs0], VarMap4};
(K, _, V1, _, V2, {Pairs0, VarMap3}) ->
%% One mandatory and one optional; what should be done in this case?
{V, VarMap4} = t_unify(V1, V2, VarMap3),
{[{K,?mand,V}|Pairs0], VarMap4}
end, {[], VarMap2}, A, B),
{t_map(Pairs, DefK, DefV), VarMap};
t_unify(?opaque(_) = T1, ?opaque(_) = T2, VarMap) ->
t_unify(t_opaque_structure(T1), t_opaque_structure(T2), VarMap);
t_unify(T1, ?opaque(_) = T2, VarMap) ->
t_unify(T1, t_opaque_structure(T2), VarMap);
t_unify(?opaque(_) = T1, T2, VarMap) ->
t_unify(t_opaque_structure(T1), T2, VarMap);
t_unify(T, T, VarMap) ->
{T, VarMap};
t_unify(?union(_)=T1, ?union(_)=T2, VarMap) ->
{Type1, Type2} = unify_union2(T1, T2),
t_unify(Type1, Type2, VarMap);
t_unify(?union(_)=T1, T2, VarMap) ->
t_unify(unify_union1(T1, T1, T2), T2, VarMap);
t_unify(T1, ?union(_)=T2, VarMap) ->
t_unify(T1, unify_union1(T2, T1, T2), VarMap);
t_unify(T1, T2, _) ->
throw({mismatch, T1, T2}).
unify_union2(?union(List1)=T1, ?union(List2)=T2) ->
case {unify_union(List1), unify_union(List2)} of
{{yes, Type1}, {yes, Type2}} -> {Type1, Type2};
{{yes, Type1}, no} -> {Type1, T2};
{no, {yes, Type2}} -> {T1, Type2};
{no, no} -> throw({mismatch, T1, T2})
end.
unify_union1(?union(List), T1, T2) ->
case unify_union(List) of
{yes, Type} -> Type;
no -> throw({mismatch, T1, T2})
end.
unify_union(List) ->
[A,B,F,I,L,N,T,M,O,Map] = List,
if O =:= ?none -> no;
true ->
S = t_opaque_structure(O),
{yes, t_sup([A,B,F,I,L,N,T,M,S,Map])}
end.
-spec is_opaque_type(erl_type(), [erl_type()]) -> boolean().
%% An opaque type is a union of types. Returns true iff any of the type
%% names (Module and Name) of the first argument (the opaque type to
%% check) occurs in any of the opaque types of the second argument.
is_opaque_type(?opaque(Elements), Opaques) ->
lists:any(fun(Opaque) -> is_opaque_type2(Opaque, Opaques) end, Elements).
is_opaque_type2(#opaque{mod = Mod1, name = Name1, args = Args1}, Opaques) ->
F1 = fun(?opaque(Es)) ->
F2 = fun(#opaque{mod = Mod, name = Name, args = Args}) ->
is_type_name(Mod1, Name1, Args1, Mod, Name, Args)
end,
lists:any(F2, Es)
end,
lists:any(F1, Opaques).
is_type_name(Mod, Name, Args1, Mod, Name, Args2) ->
length(Args1) =:= length(Args2);
is_type_name(_Mod1, _Name1, _Args1, _Mod2, _Name2, _Args2) ->
false.
%% Two functions since t_unify is not symmetric.
unify_tuple_set_and_tuple1(?tuple_set([{Arity, List}]),
?tuple(Elements2, Arity, _), VarMap) ->
%% Can only work if the single tuple has variables at correct places.
%% Collapse the tuple set.
{NewElements, VarMap1} =
unify_lists(sup_tuple_elements(List), Elements2, VarMap),
{t_tuple(NewElements), VarMap1}.
unify_tuple_set_and_tuple2(?tuple(Elements2, Arity, _),
?tuple_set([{Arity, List}]), VarMap) ->
%% Can only work if the single tuple has variables at correct places.
%% Collapse the tuple set.
{NewElements, VarMap1} =
unify_lists(Elements2, sup_tuple_elements(List), VarMap),
{t_tuple(NewElements), VarMap1}.
unify_lists(L1, L2, VarMap) ->
unify_lists(L1, L2, VarMap, []).
unify_lists([T1|Left1], [T2|Left2], VarMap, Acc) ->
{NewT, NewVarMap} = t_unify(T1, T2, VarMap),
unify_lists(Left1, Left2, NewVarMap, [NewT|Acc]);
unify_lists([], [], VarMap, Acc) ->
{lists:reverse(Acc), VarMap}.
%%t_assign_variables_to_subtype(T1, T2) ->
%% try
%% Dict = assign_vars(T1, T2, dict:new()),
%% {ok, dict:map(fun(_Param, List) -> t_sup(List) end, Dict)}
%% catch
%% throw:error -> error
%% end.
%%assign_vars(_, ?var(_), _Dict) ->
%% erlang:error("Variable in right hand side of assignment");
%%assign_vars(?any, _, Dict) ->
%% Dict;
%%assign_vars(?var(_) = Var, Type, Dict) ->
%% store_var(Var, Type, Dict);
%%assign_vars(?function(Domain1, Range1), ?function(Domain2, Range2), Dict) ->
%% DomainList =
%% case Domain2 of
%% ?any -> [];
%% ?product(List) -> List
%% end,
%% case any_none([Range2|DomainList]) of
%% true -> throw(error);
%% false ->
%% Dict1 = assign_vars(Domain1, Domain2, Dict),
%% assign_vars(Range1, Range2, Dict1)
%% end;
%%assign_vars(?list(_Contents, _Termination, ?any), ?nil, Dict) ->
%% Dict;
%%assign_vars(?list(Contents1, Termination1, Size1),
%% ?list(Contents2, Termination2, Size2), Dict) ->
%% Dict1 = assign_vars(Contents1, Contents2, Dict),
%% Dict2 = assign_vars(Termination1, Termination2, Dict1),
%% case {Size1, Size2} of
%% {S, S} -> Dict2;
%% {?any, ?nonempty_qual} -> Dict2;
%% {_, _} -> throw(error)
%% end;
%%assign_vars(?product(Types1), ?product(Types2), Dict) ->
%% case length(Types1) =:= length(Types2) of
%% true -> assign_vars_lists(Types1, Types2, Dict);
%% false -> throw(error)
%% end;
%%assign_vars(?tuple(?any, ?any, ?any), ?tuple(?any, ?any, ?any), Dict) ->
%% Dict;
%%assign_vars(?tuple(?any, ?any, ?any), ?tuple(_, _, _), Dict) ->
%% Dict;
%%assign_vars(?tuple(Elements1, Arity, _),
%% ?tuple(Elements2, Arity, _), Dict) when Arity =/= ?any ->
%% assign_vars_lists(Elements1, Elements2, Dict);
%%assign_vars(?tuple_set(_) = T, ?tuple_set(List2), Dict) ->
%% %% All Rhs tuples must already be subtypes of Lhs, so we can take
%% %% each one separatly.
%% assign_vars_lists([T || _ <- List2], List2, Dict);
%%assign_vars(?tuple(?any, ?any, ?any), ?tuple_set(_), Dict) ->
%% Dict;
%%assign_vars(?tuple(_, Arity, _) = T1, ?tuple_set(List), Dict) ->
%% case reduce_tuple_tags(List) of
%% [Tuple = ?tuple(_, Arity, _)] -> assign_vars(T1, Tuple, Dict);
%% _ -> throw(error)
%% end;
%%assign_vars(?tuple_set(List), ?tuple(_, Arity, Tag) = T2, Dict) ->
%% case [T || ?tuple(_, Arity1, Tag1) = T <- List,
%% Arity1 =:= Arity, Tag1 =:= Tag] of
%% [] -> throw(error);
%% [T1] -> assign_vars(T1, T2, Dict)
%% end;
%%assign_vars(?union(U1), T2, Dict) ->
%% ?union(U2) = force_union(T2),
%% assign_vars_lists(U1, U2, Dict);
%%assign_vars(T, T, Dict) ->
%% Dict;
%%assign_vars(T1, T2, Dict) ->
%% case t_is_subtype(T2, T1) of
%% false -> throw(error);
%% true -> Dict
%% end.
%%assign_vars_lists([T1|Left1], [T2|Left2], Dict) ->
%% assign_vars_lists(Left1, Left2, assign_vars(T1, T2, Dict));
%%assign_vars_lists([], [], Dict) ->
%% Dict.
%%store_var(?var(Id), Type, Dict) ->
%% case dict:find(Id, Dict) of
%% error -> dict:store(Id, [Type], Dict);
%% {ok, _VarType0} -> dict:update(Id, fun(X) -> [Type|X] end, Dict)
%% end.
%%-----------------------------------------------------------------------------
%% Subtraction.
%%
%% Note that the subtraction is an approximation since we do not have
%% negative types. Also, tuples and products should be handled using
%% the cartesian product of the elements, but this is not feasible to
%% do.
%%
%% Example: {a|b,c|d}\{a,d} = {a,c}|{a,d}|{b,c}|{b,d} \ {a,d} =
%% = {a,c}|{b,c}|{b,d} = {a|b,c|d}
%%
%% Instead, we can subtract if all elements but one becomes none after
%% subtracting element-wise.
%%
%% Example: {a|b,c|d}\{a|b,d} = {a,c}|{a,d}|{b,c}|{b,d} \ {a,d}|{b,d} =
%% = {a,c}|{b,c} = {a|b,c}
-spec t_subtract_list(erl_type(), [erl_type()]) -> erl_type().
t_subtract_list(T1, [T2|Left]) ->
t_subtract_list(t_subtract(T1, T2), Left);
t_subtract_list(T, []) ->
T.
-spec t_subtract(erl_type(), erl_type()) -> erl_type().
t_subtract(_, ?any) -> ?none;
t_subtract(T, ?var(_)) -> T;
t_subtract(?any, _) -> ?any;
t_subtract(?var(_) = T, _) -> T;
t_subtract(T, ?unit) -> T;
t_subtract(?unit, _) -> ?unit;
t_subtract(?none, _) -> ?none;
t_subtract(T, ?none) -> T;
t_subtract(?atom(Set1), ?atom(Set2)) ->
case set_subtract(Set1, Set2) of
?none -> ?none;
Set -> ?atom(Set)
end;
t_subtract(?bitstr(U1, B1), ?bitstr(U2, B2)) ->
subtract_bin(t_bitstr(U1, B1), t_inf(t_bitstr(U1, B1), t_bitstr(U2, B2)));
t_subtract(?function(_, _) = T1, ?function(_, _) = T2) ->
case t_is_subtype(T1, T2) of
true -> ?none;
false -> T1
end;
t_subtract(?identifier(Set1), ?identifier(Set2)) ->
case set_subtract(Set1, Set2) of
?none -> ?none;
Set -> ?identifier(Set)
end;
t_subtract(?opaque(_)=T1, ?opaque(_)=T2) ->
opaque_subtract(T1, t_opaque_structure(T2));
t_subtract(?opaque(_)=T1, T2) ->
opaque_subtract(T1, T2);
t_subtract(T1, ?opaque(_)=T2) ->
t_subtract(T1, t_opaque_structure(T2));
t_subtract(?matchstate(Pres1, Slots1), ?matchstate(Pres2, _Slots2)) ->
Pres = t_subtract(Pres1, Pres2),
case t_is_none(Pres) of
true -> ?none;
false -> ?matchstate(Pres, Slots1)
end;
t_subtract(?matchstate(Present, Slots), _) ->
?matchstate(Present, Slots);
t_subtract(?nil, ?nil) ->
?none;
t_subtract(?nil, ?nonempty_list(_, _)) ->
?nil;
t_subtract(?nil, ?list(_, _, _)) ->
?none;
t_subtract(?list(Contents, Termination, _Size) = T, ?nil) ->
case Termination =:= ?nil of
true -> ?nonempty_list(Contents, Termination);
false -> T
end;
t_subtract(?list(Contents1, Termination1, Size1) = T,
?list(Contents2, Termination2, Size2)) ->
case t_is_subtype(Contents1, Contents2) of
true ->
case t_is_subtype(Termination1, Termination2) of
true ->
case {Size1, Size2} of
{?nonempty_qual, ?unknown_qual} -> ?none;
{?unknown_qual, ?nonempty_qual} -> ?nil;
{S, S} -> ?none
end;
false ->
%% If the termination is not covered by the subtracted type
%% we cannot really say anything about the result.
T
end;
false ->
%% All contents must be covered if there is going to be any
%% change to the list.
T
end;
t_subtract(?float, ?float) -> ?none;
t_subtract(?number(_, _) = T1, ?float) -> t_inf(T1, t_integer());
t_subtract(?float, ?number(_Set, Tag)) ->
case Tag of
?unknown_qual -> ?none;
_ -> ?float
end;
t_subtract(?number(_, _), ?number(?any, ?unknown_qual)) -> ?none;
t_subtract(?number(_, _) = T1, ?integer(?any)) -> t_inf(?float, T1);
t_subtract(?int_set(Set1), ?int_set(Set2)) ->
case set_subtract(Set1, Set2) of
?none -> ?none;
Set -> ?int_set(Set)
end;
t_subtract(?int_range(From1, To1) = T1, ?int_range(_, _) = T2) ->
case t_inf(T1, T2) of
?none -> T1;
?int_range(From1, To1) -> ?none;
?int_range(neg_inf, To) -> t_from_range(To + 1, To1);
?int_range(From, pos_inf) -> t_from_range(From1, From - 1);
?int_range(From, To) -> t_sup(t_from_range(From1, From - 1),
t_from_range(To + 1, To))
end;
t_subtract(?int_range(From, To) = T1, ?int_set(Set)) ->
NewFrom = case set_is_element(From, Set) of
true -> From + 1;
false -> From
end,
NewTo = case set_is_element(To, Set) of
true -> To - 1;
false -> To
end,
if (NewFrom =:= From) and (NewTo =:= To) -> T1;
true -> t_from_range(NewFrom, NewTo)
end;
t_subtract(?int_set(Set), ?int_range(From, To)) ->
case set_filter(fun(X) -> not ((X =< From) orelse (X >= To)) end, Set) of
?none -> ?none;
NewSet -> ?int_set(NewSet)
end;
t_subtract(?integer(?any) = T1, ?integer(_)) -> T1;
t_subtract(?number(_, _) = T1, ?number(_, _)) -> T1;
t_subtract(?tuple(_, _, _), ?tuple(?any, ?any, ?any)) -> ?none;
t_subtract(?tuple_set(_), ?tuple(?any, ?any, ?any)) -> ?none;
t_subtract(?tuple(?any, ?any, ?any) = T1, ?tuple_set(_)) -> T1;
t_subtract(?tuple(Elements1, Arity1, _Tag1) = T1,
?tuple(Elements2, Arity2, _Tag2)) ->
if Arity1 =/= Arity2 -> T1;
Arity1 =:= Arity2 ->
NewElements = t_subtract_lists(Elements1, Elements2),
case [E || E <- NewElements, E =/= ?none] of
[] -> ?none;
[_] -> t_tuple(replace_nontrivial_element(Elements1, NewElements));
_ -> T1
end
end;
t_subtract(?tuple_set(List1) = T1, ?tuple(_, Arity, _) = T2) ->
case orddict:find(Arity, List1) of
error -> T1;
{ok, List2} ->
TuplesLeft0 = [Tuple || {_Arity, Tuple} <- orddict:erase(Arity, List1)],
TuplesLeft1 = lists:append(TuplesLeft0),
t_sup([t_subtract(L, T2) || L <- List2] ++ TuplesLeft1)
end;
t_subtract(?tuple(_, Arity, _) = T1, ?tuple_set(List1)) ->
case orddict:find(Arity, List1) of
error -> T1;
{ok, List2} -> t_inf([t_subtract(T1, L) || L <- List2])
end;
t_subtract(?tuple_set(_) = T1, ?tuple_set(_) = T2) ->
t_sup([t_subtract(T, T2) || T <- t_tuple_subtypes(T1)]);
t_subtract(?product(Elements1) = T1, ?product(Elements2)) ->
Arity1 = length(Elements1),
Arity2 = length(Elements2),
if Arity1 =/= Arity2 -> T1;
Arity1 =:= Arity2 ->
NewElements = t_subtract_lists(Elements1, Elements2),
case [E || E <- NewElements, E =/= ?none] of
[] -> ?none;
[_] -> t_product(replace_nontrivial_element(Elements1, NewElements));
_ -> T1
end
end;
t_subtract(?map(APairs, ADefK, ADefV) = A, ?map(_, BDefK, BDefV) = B) ->
case t_is_subtype(ADefK, BDefK) andalso t_is_subtype(ADefV, BDefV) of
false -> A;
true ->
%% We fold over the maps to produce a list of constraints, where
%% constraints are additional key-value pairs to put in Pairs. Only one
%% constraint need to be applied to produce a type that excludes the
%% right-hand-side type, so if more than one constraint is produced, we
%% just return the left-hand-side argument.
%%
%% Each case of the fold may either conclude that
%% * The arguments constrain A at least as much as B, i.e. that A so far
%% is a subtype of B. In that case they return false
%% * That for the particular arguments, A being a subtype of B does not
%% hold, but the infinimum of A and B is nonempty, and by narrowing a
%% pair in A, we can create a type that excludes some elements in the
%% infinumum. In that case, they will return that pair.
%% * That for the particular arguments, A being a subtype of B does not
%% hold, and either the infinumum of A and B is empty, or it is not
%% possible with the current representation to create a type that
%% excludes elements from B without also excluding elements that are
%% only in A. In that case, it will return the pair from A unchanged.
case
map_pairwise_merge(
%% If V1 is a subtype of V2, the case that K does not exist in A
%% remain.
fun(K, ?opt, V1, ?mand, V2) -> {K, ?opt, t_subtract(V1, V2)};
(K, _, V1, _, V2) ->
%% If we subtract an optional key, that leaves a mandatory key
case t_subtract(V1, V2) of
?none -> false;
Partial -> {K, ?mand, Partial}
end
end, A, B)
of
%% We produce a list of keys that are constrained. As only one of
%% these should apply at a time, we can't represent the difference if
%% more than one constraint is produced. If we applied all of them,
%% that would make an underapproximation, which we must not do.
[] -> ?none; %% A is a subtype of B
[E] -> t_map(mapdict_store(E, APairs), ADefK, ADefV);
_ -> A
end
end;
t_subtract(?product(P1), _) ->
?product(P1);
t_subtract(T, ?product(_)) ->
T;
t_subtract(?union(U1), ?union(U2)) ->
subtract_union(U1, U2);
t_subtract(T1, T2) ->
?union(U1) = force_union(T1),
?union(U2) = force_union(T2),
subtract_union(U1, U2).
-spec opaque_subtract(erl_type(), erl_type()) -> erl_type().
opaque_subtract(?opaque(Set1), T2) ->
List = [T1#opaque{struct = Sub} ||
#opaque{struct = S1}=T1 <- set_to_list(Set1),
not t_is_none(Sub = t_subtract(S1, T2))],
case List of
[] -> ?none;
_ -> ?opaque(ordsets:from_list(List))
end.
-spec t_subtract_lists([erl_type()], [erl_type()]) -> [erl_type()].
t_subtract_lists(L1, L2) ->
t_subtract_lists(L1, L2, []).
-spec t_subtract_lists([erl_type()], [erl_type()], [erl_type()]) -> [erl_type()].
t_subtract_lists([T1|Left1], [T2|Left2], Acc) ->
t_subtract_lists(Left1, Left2, [t_subtract(T1, T2)|Acc]);
t_subtract_lists([], [], Acc) ->
lists:reverse(Acc).
-spec subtract_union([erl_type(),...], [erl_type(),...]) -> erl_type().
subtract_union(U1, U2) ->
[A1,B1,F1,I1,L1,N1,T1,M1,O1,Map1] = U1,
[A2,B2,F2,I2,L2,N2,T2,M2,O2,Map2] = U2,
List1 = [A1,B1,F1,I1,L1,N1,T1,M1,?none,Map1],
List2 = [A2,B2,F2,I2,L2,N2,T2,M2,?none,Map2],
Sub1 = subtract_union(List1, List2, 0, []),
O = if O1 =:= ?none -> O1;
true -> t_subtract(O1, ?union(U2))
end,
Sub2 = if O2 =:= ?none -> Sub1;
true -> t_subtract(Sub1, t_opaque_structure(O2))
end,
t_sup(O, Sub2).
-spec subtract_union([erl_type()], [erl_type()], non_neg_integer(), [erl_type()]) -> erl_type().
subtract_union([T1|Left1], [T2|Left2], N, Acc) ->
case t_subtract(T1, T2) of
?none -> subtract_union(Left1, Left2, N, [?none|Acc]);
T -> subtract_union(Left1, Left2, N+1, [T|Acc])
end;
subtract_union([], [], 0, _Acc) ->
?none;
subtract_union([], [], 1, Acc) ->
[T] = [X || X <- Acc, X =/= ?none],
T;
subtract_union([], [], N, Acc) when is_integer(N), N > 1 ->
?union(lists:reverse(Acc)).
replace_nontrivial_element(El1, El2) ->
replace_nontrivial_element(El1, El2, []).
replace_nontrivial_element([T1|Left1], [?none|Left2], Acc) ->
replace_nontrivial_element(Left1, Left2, [T1|Acc]);
replace_nontrivial_element([_|Left1], [T2|_], Acc) ->
lists:reverse(Acc) ++ [T2|Left1].
subtract_bin(?bitstr(U1, B1), ?bitstr(U1, B1)) ->
?none;
subtract_bin(?bitstr(U1, B1), ?none) ->
t_bitstr(U1, B1);
subtract_bin(?bitstr(U1, B1), ?bitstr(0, B1)) ->
t_bitstr(U1, B1+U1);
subtract_bin(?bitstr(U1, B1), ?bitstr(U1, B2)) ->
if (B1+U1) =/= B2 -> t_bitstr(0, B1);
true -> t_bitstr(U1, B1)
end;
subtract_bin(?bitstr(U1, B1), ?bitstr(U2, B2)) ->
if (2 * U1) =:= U2 ->
if B1 =:= B2 ->
t_bitstr(U2, B1+U1);
(B1 + U1) =:= B2 ->
t_bitstr(U2, B1);
true ->
t_bitstr(U1, B1)
end;
true ->
t_bitstr(U1, B1)
end.
%%-----------------------------------------------------------------------------
%% Relations
%%
-spec t_is_equal(erl_type(), erl_type()) -> boolean().
t_is_equal(T, T) -> true;
t_is_equal(_, _) -> false.
-spec t_is_subtype(erl_type(), erl_type()) -> boolean().
t_is_subtype(T1, T2) ->
Inf = t_inf(T1, T2),
subtype_is_equal(T1, Inf).
%% The subtype relation has to behave correctly irrespective of opaque
%% types.
subtype_is_equal(T, T) -> true;
subtype_is_equal(T1, T2) ->
t_is_equal(case t_contains_opaque(T1) of
true -> t_unopaque(T1);
false -> T1
end,
case t_contains_opaque(T2) of
true -> t_unopaque(T2);
false -> T2
end).
-spec t_is_instance(erl_type(), erl_type()) -> boolean().
%% XXX. To be removed.
t_is_instance(ConcreteType, Type) ->
t_is_subtype(ConcreteType, t_unopaque(Type)).
-spec t_do_overlap(erl_type(), erl_type()) -> boolean().
t_do_overlap(TypeA, TypeB) ->
not (t_is_none_or_unit(t_inf(TypeA, TypeB))).
-spec t_unopaque(erl_type()) -> erl_type().
t_unopaque(T) ->
t_unopaque(T, 'universe').
-spec t_unopaque(erl_type(), opaques()) -> erl_type().
t_unopaque(?opaque(_) = T, Opaques) ->
case Opaques =:= 'universe' orelse is_opaque_type(T, Opaques) of
true -> t_unopaque(t_opaque_structure(T), Opaques);
false -> T
end;
t_unopaque(?list(ElemT, Termination, Sz), Opaques) ->
?list(t_unopaque(ElemT, Opaques), t_unopaque(Termination, Opaques), Sz);
t_unopaque(?tuple(?any, _, _) = T, _) -> T;
t_unopaque(?tuple(ArgTs, Sz, Tag), Opaques) when is_list(ArgTs) ->
NewArgTs = [t_unopaque(A, Opaques) || A <- ArgTs],
?tuple(NewArgTs, Sz, Tag);
t_unopaque(?tuple_set(Set), Opaques) ->
NewSet = [{Sz, [t_unopaque(T, Opaques) || T <- Tuples]}
|| {Sz, Tuples} <- Set],
?tuple_set(NewSet);
t_unopaque(?product(Types), Opaques) ->
?product([t_unopaque(T, Opaques) || T <- Types]);
t_unopaque(?function(Domain, Range), Opaques) ->
?function(t_unopaque(Domain, Opaques), t_unopaque(Range, Opaques));
t_unopaque(?union([A,B,F,I,L,N,T,M,O,Map]), Opaques) ->
UL = t_unopaque(L, Opaques),
UT = t_unopaque(T, Opaques),
UF = t_unopaque(F, Opaques),
UM = t_unopaque(M, Opaques),
UMap = t_unopaque(Map, Opaques),
{OF,UO} = case t_unopaque(O, Opaques) of
?opaque(_) = O1 -> {O1, []};
Type -> {?none, [Type]}
end,
t_sup([?union([A,B,UF,I,UL,N,UT,UM,OF,UMap])|UO]);
t_unopaque(?map(Pairs,DefK,DefV), Opaques) ->
t_map([{K, MNess, t_unopaque(V, Opaques)} || {K, MNess, V} <- Pairs],
t_unopaque(DefK, Opaques),
t_unopaque(DefV, Opaques));
t_unopaque(T, _) ->
T.
%%-----------------------------------------------------------------------------
%% K-depth abstraction.
%%
%% t_limit/2 is the exported function, which checks the type of the
%% second argument and calls the module local t_limit_k/2 function.
%%
-spec t_limit(erl_type(), integer()) -> erl_type().
t_limit(Term, K) when is_integer(K) ->
t_limit_k(Term, K).
t_limit_k(_, K) when K =< 0 -> ?any;
t_limit_k(?tuple(?any, ?any, ?any) = T, _K) -> T;
t_limit_k(?tuple(Elements, Arity, _), K) ->
if K =:= 1 -> t_tuple(Arity);
true -> t_tuple([t_limit_k(E, K-1) || E <- Elements])
end;
t_limit_k(?tuple_set(_) = T, K) ->
t_sup([t_limit_k(Tuple, K) || Tuple <- t_tuple_subtypes(T)]);
t_limit_k(?list(Elements, Termination, Size), K) ->
NewTermination =
if K =:= 1 ->
%% We do not want to lose the termination information.
t_limit_k(Termination, K);
true -> t_limit_k(Termination, K - 1)
end,
NewElements = t_limit_k(Elements, K - 1),
TmpList = t_cons(NewElements, NewTermination),
case Size of
?nonempty_qual -> TmpList;
?unknown_qual ->
?list(NewElements1, NewTermination1, _) = TmpList,
?list(NewElements1, NewTermination1, ?unknown_qual)
end;
t_limit_k(?function(Domain, Range), K) ->
%% The domain is either a product or any() so we do not decrease the K.
?function(t_limit_k(Domain, K), t_limit_k(Range, K-1));
t_limit_k(?product(Elements), K) ->
?product([t_limit_k(X, K - 1) || X <- Elements]);
t_limit_k(?union(Elements), K) ->
?union([t_limit_k(X, K) || X <- Elements]);
t_limit_k(?opaque(Es), K) ->
List = [begin
NewS = t_limit_k(S, K),
Opaque#opaque{struct = NewS}
end || #opaque{struct = S} = Opaque <- set_to_list(Es)],
?opaque(ordsets:from_list(List));
t_limit_k(?map(Pairs0, DefK0, DefV0), K) ->
Fun = fun({EK, MNess, EV}, {Exact, DefK1, DefV1}) ->
LV = t_limit_k(EV, K - 1),
case t_limit_k(EK, K - 1) of
EK -> {[{EK,MNess,LV}|Exact], DefK1, DefV1};
LK -> {Exact, t_sup(LK, DefK1), t_sup(LV, DefV1)}
end
end,
{Pairs, DefK2, DefV2} = lists:foldr(Fun, {[], DefK0, DefV0}, Pairs0),
t_map(Pairs, t_limit_k(DefK2, K - 1), t_limit_k(DefV2, K - 1));
t_limit_k(T, _K) -> T.
%%============================================================================
%%
%% Abstract records. Used for comparing contracts.
%%
%%============================================================================
-spec t_abstract_records(erl_type(), type_table()) -> erl_type().
t_abstract_records(?list(Contents, Termination, Size), RecDict) ->
case t_abstract_records(Contents, RecDict) of
?none -> ?none;
NewContents ->
%% Be careful here to make the termination collapse if necessary.
case t_abstract_records(Termination, RecDict) of
?nil -> ?list(NewContents, ?nil, Size);
?any -> ?list(NewContents, ?any, Size);
Other ->
?list(NewContents2, NewTermination, _) = t_cons(NewContents, Other),
?list(NewContents2, NewTermination, Size)
end
end;
t_abstract_records(?function(Domain, Range), RecDict) ->
?function(t_abstract_records(Domain, RecDict),
t_abstract_records(Range, RecDict));
t_abstract_records(?product(Types), RecDict) ->
?product([t_abstract_records(T, RecDict) || T <- Types]);
t_abstract_records(?union(Types), RecDict) ->
t_sup([t_abstract_records(T, RecDict) || T <- Types]);
t_abstract_records(?tuple(?any, ?any, ?any) = T, _RecDict) ->
T;
t_abstract_records(?tuple(Elements, Arity, ?atom(_) = Tag), RecDict) ->
[TagAtom] = atom_vals(Tag),
case lookup_record(TagAtom, Arity - 1, RecDict) of
error -> t_tuple([t_abstract_records(E, RecDict) || E <- Elements]);
{ok, Fields} -> t_tuple([Tag|[T || {_Name, _Abstr, T} <- Fields]])
end;
t_abstract_records(?tuple(Elements, _Arity, _Tag), RecDict) ->
t_tuple([t_abstract_records(E, RecDict) || E <- Elements]);
t_abstract_records(?tuple_set(_) = Tuples, RecDict) ->
t_sup([t_abstract_records(T, RecDict) || T <- t_tuple_subtypes(Tuples)]);
t_abstract_records(?opaque(_)=Type, RecDict) ->
t_abstract_records(t_opaque_structure(Type), RecDict);
t_abstract_records(T, _RecDict) ->
T.
%%=============================================================================
%%
%% Prettyprinter
%%
%%=============================================================================
-spec t_to_string(erl_type()) -> string().
t_to_string(T) ->
t_to_string(T, maps:new()).
-spec t_to_string(erl_type(), type_table()) -> string().
t_to_string(?any, _RecDict) ->
"any()";
t_to_string(?none, _RecDict) ->
"none()";
t_to_string(?unit, _RecDict) ->
"no_return()";
t_to_string(?atom(?any), _RecDict) ->
"atom()";
t_to_string(?atom(Set), _RecDict) ->
case set_size(Set) of
2 ->
case set_is_element(true, Set) andalso set_is_element(false, Set) of
true -> "boolean()";
false -> set_to_string(Set)
end;
_ ->
set_to_string(Set)
end;
t_to_string(?bitstr(0, 0), _RecDict) ->
"<<>>";
t_to_string(?bitstr(8, 0), _RecDict) ->
"binary()";
t_to_string(?bitstr(1, 0), _RecDict) ->
"bitstring()";
t_to_string(?bitstr(0, B), _RecDict) ->
flat_format("<<_:~w>>", [B]);
t_to_string(?bitstr(U, 0), _RecDict) ->
flat_format("<<_:_*~w>>", [U]);
t_to_string(?bitstr(U, B), _RecDict) ->
flat_format("<<_:~w,_:_*~w>>", [B, U]);
t_to_string(?function(?any, ?any), _RecDict) ->
"fun()";
t_to_string(?function(?any, Range), RecDict) ->
"fun((...) -> " ++ t_to_string(Range, RecDict) ++ ")";
t_to_string(?function(?product(ArgList), Range), RecDict) ->
"fun((" ++ comma_sequence(ArgList, RecDict) ++ ") -> "
++ t_to_string(Range, RecDict) ++ ")";
t_to_string(?identifier(Set), _RecDict) ->
case Set of
?any -> "identifier()";
_ ->
flat_join([flat_format("~w()", [T]) || T <- set_to_list(Set)], " | ")
end;
t_to_string(?opaque(Set), RecDict) ->
flat_join([opaque_type(Mod, Name, Args, S, RecDict) ||
#opaque{mod = Mod, name = Name, struct = S, args = Args}
<- set_to_list(Set)],
" | ");
t_to_string(?matchstate(Pres, Slots), RecDict) ->
flat_format("ms(~ts,~ts)", [t_to_string(Pres, RecDict),
t_to_string(Slots,RecDict)]);
t_to_string(?nil, _RecDict) ->
"[]";
t_to_string(?nonempty_list(Contents, Termination), RecDict) ->
ContentString = t_to_string(Contents, RecDict),
case Termination of
?nil ->
case Contents of
?char -> "nonempty_string()";
_ -> "["++ContentString++",...]"
end;
?any ->
%% Just a safety check.
case Contents =:= ?any of
true -> ok;
false ->
%% XXX. See comment below.
%% erlang:error({illegal_list, ?nonempty_list(Contents, Termination)})
ok
end,
"nonempty_maybe_improper_list()";
_ ->
case t_is_subtype(t_nil(), Termination) of
true ->
"nonempty_maybe_improper_list("++ContentString++","
++t_to_string(Termination, RecDict)++")";
false ->
"nonempty_improper_list("++ContentString++","
++t_to_string(Termination, RecDict)++")"
end
end;
t_to_string(?list(Contents, Termination, ?unknown_qual), RecDict) ->
ContentString = t_to_string(Contents, RecDict),
case Termination of
?nil ->
case Contents of
?char -> "string()";
_ -> "["++ContentString++"]"
end;
?any ->
%% Just a safety check.
%% XXX. Types such as "maybe_improper_list(integer(), any())"
%% are OK, but cannot be printed!?
case Contents =:= ?any of
true -> ok;
false ->
ok
%% L = ?list(Contents, Termination, ?unknown_qual),
%% erlang:error({illegal_list, L})
end,
"maybe_improper_list()";
_ ->
case t_is_subtype(t_nil(), Termination) of
true ->
"maybe_improper_list("++ContentString++","
++t_to_string(Termination, RecDict)++")";
false ->
"improper_list("++ContentString++","
++t_to_string(Termination, RecDict)++")"
end
end;
t_to_string(?int_set(Set), _RecDict) ->
set_to_string(Set);
t_to_string(?byte, _RecDict) -> "byte()";
t_to_string(?char, _RecDict) -> "char()";
t_to_string(?integer_pos, _RecDict) -> "pos_integer()";
t_to_string(?integer_non_neg, _RecDict) -> "non_neg_integer()";
t_to_string(?integer_neg, _RecDict) -> "neg_integer()";
t_to_string(?int_range(From, To), _RecDict) ->
flat_format("~w..~w", [From, To]);
t_to_string(?integer(?any), _RecDict) -> "integer()";
t_to_string(?float, _RecDict) -> "float()";
t_to_string(?number(?any, ?unknown_qual), _RecDict) -> "number()";
t_to_string(?product(List), RecDict) ->
"<" ++ comma_sequence(List, RecDict) ++ ">";
t_to_string(?map([],?any,?any), _RecDict) -> "map()";
t_to_string(?map(Pairs0,DefK,DefV), RecDict) ->
{Pairs, ExtraEl} =
case {DefK, DefV} of
{?none, ?none} -> {Pairs0, []};
_ -> {Pairs0 ++ [{DefK,?opt,DefV}], []}
end,
Tos = fun(T) -> case T of
?any -> "_";
_ -> t_to_string(T, RecDict)
end end,
StrMand = [{Tos(K),Tos(V)}||{K,?mand,V}<-Pairs],
StrOpt = [{Tos(K),Tos(V)}||{K,?opt,V}<-Pairs],
"#{" ++ flat_join([K ++ ":=" ++ V||{K,V}<-StrMand]
++ [K ++ "=>" ++ V||{K,V}<-StrOpt]
++ ExtraEl, ", ") ++ "}";
t_to_string(?tuple(?any, ?any, ?any), _RecDict) -> "tuple()";
t_to_string(?tuple(Elements, _Arity, ?any), RecDict) ->
"{" ++ comma_sequence(Elements, RecDict) ++ "}";
t_to_string(?tuple(Elements, Arity, Tag), RecDict) ->
[TagAtom] = atom_vals(Tag),
case lookup_record(TagAtom, Arity-1, RecDict) of
error -> "{" ++ comma_sequence(Elements, RecDict) ++ "}";
{ok, FieldNames} ->
record_to_string(TagAtom, Elements, FieldNames, RecDict)
end;
t_to_string(?tuple_set(_) = T, RecDict) ->
union_sequence(t_tuple_subtypes(T), RecDict);
t_to_string(?union(Types), RecDict) ->
union_sequence([T || T <- Types, T =/= ?none], RecDict);
t_to_string(?var(Id), _RecDict) when is_atom(Id) ->
flat_format("~s", [atom_to_list(Id)]);
t_to_string(?var(Id), _RecDict) when is_integer(Id) ->
flat_format("var(~w)", [Id]).
record_to_string(Tag, [_|Fields], FieldNames, RecDict) ->
FieldStrings = record_fields_to_string(Fields, FieldNames, RecDict, []),
"#" ++ atom_to_string(Tag) ++ "{" ++ flat_join(FieldStrings, ",") ++ "}".
record_fields_to_string([F|Fs], [{FName, _Abstr, DefType}|FDefs],
RecDict, Acc) ->
NewAcc =
case
t_is_equal(F, t_any()) orelse
(t_is_any_atom('undefined', F) andalso
not t_is_none(t_inf(F, DefType)))
of
true -> Acc;
false ->
StrFV = atom_to_string(FName) ++ "::" ++ t_to_string(F, RecDict),
[StrFV|Acc]
end,
record_fields_to_string(Fs, FDefs, RecDict, NewAcc);
record_fields_to_string([], [], _RecDict, Acc) ->
lists:reverse(Acc).
-spec record_field_diffs_to_string(erl_type(), type_table()) -> string().
record_field_diffs_to_string(?tuple([_|Fs], Arity, Tag), RecDict) ->
[TagAtom] = atom_vals(Tag),
{ok, FieldNames} = lookup_record(TagAtom, Arity-1, RecDict),
%% io:format("RecCElems = ~p\nRecTypes = ~p\n", [Fs, FieldNames]),
FieldDiffs = field_diffs(Fs, FieldNames, RecDict, []),
flat_join(FieldDiffs, " and ").
field_diffs([F|Fs], [{FName, _Abstr, DefType}|FDefs], RecDict, Acc) ->
%% Don't care about opacity for now.
NewAcc =
case not t_is_none(t_inf(F, DefType)) of
true -> Acc;
false ->
Str = atom_to_string(FName) ++ "::" ++ t_to_string(DefType, RecDict),
[Str|Acc]
end,
field_diffs(Fs, FDefs, RecDict, NewAcc);
field_diffs([], [], _, Acc) ->
lists:reverse(Acc).
comma_sequence(Types, RecDict) ->
List = [case T =:= ?any of
true -> "_";
false -> t_to_string(T, RecDict)
end || T <- Types],
flat_join(List, ",").
union_sequence(Types, RecDict) ->
List = [t_to_string(T, RecDict) || T <- Types],
flat_join(List, " | ").
-ifdef(DEBUG).
opaque_type(Mod, Name, _Args, S, RecDict) ->
ArgsString = comma_sequence(_Args, RecDict),
String = t_to_string(S, RecDict),
opaque_name(Mod, Name, ArgsString) ++ "[" ++ String ++ "]".
-else.
opaque_type(Mod, Name, Args, _S, RecDict) ->
ArgsString = comma_sequence(Args, RecDict),
opaque_name(Mod, Name, ArgsString).
-endif.
opaque_name(Mod, Name, Extra) ->
S = mod_name(Mod, Name),
flat_format("~ts(~ts)", [S, Extra]).
mod_name(Mod, Name) ->
flat_format("~w:~tw", [Mod, Name]).
%%=============================================================================
%%
%% Build a type from parse forms.
%%
%%=============================================================================
-type type_names() :: [type_key() | record_key()].
-type mta() :: {module(), atom(), arity()}.
-type mra() :: {module(), atom(), arity()}.
-type site() :: {'type', mta()} | {'spec', mfa()} | {'record', mra()}.
-type cache_key() :: {module(), atom(), expand_depth(),
[erl_type()], type_names()}.
-type mod_type_table() :: ets:tid().
-type mod_records() :: dict:dict(module(), type_table()).
-record(cache,
{
types = maps:new() :: #{cache_key() => {erl_type(), expand_limit()}},
mod_recs = {mrecs, dict:new()} :: {'mrecs', mod_records()}
}).
-opaque cache() :: #cache{}.
-spec t_from_form(parse_form(), sets:set(mfa()), site(), mod_type_table(),
var_table(), cache()) -> {erl_type(), cache()}.
t_from_form(Form, ExpTypes, Site, RecDict, VarTab, Cache) ->
t_from_form1(Form, ExpTypes, Site, RecDict, VarTab, Cache).
%% Replace external types with with none().
-spec t_from_form_without_remote(parse_form(), site(), type_table()) ->
erl_type().
t_from_form_without_remote(Form, Site, TypeTable) ->
Module = site_module(Site),
ModRecs = dict:from_list([{Module, TypeTable}]),
ExpTypes = replace_by_none,
VarTab = var_table__new(),
Cache0 = cache__new(),
Cache = Cache0#cache{mod_recs = {mrecs, ModRecs}},
{Type, _} = t_from_form1(Form, ExpTypes, Site, undefined, VarTab, Cache),
Type.
-type expand_limit() :: integer().
-type expand_depth() :: integer().
-record(from_form, {site :: site() | {'check', mta()},
xtypes :: sets:set(mfa()) | 'replace_by_none',
mrecs :: 'undefined' | mod_type_table(),
vtab :: var_table(),
tnames :: type_names()}).
-spec t_from_form_check_remote(parse_form(), sets:set(mfa()), mta(),
mod_type_table()) -> 'ok'.
t_from_form_check_remote(Form, ExpTypes, MTA, RecDict) ->
State = #from_form{site = {check, MTA},
xtypes = ExpTypes,
mrecs = RecDict,
vtab = var_table__new(),
tnames = []},
D = (1 bsl 25), % unlimited
L = (1 bsl 25),
Cache0 = cache__new(),
_ = t_from_form2(Form, State, D, L, Cache0),
ok.
%% REC_TYPE_LIMIT is used for limiting the depth of recursive types.
%% EXPAND_LIMIT is used for limiting the size of types by
%% limiting the number of elements of lists within one type form.
%% EXPAND_DEPTH is used in conjunction with EXPAND_LIMIT to make the
%% types balanced (unions will otherwise collapse to any()) by limiting
%% the depth the same way as t_limit/2 does.
-spec t_from_form1(parse_form(), sets:set(mfa()) | 'replace_by_none',
site(), 'undefined' | mod_type_table(), var_table(),
cache()) -> {erl_type(), cache()}.
t_from_form1(Form, ET, Site, MR, V, C) ->
TypeNames = initial_typenames(Site),
D = ?EXPAND_DEPTH,
L = ?EXPAND_LIMIT,
State = #from_form{site = Site,
xtypes = ET,
mrecs = MR,
vtab = V,
tnames = TypeNames},
t_from_form2(Form, State, D, L, C).
t_from_form2(Form, State, D, L, C) ->
{T0, L0, C0} = from_form(Form, State, D, L, C),
if
L0 =< 0 ->
{T1, _, C1} = from_form(Form, State, 1, L, C0),
from_form_loop(Form, State, 2, L, C1, T1);
true ->
{T0, C0}
end.
initial_typenames({type, _MTA}=Site) -> [Site];
initial_typenames({spec, _MFA}) -> [];
initial_typenames({record, _MRA}) -> [].
from_form_loop(Form, State, D, Limit, C, T0) ->
{T1, L1, C1} = from_form(Form, State, D, Limit, C),
Delta = Limit - L1,
if
L1 =< 0 ->
{T0, C1};
Delta * 8 > Limit ->
%% Save some time by assuming next depth will exceed the limit.
{T1, C1};
true ->
D1 = D + 1,
from_form_loop(Form, State, D1, Limit, C1, T1)
end.
-spec from_form(parse_form(),
#from_form{},
expand_depth(),
expand_limit(),
cache()) -> {erl_type(), expand_limit(), cache()}.
%% If there is something wrong with parse_form()
%% throw({error, io_lib:chars()} is called;
%% for unknown remote types
%% self() ! {self(), ext_types, {RemMod, Name, ArgsLen}}
%% is called, unless 'replace_by_none' is given.
%%
%% It is assumed that site_module(S) can be found in MR.
from_form(_, _S, D, L, C) when D =< 0 ; L =< 0 ->
{t_any(), L, C};
from_form({var, _L, '_'}, _S, _D, L, C) ->
{t_any(), L, C};
from_form({var, _L, Name}, S, _D, L, C) ->
V = S#from_form.vtab,
case maps:find(Name, V) of
error -> {t_var(Name), L, C};
{ok, Val} -> {Val, L, C}
end;
from_form({ann_type, _L, [_Var, Type]}, S, D, L, C) ->
from_form(Type, S, D, L, C);
from_form({paren_type, _L, [Type]}, S, D, L, C) ->
from_form(Type, S, D, L, C);
from_form({remote_type, _L, [{atom, _, Module}, {atom, _, Type}, Args]},
S, D, L, C) ->
remote_from_form(Module, Type, Args, S, D, L, C);
from_form({atom, _L, Atom}, _S, _D, L, C) ->
{t_atom(Atom), L, C};
from_form({integer, _L, Int}, _S, _D, L, C) ->
{t_integer(Int), L, C};
from_form({char, _L, Char}, _S, _D, L, C) ->
{t_integer(Char), L, C};
from_form({op, _L, _Op, _Arg} = Op, _S, _D, L, C) ->
case erl_eval:partial_eval(Op) of
{integer, _, Val} ->
{t_integer(Val), L, C};
_ -> throw({error, io_lib:format("Unable to evaluate type ~w\n", [Op])})
end;
from_form({op, _L, _Op, _Arg1, _Arg2} = Op, _S, _D, L, C) ->
case erl_eval:partial_eval(Op) of
{integer, _, Val} ->
{t_integer(Val), L, C};
_ -> throw({error, io_lib:format("Unable to evaluate type ~w\n", [Op])})
end;
from_form({type, _L, any, []}, _S, _D, L, C) ->
{t_any(), L, C};
from_form({type, _L, arity, []}, _S, _D, L, C) ->
{t_arity(), L, C};
from_form({type, _L, atom, []}, _S, _D, L, C) ->
{t_atom(), L, C};
from_form({type, _L, binary, []}, _S, _D, L, C) ->
{t_binary(), L, C};
from_form({type, _L, binary, [Base, Unit]} = Type, _S, _D, L, C) ->
case {erl_eval:partial_eval(Base), erl_eval:partial_eval(Unit)} of
{{integer, _, B}, {integer, _, U}} when B >= 0, U >= 0 ->
{t_bitstr(U, B), L, C};
_ -> throw({error, io_lib:format("Unable to evaluate type ~w\n", [Type])})
end;
from_form({type, _L, bitstring, []}, _S, _D, L, C) ->
{t_bitstr(), L, C};
from_form({type, _L, bool, []}, _S, _D, L, C) ->
{t_boolean(), L, C}; % XXX: Temporarily
from_form({type, _L, boolean, []}, _S, _D, L, C) ->
{t_boolean(), L, C};
from_form({type, _L, byte, []}, _S, _D, L, C) ->
{t_byte(), L, C};
from_form({type, _L, char, []}, _S, _D, L, C) ->
{t_char(), L, C};
from_form({type, _L, float, []}, _S, _D, L, C) ->
{t_float(), L, C};
from_form({type, _L, function, []}, _S, _D, L, C) ->
{t_fun(), L, C};
from_form({type, _L, 'fun', []}, _S, _D, L, C) ->
{t_fun(), L, C};
from_form({type, _L, 'fun', [{type, _, any}, Range]}, S, D, L, C) ->
{T, L1, C1} = from_form(Range, S, D - 1, L - 1, C),
{t_fun(T), L1, C1};
from_form({type, _L, 'fun', [{type, _, product, Domain}, Range]},
S, D, L, C) ->
{Dom1, L1, C1} = list_from_form(Domain, S, D, L, C),
{Ran1, L2, C2} = from_form(Range, S, D, L1, C1),
{t_fun(Dom1, Ran1), L2, C2};
from_form({type, _L, identifier, []}, _S, _D, L, C) ->
{t_identifier(), L, C};
from_form({type, _L, integer, []}, _S, _D, L, C) ->
{t_integer(), L, C};
from_form({type, _L, iodata, []}, _S, _D, L, C) ->
{t_iodata(), L, C};
from_form({type, _L, iolist, []}, _S, _D, L, C) ->
{t_iolist(), L, C};
from_form({type, _L, list, []}, _S, _D, L, C) ->
{t_list(), L, C};
from_form({type, _L, list, [Type]}, S, D, L, C) ->
{T, L1, C1} = from_form(Type, S, D - 1, L - 1, C),
{t_list(T), L1, C1};
from_form({type, _L, map, any}, S, D, L, C) ->
builtin_type(map, t_map(), S, D, L, C);
from_form({type, _L, map, List}, S, D0, L, C) ->
{Pairs1, L5, C5} =
fun PairsFromForm(_, L1, C1) when L1 =< 0 -> {[{?any,?opt,?any}], L1, C1};
PairsFromForm([], L1, C1) -> {[], L1, C1};
PairsFromForm([{type, _, Oper, [KF, VF]}|T], L1, C1) ->
D = D0 - 1,
{Key, L2, C2} = from_form(KF, S, D, L1, C1),
{Val, L3, C3} = from_form(VF, S, D, L2, C2),
{Pairs0, L4, C4} = PairsFromForm(T, L3 - 1, C3),
case Oper of
map_field_assoc -> {[{Key,?opt, Val}|Pairs0], L4, C4};
map_field_exact -> {[{Key,?mand,Val}|Pairs0], L4, C4}
end
end(List, L, C),
try
Pairs2 = singleton_elements(Pairs1),
{Pairs, DefK, DefV} = map_from_form(Pairs2, [], [], [], ?none, ?none),
{t_map(Pairs, DefK, DefV), L5, C5}
catch none -> {t_none(), L5, C5}
end;
from_form({type, _L, mfa, []}, _S, _D, L, C) ->
{t_mfa(), L, C};
from_form({type, _L, module, []}, _S, _D, L, C) ->
{t_module(), L, C};
from_form({type, _L, nil, []}, _S, _D, L, C) ->
{t_nil(), L, C};
from_form({type, _L, neg_integer, []}, _S, _D, L, C) ->
{t_neg_integer(), L, C};
from_form({type, _L, non_neg_integer, []}, _S, _D, L, C) ->
{t_non_neg_integer(), L, C};
from_form({type, _L, no_return, []}, _S, _D, L, C) ->
{t_unit(), L, C};
from_form({type, _L, node, []}, _S, _D, L, C) ->
{t_node(), L, C};
from_form({type, _L, none, []}, _S, _D, L, C) ->
{t_none(), L, C};
from_form({type, _L, nonempty_list, []}, _S, _D, L, C) ->
{t_nonempty_list(), L, C};
from_form({type, _L, nonempty_list, [Type]}, S, D, L, C) ->
{T, L1, C1} = from_form(Type, S, D, L - 1, C),
{t_nonempty_list(T), L1, C1};
from_form({type, _L, nonempty_improper_list, [Cont, Term]}, S, D, L, C) ->
{T1, L1, C1} = from_form(Cont, S, D, L - 1, C),
{T2, L2, C2} = from_form(Term, S, D, L1, C1),
{t_cons(T1, T2), L2, C2};
from_form({type, _L, nonempty_maybe_improper_list, []}, _S, _D, L, C) ->
{t_cons(?any, ?any), L, C};
from_form({type, _L, nonempty_maybe_improper_list, [Cont, Term]},
S, D, L, C) ->
{T1, L1, C1} = from_form(Cont, S, D, L - 1, C),
{T2, L2, C2} = from_form(Term, S, D, L1, C1),
{t_cons(T1, T2), L2, C2};
from_form({type, _L, nonempty_string, []}, _S, _D, L, C) ->
{t_nonempty_string(), L, C};
from_form({type, _L, number, []}, _S, _D, L, C) ->
{t_number(), L, C};
from_form({type, _L, pid, []}, _S, _D, L, C) ->
{t_pid(), L, C};
from_form({type, _L, port, []}, _S, _D, L, C) ->
{t_port(), L, C};
from_form({type, _L, pos_integer, []}, _S, _D, L, C) ->
{t_pos_integer(), L, C};
from_form({type, _L, maybe_improper_list, []}, _S, _D, L, C) ->
{t_maybe_improper_list(), L, C};
from_form({type, _L, maybe_improper_list, [Content, Termination]},
S, D, L, C) ->
{T1, L1, C1} = from_form(Content, S, D, L - 1, C),
{T2, L2, C2} = from_form(Termination, S, D, L1, C1),
{t_maybe_improper_list(T1, T2), L2, C2};
from_form({type, _L, product, Elements}, S, D, L, C) ->
{Lst, L1, C1} = list_from_form(Elements, S, D - 1, L, C),
{t_product(Lst), L1, C1};
from_form({type, _L, range, [From, To]} = Type, _S, _D, L, C) ->
case {erl_eval:partial_eval(From), erl_eval:partial_eval(To)} of
{{integer, _, FromVal}, {integer, _, ToVal}} ->
{t_from_range(FromVal, ToVal), L, C};
_ -> throw({error, io_lib:format("Unable to evaluate type ~w\n", [Type])})
end;
from_form({type, _L, record, [Name|Fields]}, S, D, L, C) ->
record_from_form(Name, Fields, S, D, L, C);
from_form({type, _L, reference, []}, _S, _D, L, C) ->
{t_reference(), L, C};
from_form({type, _L, string, []}, _S, _D, L, C) ->
{t_string(), L, C};
from_form({type, _L, term, []}, _S, _D, L, C) ->
{t_any(), L, C};
from_form({type, _L, timeout, []}, _S, _D, L, C) ->
{t_timeout(), L, C};
from_form({type, _L, tuple, any}, _S, _D, L, C) ->
{t_tuple(), L, C};
from_form({type, _L, tuple, Args}, S, D, L, C) ->
{Lst, L1, C1} = list_from_form(Args, S, D - 1, L, C),
{t_tuple(Lst), L1, C1};
from_form({type, _L, union, Args}, S, D, L, C) ->
{Lst, L1, C1} = list_from_form(Args, S, D, L, C),
{t_sup(Lst), L1, C1};
from_form({user_type, _L, Name, Args}, S, D, L, C) ->
type_from_form(Name, Args, S, D, L, C);
from_form({type, _L, Name, Args}, S, D, L, C) ->
%% Compatibility: modules compiled before Erlang/OTP 18.0.
type_from_form(Name, Args, S, D, L, C);
from_form({opaque, _L, Name, {Mod, Args, Rep}}, _S, _D, L, C) ->
%% XXX. To be removed.
{t_opaque(Mod, Name, Args, Rep), L, C}.
builtin_type(Name, Type, S, D, L, C) ->
#from_form{site = Site, mrecs = MR} = S,
M = site_module(Site),
case lookup_module_types(M, MR, C) of
{R, C1} ->
case lookup_type(Name, 0, R) of
{_, {{_M, _FL, _F, _A}, _T}} ->
type_from_form(Name, [], S, D, L, C1);
error ->
{Type, L, C1}
end;
error ->
{Type, L, C}
end.
type_from_form(Name, Args, S, D, L, C) ->
#from_form{site = Site, mrecs = MR, tnames = TypeNames} = S,
ArgsLen = length(Args),
Module = site_module(Site),
TypeName = {type, {Module, Name, ArgsLen}},
case can_unfold_more(TypeName, TypeNames) of
true ->
{R, C1} = lookup_module_types(Module, MR, C),
type_from_form1(Name, Args, ArgsLen, R, TypeName, TypeNames, Site,
S, D, L, C1);
false ->
{t_any(), L, C}
end.
type_from_form1(Name, Args, ArgsLen, R, TypeName, TypeNames, Site,
S, D, L, C) ->
case lookup_type(Name, ArgsLen, R) of
{_, {_, _}} when element(1, Site) =:= check ->
{_ArgTypes, L1, C1} = list_from_form(Args, S, D, L, C),
{t_any(), L1, C1};
{Tag, {{Module, _FileName, Form, ArgNames}, Type}} ->
NewTypeNames = [TypeName|TypeNames],
S1 = S#from_form{tnames = NewTypeNames},
{ArgTypes, L1, C1} = list_from_form(Args, S1, D, L, C),
CKey = cache_key(Module, Name, ArgTypes, TypeNames, D),
case cache_find(CKey, C) of
{CachedType, DeltaL} ->
{CachedType, L1 - DeltaL, C};
error ->
List = lists:zip(ArgNames, ArgTypes),
TmpV = maps:from_list(List),
S2 = S1#from_form{site = TypeName, vtab = TmpV},
Fun = fun(DD, LL) -> from_form(Form, S2, DD, LL, C1) end,
{NewType, L3, C3} =
case Tag of
type ->
recur_limit(Fun, D, L1, TypeName, TypeNames);
opaque ->
{Rep, L2, C2} = recur_limit(Fun, D, L1, TypeName, TypeNames),
Rep1 = choose_opaque_type(Rep, Type),
Rep2 = case cannot_have_opaque(Rep1, TypeName, TypeNames) of
true -> Rep;
false ->
ArgTypes2 = subst_all_vars_to_any_list(ArgTypes),
t_opaque(Module, Name, ArgTypes2, Rep1)
end,
{Rep2, L2, C2}
end,
C4 = cache_put(CKey, NewType, L1 - L3, C3),
{NewType, L3, C4}
end;
error ->
Msg = io_lib:format("Unable to find type ~tw/~w\n",
[Name, ArgsLen]),
throw({error, Msg})
end.
remote_from_form(RemMod, Name, Args, S, D, L, C) ->
#from_form{site = Site, xtypes = ET, mrecs = MR, tnames = TypeNames} = S,
if
ET =:= replace_by_none ->
{t_none(), L, C};
true ->
ArgsLen = length(Args),
MFA = {RemMod, Name, ArgsLen},
case lookup_module_types(RemMod, MR, C) of
error ->
self() ! {self(), ext_types, MFA},
{t_any(), L, C};
{RemDict, C1} ->
case sets:is_element(MFA, ET) of
true ->
RemType = {type, MFA},
case can_unfold_more(RemType, TypeNames) of
true ->
remote_from_form1(RemMod, Name, Args, ArgsLen, RemDict,
RemType, TypeNames, Site, S, D, L, C1);
false ->
{t_any(), L, C1}
end;
false ->
self() ! {self(), ext_types, {RemMod, Name, ArgsLen}},
{t_any(), L, C1}
end
end
end.
remote_from_form1(RemMod, Name, Args, ArgsLen, RemDict, RemType, TypeNames,
Site, S, D, L, C) ->
case lookup_type(Name, ArgsLen, RemDict) of
{_, {_, _}} when element(1, Site) =:= check ->
{_ArgTypes, L1, C1} = list_from_form(Args, S, D, L, C),
{t_any(), L1, C1};
{Tag, {{Mod, _FileLine, Form, ArgNames}, Type}} ->
NewTypeNames = [RemType|TypeNames],
S1 = S#from_form{tnames = NewTypeNames},
{ArgTypes, L1, C1} = list_from_form(Args, S1, D, L, C),
CKey = cache_key(RemMod, Name, ArgTypes, TypeNames, D),
case cache_find(CKey, C) of
{CachedType, DeltaL} ->
{CachedType, L - DeltaL, C};
error ->
List = lists:zip(ArgNames, ArgTypes),
TmpVarTab = maps:from_list(List),
S2 = S1#from_form{site = RemType, vtab = TmpVarTab},
Fun = fun(DD, LL) -> from_form(Form, S2, DD, LL, C1) end,
{NewType, L3, C3} =
case Tag of
type ->
recur_limit(Fun, D, L1, RemType, TypeNames);
opaque ->
{NewRep, L2, C2} = recur_limit(Fun, D, L1, RemType, TypeNames),
NewRep1 = choose_opaque_type(NewRep, Type),
NewRep2 =
case cannot_have_opaque(NewRep1, RemType, TypeNames) of
true -> NewRep;
false ->
ArgTypes2 = subst_all_vars_to_any_list(ArgTypes),
t_opaque(Mod, Name, ArgTypes2, NewRep1)
end,
{NewRep2, L2, C2}
end,
C4 = cache_put(CKey, NewType, L1 - L3, C3),
{NewType, L3, C4}
end;
error ->
Msg = io_lib:format("Unable to find remote type ~w:~tw()\n",
[RemMod, Name]),
throw({error, Msg})
end.
subst_all_vars_to_any_list(Types) ->
[subst_all_vars_to_any(Type) || Type <- Types].
%% Opaque types (both local and remote) are problematic when it comes
%% to the limits (TypeNames, D, and L). The reason is that if any() is
%% substituted for a more specialized subtype of an opaque type, the
%% property stated along with decorate_with_opaque() (the type has to
%% be a subtype of the declared type) no longer holds.
%%
%% The less than perfect remedy: if the opaque type created from a
%% form is not a subset of the declared type, the declared type is
%% used instead, effectively bypassing the limits, and potentially
%% resulting in huge types.
choose_opaque_type(Type, DeclType) ->
case
t_is_subtype(subst_all_vars_to_any(Type),
subst_all_vars_to_any(DeclType))
of
true -> Type;
false -> DeclType
end.
record_from_form({atom, _, Name}, ModFields, S, D0, L0, C) ->
#from_form{site = Site, mrecs = MR, tnames = TypeNames} = S,
RecordType = {record, Name},
case can_unfold_more(RecordType, TypeNames) of
true ->
M = site_module(Site),
{R, C1} = lookup_module_types(M, MR, C),
case lookup_record(Name, R) of
{ok, _} when element(1, Site) =:= check ->
{t_any(), L0, C1};
{ok, DeclFields} ->
NewTypeNames = [RecordType|TypeNames],
Site1 = {record, {M, Name, length(DeclFields)}},
S1 = S#from_form{site = Site1, tnames = NewTypeNames},
Fun = fun(D, L) ->
{GetModRec, L1, C2} =
get_mod_record(ModFields, DeclFields, S1, D, L, C1),
case GetModRec of
{error, FieldName} ->
throw({error,
io_lib:format("Illegal declaration of #~tw{~tw}\n",
[Name, FieldName])});
{ok, NewFields} ->
S2 = S1#from_form{vtab = var_table__new()},
{NewFields1, L2, C3} =
fields_from_form(NewFields, S2, D, L1, C2),
Rec = t_tuple(
[t_atom(Name)|[Type
|| {_FieldName, Type} <- NewFields1]]),
{Rec, L2, C3}
end
end,
recur_limit(Fun, D0, L0, RecordType, TypeNames);
error ->
throw({error, io_lib:format("Unknown record #~tw{}\n", [Name])})
end;
false ->
{t_any(), L0, C}
end.
get_mod_record([], DeclFields, _S, _D, L, C) ->
{{ok, DeclFields}, L, C};
get_mod_record(ModFields, DeclFields, S, D, L, C) ->
DeclFieldsDict = lists:keysort(1, DeclFields),
{ModFieldsDict, L1, C1} = build_field_dict(ModFields, S, D, L, C),
case get_mod_record_types(DeclFieldsDict, ModFieldsDict, []) of
{error, _FieldName} = Error -> {Error, L1, C1};
{ok, FinalKeyDict} ->
Fields = [lists:keyfind(FieldName, 1, FinalKeyDict)
|| {FieldName, _, _} <- DeclFields],
{{ok, Fields}, L1, C1}
end.
build_field_dict(FieldTypes, S, D, L, C) ->
build_field_dict(FieldTypes, S, D, L, C, []).
build_field_dict([{type, _, field_type, [{atom, _, Name}, Type]}|Left],
S, D, L, C, Acc) ->
{T, L1, C1} = from_form(Type, S, D, L - 1, C),
NewAcc = [{Name, Type, T}|Acc],
build_field_dict(Left, S, D, L1, C1, NewAcc);
build_field_dict([], _S, _D, L, C, Acc) ->
{lists:keysort(1, Acc), L, C}.
get_mod_record_types([{FieldName, _Abstr, _DeclType}|Left1],
[{FieldName, TypeForm, ModType}|Left2],
Acc) ->
get_mod_record_types(Left1, Left2, [{FieldName, TypeForm, ModType}|Acc]);
get_mod_record_types([{FieldName1, _Abstr, _DeclType} = DT|Left1],
[{FieldName2, _FormType, _ModType}|_] = List2,
Acc) when FieldName1 < FieldName2 ->
get_mod_record_types(Left1, List2, [DT|Acc]);
get_mod_record_types(Left1, [], Acc) ->
{ok, lists:keysort(1, Left1++Acc)};
get_mod_record_types(_, [{FieldName2, _FormType, _ModType}|_], _Acc) ->
{error, FieldName2}.
%% It is important to create a limited version of the record type
%% since nested record types can otherwise easily result in huge
%% terms.
fields_from_form([], _S, _D, L, C) ->
{[], L, C};
fields_from_form([{Name, Abstr, _Type}|Tail], S, D, L, C) ->
{T, L1, C1} = from_form(Abstr, S, D, L, C),
{F, L2, C2} = fields_from_form(Tail, S, D, L1, C1),
{[{Name, T}|F], L2, C2}.
list_from_form([], _S, _D, L, C) ->
{[], L, C};
list_from_form([H|Tail], S, D, L, C) ->
{H1, L1, C1} = from_form(H, S, D, L - 1, C),
{T1, L2, C2} = list_from_form(Tail, S, D, L1, C1),
{[H1|T1], L2, C2}.
%% Separates singleton types in keys (see is_singleton_type/1).
singleton_elements([]) ->
[];
singleton_elements([{K,?mand,V}=Pair|Pairs]) ->
case is_singleton_type(K) of
true ->
[Pair|singleton_elements(Pairs)];
false ->
singleton_elements([{K,?opt,V}|Pairs])
end;
singleton_elements([{Key0,MNess,Val}|Pairs]) ->
[{Key,MNess,Val} || Key <- separate_key(Key0)] ++ singleton_elements(Pairs).
%% To be in sync with is_singleton_type/1.
%% Does not separate tuples and maps as doing that has potential
%% to be very expensive.
separate_key(?atom(Atoms)) when Atoms =/= ?any ->
[t_atom(A) || A <- Atoms];
separate_key(?number(_, _) = T) ->
t_elements(T);
separate_key(?union(List)) ->
lists:append([separate_key(K) || K <- List, not t_is_none(K)]);
separate_key(Key) -> [Key].
%% Sorts, combines non-singleton pairs, and applies precendence and
%% mandatoriness rules.
map_from_form([], ShdwPs, MKs, Pairs, DefK, DefV) ->
verify_possible(MKs, ShdwPs),
{promote_to_mand(MKs, Pairs), DefK, DefV};
map_from_form([{SKey,MNess,Val}|SPairs], ShdwPs0, MKs0, Pairs0, DefK0, DefV0) ->
Key = lists:foldl(fun({K,_},S)->t_subtract(S,K)end, SKey, ShdwPs0),
ShdwPs = case Key of ?none -> ShdwPs0; _ -> [{Key,Val}|ShdwPs0] end,
MKs = case MNess of ?mand -> [SKey|MKs0]; ?opt -> MKs0 end,
if MNess =:= ?mand, SKey =:= ?none -> throw(none);
true -> ok
end,
{Pairs, DefK, DefV} =
case is_singleton_type(Key) of
true ->
MNess1 = case Val =:= ?none of true -> ?opt; false -> MNess end,
{mapdict_insert({Key,MNess1,Val}, Pairs0), DefK0, DefV0};
false ->
case Key =:= ?none orelse Val =:= ?none of
true -> {Pairs0, DefK0, DefV0};
false -> {Pairs0, t_sup(DefK0, Key), t_sup(DefV0, Val)}
end
end,
map_from_form(SPairs, ShdwPs, MKs, Pairs, DefK, DefV).
%% Verifies that all mandatory keys are possible, throws 'none' otherwise
verify_possible(MKs, ShdwPs) ->
lists:foreach(fun(M) -> verify_possible_1(M, ShdwPs) end, MKs).
verify_possible_1(M, ShdwPs) ->
case lists:any(fun({K,_}) -> t_inf(M, K) =/= ?none end, ShdwPs) of
true -> ok;
false -> throw(none)
end.
-spec promote_to_mand([erl_type()], t_map_dict()) -> t_map_dict().
promote_to_mand(_, []) -> [];
promote_to_mand(MKs, [E={K,_,V}|T]) ->
[case lists:any(fun(M) -> t_is_equal(K,M) end, MKs) of
true -> {K, ?mand, V};
false -> E
end|promote_to_mand(MKs, T)].
-define(RECUR_EXPAND_LIMIT, 10).
-define(RECUR_EXPAND_DEPTH, 2).
%% If more of the limited resources is spent on the non-recursive
%% forms, more warnings are found. And the analysis is also a bit
%% faster.
%%
%% Setting REC_TYPE_LIMIT to 1 would work also work well.
recur_limit(Fun, D, L, _, _) when L =< ?RECUR_EXPAND_DEPTH,
D =< ?RECUR_EXPAND_LIMIT ->
Fun(D, L);
recur_limit(Fun, D, L, TypeName, TypeNames) ->
case is_recursive(TypeName, TypeNames) of
true ->
{T, L1, C1} = Fun(?RECUR_EXPAND_DEPTH, ?RECUR_EXPAND_LIMIT),
{T, L - L1, C1};
false ->
Fun(D, L)
end.
-spec t_check_record_fields(parse_form(), sets:set(mfa()), site(),
mod_type_table(), var_table(), cache()) -> cache().
t_check_record_fields(Form, ExpTypes, Site, RecDict, VarTable, Cache) ->
State = #from_form{site = Site,
xtypes = ExpTypes,
mrecs = RecDict,
vtab = VarTable,
tnames = []},
check_record_fields(Form, State, Cache).
-spec check_record_fields(parse_form(), #from_form{}, cache()) -> cache().
%% If there is something wrong with parse_form()
%% throw({error, io_lib:chars()} is called.
check_record_fields({var, _L, _}, _S, C) -> C;
check_record_fields({ann_type, _L, [_Var, Type]}, S, C) ->
check_record_fields(Type, S, C);
check_record_fields({paren_type, _L, [Type]}, S, C) ->
check_record_fields(Type, S, C);
check_record_fields({remote_type, _L, [{atom, _, _}, {atom, _, _}, Args]},
S, C) ->
list_check_record_fields(Args, S, C);
check_record_fields({atom, _L, _}, _S, C) -> C;
check_record_fields({integer, _L, _}, _S, C) -> C;
check_record_fields({char, _L, _}, _S, C) -> C;
check_record_fields({op, _L, _Op, _Arg}, _S, C) -> C;
check_record_fields({op, _L, _Op, _Arg1, _Arg2}, _S, C) -> C;
check_record_fields({type, _L, tuple, any}, _S, C) -> C;
check_record_fields({type, _L, map, any}, _S, C) -> C;
check_record_fields({type, _L, binary, [_Base, _Unit]}, _S, C) -> C;
check_record_fields({type, _L, 'fun', [{type, _, any}, Range]}, S, C) ->
check_record_fields(Range, S, C);
check_record_fields({type, _L, range, [_From, _To]}, _S, C) -> C;
check_record_fields({type, _L, record, [Name|Fields]}, S, C) ->
check_record(Name, Fields, S, C);
check_record_fields({type, _L, _, Args}, S, C) ->
list_check_record_fields(Args, S, C);
check_record_fields({user_type, _L, _Name, Args}, S, C) ->
list_check_record_fields(Args, S, C).
check_record({atom, _, Name}, ModFields, S, C) ->
#from_form{site = Site, mrecs = MR} = S,
M = site_module(Site),
{R, C1} = lookup_module_types(M, MR, C),
{ok, DeclFields} = lookup_record(Name, R),
case check_fields(Name, ModFields, DeclFields, S, C1) of
{error, FieldName} ->
throw({error, io_lib:format("Illegal declaration of #~tw{~tw}\n",
[Name, FieldName])});
C2 -> C2
end.
check_fields(RecName, [{type, _, field_type, [{atom, _, Name}, Abstr]}|Left],
DeclFields, S, C) ->
#from_form{site = Site0, xtypes = ET, mrecs = MR, vtab = V} = S,
M = site_module(Site0),
Site = {record, {M, RecName, length(DeclFields)}},
{Type, C1} = t_from_form(Abstr, ET, Site, MR, V, C),
{Name, _, DeclType} = lists:keyfind(Name, 1, DeclFields),
TypeNoVars = subst_all_vars_to_any(Type),
case t_is_subtype(TypeNoVars, DeclType) of
false -> {error, Name};
true -> check_fields(RecName, Left, DeclFields, S, C1)
end;
check_fields(_RecName, [], _Decl, _S, C) ->
C.
list_check_record_fields([], _S, C) ->
C;
list_check_record_fields([H|Tail], S, C) ->
C1 = check_record_fields(H, S, C),
list_check_record_fields(Tail, S, C1).
site_module({_, {Module, _, _}}) ->
Module.
-spec cache__new() -> cache().
cache__new() ->
#cache{}.
-spec cache_key(module(), atom(), [erl_type()],
type_names(), expand_depth()) -> cache_key().
%% If TypeNames is left out from the key, the cache is smaller, and
%% the form-to-type translation is faster. But it would be a shame if,
%% for example, any() is used, where a more complex type should be
%% used. There is also a slight risk of creating unnecessarily big
%% types.
cache_key(Module, Name, ArgTypes, TypeNames, D) ->
{Module, Name, D, ArgTypes, TypeNames}.
-spec cache_find(cache_key(), cache()) ->
{erl_type(), expand_limit()} | 'error'.
cache_find(Key, #cache{types = Types}) ->
case maps:find(Key, Types) of
{ok, Value} ->
Value;
error ->
error
end.
-spec cache_put(cache_key(), erl_type(), expand_limit(), cache()) -> cache().
cache_put(_Key, _Type, DeltaL, Cache) when DeltaL < 0 ->
%% The type is truncated; do not reuse it.
Cache;
cache_put(Key, Type, DeltaL, #cache{types = Types} = Cache) ->
NewTypes = maps:put(Key, {Type, DeltaL}, Types),
Cache#cache{types = NewTypes}.
-spec t_var_names([parse_form()]) -> [atom()].
t_var_names([{var, _, Name}|L]) when Name =/= '_' ->
[Name|t_var_names(L)];
t_var_names([]) ->
[].
-spec t_form_to_string(parse_form()) -> string().
t_form_to_string({var, _L, '_'}) -> "_";
t_form_to_string({var, _L, Name}) -> atom_to_list(Name);
t_form_to_string({atom, _L, Atom}) ->
io_lib:write_string(atom_to_list(Atom), $'); % To quote or not to quote... '
t_form_to_string({integer, _L, Int}) -> integer_to_list(Int);
t_form_to_string({char, _L, Char}) -> integer_to_list(Char);
t_form_to_string({op, _L, _Op, _Arg} = Op) ->
case erl_eval:partial_eval(Op) of
{integer, _, _} = Int -> t_form_to_string(Int);
_ -> io_lib:format("Badly formed type ~w", [Op])
end;
t_form_to_string({op, _L, _Op, _Arg1, _Arg2} = Op) ->
case erl_eval:partial_eval(Op) of
{integer, _, _} = Int -> t_form_to_string(Int);
_ -> io_lib:format("Badly formed type ~w", [Op])
end;
t_form_to_string({ann_type, _L, [Var, Type]}) ->
t_form_to_string(Var) ++ "::" ++ t_form_to_string(Type);
t_form_to_string({paren_type, _L, [Type]}) ->
flat_format("(~ts)", [t_form_to_string(Type)]);
t_form_to_string({remote_type, _L, [{atom, _, Mod}, {atom, _, Name}, Args]}) ->
ArgString = "(" ++ flat_join(t_form_to_string_list(Args), ",") ++ ")",
flat_format("~w:~tw", [Mod, Name]) ++ ArgString;
t_form_to_string({type, _L, arity, []}) -> "arity()";
t_form_to_string({type, _L, binary, []}) -> "binary()";
t_form_to_string({type, _L, binary, [Base, Unit]} = Type) ->
case {erl_eval:partial_eval(Base), erl_eval:partial_eval(Unit)} of
{{integer, _, B}, {integer, _, U}} ->
%% the following mirrors the clauses of t_to_string/2
case {U, B} of
{0, 0} -> "<<>>";
{8, 0} -> "binary()";
{1, 0} -> "bitstring()";
{0, B} -> flat_format("<<_:~w>>", [B]);
{U, 0} -> flat_format("<<_:_*~w>>", [U]);
{U, B} -> flat_format("<<_:~w,_:_*~w>>", [B, U])
end;
_ -> io_lib:format("Badly formed bitstr type ~w", [Type])
end;
t_form_to_string({type, _L, bitstring, []}) -> "bitstring()";
t_form_to_string({type, _L, 'fun', []}) -> "fun()";
t_form_to_string({type, _L, 'fun', [{type, _, any}, Range]}) ->
"fun(...) -> " ++ t_form_to_string(Range);
t_form_to_string({type, _L, 'fun', [{type, _, product, Domain}, Range]}) ->
"fun((" ++ flat_join(t_form_to_string_list(Domain), ",") ++ ") -> "
++ t_form_to_string(Range) ++ ")";
t_form_to_string({type, _L, iodata, []}) -> "iodata()";
t_form_to_string({type, _L, iolist, []}) -> "iolist()";
t_form_to_string({type, _L, list, [Type]}) ->
"[" ++ t_form_to_string(Type) ++ "]";
t_form_to_string({type, _L, map, any}) -> "map()";
t_form_to_string({type, _L, map, Args}) ->
"#{" ++ flat_join(t_form_to_string_list(Args), ",") ++ "}";
t_form_to_string({type, _L, map_field_assoc, [Key, Val]}) ->
t_form_to_string(Key) ++ "=>" ++ t_form_to_string(Val);
t_form_to_string({type, _L, map_field_exact, [Key, Val]}) ->
t_form_to_string(Key) ++ ":=" ++ t_form_to_string(Val);
t_form_to_string({type, _L, mfa, []}) -> "mfa()";
t_form_to_string({type, _L, module, []}) -> "module()";
t_form_to_string({type, _L, node, []}) -> "node()";
t_form_to_string({type, _L, nonempty_list, [Type]}) ->
"[" ++ t_form_to_string(Type) ++ ",...]";
t_form_to_string({type, _L, nonempty_string, []}) -> "nonempty_string()";
t_form_to_string({type, _L, product, Elements}) ->
"<" ++ flat_join(t_form_to_string_list(Elements), ",") ++ ">";
t_form_to_string({type, _L, range, [From, To]} = Type) ->
case {erl_eval:partial_eval(From), erl_eval:partial_eval(To)} of
{{integer, _, FromVal}, {integer, _, ToVal}} ->
flat_format("~w..~w", [FromVal, ToVal]);
_ -> flat_format("Badly formed type ~w",[Type])
end;
t_form_to_string({type, _L, record, [{atom, _, Name}]}) ->
flat_format("#~tw{}", [Name]);
t_form_to_string({type, _L, record, [{atom, _, Name}|Fields]}) ->
FieldString = flat_join(t_form_to_string_list(Fields), ","),
flat_format("#~tw{~ts}", [Name, FieldString]);
t_form_to_string({type, _L, field_type, [{atom, _, Name}, Type]}) ->
flat_format("~tw::~ts", [Name, t_form_to_string(Type)]);
t_form_to_string({type, _L, term, []}) -> "term()";
t_form_to_string({type, _L, timeout, []}) -> "timeout()";
t_form_to_string({type, _L, tuple, any}) -> "tuple()";
t_form_to_string({type, _L, tuple, Args}) ->
"{" ++ flat_join(t_form_to_string_list(Args), ",") ++ "}";
t_form_to_string({type, _L, union, Args}) ->
flat_join(t_form_to_string_list(Args), " | ");
t_form_to_string({type, _L, Name, []} = T) ->
try
M = mod,
Site = {type, {M,Name,0}},
V = var_table__new(),
C = cache__new(),
State = #from_form{site = Site,
xtypes = sets:new(),
mrecs = 'undefined',
vtab = V,
tnames = []},
{T1, _, _} = from_form(T, State, _Deep=1000, _ALot=1000000, C),
t_to_string(T1)
catch throw:{error, _} -> atom_to_string(Name) ++ "()"
end;
t_form_to_string({user_type, _L, Name, List}) ->
flat_format("~tw(~ts)",
[Name, flat_join(t_form_to_string_list(List), ",")]);
t_form_to_string({type, L, Name, List}) ->
%% Compatibility: modules compiled before Erlang/OTP 18.0.
t_form_to_string({user_type, L, Name, List}).
t_form_to_string_list(List) ->
t_form_to_string_list(List, []).
t_form_to_string_list([H|T], Acc) ->
t_form_to_string_list(T, [t_form_to_string(H)|Acc]);
t_form_to_string_list([], Acc) ->
lists:reverse(Acc).
-spec atom_to_string(atom()) -> string().
atom_to_string(Atom) ->
flat_format("~tw", [Atom]).
%%=============================================================================
%%
%% Utilities
%%
%%=============================================================================
-spec any_none([erl_type()]) -> boolean().
any_none([?none|_Left]) -> true;
any_none([_|Left]) -> any_none(Left);
any_none([]) -> false.
-spec any_none_or_unit([erl_type()]) -> boolean().
any_none_or_unit([?none|_]) -> true;
any_none_or_unit([?unit|_]) -> true;
any_none_or_unit([_|Left]) -> any_none_or_unit(Left);
any_none_or_unit([]) -> false.
-spec is_erl_type(any()) -> boolean().
is_erl_type(?any) -> true;
is_erl_type(?none) -> true;
is_erl_type(?unit) -> true;
is_erl_type(#c{}) -> true;
is_erl_type(_) -> false.
-spec lookup_module_types(module(), mod_type_table(), cache()) ->
'error' | {type_table(), cache()}.
lookup_module_types(Module, CodeTable, Cache) ->
#cache{mod_recs = {mrecs, MRecs}} = Cache,
case dict:find(Module, MRecs) of
{ok, R} ->
{R, Cache};
error ->
try ets:lookup_element(CodeTable, Module, 2) of
R ->
NewMRecs = dict:store(Module, R, MRecs),
{R, Cache#cache{mod_recs = {mrecs, NewMRecs}}}
catch
_:_ -> error
end
end.
-spec lookup_record(atom(), type_table()) ->
'error' | {'ok', [{atom(), parse_form(), erl_type()}]}.
lookup_record(Tag, Table) when is_atom(Tag) ->
case maps:find({record, Tag}, Table) of
{ok, {_FileLine, [{_Arity, Fields}]}} ->
{ok, Fields};
{ok, {_FileLine, List}} when is_list(List) ->
%% This will have to do, since we do not know which record we
%% are looking for.
error;
error ->
error
end.
-spec lookup_record(atom(), arity(), type_table()) ->
'error' | {'ok', [{atom(), parse_form(), erl_type()}]}.
lookup_record(Tag, Arity, Table) when is_atom(Tag) ->
case maps:find({record, Tag}, Table) of
{ok, {_FileLine, [{Arity, Fields}]}} -> {ok, Fields};
{ok, {_FileLine, OrdDict}} -> orddict:find(Arity, OrdDict);
error -> error
end.
-spec lookup_type(_, _, _) -> {'type' | 'opaque', type_value()} | 'error'.
lookup_type(Name, Arity, Table) ->
case maps:find({type, Name, Arity}, Table) of
error ->
case maps:find({opaque, Name, Arity}, Table) of
error -> error;
{ok, Found} -> {opaque, Found}
end;
{ok, Found} -> {type, Found}
end.
-spec type_is_defined('type' | 'opaque', atom(), arity(), type_table()) ->
boolean().
type_is_defined(TypeOrOpaque, Name, Arity, Table) ->
maps:is_key({TypeOrOpaque, Name, Arity}, Table).
cannot_have_opaque(Type, TypeName, TypeNames) ->
t_is_none(Type) orelse is_recursive(TypeName, TypeNames).
is_recursive(TypeName, TypeNames) ->
lists:member(TypeName, TypeNames).
can_unfold_more(TypeName, TypeNames) ->
Fun = fun(E, Acc) -> case E of TypeName -> Acc + 1; _ -> Acc end end,
lists:foldl(Fun, 0, TypeNames) < ?REC_TYPE_LIMIT.
-spec do_opaque(erl_type(), opaques(), fun((_) -> T)) -> T.
%% Probably a little faster than calling t_unopaque/2.
%% Unions that are due to opaque types are unopaqued.
do_opaque(?opaque(_) = Type, Opaques, Pred) ->
case Opaques =:= 'universe' orelse is_opaque_type(Type, Opaques) of
true -> do_opaque(t_opaque_structure(Type), Opaques, Pred);
false -> Pred(Type)
end;
do_opaque(?union(List) = Type, Opaques, Pred) ->
[A,B,F,I,L,N,T,M,O,Map] = List,
if O =:= ?none -> Pred(Type);
true ->
case Opaques =:= 'universe' orelse is_opaque_type(O, Opaques) of
true ->
S = t_opaque_structure(O),
do_opaque(t_sup([A,B,F,I,L,N,T,M,S,Map]), Opaques, Pred);
false -> Pred(Type)
end
end;
do_opaque(Type, _Opaques, Pred) ->
Pred(Type).
map_all_values(?map(Pairs,_,DefV)) ->
[DefV|[V || {V, _, _} <- Pairs]].
map_all_keys(?map(Pairs,DefK,_)) ->
[DefK|[K || {_, _, K} <- Pairs]].
map_all_types(M) ->
map_all_keys(M) ++ map_all_values(M).
%% Tests if a type has exactly one possible value.
-spec t_is_singleton(erl_type()) -> boolean().
t_is_singleton(Type) ->
t_is_singleton(Type, 'universe').
-spec t_is_singleton(erl_type(), opaques()) -> boolean().
t_is_singleton(Type, Opaques) ->
do_opaque(Type, Opaques, fun is_singleton_type/1).
%% To be in sync with separate_key/1.
%% Used to also recognize maps and tuples.
is_singleton_type(?nil) -> true;
is_singleton_type(?atom(?any)) -> false;
is_singleton_type(?atom(Set)) ->
ordsets:size(Set) =:= 1;
is_singleton_type(?int_range(V, V)) -> true;
is_singleton_type(?int_set(Set)) ->
ordsets:size(Set) =:= 1;
is_singleton_type(_) ->
false.
%% Returns the only possible value of a singleton type.
-spec t_singleton_to_term(erl_type(), opaques()) -> term().
t_singleton_to_term(Type, Opaques) ->
do_opaque(Type, Opaques, fun singleton_type_to_term/1).
singleton_type_to_term(?nil) -> [];
singleton_type_to_term(?atom(Set)) when Set =/= ?any ->
case ordsets:size(Set) of
1 -> hd(ordsets:to_list(Set));
_ -> error(badarg)
end;
singleton_type_to_term(?int_range(V, V)) -> V;
singleton_type_to_term(?int_set(Set)) ->
case ordsets:size(Set) of
1 -> hd(ordsets:to_list(Set));
_ -> error(badarg)
end;
singleton_type_to_term(?tuple(Types, Arity, _)) when is_integer(Arity) ->
lists:map(fun singleton_type_to_term/1, Types);
singleton_type_to_term(?tuple_set([{Arity, [OnlyTuple]}]))
when is_integer(Arity) ->
singleton_type_to_term(OnlyTuple);
singleton_type_to_term(?map(Pairs, ?none, ?none)) ->
maps:from_list([{singleton_type_to_term(K), singleton_type_to_term(V)}
|| {K,?mand,V} <- Pairs]).
%% -----------------------------------
%% Set
%%
set_singleton(Element) ->
ordsets:from_list([Element]).
set_is_singleton(Element, Set) ->
set_singleton(Element) =:= Set.
set_is_element(Element, Set) ->
ordsets:is_element(Element, Set).
set_union(?any, _) -> ?any;
set_union(_, ?any) -> ?any;
set_union(S1, S2) ->
case ordsets:union(S1, S2) of
S when length(S) =< ?SET_LIMIT -> S;
_ -> ?any
end.
%% The intersection and subtraction can return ?none.
%% This should always be handled right away since ?none is not a valid set.
%% However, ?any is considered a valid set.
set_intersection(?any, S) -> S;
set_intersection(S, ?any) -> S;
set_intersection(S1, S2) ->
case ordsets:intersection(S1, S2) of
[] -> ?none;
S -> S
end.
set_subtract(_, ?any) -> ?none;
set_subtract(?any, _) -> ?any;
set_subtract(S1, S2) ->
case ordsets:subtract(S1, S2) of
[] -> ?none;
S -> S
end.
set_from_list(List) ->
case length(List) of
L when L =< ?SET_LIMIT -> ordsets:from_list(List);
L when L > ?SET_LIMIT -> ?any
end.
set_to_list(Set) ->
ordsets:to_list(Set).
set_filter(Fun, Set) ->
case ordsets:filter(Fun, Set) of
[] -> ?none;
NewSet -> NewSet
end.
set_size(Set) ->
ordsets:size(Set).
set_to_string(Set) ->
L = [case is_atom(X) of
true -> io_lib:write_string(atom_to_list(X), $'); % stupid emacs '
false -> flat_format("~tw", [X])
end || X <- set_to_list(Set)],
flat_join(L, " | ").
set_min([H|_]) -> H.
set_max(Set) ->
hd(lists:reverse(Set)).
flat_format(F, S) ->
lists:flatten(io_lib:format(F, S)).
flat_join(List, Sep) ->
lists:flatten(lists:join(Sep, List)).
%%=============================================================================
%%
%% Utilities for the binary type
%%
%%=============================================================================
-spec gcd(integer(), integer()) -> integer().
gcd(A, B) when B > A ->
gcd1(B, A);
gcd(A, B) ->
gcd1(A, B).
-spec gcd1(integer(), integer()) -> integer().
gcd1(A, 0) -> A;
gcd1(A, B) ->
case A rem B of
0 -> B;
X -> gcd1(B, X)
end.
-spec bitstr_concat(erl_type(), erl_type()) -> erl_type().
bitstr_concat(?none, _) -> ?none;
bitstr_concat(_, ?none) -> ?none;
bitstr_concat(?bitstr(U1, B1), ?bitstr(U2, B2)) ->
t_bitstr(gcd(U1, U2), B1+B2).
-spec bitstr_match(erl_type(), erl_type()) -> erl_type().
bitstr_match(?none, _) -> ?none;
bitstr_match(_, ?none) -> ?none;
bitstr_match(?bitstr(0, B1), ?bitstr(0, B2)) when B1 =< B2 ->
t_bitstr(0, B2-B1);
bitstr_match(?bitstr(0, _B1), ?bitstr(0, _B2)) ->
?none;
bitstr_match(?bitstr(0, B1), ?bitstr(U2, B2)) when B1 =< B2 ->
t_bitstr(U2, B2-B1);
bitstr_match(?bitstr(0, B1), ?bitstr(U2, B2)) ->
t_bitstr(U2, handle_base(U2, B2-B1));
bitstr_match(?bitstr(_, B1), ?bitstr(0, B2)) when B1 > B2 ->
?none;
bitstr_match(?bitstr(U1, B1), ?bitstr(U2, B2)) ->
GCD = gcd(U1, U2),
t_bitstr(GCD, handle_base(GCD, B2-B1)).
-spec handle_base(integer(), integer()) -> integer().
handle_base(Unit, Pos) when Pos >= 0 ->
Pos rem Unit;
handle_base(Unit, Neg) ->
(Unit+(Neg rem Unit)) rem Unit.
family(L) ->
R = sofs:relation(L),
F = sofs:relation_to_family(R),
sofs:to_external(F).
%%=============================================================================
%%
%% Interface functions for abstract data types defined in this module
%%
%%=============================================================================
-spec var_table__new() -> var_table().
var_table__new() ->
maps:new().