%%
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 1996-2016. All Rights Reserved.
%%
%% 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.
%%
%% %CopyrightEnd%
%%
-module(erlang).
-export([apply/2,apply/3,spawn/4,spawn_link/4,
spawn_monitor/1,spawn_monitor/3,
spawn_opt/2,spawn_opt/3,spawn_opt/4,spawn_opt/5,
disconnect_node/1]).
-export([spawn/1, spawn_link/1, spawn/2, spawn_link/2]).
-export([yield/0]).
-export([crasher/6]).
-export([fun_info/1]).
-export([send_nosuspend/2, send_nosuspend/3]).
-export([localtime_to_universaltime/1]).
-export([suspend_process/1]).
-export([min/2, max/2]).
-export([dlink/1, dunlink/1, dsend/2, dsend/3, dgroup_leader/2,
dexit/2, dmonitor_node/3, dmonitor_p/2]).
-export([delay_trap/2]).
-export([set_cookie/2, get_cookie/0]).
-export([nodes/0]).
-export([integer_to_list/2]).
-export([integer_to_binary/2]).
-export([set_cpu_topology/1, format_cpu_topology/1]).
-export([await_proc_exit/3]).
-export([memory/0, memory/1]).
-export([alloc_info/1, alloc_sizes/1]).
-export([gather_sched_wall_time_result/1,
await_sched_wall_time_modifications/2,
gather_gc_info_result/1]).
-deprecated([now/0]).
%% Get rid of autoimports of spawn to avoid clashes with ourselves.
-compile({no_auto_import,[spawn_link/1]}).
-compile({no_auto_import,[spawn_link/4]}).
-compile({no_auto_import,[spawn_opt/2]}).
-compile({no_auto_import,[spawn_opt/4]}).
-compile({no_auto_import,[spawn_opt/5]}).
-export_type([timestamp/0]).
-export_type([time_unit/0]).
-export_type([deprecated_time_unit/0]).
-type ext_binary() :: binary().
-type timestamp() :: {MegaSecs :: non_neg_integer(),
Secs :: non_neg_integer(),
MicroSecs :: non_neg_integer()}.
-type time_unit() ::
pos_integer()
| 'second'
| 'millisecond'
| 'microsecond'
| 'nanosecond'
| 'native'
| 'perf_counter'
| deprecated_time_unit().
%% Deprecated symbolic units...
-type deprecated_time_unit() ::
'seconds'
| 'milli_seconds'
| 'micro_seconds'
| 'nano_seconds'.
-opaque prepared_code() :: reference().
-export_type([prepared_code/0]).
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Native code BIF stubs and their types
%% (BIF's actually implemented in this module goes last in the file)
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Exports for all native code stubs
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
-export([adler32/1, adler32/2, adler32_combine/3, append_element/2]).
-export([atom_to_binary/2, atom_to_list/1, binary_part/2, binary_part/3]).
-export([binary_to_atom/2, binary_to_existing_atom/2, binary_to_float/1]).
-export([binary_to_integer/1,binary_to_integer/2]).
-export([binary_to_list/1]).
-export([binary_to_list/3, binary_to_term/1, binary_to_term/2]).
-export([bit_size/1, bitsize/1, bitstring_to_list/1]).
-export([bump_reductions/1, byte_size/1, call_on_load_function/1]).
-export([cancel_timer/1, cancel_timer/2, ceil/1,
check_old_code/1, check_process_code/2,
check_process_code/3, crc32/1]).
-export([crc32/2, crc32_combine/3, date/0, decode_packet/3]).
-export([delete_element/2]).
-export([delete_module/1, demonitor/1, demonitor/2, display/1]).
-export([display_nl/0, display_string/1, dist_exit/3, erase/0, erase/1]).
-export([error/1, error/2, exit/1, exit/2, external_size/1]).
-export([external_size/2, finish_after_on_load/2, finish_loading/1, float/1]).
-export([float_to_binary/1, float_to_binary/2,
float_to_list/1, float_to_list/2, floor/1]).
-export([fun_info/2, fun_info_mfa/1, fun_to_list/1, function_exported/3]).
-export([garbage_collect/0, garbage_collect/1, garbage_collect/2]).
-export([garbage_collect_message_area/0, get/0, get/1, get_keys/0, get_keys/1]).
-export([get_module_info/1, get_stacktrace/0, group_leader/0]).
-export([group_leader/2]).
-export([halt/0, halt/1, halt/2,
has_prepared_code_on_load/1, hibernate/3]).
-export([insert_element/3]).
-export([integer_to_binary/1, integer_to_list/1]).
-export([iolist_size/1, iolist_to_binary/1]).
-export([is_alive/0, is_builtin/3, is_process_alive/1, length/1, link/1]).
-export([list_to_atom/1, list_to_binary/1]).
-export([list_to_bitstring/1, list_to_existing_atom/1, list_to_float/1]).
-export([list_to_integer/1, list_to_integer/2]).
-export([list_to_pid/1, list_to_ref/1, list_to_tuple/1, loaded/0]).
-export([localtime/0, make_ref/0]).
-export([map_size/1, match_spec_test/3, md5/1, md5_final/1]).
-export([md5_init/0, md5_update/2, module_loaded/1, monitor/2]).
-export([monitor_node/2, monitor_node/3, nif_error/1, nif_error/2]).
-export([node/0, node/1, now/0, phash/2, phash2/1, phash2/2]).
-export([pid_to_list/1, port_close/1, port_command/2, port_command/3]).
-export([port_connect/2, port_control/3, port_get_data/1]).
-export([port_set_data/2, port_to_list/1, ports/0]).
-export([posixtime_to_universaltime/1, pre_loaded/0, prepare_loading/2]).
-export([monotonic_time/0, monotonic_time/1]).
-export([system_time/0, system_time/1]).
-export([convert_time_unit/3]).
-export([unique_integer/0, unique_integer/1]).
-export([time_offset/0, time_offset/1, timestamp/0]).
-export([process_display/2]).
-export([process_flag/3, process_info/1, processes/0, purge_module/1]).
-export([put/2, raise/3, read_timer/1, read_timer/2, ref_to_list/1, register/2]).
-export([send_after/3, send_after/4, start_timer/3, start_timer/4]).
-export([registered/0, resume_process/1, round/1, self/0]).
-export([seq_trace/2, seq_trace_print/1, seq_trace_print/2, setnode/2]).
-export([setnode/3, size/1, spawn/3, spawn_link/3, split_binary/2]).
-export([suspend_process/2, system_monitor/0]).
-export([system_monitor/1, system_monitor/2, system_profile/0]).
-export([system_profile/2, throw/1, time/0, trace/3, trace_delivered/1]).
-export([trace_info/2, trunc/1, tuple_size/1, universaltime/0]).
-export([universaltime_to_posixtime/1, unlink/1, unregister/1, whereis/1]).
-export([abs/1, append/2, element/2, get_module_info/2, hd/1,
is_atom/1, is_binary/1, is_bitstring/1, is_boolean/1,
is_float/1, is_function/1, is_function/2, is_integer/1,
is_list/1, is_map/1, is_number/1, is_pid/1, is_port/1, is_record/2,
is_record/3, is_reference/1, is_tuple/1, load_module/2,
load_nif/2, localtime_to_universaltime/2, make_fun/3,
make_tuple/2, make_tuple/3, nodes/1, open_port/2,
port_call/2, port_call/3, port_info/1, port_info/2, process_flag/2,
process_info/2, send/2, send/3, seq_trace_info/1,
setelement/3, spawn_opt/1,
statistics/1, subtract/2, system_flag/2,
term_to_binary/1, term_to_binary/2, tl/1, trace_pattern/2,
trace_pattern/3, tuple_to_list/1, system_info/1,
universaltime_to_localtime/1]).
-export([dt_get_tag/0, dt_get_tag_data/0, dt_prepend_vm_tag_data/1, dt_append_vm_tag_data/1,
dt_put_tag/1, dt_restore_tag/1, dt_spread_tag/1]).
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%% Simple native code BIFs
%%% These are here for the types/specs, the real implementation is in the C code.
%%% The first chunk is originally auto-generated from
%%% $ERL_TOP/lib/hipe/cerl/erl_bif_types.erl as released in R15B.
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% types
-type fun_info_item() ::
arity |
env |
index |
name |
module |
new_index |
new_uniq |
pid |
type |
uniq.
-type seq_trace_info() ::
'send' |
'receive' |
'print' |
'timestamp' |
'monotonic_timestamp' |
'strict_monotonic_timestamp' |
'label' |
'serial'.
-type seq_trace_info_returns() ::
{ seq_trace_info(), non_neg_integer() |
boolean() |
{ non_neg_integer(), non_neg_integer() } } |
[].
-type system_profile_option() ::
'exclusive' |
'runnable_ports' |
'runnable_procs' |
'scheduler' |
'timestamp' |
'monotonic_timestamp' |
'strict_monotonic_timestamp'.
-type system_monitor_option() ::
'busy_port' |
'busy_dist_port' |
{'long_gc', non_neg_integer()} |
{'long_schedule', non_neg_integer()} |
{'large_heap', non_neg_integer()}.
-type raise_stacktrace() ::
[{module(), atom(), arity() | [term()]} |
{function(), [term()]}] |
[{module(), atom(), arity() | [term()], [{atom(),term()}]} |
{function(), [term()], [{atom(),term()}]}].
-type bitstring_list() ::
maybe_improper_list(byte() | bitstring() | bitstring_list(), bitstring() | []).
-type trace_flag() ::
all |
send |
'receive' |
procs |
ports |
call |
arity |
return_to |
silent |
running |
exiting |
running_procs |
running_ports |
garbage_collection |
timestamp |
cpu_timestamp |
monotonic_timestamp |
strict_monotonic_timestamp |
set_on_spawn |
set_on_first_spawn |
set_on_link |
set_on_first_link |
{tracer, pid() | port()} |
{tracer, module(), term()}.
-type trace_info_item_result() ::
{traced, global | local | false | undefined} |
{match_spec, trace_match_spec() | false | undefined} |
{meta, pid() | port() | false | undefined | []} |
{meta, module(), term() } |
{meta_match_spec, trace_match_spec() | false | undefined} |
{call_count, non_neg_integer() | boolean() | undefined} |
{call_time, [{pid(), non_neg_integer(),
non_neg_integer(), non_neg_integer()}] | boolean() | undefined}.
-type trace_info_flag() ::
send |
'receive' |
set_on_spawn |
call |
return_to |
procs |
set_on_first_spawn |
set_on_link |
running |
garbage_collection |
timestamp |
monotonic_timestamp |
strict_monotonic_timestamp |
arity.
-type trace_info_return() ::
undefined |
{flags, [trace_info_flag()]} |
{tracer, pid() | port() | []} |
{tracer, module(), term()} |
trace_info_item_result() |
{all, [ trace_info_item_result() ] | false | undefined}.
%% Specs and stubs
%% adler32/1
-spec erlang:adler32(Data) -> non_neg_integer() when
Data :: iodata().
adler32(_Data) ->
erlang:nif_error(undefined).
%% adler32/2
-spec erlang:adler32(OldAdler, Data) -> non_neg_integer() when
OldAdler :: non_neg_integer(),
Data :: iodata().
adler32(_OldAdler, _Data) ->
erlang:nif_error(undefined).
%% adler32_combine/3
-spec erlang:adler32_combine(FirstAdler, SecondAdler, SecondSize) -> non_neg_integer() when
FirstAdler :: non_neg_integer(),
SecondAdler :: non_neg_integer(),
SecondSize :: non_neg_integer().
adler32_combine(_FirstAdler, _SecondAdler, _SecondSize) ->
erlang:nif_error(undefined).
%% append_element/2
-spec erlang:append_element(Tuple1, Term) -> Tuple2 when
Tuple1 :: tuple(),
Tuple2 :: tuple(),
Term :: term().
append_element(_Tuple1, _Term) ->
erlang:nif_error(undefined).
%% atom_to_binary/2
-spec atom_to_binary(Atom, Encoding) -> binary() when
Atom :: atom(),
Encoding :: latin1 | unicode | utf8.
atom_to_binary(_Atom, _Encoding) ->
erlang:nif_error(undefined).
%% atom_to_list/1
-spec atom_to_list(Atom) -> string() when
Atom :: atom().
atom_to_list(_Atom) ->
erlang:nif_error(undefined).
%% binary_part/2
%% Shadowed by erl_bif_types: erlang:binary_part/2
-spec binary_part(Subject, PosLen) -> binary() when
Subject :: binary(),
PosLen :: {Start :: non_neg_integer(), Length :: integer()}.
binary_part(_Subject, _PosLen) ->
erlang:nif_error(undefined).
%% binary_part/3
%% Shadowed by erl_bif_types: erlang:binary_part/3
-spec binary_part(Subject, Start, Length) -> binary() when
Subject :: binary(),
Start :: non_neg_integer(),
Length :: integer().
binary_part(_Subject, _Start, _Length) ->
erlang:nif_error(undefined).
%% binary_to_atom/2
-spec binary_to_atom(Binary, Encoding) -> atom() when
Binary :: binary(),
Encoding :: latin1 | unicode | utf8.
binary_to_atom(_Binary, _Encoding) ->
erlang:nif_error(undefined).
%% binary_to_existing_atom/2
-spec binary_to_existing_atom(Binary, Encoding) -> atom() when
Binary :: binary(),
Encoding :: latin1 | unicode | utf8.
binary_to_existing_atom(_Binary, _Encoding) ->
erlang:nif_error(undefined).
%% binary_to_float/1
-spec binary_to_float(Binary) -> float() when
Binary :: binary().
binary_to_float(_Binary) ->
erlang:nif_error(undefined).
%% binary_to_integer/1
-spec binary_to_integer(Binary) -> integer() when
Binary :: binary().
binary_to_integer(_Binary) ->
erlang:nif_error(undefined).
%% binary_to_integer/2
-spec binary_to_integer(Binary,Base) -> integer() when
Binary :: binary(),
Base :: 2..36.
binary_to_integer(_Binary,_Base) ->
erlang:nif_error(undefined).
%% binary_to_list/1
-spec binary_to_list(Binary) -> [byte()] when
Binary :: binary().
binary_to_list(_Binary) ->
erlang:nif_error(undefined).
%% binary_to_list/3
-spec binary_to_list(Binary, Start, Stop) -> [byte()] when
Binary :: binary(),
Start :: pos_integer(),
Stop :: pos_integer().
binary_to_list(_Binary, _Start, _Stop) ->
erlang:nif_error(undefined).
%% binary_to_term/1
-spec binary_to_term(Binary) -> term() when
Binary :: ext_binary().
binary_to_term(_Binary) ->
erlang:nif_error(undefined).
%% binary_to_term/2
-spec binary_to_term(Binary, Opts) -> term() when
Binary :: ext_binary(),
Opts :: [safe].
binary_to_term(_Binary, _Opts) ->
erlang:nif_error(undefined).
%% bit_size/1
%% Shadowed by erl_bif_types: erlang:bit_size/1
-spec bit_size(Bitstring) -> non_neg_integer() when
Bitstring :: bitstring().
bit_size(_Bitstring) ->
erlang:nif_error(undefined).
%% bitsize/1
-spec bitsize(P1) -> non_neg_integer() when
P1 :: bitstring().
bitsize(_P1) ->
erlang:nif_error(undefined).
%% bitstring_to_list/1
-spec bitstring_to_list(Bitstring) -> [byte() | bitstring()] when
Bitstring :: bitstring().
bitstring_to_list(_Bitstring) ->
erlang:nif_error(undefined).
%% bump_reductions/1
-spec erlang:bump_reductions(Reductions) -> true when
Reductions :: pos_integer().
bump_reductions(_Reductions) ->
erlang:nif_error(undefined).
%% byte_size/1
%% Shadowed by erl_bif_types: erlang:byte_size/1
-spec byte_size(Bitstring) -> non_neg_integer() when
Bitstring :: bitstring().
byte_size(_Bitstring) ->
erlang:nif_error(undefined).
%% call_on_load_function/1
-spec erlang:call_on_load_function(P1) -> term() when
P1 :: atom().
call_on_load_function(_P1) ->
erlang:nif_error(undefined).
%% cancel_timer/1
-spec erlang:cancel_timer(TimerRef) -> Result when
TimerRef :: reference(),
Time :: non_neg_integer(),
Result :: Time | false.
cancel_timer(_TimerRef) ->
erlang:nif_error(undefined).
%% cancel_timer/2
-spec erlang:cancel_timer(TimerRef, Options) -> Result | ok when
TimerRef :: reference(),
Async :: boolean(),
Info :: boolean(),
Option :: {async, Async} | {info, Info},
Options :: [Option],
Time :: non_neg_integer(),
Result :: Time | false.
cancel_timer(_TimerRef, _Options) ->
erlang:nif_error(undefined).
%% ceil/1
%% Shadowed by erl_bif_types: erlang:ceil/1
-spec ceil(Number) -> integer() when
Number :: number().
ceil(_) ->
erlang:nif_error(undef).
%% check_old_code/1
-spec check_old_code(Module) -> boolean() when
Module :: module().
check_old_code(_Module) ->
erlang:nif_error(undefined).
%% check_process_code/2
-spec check_process_code(Pid, Module) -> CheckResult when
Pid :: pid(),
Module :: module(),
CheckResult :: boolean().
check_process_code(Pid, Module) ->
try
erts_internal:check_process_code(Pid, Module, [{allow_gc, true}])
catch
error:Error -> erlang:error(Error, [Pid, Module])
end.
%% check_process_code/3
-spec check_process_code(Pid, Module, OptionList) -> CheckResult | async when
Pid :: pid(),
Module :: module(),
RequestId :: term(),
Option :: {async, RequestId} | {allow_gc, boolean()},
OptionList :: [Option],
CheckResult :: boolean() | aborted.
check_process_code(Pid, Module, OptionList) ->
try
erts_internal:check_process_code(Pid, Module, OptionList)
catch
error:Error -> erlang:error(Error, [Pid, Module, OptionList])
end.
%% crc32/1
-spec erlang:crc32(Data) -> non_neg_integer() when
Data :: iodata().
crc32(_Data) ->
erlang:nif_error(undefined).
%% crc32/2
-spec erlang:crc32(OldCrc, Data) -> non_neg_integer() when
OldCrc :: non_neg_integer(),
Data :: iodata().
crc32(_OldCrc, _Data) ->
erlang:nif_error(undefined).
%% crc32_combine/3
-spec erlang:crc32_combine(FirstCrc, SecondCrc, SecondSize) -> non_neg_integer() when
FirstCrc :: non_neg_integer(),
SecondCrc :: non_neg_integer(),
SecondSize :: non_neg_integer().
crc32_combine(_FirstCrc, _SecondCrc, _SecondSize) ->
erlang:nif_error(undefined).
%% date/0
-spec date() -> Date when
Date :: calendar:date().
date() ->
erlang:nif_error(undefined).
%% decode_packet/3
-spec erlang:decode_packet(Type, Bin, Options) ->
{ok, Packet, Rest} |
{more, Length} |
{error, Reason} when
Type :: 'raw' | 0 | 1 | 2 | 4 | 'asn1' | 'cdr' | 'sunrm' | 'fcgi'
| 'tpkt' | 'line' | 'http' | 'http_bin' | 'httph' | 'httph_bin',
Bin :: binary(),
Options :: [Opt],
Opt :: {packet_size, non_neg_integer()}
| {line_length, non_neg_integer()},
Packet :: binary() | HttpPacket,
Rest :: binary(),
Length :: non_neg_integer() | undefined,
Reason :: term(),
HttpPacket :: HttpRequest
| HttpResponse
| HttpHeader
| 'http_eoh'
| HttpError,
HttpRequest :: {'http_request', HttpMethod, HttpUri, HttpVersion},
HttpResponse :: {'http_response', HttpVersion, integer(), HttpString},
HttpHeader :: {'http_header',
integer(),
HttpField,
Reserved :: term(),
Value :: HttpString},
HttpError :: {'http_error', HttpString},
HttpMethod :: 'OPTIONS' | 'GET' | 'HEAD' | 'POST' | 'PUT' | 'DELETE'
| 'TRACE' | HttpString,
HttpUri :: '*'
| { 'absoluteURI',
'http' | 'https',
Host :: HttpString,
Port :: inet:port_number() | 'undefined',
Path :: HttpString}
| {'scheme', Scheme :: HttpString, HttpString}
| {'abs_path', HttpString}
| HttpString,
HttpVersion :: {Major :: non_neg_integer(), Minor :: non_neg_integer()},
HttpField :: 'Cache-Control'
| 'Connection'
| 'Date'
| 'Pragma'
| 'Transfer-Encoding'
| 'Upgrade'
| 'Via'
| 'Accept'
| 'Accept-Charset'
| 'Accept-Encoding'
| 'Accept-Language'
| 'Authorization'
| 'From'
| 'Host'
| 'If-Modified-Since'
| 'If-Match'
| 'If-None-Match'
| 'If-Range'
| 'If-Unmodified-Since'
| 'Max-Forwards'
| 'Proxy-Authorization'
| 'Range'
| 'Referer'
| 'User-Agent'
| 'Age'
| 'Location'
| 'Proxy-Authenticate'
| 'Public'
| 'Retry-After'
| 'Server'
| 'Vary'
| 'Warning'
|'Www-Authenticate'
| 'Allow'
| 'Content-Base'
| 'Content-Encoding'
| 'Content-Language'
| 'Content-Length'
| 'Content-Location'
| 'Content-Md5'
| 'Content-Range'
| 'Content-Type'
| 'Etag'
| 'Expires'
| 'Last-Modified'
| 'Accept-Ranges'
| 'Set-Cookie'
| 'Set-Cookie2'
| 'X-Forwarded-For'
| 'Cookie'
| 'Keep-Alive'
| 'Proxy-Connection'
| HttpString,
HttpString :: string() | binary().
decode_packet(_Type, _Bin, _Options) ->
erlang:nif_error(undefined).
%% delete_element/2
-spec erlang:delete_element(Index, Tuple1) -> Tuple2 when
Index :: pos_integer(),
Tuple1 :: tuple(),
Tuple2 :: tuple().
delete_element(_Index, _Tuple1) ->
erlang:nif_error(undefined).
%% delete_module/1
-spec delete_module(Module) -> true | undefined when
Module :: module().
delete_module(_Module) ->
erlang:nif_error(undefined).
%% demonitor/1
-spec demonitor(MonitorRef) -> true when
MonitorRef :: reference().
demonitor(_MonitorRef) ->
erlang:nif_error(undefined).
%% demonitor/2
-spec demonitor(MonitorRef, OptionList) -> boolean() when
MonitorRef :: reference(),
OptionList :: [Option],
Option :: flush | info.
demonitor(_MonitorRef, _OptionList) ->
erlang:nif_error(undefined).
%% display/1
-spec erlang:display(Term) -> true when
Term :: term().
display(_Term) ->
erlang:nif_error(undefined).
%% display_nl/0
-spec erlang:display_nl() -> true.
display_nl() ->
erlang:nif_error(undefined).
%% display_string/1
-spec erlang:display_string(P1) -> true when
P1 :: string().
display_string(_P1) ->
erlang:nif_error(undefined).
%% dist_exit/3
-spec erlang:dist_exit(P1, P2, P3) -> true when
P1 :: pid(),
P2 :: kill | noconnection | normal,
P3 :: pid() | port().
dist_exit(_P1, _P2, _P3) ->
erlang:nif_error(undefined).
%% dt_append_vm_tag_data/1
-spec erlang:dt_append_vm_tag_data(IoData) -> IoDataRet when
IoData :: iodata(),
IoDataRet :: iodata().
dt_append_vm_tag_data(_IoData) ->
erlang:nif_error(undefined).
%% dt_get_tag/0
-spec erlang:dt_get_tag() -> binary() | undefined.
dt_get_tag() ->
erlang:nif_error(undefined).
%% dt_get_tag_data/0
-spec erlang:dt_get_tag_data() -> binary() | undefined.
dt_get_tag_data() ->
erlang:nif_error(undefined).
%% dt_prepend_vm_tag_data/1
-spec erlang:dt_prepend_vm_tag_data(IoData) -> IoDataRet when
IoData :: iodata(),
IoDataRet :: iodata().
dt_prepend_vm_tag_data(_IoData) ->
erlang:nif_error(undefined).
%% dt_put_tag/1
-spec erlang:dt_put_tag(IoData) -> binary() | undefined when
IoData :: iodata().
dt_put_tag(_IoData) ->
erlang:nif_error(undefined).
%% dt_restore_tag/1
-spec erlang:dt_restore_tag(TagData) -> true when
TagData :: term().
dt_restore_tag(_TagData) ->
erlang:nif_error(undefined).
%% dt_spread_tag/1
-spec erlang:dt_spread_tag(boolean()) -> TagData when
TagData :: term().
dt_spread_tag(_Bool) ->
erlang:nif_error(undefined).
%% erase/0
-spec erase() -> [{Key, Val}] when
Key :: term(),
Val :: term().
erase() ->
erlang:nif_error(undefined).
%% erase/1
-spec erase(Key) -> Val | undefined when
Key :: term(),
Val :: term().
erase(_Key) ->
erlang:nif_error(undefined).
%% error/1
%% Shadowed by erl_bif_types: erlang:error/1
-spec error(Reason) -> no_return() when
Reason :: term().
error(_Reason) ->
erlang:nif_error(undefined).
%% error/2
%% Shadowed by erl_bif_types: erlang:error/2
-spec error(Reason, Args) -> no_return() when
Reason :: term(),
Args :: [term()].
error(_Reason, _Args) ->
erlang:nif_error(undefined).
%% exit/1
%% Shadowed by erl_bif_types: erlang:exit/1
-spec exit(Reason) -> no_return() when
Reason :: term().
exit(_Reason) ->
erlang:nif_error(undefined).
%% exit/2
-spec exit(Pid, Reason) -> true when
Pid :: pid() | port(),
Reason :: term().
exit(_Pid, _Reason) ->
erlang:nif_error(undefined).
%% external_size/1
-spec erlang:external_size(Term) -> non_neg_integer() when
Term :: term().
external_size(_Term) ->
erlang:nif_error(undefined).
%% external_size/2
-spec erlang:external_size(Term, Options) -> non_neg_integer() when
Term :: term(),
Options :: [{minor_version, Version :: non_neg_integer()}].
external_size(_Term, _Options) ->
erlang:nif_error(undefined).
%% finish_loading/2
-spec erlang:finish_loading(PreparedCodeList) -> ok | Error when
PreparedCodeList :: [PreparedCode],
PreparedCode :: prepared_code(),
ModuleList :: [module()],
Error :: {not_purged,ModuleList} | {on_load,ModuleList}.
finish_loading(_List) ->
erlang:nif_error(undefined).
%% finish_after_on_load/2
-spec erlang:finish_after_on_load(P1, P2) -> true when
P1 :: atom(),
P2 :: boolean().
finish_after_on_load(_P1, _P2) ->
erlang:nif_error(undefined).
%% float/1
%% Shadowed by erl_bif_types: erlang:float/1
-spec float(Number) -> float() when
Number :: number().
float(_Number) ->
erlang:nif_error(undefined).
%% float_to_binary/1
-spec float_to_binary(Float) -> binary() when
Float :: float().
float_to_binary(_Float) ->
erlang:nif_error(undefined).
%% float_to_binary/2
-spec float_to_binary(Float, Options) -> binary() when
Float :: float(),
Options :: [Option],
Option :: {decimals, Decimals :: 0..253} |
{scientific, Decimals :: 0..249} |
compact.
float_to_binary(_Float, _Options) ->
erlang:nif_error(undefined).
%% float_to_list/1
-spec float_to_list(Float) -> string() when
Float :: float().
float_to_list(_Float) ->
erlang:nif_error(undefined).
%% float_to_list/2
-spec float_to_list(Float, Options) -> string() when
Float :: float(),
Options :: [Option],
Option :: {decimals, Decimals :: 0..253} |
{scientific, Decimals :: 0..249} |
compact.
float_to_list(_Float, _Options) ->
erlang:nif_error(undefined).
%% floor/1
%% Shadowed by erl_bif_types: erlang:floor/1
-spec floor(Number) -> integer() when
Number :: number().
floor(_) ->
erlang:nif_error(undef).
%% fun_info/2
-spec erlang:fun_info(Fun, Item) -> {Item, Info} when
Fun :: function(),
Item :: fun_info_item(),
Info :: term().
fun_info(_Fun, _Item) ->
erlang:nif_error(undefined).
%% fun_info_mfa/1
-spec erlang:fun_info_mfa(Fun) -> {Mod, Name, Arity} when
Fun :: function(),
Mod :: atom(),
Name :: atom(),
Arity :: non_neg_integer().
fun_info_mfa(_Fun) ->
erlang:nif_error(undefined).
%% fun_to_list/1
-spec erlang:fun_to_list(Fun) -> string() when
Fun :: function().
fun_to_list(_Fun) ->
erlang:nif_error(undefined).
%% function_exported/3
-spec erlang:function_exported(Module, Function, Arity) -> boolean() when
Module :: module(),
Function :: atom(),
Arity :: arity().
function_exported(_Module, _Function, _Arity) ->
erlang:nif_error(undefined).
%% garbage_collect/0
-spec garbage_collect() -> true.
garbage_collect() ->
erts_internal:garbage_collect(major).
%% garbage_collect/1
-spec garbage_collect(Pid) -> GCResult when
Pid :: pid(),
GCResult :: boolean().
garbage_collect(Pid) ->
try
erlang:garbage_collect(Pid, [])
catch
error:Error -> erlang:error(Error, [Pid])
end.
-record(gcopt, {
async = sync :: sync | {async, _},
type = major % default major, can also be minor
}).
%% garbage_collect/2
-spec garbage_collect(Pid, OptionList) -> GCResult | async when
Pid :: pid(),
RequestId :: term(),
Option :: {async, RequestId} | {type, 'major' | 'minor'},
OptionList :: [Option],
GCResult :: boolean().
garbage_collect(Pid, OptionList) ->
try
GcOpts = get_gc_opts(OptionList, #gcopt{}),
case GcOpts#gcopt.async of
{async, ReqId} ->
{priority, Prio} = erlang:process_info(erlang:self(),
priority),
erts_internal:request_system_task(
Pid, Prio, {garbage_collect, ReqId, GcOpts#gcopt.type}),
async;
sync ->
case Pid == erlang:self() of
true ->
erts_internal:garbage_collect(GcOpts#gcopt.type);
false ->
{priority, Prio} = erlang:process_info(erlang:self(),
priority),
ReqId = erlang:make_ref(),
erts_internal:request_system_task(
Pid, Prio,
{garbage_collect, ReqId, GcOpts#gcopt.type}),
receive
{garbage_collect, ReqId, GCResult} ->
GCResult
end
end
end
catch
error:Error -> erlang:error(Error, [Pid, OptionList])
end.
% gets async opt and verify valid option list
get_gc_opts([{async, _ReqId} = AsyncTuple | Options], GcOpt = #gcopt{}) ->
get_gc_opts(Options, GcOpt#gcopt{ async = AsyncTuple });
get_gc_opts([{type, T} | Options], GcOpt = #gcopt{}) ->
get_gc_opts(Options, GcOpt#gcopt{ type = T });
get_gc_opts([], GcOpt) ->
GcOpt.
%% garbage_collect_message_area/0
-spec erlang:garbage_collect_message_area() -> boolean().
garbage_collect_message_area() ->
erlang:nif_error(undefined).
%% get/0
-spec get() -> [{Key, Val}] when
Key :: term(),
Val :: term().
get() ->
erlang:nif_error(undefined).
%% get/1
-spec get(Key) -> Val | undefined when
Key :: term(),
Val :: term().
get(_Key) ->
erlang:nif_error(undefined).
%% get_keys/0
-spec get_keys() -> [Key] when
Key :: term().
get_keys() ->
erlang:nif_error(undefined).
%% get_keys/1
-spec get_keys(Val) -> [Key] when
Val :: term(),
Key :: term().
get_keys(_Val) ->
erlang:nif_error(undefined).
%% get_module_info/1
-spec erlang:get_module_info(Module) -> [{Item, term()}] when
Item :: module | exports | attributes | compile | native | md5,
Module :: atom().
get_module_info(_Module) ->
erlang:nif_error(undefined).
%% get_stacktrace/0
-spec erlang:get_stacktrace() -> [stack_item()].
get_stacktrace() ->
erlang:nif_error(undefined).
%% group_leader/0
-spec group_leader() -> pid().
group_leader() ->
erlang:nif_error(undefined).
%% group_leader/2
-spec group_leader(GroupLeader, Pid) -> true when
GroupLeader :: pid(),
Pid :: pid().
group_leader(_GroupLeader, _Pid) ->
erlang:nif_error(undefined).
%% halt/0
%% Shadowed by erl_bif_types: erlang:halt/0
-spec halt() -> no_return().
halt() ->
erlang:halt(0, []).
%% halt/1
%% Shadowed by erl_bif_types: erlang:halt/1
-spec halt(Status) -> no_return() when
Status :: non_neg_integer() | 'abort' | string().
halt(Status) ->
erlang:halt(Status, []).
%% halt/2
%% Shadowed by erl_bif_types: erlang:halt/2
-spec halt(Status, Options) -> no_return() when
Status :: non_neg_integer() | 'abort' | string(),
Options :: [Option],
Option :: {flush, boolean()}.
halt(_Status, _Options) ->
erlang:nif_error(undefined).
%% has_prepared_code_on_load/1
-spec erlang:has_prepared_code_on_load(PreparedCode) -> boolean() when
PreparedCode :: prepared_code().
has_prepared_code_on_load(_PreparedCode) ->
erlang:nif_error(undefined).
%% hibernate/3
-spec erlang:hibernate(Module, Function, Args) -> no_return() when
Module :: module(),
Function :: atom(),
Args :: [term()].
hibernate(_Module, _Function, _Args) ->
erlang:nif_error(undefined).
%% insert_element/3
-spec erlang:insert_element(Index, Tuple1, Term) -> Tuple2 when
Index :: pos_integer(),
Tuple1 :: tuple(),
Tuple2 :: tuple(),
Term :: term().
insert_element(_Index, _Tuple1, _Term) ->
erlang:nif_error(undefined).
%% integer_to_binary/1
-spec integer_to_binary(Integer) -> binary() when
Integer :: integer().
integer_to_binary(_Integer) ->
erlang:nif_error(undefined).
%% integer_to_list/1
-spec integer_to_list(Integer) -> string() when
Integer :: integer().
integer_to_list(_Integer) ->
erlang:nif_error(undefined).
%% iolist_size/1
-spec iolist_size(Item) -> non_neg_integer() when
Item :: iolist() | binary().
iolist_size(_Item) ->
erlang:nif_error(undefined).
%% iolist_to_binary/1
-spec iolist_to_binary(IoListOrBinary) -> binary() when
IoListOrBinary :: iolist() | binary().
iolist_to_binary(_IoListOrBinary) ->
erlang:nif_error(undefined).
%% is_alive/0
-spec is_alive() -> boolean().
is_alive() ->
erlang:nif_error(undefined).
%% is_builtin/3
-spec erlang:is_builtin(Module, Function, Arity) -> boolean() when
Module :: module(),
Function :: atom(),
Arity :: arity().
is_builtin(_Module, _Function, _Arity) ->
erlang:nif_error(undefined).
%% is_process_alive/1
-spec is_process_alive(Pid) -> boolean() when
Pid :: pid().
is_process_alive(_Pid) ->
erlang:nif_error(undefined).
%% length/1
%% Shadowed by erl_bif_types: erlang:length/1
-spec length(List) -> non_neg_integer() when
List :: [term()].
length(_List) ->
erlang:nif_error(undefined).
%% link/1
-spec link(PidOrPort) -> true when
PidOrPort :: pid() | port().
link(_PidOrPort) ->
erlang:nif_error(undefined).
%% list_to_atom/1
-spec list_to_atom(String) -> atom() when
String :: string().
list_to_atom(_String) ->
erlang:nif_error(undefined).
%% list_to_binary/1
-spec list_to_binary(IoList) -> binary() when
IoList :: iolist().
list_to_binary(_IoList) ->
erlang:nif_error(undefined).
%% list_to_bitstring/1
-spec list_to_bitstring(BitstringList) -> bitstring() when
BitstringList :: bitstring_list().
list_to_bitstring(_BitstringList) ->
erlang:nif_error(undefined).
%% list_to_existing_atom/1
-spec list_to_existing_atom(String) -> atom() when
String :: string().
list_to_existing_atom(_String) ->
erlang:nif_error(undefined).
%% list_to_float/1
-spec list_to_float(String) -> float() when
String :: string().
list_to_float(_String) ->
erlang:nif_error(undefined).
%% list_to_integer/1
-spec list_to_integer(String) -> integer() when
String :: string().
list_to_integer(_String) ->
erlang:nif_error(undefined).
%% list_to_integer/2
-spec list_to_integer(String, Base) -> integer() when
String :: string(),
Base :: 2..36.
list_to_integer(_String,_Base) ->
erlang:nif_error(undefined).
%% list_to_pid/1
-spec list_to_pid(String) -> pid() when
String :: string().
list_to_pid(_String) ->
erlang:nif_error(undefined).
%% list_to_ref/1
-spec list_to_ref(String) -> reference() when
String :: string().
list_to_ref(_String) ->
erlang:nif_error(undefined).
%% list_to_tuple/1
-spec list_to_tuple(List) -> tuple() when
List :: [term()].
list_to_tuple(_List) ->
erlang:nif_error(undefined).
%% loaded/0
-spec erlang:loaded() -> [Module] when
Module :: module().
loaded() ->
erlang:nif_error(undefined).
%% localtime/0
-spec erlang:localtime() -> DateTime when
DateTime :: calendar:datetime().
localtime() ->
erlang:nif_error(undefined).
%% make_ref/0
-spec make_ref() -> reference().
make_ref() ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:map_size/1
-spec map_size(Map) -> non_neg_integer() when
Map :: map().
map_size(_Map) ->
erlang:nif_error(undefined).
%% match_spec_test/3
-spec erlang:match_spec_test(MatchAgainst, MatchSpec, Type) -> TestResult when
MatchAgainst :: [term()] | tuple(),
MatchSpec :: term(),
Type :: table | trace,
TestResult :: {ok, term(), [return_trace], [ {error | warning, string()} ]} | {error, [ {error | warning, string()} ]}.
match_spec_test(_P1, _P2, _P3) ->
erlang:nif_error(undefined).
%% md5/1
-spec erlang:md5(Data) -> Digest when
Data :: iodata(),
Digest :: binary().
md5(_Data) ->
erlang:nif_error(undefined).
%% md5_final/1
-spec erlang:md5_final(Context) -> Digest when
Context :: binary(),
Digest :: binary().
md5_final(_Context) ->
erlang:nif_error(undefined).
%% md5_init/0
-spec erlang:md5_init() -> Context when
Context :: binary().
md5_init() ->
erlang:nif_error(undefined).
%% md5_update/2
-spec erlang:md5_update(Context, Data) -> NewContext when
Context :: binary(),
Data :: iodata(),
NewContext :: binary().
md5_update(_Context, _Data) ->
erlang:nif_error(undefined).
%% module_loaded/1
-spec module_loaded(Module) -> boolean() when
Module :: module().
module_loaded(_Module) ->
erlang:nif_error(undefined).
-type registered_name() :: atom().
-type registered_process_identifier() :: registered_name() | {registered_name(), node()}.
-type monitor_process_identifier() :: pid() | registered_process_identifier().
-type monitor_port_identifier() :: port() | registered_name().
%% monitor/2
-spec monitor
(process, monitor_process_identifier()) -> MonitorRef
when MonitorRef :: reference();
(port, monitor_port_identifier()) -> MonitorRef
when MonitorRef :: reference();
(time_offset, clock_service) -> MonitorRef
when MonitorRef :: reference().
monitor(_Type, _Item) ->
erlang:nif_error(undefined).
%% monitor_node/2
-spec monitor_node(Node, Flag) -> true when
Node :: node(),
Flag :: boolean().
monitor_node(_Node, _Flag) ->
erlang:nif_error(undefined).
%% monitor_node/3
-spec erlang:monitor_node(Node, Flag, Options) -> true when
Node :: node(),
Flag :: boolean(),
Options :: [Option],
Option :: allow_passive_connect.
monitor_node(_Node, _Flag, _Options) ->
erlang:nif_error(undefined).
%% nif_error/1
%% Shadowed by erl_bif_types: erlang:nif_error/1
-spec erlang:nif_error(Reason) -> no_return() when
Reason :: term().
nif_error(_Reason) ->
erlang:nif_error(undefined).
%% nif_error/2
%% Shadowed by erl_bif_types: erlang:nif_error/2
-spec erlang:nif_error(Reason, Args) -> no_return() when
Reason :: term(),
Args :: [term()].
nif_error(_Reason, _Args) ->
erlang:nif_error(undefined).
%% node/0
%% Shadowed by erl_bif_types: erlang:node/0
-spec node() -> Node when
Node :: node().
node() ->
erlang:nif_error(undefined).
%% node/1
%% Shadowed by erl_bif_types: erlang:node/1
-spec node(Arg) -> Node when
Arg :: pid() | port() | reference(),
Node :: node().
node(_Arg) ->
erlang:nif_error(undefined).
%% now/0
-spec now() -> Timestamp when
Timestamp :: timestamp().
now() ->
erlang:nif_error(undefined).
%% phash/2
-spec erlang:phash(Term, Range) -> Hash when
Term :: term(),
Range :: pos_integer(),
Hash :: pos_integer().
phash(_Term, _Range) ->
erlang:nif_error(undefined).
%% phash2/1
-spec erlang:phash2(Term) -> Hash when
Term :: term(),
Hash :: non_neg_integer().
phash2(_Term) ->
erlang:nif_error(undefined).
%% phash2/2
-spec erlang:phash2(Term, Range) -> Hash when
Term :: term(),
Range :: pos_integer(),
Hash :: non_neg_integer().
phash2(_Term, _Range) ->
erlang:nif_error(undefined).
%% pid_to_list/1
-spec pid_to_list(Pid) -> string() when
Pid :: pid().
pid_to_list(_Pid) ->
erlang:nif_error(undefined).
%% port_to_list/1
-spec port_to_list(Port) -> string() when
Port :: port().
port_to_list(_Port) ->
erlang:nif_error(undefined).
%% ports/0
-spec erlang:ports() -> [port()].
ports() ->
erlang:nif_error(undefined).
%% posixtime_to_universaltime/1
-spec erlang:posixtime_to_universaltime(P1) -> {calendar:date(), calendar:time()} when
P1 :: integer().
posixtime_to_universaltime(_P1) ->
erlang:nif_error(undefined).
-spec erlang:unique_integer(ModifierList) -> integer() when
ModifierList :: [Modifier],
Modifier :: positive | monotonic.
unique_integer(_ModifierList) ->
erlang:nif_error(undefined).
-spec erlang:unique_integer() -> integer().
unique_integer() ->
erlang:nif_error(undefined).
-spec erlang:monotonic_time() -> integer().
monotonic_time() ->
erlang:nif_error(undefined).
-spec erlang:monotonic_time(Unit) -> integer() when
Unit :: time_unit().
monotonic_time(_Unit) ->
erlang:nif_error(undefined).
-spec erlang:system_time() -> integer().
system_time() ->
erlang:nif_error(undefined).
-spec erlang:system_time(Unit) -> integer() when
Unit :: time_unit().
system_time(_Unit) ->
erlang:nif_error(undefined).
-spec erlang:convert_time_unit(Time, FromUnit, ToUnit) -> ConvertedTime when
Time :: integer(),
ConvertedTime :: integer(),
FromUnit :: time_unit(),
ToUnit :: time_unit().
convert_time_unit(Time, FromUnit, ToUnit) ->
try
FU = case FromUnit of
native -> erts_internal:time_unit();
perf_counter -> erts_internal:perf_counter_unit();
nanosecond -> 1000*1000*1000;
microsecond -> 1000*1000;
millisecond -> 1000;
second -> 1;
%% Deprecated symbolic units...
nano_seconds -> 1000*1000*1000;
micro_seconds -> 1000*1000;
milli_seconds -> 1000;
seconds -> 1;
_ when FromUnit > 0 -> FromUnit
end,
TU = case ToUnit of
native -> erts_internal:time_unit();
perf_counter -> erts_internal:perf_counter_unit();
nanosecond -> 1000*1000*1000;
microsecond -> 1000*1000;
millisecond -> 1000;
second -> 1;
%% Deprecated symbolic units...
nano_seconds -> 1000*1000*1000;
micro_seconds -> 1000*1000;
milli_seconds -> 1000;
seconds -> 1;
_ when ToUnit > 0 -> ToUnit
end,
case Time < 0 of
true -> TU*Time - (FU - 1);
false -> TU*Time
end div FU
catch
_ : _ ->
erlang:error(badarg, [Time, FromUnit, ToUnit])
end.
-spec erlang:time_offset() -> integer().
time_offset() ->
erlang:nif_error(undefined).
-spec erlang:time_offset(Unit) -> integer() when
Unit :: time_unit().
time_offset(_Unit) ->
erlang:nif_error(undefined).
-spec erlang:timestamp() -> Timestamp when
Timestamp :: timestamp().
timestamp() ->
erlang:nif_error(undefined).
%% prepare_loading/2
-spec erlang:prepare_loading(Module, Code) -> PreparedCode | {error, Reason} when
Module :: module(),
Code :: binary(),
PreparedCode :: prepared_code(),
Reason :: bad_file.
prepare_loading(_Module, _Code) ->
erlang:nif_error(undefined).
%% pre_loaded/0
-spec pre_loaded() -> [module()].
pre_loaded() ->
erlang:nif_error(undefined).
%% process_display/2
-spec erlang:process_display(Pid, Type) -> true when
Pid :: pid(),
Type :: backtrace.
process_display(_Pid, _Type) ->
erlang:nif_error(undefined).
%% process_flag/3
-spec process_flag(Pid, Flag, Value) -> OldValue when
Pid :: pid(),
Flag :: save_calls,
Value :: non_neg_integer(),
OldValue :: non_neg_integer().
process_flag(_Pid, _Flag, _Value) ->
erlang:nif_error(undefined).
%% process_info/1
-spec process_info(Pid) -> Info when
Pid :: pid(),
Info :: [InfoTuple] | undefined,
InfoTuple :: process_info_result_item().
process_info(_Pid) ->
erlang:nif_error(undefined).
%% processes/0
-spec processes() -> [pid()].
processes() ->
erlang:nif_error(undefined).
%% purge_module/1
-spec purge_module(Module) -> true when
Module :: atom().
purge_module(Module) when erlang:is_atom(Module) ->
case erts_code_purger:purge(Module) of
{false, _} ->
erlang:error(badarg, [Module]);
{true, _} ->
true
end;
purge_module(Arg) ->
erlang:error(badarg, [Arg]).
%% put/2
-spec put(Key, Val) -> term() when
Key :: term(),
Val :: term().
put(_Key, _Val) ->
erlang:nif_error(undefined).
%% raise/3
-spec erlang:raise(Class, Reason, Stacktrace) -> no_return() when
Class :: error | exit | throw,
Reason :: term(),
Stacktrace :: raise_stacktrace().
raise(_Class, _Reason, _Stacktrace) ->
erlang:nif_error(undefined).
%% read_timer/1
-spec erlang:read_timer(TimerRef) -> Result when
TimerRef :: reference(),
Time :: non_neg_integer(),
Result :: Time | false.
read_timer(_TimerRef) ->
erlang:nif_error(undefined).
%% read_timer/2
-spec erlang:read_timer(TimerRef, Options) -> Result | ok when
TimerRef :: reference(),
Async :: boolean(),
Option :: {async, Async},
Options :: [Option],
Time :: non_neg_integer(),
Result :: Time | false.
read_timer(_TimerRef, _Options) ->
erlang:nif_error(undefined).
%% ref_to_list/1
-spec ref_to_list(Ref) -> string() when
Ref :: reference().
ref_to_list(_Ref) ->
erlang:nif_error(undefined).
%% register/2
-spec register(RegName, PidOrPort) -> true when
RegName :: atom(),
PidOrPort :: port() | pid().
register(_RegName, _PidOrPort) ->
erlang:nif_error(undefined).
%% registered/0
-spec registered() -> [RegName] when
RegName :: atom().
registered() ->
erlang:nif_error(undefined).
%% resume_process/1
-spec erlang:resume_process(Suspendee) -> true when
Suspendee :: pid().
resume_process(_Suspendee) ->
erlang:nif_error(undefined).
%% round/1
%% Shadowed by erl_bif_types: erlang:round/1
-spec round(Number) -> integer() when
Number :: number().
round(_Number) ->
erlang:nif_error(undefined).
%% self/0
%% Shadowed by erl_bif_types: erlang:self/0
-spec self() -> pid().
self() ->
erlang:nif_error(undefined).
%% send_after/3
-spec erlang:send_after(Time, Dest, Msg) -> TimerRef when
Time :: non_neg_integer(),
Dest :: pid() | atom(),
Msg :: term(),
TimerRef :: reference().
send_after(_Time, _Dest, _Msg) ->
erlang:nif_error(undefined).
%% send_after/4
-spec erlang:send_after(Time, Dest, Msg, Options) -> TimerRef when
Time :: integer(),
Dest :: pid() | atom(),
Msg :: term(),
Options :: [Option],
Abs :: boolean(),
Option :: {abs, Abs},
TimerRef :: reference().
send_after(_Time, _Dest, _Msg, _Options) ->
erlang:nif_error(undefined).
%% seq_trace/2
-spec erlang:seq_trace(P1, P2) -> seq_trace_info_returns() | {term(), term(), term(), term(), term()} when
P1 :: atom(),
P2 :: boolean() | {integer(), integer()} | integer() | [].
seq_trace(_P1, _P2) ->
erlang:nif_error(undefined).
%% seq_trace_print/1
-spec erlang:seq_trace_print(P1) -> boolean() when
P1 :: term().
seq_trace_print(_P1) ->
erlang:nif_error(undefined).
%% seq_trace_print/2
-spec erlang:seq_trace_print(P1, P2) -> boolean() when
P1 :: atom() | integer(),
P2 :: term().
seq_trace_print(_P1, _P2) ->
erlang:nif_error(undefined).
%% setnode/2
-spec erlang:setnode(P1, P2) -> true when
P1 :: atom(),
P2 :: integer().
setnode(_P1, _P2) ->
erlang:nif_error(undefined).
%% setnode/3
-spec erlang:setnode(P1, P2, P3) -> true when
P1 :: atom(),
P2 :: port(),
P3 :: {term(), term(), term(), term()}.
setnode(_P1, _P2, _P3) ->
erlang:nif_error(undefined).
%% size/1
%% Shadowed by erl_bif_types: erlang:size/1
-spec size(Item) -> non_neg_integer() when
Item :: tuple() | binary().
size(_Item) ->
erlang:nif_error(undefined).
%% spawn/3
-spec spawn(Module, Function, Args) -> pid() when
Module :: module(),
Function :: atom(),
Args :: [term()].
spawn(_Module, _Function, _Args) ->
erlang:nif_error(undefined).
%% spawn_link/3
-spec spawn_link(Module, Function, Args) -> pid() when
Module :: module(),
Function :: atom(),
Args :: [term()].
spawn_link(_Module, _Function, _Args) ->
erlang:nif_error(undefined).
%% split_binary/2
-spec split_binary(Bin, Pos) -> {binary(), binary()} when
Bin :: binary(),
Pos :: non_neg_integer().
split_binary(_Bin, _Pos) ->
erlang:nif_error(undefined).
%% start_timer/3
-spec erlang:start_timer(Time, Dest, Msg) -> TimerRef when
Time :: non_neg_integer(),
Dest :: pid() | atom(),
Msg :: term(),
TimerRef :: reference().
start_timer(_Time, _Dest, _Msg) ->
erlang:nif_error(undefined).
%% start_timer/4
-spec erlang:start_timer(Time, Dest, Msg, Options) -> TimerRef when
Time :: integer(),
Dest :: pid() | atom(),
Msg :: term(),
Options :: [Option],
Abs :: boolean(),
Option :: {abs, Abs},
TimerRef :: reference().
start_timer(_Time, _Dest, _Msg, _Options) ->
erlang:nif_error(undefined).
%% suspend_process/2
-spec erlang:suspend_process(Suspendee, OptList) -> boolean() when
Suspendee :: pid(),
OptList :: [Opt],
Opt :: unless_suspending | asynchronous.
suspend_process(_Suspendee, _OptList) ->
erlang:nif_error(undefined).
%% system_monitor/0
-spec erlang:system_monitor() -> MonSettings when
MonSettings :: undefined | { MonitorPid, Options },
MonitorPid :: pid(),
Options :: [ system_monitor_option() ].
system_monitor() ->
erlang:nif_error(undefined).
%% system_monitor/1
-spec erlang:system_monitor(Arg) -> MonSettings when
Arg :: undefined | { MonitorPid, Options },
MonSettings :: undefined | { MonitorPid, Options },
MonitorPid :: pid(),
Options :: [ system_monitor_option() ].
system_monitor(_Arg) ->
erlang:nif_error(undefined).
%% system_monitor/2
-spec erlang:system_monitor(MonitorPid, Options) -> MonSettings when
MonitorPid :: pid(),
Options :: [ system_monitor_option() ],
MonSettings :: undefined | { OldMonitorPid, OldOptions },
OldMonitorPid :: pid(),
OldOptions :: [ system_monitor_option() ].
system_monitor(_MonitorPid, _Options) ->
erlang:nif_error(undefined).
%% system_profile/0
-spec erlang:system_profile() -> ProfilerSettings when
ProfilerSettings :: undefined | { ProfilerPid, Options},
ProfilerPid :: pid() | port(),
Options :: [ system_profile_option() ].
system_profile() ->
erlang:nif_error(undefined).
%% system_profile/2
-spec erlang:system_profile(ProfilerPid, Options) -> ProfilerSettings when
ProfilerPid :: pid() | port() | undefined,
Options :: [ system_profile_option() ],
ProfilerSettings :: undefined | { pid() | port(), [ system_profile_option() ]}.
system_profile(_ProfilerPid, _Options) ->
erlang:nif_error(undefined).
%% throw/1
%% Shadowed by erl_bif_types: erlang:throw/1
-spec throw(Any) -> no_return() when
Any :: term().
throw(_Any) ->
erlang:nif_error(undefined).
%% time/0
-spec time() -> Time when
Time :: calendar:time().
time() ->
erlang:nif_error(undefined).
%% trace/3
-spec erlang:trace(PidPortSpec, How, FlagList) -> integer() when
PidPortSpec :: pid() | port()
| all | processes | ports
| existing | existing_processes | existing_ports
| new | new_processes | new_ports,
How :: boolean(),
FlagList :: [trace_flag()].
trace(PidPortSpec, How, FlagList) ->
%% Make sure that we have loaded the tracer module
case lists:keyfind(tracer, 1, FlagList) of
{tracer, Module, State} when erlang:is_atom(Module) ->
case erlang:module_loaded(Module) of
false ->
Module:enabled(trace_status, erlang:self(), State);
true ->
ok
end;
_ ->
ignore
end,
try erts_internal:trace(PidPortSpec, How, FlagList) of
Res -> Res
catch E:R ->
{_, [_ | CST]} = erlang:process_info(
erlang:self(), current_stacktrace),
erlang:raise(
E, R, [{?MODULE, trace, [PidPortSpec, How, FlagList], []} | CST])
end.
%% trace_delivered/1
-spec erlang:trace_delivered(Tracee) -> Ref when
Tracee :: pid() | all,
Ref :: reference().
trace_delivered(_Tracee) ->
erlang:nif_error(undefined).
%% trace_info/2
-spec erlang:trace_info(PidPortFuncEvent, Item) -> Res when
PidPortFuncEvent :: pid() | port() | new | new_processes | new_ports
| {Module, Function, Arity} | on_load | send | 'receive',
Module :: module(),
Function :: atom(),
Arity :: arity(),
Item :: flags | tracer | traced | match_spec
| meta | meta_match_spec | call_count | call_time | all,
Res :: trace_info_return().
trace_info(_PidPortFuncEvent, _Item) ->
erlang:nif_error(undefined).
%% trunc/1
%% Shadowed by erl_bif_types: erlang:trunc/1
-spec trunc(Number) -> integer() when
Number :: number().
trunc(_Number) ->
erlang:nif_error(undefined).
%% tuple_size/1
%% Shadowed by erl_bif_types: erlang:tuple_size/1
-spec tuple_size(Tuple) -> non_neg_integer() when
Tuple :: tuple().
tuple_size(_Tuple) ->
erlang:nif_error(undefined).
%% universaltime/0
-spec erlang:universaltime() -> DateTime when
DateTime :: calendar:datetime().
universaltime() ->
erlang:nif_error(undefined).
%% universaltime_to_posixtime/1
-spec erlang:universaltime_to_posixtime(P1) -> integer() when
P1 :: {calendar:date(), calendar:time()}.
universaltime_to_posixtime(_P1) ->
erlang:nif_error(undefined).
%% unlink/1
-spec unlink(Id) -> true when
Id :: pid() | port().
unlink(_Id) ->
erlang:nif_error(undefined).
%% unregister/1
-spec unregister(RegName) -> true when
RegName :: atom().
unregister(_RegName) ->
erlang:nif_error(undefined).
%% whereis/1
-spec whereis(RegName) -> pid() | port() | undefined when
RegName :: atom().
whereis(_RegName) ->
erlang:nif_error(undefined).
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%% More complicated native code BIFs
%%% These are here for the types/specs, the real implementation is in the C code.
%%% This chunk is handwritten, i.e. contains more complicated specs.
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% types and specs
%% Shadowed by erl_bif_types: erlang:abs/1
-spec abs(Float) -> float() when
Float :: float();
(Int) -> non_neg_integer() when
Int :: integer().
abs(_Number) ->
erlang:nif_error(undefined).
%% Not documented
%% Shadowed by erl_bif_types: erlang:append/2
-spec erlang:append(List,Tail) -> maybe_improper_list() when
List :: [term()],
Tail :: term().
append(_List,_Tail) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:element/2
-spec element(N, Tuple) -> term() when
N :: pos_integer(),
Tuple :: tuple().
element(_N, _Tuple) ->
erlang:nif_error(undefined).
%% Not documented
-type module_info_key() :: attributes | compile | exports | functions | md5
| module | native | native_addresses.
-spec erlang:get_module_info(Module, Item) -> ModuleInfo when
Module :: atom(),
Item :: module_info_key(),
ModuleInfo :: term().
get_module_info(_Module, _Item) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:hd/1
-spec hd(List) -> term() when
List :: [term(), ...].
hd(_List) ->
erlang:nif_error(undefined).
%% erlang:info/1 no longer exists!
%% Shadowed by erl_bif_types: erlang:is_atom/1
-spec is_atom(Term) -> boolean() when
Term :: term().
is_atom(_Term) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:is_binary/1
-spec is_binary(Term) -> boolean() when
Term :: term().
is_binary(_Term) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:is_bitstring/1
-spec is_bitstring(Term) -> boolean() when
Term :: term().
is_bitstring(_Term) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:is_boolean/1
-spec is_boolean(Term) -> boolean() when
Term :: term().
is_boolean(_Term) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:is_float/1
-spec is_float(Term) -> boolean() when
Term :: term().
is_float(_Term) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:is_function/1
-spec is_function(Term) -> boolean() when
Term :: term().
is_function(_Term) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:is_function/2
-spec is_function(Term, Arity) -> boolean() when
Term :: term(),
Arity :: arity().
is_function(_Term, _Arity) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:is_integer/1
-spec is_integer(Term) -> boolean() when
Term :: term().
is_integer(_Term) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:is_list/1
-spec is_list(Term) -> boolean() when
Term :: term().
is_list(_Term) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:is_number/1
-spec is_number(Term) -> boolean() when
Term :: term().
is_number(_Term) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:is_pid/1
-spec is_pid(Term) -> boolean() when
Term :: term().
is_pid(_Term) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:is_map/1
-spec is_map(Term) -> boolean() when
Term :: term().
is_map(_Term) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:is_port/1
-spec is_port(Term) -> boolean() when
Term :: term().
is_port(_Term) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:is_record/2
-spec is_record(Term,RecordTag) -> boolean() when
Term :: term(),
RecordTag :: atom().
is_record(_Term,_RecordTag) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:is_record/3
-spec is_record(Term,RecordTag,Size) -> boolean() when
Term :: term(),
RecordTag :: atom(),
Size :: non_neg_integer().
is_record(_Term,_RecordTag,_Size) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:is_reference/1
-spec is_reference(Term) -> boolean() when
Term :: term().
is_reference(_Term) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:is_tuple/1
-spec is_tuple(Term) -> boolean() when
Term :: term().
is_tuple(_Term) ->
erlang:nif_error(undefined).
-spec load_module(Module, Binary) -> {module, Module} | {error, Reason} when
Module :: module(),
Binary :: binary(),
Reason :: badfile | not_purged | on_load.
load_module(Mod, Code) ->
case erlang:prepare_loading(Mod, Code) of
{error,_}=Error ->
Error;
Prep when erlang:is_reference(Prep) ->
case erlang:finish_loading([Prep]) of
ok ->
{module,Mod};
{Error,[Mod]} ->
{error,Error}
end
end.
-spec erlang:load_nif(Path, LoadInfo) -> ok | Error when
Path :: string(),
LoadInfo :: term(),
Error :: {error, {Reason, Text :: string()}},
Reason :: load_failed | bad_lib | load | reload | upgrade | old_code.
load_nif(_Path, _LoadInfo) ->
erlang:nif_error(undefined).
-spec erlang:localtime_to_universaltime(Localtime, IsDst) -> Universaltime when
Localtime :: calendar:datetime(),
Universaltime :: calendar:datetime(),
IsDst :: true | false | undefined.
localtime_to_universaltime(_Localtime, _IsDst) ->
erlang:nif_error(undefined).
%% CHECK! Why the strange very thorough specification of the error
%% condition with disallowed arity in erl_bif_types?
%% Not documented
%% Shadowed by erl_bif_types: erlang:make_fun/3
-spec erlang:make_fun(Module, Function, Arity) -> function() when
Module :: atom(),
Function :: atom(),
Arity :: arity().
make_fun(_Module,_Function, _Arity) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:make_tuple/2
-spec erlang:make_tuple(Arity, InitialValue) -> tuple() when
Arity :: arity(),
InitialValue :: term().
make_tuple(_Arity,_InitialValue) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:make_tuple/3
-spec erlang:make_tuple(Arity, DefaultValue, InitList) -> tuple() when
Arity :: arity(),
DefaultValue :: term(),
InitList :: [{Position :: pos_integer(), term()}].
make_tuple(_Arity,_DefaultValue,_InitList) ->
erlang:nif_error(undefined).
-spec nodes(Arg) -> Nodes when
Arg :: NodeType | [NodeType],
NodeType :: visible | hidden | connected | this | known,
Nodes :: [node()].
nodes(_Arg) ->
erlang:nif_error(undefined).
-spec open_port(PortName, PortSettings) -> port() when
PortName :: {spawn, Command :: string() | binary()} |
{spawn_driver, Command :: string() | binary()} |
{spawn_executable, FileName :: file:name() } |
{fd, In :: non_neg_integer(), Out :: non_neg_integer()},
PortSettings :: [Opt],
Opt :: {packet, N :: 1 | 2 | 4}
| stream
| {line, L :: non_neg_integer()}
| {cd, Dir :: string() | binary()}
| {env, Env :: [{Name :: string(), Val :: string() | false}]}
| {args, [string() | binary()]}
| {arg0, string() | binary()}
| exit_status
| use_stdio
| nouse_stdio
| stderr_to_stdout
| in
| out
| binary
| eof
| {parallelism, Boolean :: boolean()}
| hide.
open_port(PortName, PortSettings) ->
case case erts_internal:open_port(PortName, PortSettings) of
Ref when erlang:is_reference(Ref) -> receive {Ref, Res} -> Res end;
Res -> Res
end of
Port when erlang:is_port(Port) -> Port;
Error -> erlang:error(Error, [PortName, PortSettings])
end.
-type priority_level() ::
low | normal | high | max.
-type message_queue_data() ::
off_heap | on_heap.
-spec process_flag(trap_exit, Boolean) -> OldBoolean when
Boolean :: boolean(),
OldBoolean :: boolean();
(error_handler, Module) -> OldModule when
Module :: atom(),
OldModule :: atom();
(min_heap_size, MinHeapSize) -> OldMinHeapSize when
MinHeapSize :: non_neg_integer(),
OldMinHeapSize :: non_neg_integer();
(min_bin_vheap_size, MinBinVHeapSize) -> OldMinBinVHeapSize when
MinBinVHeapSize :: non_neg_integer(),
OldMinBinVHeapSize :: non_neg_integer();
(max_heap_size, MaxHeapSize) -> OldMaxHeapSize when
MaxHeapSize :: max_heap_size(),
OldMaxHeapSize :: max_heap_size();
(message_queue_data, MQD) -> OldMQD when
MQD :: message_queue_data(),
OldMQD :: message_queue_data();
(priority, Level) -> OldLevel when
Level :: priority_level(),
OldLevel :: priority_level();
(save_calls, N) -> OldN when
N :: 0..10000,
OldN :: 0..10000;
(sensitive, Boolean) -> OldBoolean when
Boolean :: boolean(),
OldBoolean :: boolean();
%% Deliberately not documented.
({monitor_nodes, term()}, term()) -> term();
(monitor_nodes, term()) -> term().
process_flag(_Flag, _Value) ->
erlang:nif_error(undefined).
-type process_info_item() ::
backtrace |
binary |
catchlevel |
current_function |
current_location |
current_stacktrace |
dictionary |
error_handler |
garbage_collection |
garbage_collection_info |
group_leader |
heap_size |
initial_call |
links |
last_calls |
memory |
message_queue_len |
messages |
min_heap_size |
min_bin_vheap_size |
monitored_by |
monitors |
message_queue_data |
priority |
reductions |
registered_name |
sequential_trace_token |
stack_size |
status |
suspending |
total_heap_size |
trace |
trap_exit.
-type process_info_result_item() ::
{backtrace, Bin :: binary()} |
{binary, BinInfo :: [{non_neg_integer(),
non_neg_integer(),
non_neg_integer()}]} |
{catchlevel, CatchLevel :: non_neg_integer()} |
{current_function,
{Module :: module(), Function :: atom(), Arity :: arity()}} |
{current_location,
{Module :: module(), Function :: atom(), Arity :: arity(),
Location :: [{file, Filename :: string()} | % not a stack_item()!
{line, Line :: pos_integer()}]}} |
{current_stacktrace, Stack :: [stack_item()]} |
{dictionary, Dictionary :: [{Key :: term(), Value :: term()}]} |
{error_handler, Module :: module()} |
{garbage_collection, GCInfo :: [{atom(),non_neg_integer()}]} |
{garbage_collection_info, GCInfo :: [{atom(),non_neg_integer()}]} |
{group_leader, GroupLeader :: pid()} |
{heap_size, Size :: non_neg_integer()} |
{initial_call, mfa()} |
{links, PidsAndPorts :: [pid() | port()]} |
{last_calls, false | (Calls :: [mfa()])} |
{memory, Size :: non_neg_integer()} |
{message_queue_len, MessageQueueLen :: non_neg_integer()} |
{messages, MessageQueue :: [term()]} |
{min_heap_size, MinHeapSize :: non_neg_integer()} |
{min_bin_vheap_size, MinBinVHeapSize :: non_neg_integer()} |
{max_heap_size, MaxHeapSize :: max_heap_size()} |
{monitored_by, Pids :: [pid()]} |
{monitors,
Monitors :: [{process | port, Pid :: pid() | port() |
{RegName :: atom(), Node :: node()}}]} |
{message_queue_data, MQD :: message_queue_data()} |
{priority, Level :: priority_level()} |
{reductions, Number :: non_neg_integer()} |
{registered_name, [] | (Atom :: atom())} |
{sequential_trace_token, [] | (SequentialTraceToken :: term())} |
{stack_size, Size :: non_neg_integer()} |
{status, Status :: exiting | garbage_collecting | waiting | running | runnable | suspended} |
{suspending,
SuspendeeList :: [{Suspendee :: pid(),
ActiveSuspendCount :: non_neg_integer(),
OutstandingSuspendCount ::non_neg_integer()}]} |
{total_heap_size, Size :: non_neg_integer()} |
{trace, InternalTraceFlags :: non_neg_integer()} |
{trap_exit, Boolean :: boolean()}.
-type stack_item() ::
{Module :: module(),
Function :: atom(),
Arity :: arity() | (Args :: [term()]),
Location :: [{file, Filename :: string()} |
{line, Line :: pos_integer()}]}.
-spec process_info(Pid, Item) ->
InfoTuple | [] | undefined when
Pid :: pid(),
Item :: process_info_item(),
InfoTuple :: process_info_result_item();
(Pid, ItemList) -> InfoTupleList | [] | undefined when
Pid :: pid(),
ItemList :: [Item],
Item :: process_info_item(),
InfoTupleList :: [InfoTuple],
InfoTuple :: process_info_result_item().
process_info(_Pid,_ItemSpec) ->
erlang:nif_error(undefined).
-spec erlang:send(Dest, Msg) -> Msg when
Dest :: dst(),
Msg :: term().
send(_Dest,_Msg) ->
erlang:nif_error(undefined).
-spec erlang:send(Dest, Msg, Options) -> Res when
Dest :: dst(),
Msg :: term(),
Options :: [nosuspend | noconnect],
Res :: ok | nosuspend | noconnect.
send(_Dest,_Msg,_Options) ->
erlang:nif_error(undefined).
%% Not documented
-spec erlang:seq_trace_info(send) -> {send, boolean()};
('receive') -> {'receive', boolean()};
(print) -> {print, boolean()};
(timestamp) -> {timestamp, boolean()};
(monotonic_timestamp) -> {timestamp, boolean()};
(strict_monotonic_timestamp) -> {strict_monotonic_timestamp, boolean()};
(label) -> [] | {label, non_neg_integer()};
(serial) -> [] | {serial, {non_neg_integer(), non_neg_integer()}}.
seq_trace_info(_What) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:setelement/3
-spec setelement(Index, Tuple1, Value) -> Tuple2 when
Index :: pos_integer(),
Tuple1 :: tuple(),
Tuple2 :: tuple(),
Value :: term().
setelement(_Index, _Tuple1, _Value) ->
erlang:nif_error(undefined).
-spec erlang:spawn_opt({Module, Function, Args, Options}) -> pid() | {pid(), reference()} when
Module :: module(),
Function :: atom(),
Args :: [term()],
Options :: [Option],
Option :: link | monitor
| {priority, Level :: priority_level()}
| {fullsweep_after, Number :: non_neg_integer()}
| {min_heap_size, Size :: non_neg_integer()}
| {max_heap_size, Size :: max_heap_size()}
| {min_bin_vheap_size, VSize :: non_neg_integer()}.
spawn_opt(_Tuple) ->
erlang:nif_error(undefined).
-spec statistics(active_tasks) -> [ActiveTasks] when
ActiveTasks :: non_neg_integer();
(context_switches) -> {ContextSwitches,0} when
ContextSwitches :: non_neg_integer();
(exact_reductions) -> {Total_Exact_Reductions,
Exact_Reductions_Since_Last_Call} when
Total_Exact_Reductions :: non_neg_integer(),
Exact_Reductions_Since_Last_Call :: non_neg_integer();
(garbage_collection) -> {Number_of_GCs, Words_Reclaimed, 0} when
Number_of_GCs :: non_neg_integer(),
Words_Reclaimed :: non_neg_integer();
(io) -> {{input, Input}, {output, Output}} when
Input :: non_neg_integer(),
Output :: non_neg_integer();
(microstate_accounting) -> [MSAcc_Thread] | undefined when
MSAcc_Thread :: #{ type := MSAcc_Thread_Type,
id := MSAcc_Thread_Id,
counters := MSAcc_Counters},
MSAcc_Thread_Type :: scheduler | async | aux,
MSAcc_Thread_Id :: non_neg_integer(),
MSAcc_Counters :: #{ MSAcc_Thread_State => non_neg_integer() },
MSAcc_Thread_State :: alloc | aux | bif | busy_wait | check_io |
emulator | ets | gc | gc_fullsweep | nif |
other | port | send | sleep | timers;
(reductions) -> {Total_Reductions,
Reductions_Since_Last_Call} when
Total_Reductions :: non_neg_integer(),
Reductions_Since_Last_Call :: non_neg_integer();
(run_queue) -> non_neg_integer();
(run_queue_lengths) -> [RunQueueLength] when
RunQueueLength :: non_neg_integer();
(runtime) -> {Total_Run_Time, Time_Since_Last_Call} when
Total_Run_Time :: non_neg_integer(),
Time_Since_Last_Call :: non_neg_integer();
(scheduler_wall_time) -> [{SchedulerId, ActiveTime, TotalTime}] | undefined when
SchedulerId :: pos_integer(),
ActiveTime :: non_neg_integer(),
TotalTime :: non_neg_integer();
(scheduler_wall_time_all) -> [{SchedulerId, ActiveTime, TotalTime}] | undefined when
SchedulerId :: pos_integer(),
ActiveTime :: non_neg_integer(),
TotalTime :: non_neg_integer();
(total_active_tasks) -> ActiveTasks when
ActiveTasks :: non_neg_integer();
(total_run_queue_lengths) -> TotalRunQueueLengths when
TotalRunQueueLengths :: non_neg_integer();
(wall_clock) -> {Total_Wallclock_Time,
Wallclock_Time_Since_Last_Call} when
Total_Wallclock_Time :: non_neg_integer(),
Wallclock_Time_Since_Last_Call :: non_neg_integer().
statistics(_Item) ->
erlang:nif_error(undefined).
%% Not documented
%% Shadowed by erl_bif_types: erlang:subtract/2
-spec erlang:subtract([term()], [term()]) -> [term()].
subtract(_,_) ->
erlang:nif_error(undefined).
-type scheduler_bind_type() ::
'no_node_processor_spread' |
'no_node_thread_spread' |
'no_spread' |
'processor_spread' |
'spread' |
'thread_spread' |
'thread_no_node_processor_spread' |
'unbound'.
-spec erlang:system_flag(backtrace_depth, Depth) -> OldDepth when
Depth :: non_neg_integer(),
OldDepth :: non_neg_integer();
(cpu_topology, CpuTopology) -> OldCpuTopology when
CpuTopology :: cpu_topology(),
OldCpuTopology :: cpu_topology();
(dirty_cpu_schedulers_online, DirtyCPUSchedulersOnline) ->
OldDirtyCPUSchedulersOnline when
DirtyCPUSchedulersOnline :: pos_integer(),
OldDirtyCPUSchedulersOnline :: pos_integer();
(fullsweep_after, Number) -> OldNumber when
Number :: non_neg_integer(),
OldNumber :: non_neg_integer();
(microstate_accounting, Action) -> OldState when
Action :: true | false | reset,
OldState :: true | false;
(min_heap_size, MinHeapSize) -> OldMinHeapSize when
MinHeapSize :: non_neg_integer(),
OldMinHeapSize :: non_neg_integer();
(min_bin_vheap_size, MinBinVHeapSize) ->
OldMinBinVHeapSize when
MinBinVHeapSize :: non_neg_integer(),
OldMinBinVHeapSize :: non_neg_integer();
(max_heap_size, MaxHeapSize) -> OldMaxHeapSize when
MaxHeapSize :: max_heap_size(),
OldMaxHeapSize :: max_heap_size();
(multi_scheduling, BlockState) -> OldBlockState when
BlockState :: block | unblock | block_normal | unblock_normal,
OldBlockState :: blocked | disabled | enabled;
(scheduler_bind_type, How) -> OldBindType when
How :: scheduler_bind_type() | default_bind,
OldBindType :: scheduler_bind_type();
(scheduler_wall_time, Boolean) -> OldBoolean when
Boolean :: boolean(),
OldBoolean :: boolean();
(schedulers_online, SchedulersOnline) ->
OldSchedulersOnline when
SchedulersOnline :: pos_integer(),
OldSchedulersOnline :: pos_integer();
(trace_control_word, TCW) -> OldTCW when
TCW :: non_neg_integer(),
OldTCW :: non_neg_integer();
(time_offset, finalize) -> OldState when
OldState :: preliminary | final | volatile;
%% These are deliberately not documented
(internal_cpu_topology, term()) -> term();
(sequential_tracer, pid() | port() | {module(), term()} | false) -> pid() | port() | false;
(1,0) -> true.
system_flag(_Flag, _Value) ->
erlang:nif_error(undefined).
-spec term_to_binary(Term) -> ext_binary() when
Term :: term().
term_to_binary(_Term) ->
erlang:nif_error(undefined).
-spec term_to_binary(Term, Options) -> ext_binary() when
Term :: term(),
Options :: [compressed |
{compressed, Level :: 0..9} |
{minor_version, Version :: 0..1} ].
term_to_binary(_Term, _Options) ->
erlang:nif_error(undefined).
%% Shadowed by erl_bif_types: erlang:tl/1
-spec tl(List) -> term() when
List :: [term(), ...].
tl(_List) ->
erlang:nif_error(undefined).
-type match_variable() :: atom(). % Approximation of '$1' | '$2' | ...
-type trace_pattern_mfa() ::
{atom(),atom(),arity() | '_'} | on_load.
-type trace_match_spec() ::
[{[term()] | '_' | match_variable() ,[term()],[term()]}].
-spec erlang:trace_pattern(MFA, MatchSpec) -> non_neg_integer() when
MFA :: trace_pattern_mfa() | send | 'receive',
MatchSpec :: (MatchSpecList :: trace_match_spec())
| boolean()
| restart
| pause.
trace_pattern(MFA, MatchSpec) ->
try erts_internal:trace_pattern(MFA, MatchSpec, []) of
Res -> Res
catch E:R ->
{_, [_ | CST]} = erlang:process_info(
erlang:self(), current_stacktrace),
erlang:raise(
E, R, [{?MODULE, trace_pattern, [MFA, MatchSpec], []} | CST])
end.
-type trace_pattern_flag() ::
global | local |
meta | {meta, Pid :: pid()} |
{meta, TracerModule :: module(), TracerState :: term()} |
call_count |
call_time.
-spec erlang:trace_pattern(send, MatchSpec, []) -> non_neg_integer() when
MatchSpec :: (MatchSpecList :: trace_match_spec())
| boolean();
('receive', MatchSpec, []) -> non_neg_integer() when
MatchSpec :: (MatchSpecList :: trace_match_spec())
| boolean();
(MFA, MatchSpec, FlagList) -> non_neg_integer() when
MFA :: trace_pattern_mfa(),
MatchSpec :: (MatchSpecList :: trace_match_spec())
| boolean()
| restart
| pause,
FlagList :: [ trace_pattern_flag() ].
trace_pattern(MFA, MatchSpec, FlagList) ->
%% Make sure that we have loaded the tracer module
case lists:keyfind(meta, 1, FlagList) of
{meta, Module, State} when erlang:is_atom(Module) ->
case erlang:module_loaded(Module) of
false ->
Module:enabled(trace_status, erlang:self(), State);
true ->
ok
end;
_ ->
ignore
end,
try erts_internal:trace_pattern(MFA, MatchSpec, FlagList) of
Res -> Res
catch E:R ->
{_, [_ | CST]} = erlang:process_info(
erlang:self(), current_stacktrace),
erlang:raise(
E, R, [{?MODULE, trace_pattern, [MFA, MatchSpec, FlagList], []} | CST])
end.
%% Shadowed by erl_bif_types: erlang:tuple_to_list/1
-spec tuple_to_list(Tuple) -> [term()] when
Tuple :: tuple().
tuple_to_list(_Tuple) ->
erlang:nif_error(undefined).
-type cpu_topology() ::
[LevelEntry :: level_entry()] | undefined.
-type level_entry() ::
{LevelTag :: level_tag(), SubLevel :: sub_level()}
| {LevelTag :: level_tag(),
InfoList :: info_list(),
SubLevel :: sub_level()}.
-type level_tag() :: core | node | processor | thread.
-type sub_level() :: [LevelEntry :: level_entry()]
| (LogicalCpuId :: {logical, non_neg_integer()}).
-type info_list() :: [].
%% Note: changing the ordering number of a clause will change the docs!
%% Shadowed by erl_bif_types: erlang:system_info/1
-spec erlang:system_info
(allocated_areas) -> [ tuple() ];
(allocator) ->
{Allocator, Version, Features, Settings} when
Allocator :: undefined | glibc,
Version :: [non_neg_integer()],
Features :: [atom()],
Settings :: [{Subsystem :: atom(),
[{Parameter :: atom(),
Value :: term()}]}];
(alloc_util_allocators) -> [Alloc] when
Alloc :: atom();
({allocator, Alloc}) -> [_] when %% More or less anything
Alloc :: atom();
({allocator_sizes, Alloc}) -> [_] when %% More or less anything
Alloc :: atom();
(atom_count) -> pos_integer();
(atom_limit) -> pos_integer();
(build_type) -> opt | debug | purify | quantify | purecov |
gcov | valgrind | gprof | lcnt | frmptr;
(c_compiler_used) -> {atom(), term()};
(check_io) -> [_];
(compat_rel) -> integer();
(cpu_topology) -> CpuTopology when
CpuTopology :: cpu_topology();
({cpu_topology, defined | detected | used}) -> CpuTopology when
CpuTopology :: cpu_topology();
(creation) -> integer();
(debug_compiled) -> boolean();
(delayed_node_table_gc) -> infinity | non_neg_integer();
(dirty_cpu_schedulers) -> non_neg_integer();
(dirty_cpu_schedulers_online) -> non_neg_integer();
(dirty_io_schedulers) -> non_neg_integer();
(dist) -> binary();
(dist_buf_busy_limit) -> non_neg_integer();
(dist_ctrl) -> {Node :: node(),
ControllingEntity :: port() | pid()};
(driver_version) -> string();
(dynamic_trace) -> none | dtrace | systemtap;
(dynamic_trace_probes) -> boolean();
(elib_malloc) -> false;
(eager_check_io) -> boolean();
(ets_limit) -> pos_integer();
(fullsweep_after) -> {fullsweep_after, non_neg_integer()};
(garbage_collection) -> [{atom(), integer()}];
(heap_sizes) -> [non_neg_integer()];
(heap_type) -> private;
(info) -> binary();
(kernel_poll) -> boolean();
(loaded) -> binary();
(logical_processors |
logical_processors_available |
logical_processors_online) -> unknown | pos_integer();
(machine) -> string();
(max_heap_size) -> {max_heap_size, MaxHeapSize :: max_heap_size()};
(message_queue_data) -> message_queue_data();
(min_heap_size) -> {min_heap_size, MinHeapSize :: pos_integer()};
(min_bin_vheap_size) -> {min_bin_vheap_size,
MinBinVHeapSize :: pos_integer()};
(modified_timing_level) -> integer() | undefined;
(multi_scheduling) -> disabled | blocked | blocked_normal | enabled;
(multi_scheduling_blockers) -> [Pid :: pid()];
(nif_version) -> string();
(normal_multi_scheduling_blockers) -> [Pid :: pid()];
(otp_release) -> string();
(os_monotonic_time_source) -> [{atom(),term()}];
(os_system_time_source) -> [{atom(),term()}];
(port_count) -> non_neg_integer();
(port_limit) -> pos_integer();
(process_count) -> pos_integer();
(process_limit) -> pos_integer();
(procs) -> binary();
(scheduler_bind_type) -> spread |
processor_spread |
thread_spread |
thread_no_node_processor_spread |
no_node_processor_spread |
no_node_thread_spread |
no_spread |
unbound;
(scheduler_bindings) -> tuple();
(scheduler_id) -> SchedulerId :: pos_integer();
(schedulers | schedulers_online) -> pos_integer();
(smp_support) -> boolean();
(start_time) -> integer();
(system_version) -> string();
(system_architecture) -> string();
(threads) -> boolean();
(thread_pool_size) -> non_neg_integer();
(time_correction) -> true | false;
(time_offset) -> preliminary | final | volatile;
(time_warp_mode) -> no_time_warp | single_time_warp | multi_time_warp;
(tolerant_timeofday) -> enabled | disabled;
(trace_control_word) -> non_neg_integer();
(update_cpu_info) -> changed | unchanged;
(version) -> string();
(wordsize | {wordsize, internal} | {wordsize, external}) -> 4 | 8.
system_info(_Item) ->
erlang:nif_error(undefined).
-spec erlang:universaltime_to_localtime(Universaltime) -> Localtime when
Localtime :: calendar:datetime(),
Universaltime :: calendar:datetime().
universaltime_to_localtime(_Universaltime) ->
erlang:nif_error(undefined).
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%% End of native code BIFs
%%% Actual Erlang implementation of some BIF's follow
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%--------------------------------------------------------------------------
%% Shadowed by erl_bif_types: erlang:apply/2
-spec apply(Fun, Args) -> term() when
Fun :: function(),
Args :: [term()].
apply(Fun, Args) ->
erlang:apply(Fun, Args).
%% Shadowed by erl_bif_types: erlang:apply/3
-spec apply(Module, Function, Args) -> term() when
Module :: module(),
Function :: atom(),
Args :: [term()].
apply(Mod, Name, Args) ->
erlang:apply(Mod, Name, Args).
%% Spawns with a fun
-spec spawn(Fun) -> pid() when
Fun :: function().
spawn(F) when erlang:is_function(F) ->
erlang:spawn(erlang, apply, [F, []]);
spawn({M,F}=MF) when erlang:is_atom(M), erlang:is_atom(F) ->
erlang:spawn(erlang, apply, [MF, []]);
spawn(F) ->
erlang:error(badarg, [F]).
-spec spawn(Node, Fun) -> pid() when
Node :: node(),
Fun :: function().
spawn(N, F) when N =:= erlang:node() ->
erlang:spawn(F);
spawn(N, F) when erlang:is_function(F) ->
erlang:spawn(N, erlang, apply, [F, []]);
spawn(N, {M,F}=MF) when erlang:is_atom(M), erlang:is_atom(F) ->
erlang:spawn(N, erlang, apply, [MF, []]);
spawn(N, F) ->
erlang:error(badarg, [N, F]).
-spec spawn_link(Fun) -> pid() when
Fun :: function().
spawn_link(F) when erlang:is_function(F) ->
erlang:spawn_link(erlang, apply, [F, []]);
spawn_link({M,F}=MF) when erlang:is_atom(M), erlang:is_atom(F) ->
erlang:spawn_link(erlang, apply, [MF, []]);
spawn_link(F) ->
erlang:error(badarg, [F]).
-spec spawn_link(Node, Fun) -> pid() when
Node :: node(),
Fun :: function().
spawn_link(N, F) when N =:= erlang:node() ->
spawn_link(F);
spawn_link(N, F) when erlang:is_function(F) ->
spawn_link(N, erlang, apply, [F, []]);
spawn_link(N, {M,F}=MF) when erlang:is_atom(M), erlang:is_atom(F) ->
spawn_link(N, erlang, apply, [MF, []]);
spawn_link(N, F) ->
erlang:error(badarg, [N, F]).
%% Spawn and atomically set up a monitor.
-spec spawn_monitor(Fun) -> {pid(), reference()} when
Fun :: function().
spawn_monitor(F) when erlang:is_function(F, 0) ->
erlang:spawn_opt({erlang,apply,[F,[]],[monitor]});
spawn_monitor(F) ->
erlang:error(badarg, [F]).
-spec spawn_monitor(Module, Function, Args) -> {pid(), reference()} when
Module :: module(),
Function :: atom(),
Args :: [term()].
spawn_monitor(M, F, A) when erlang:is_atom(M),
erlang:is_atom(F),
erlang:is_list(A) ->
erlang:spawn_opt({M,F,A,[monitor]});
spawn_monitor(M, F, A) ->
erlang:error(badarg, [M,F,A]).
-type max_heap_size() ::
Size :: non_neg_integer()
%% TODO change size => to := when -type maps support is finalized
| #{ size => non_neg_integer(),
kill => boolean(),
error_logger => boolean() }.
-type spawn_opt_option() ::
link
| monitor
| {priority, Level :: priority_level()}
| {fullsweep_after, Number :: non_neg_integer()}
| {min_heap_size, Size :: non_neg_integer()}
| {min_bin_vheap_size, VSize :: non_neg_integer()}
| {max_heap_size, Size :: max_heap_size()}
| {message_queue_data, MQD :: message_queue_data()}.
-spec spawn_opt(Fun, Options) -> pid() | {pid(), reference()} when
Fun :: function(),
Options :: [spawn_opt_option()].
spawn_opt(F, O) when erlang:is_function(F) ->
spawn_opt(erlang, apply, [F, []], O);
spawn_opt({M,F}=MF, O) when erlang:is_atom(M), erlang:is_atom(F) ->
spawn_opt(erlang, apply, [MF, []], O);
spawn_opt({M,F,A}, O) -> % For (undocumented) backward compatibility
spawn_opt(M, F, A, O);
spawn_opt(F, O) ->
erlang:error(badarg, [F, O]).
-spec spawn_opt(Node, Fun, Options) -> pid() | {pid(), reference()} when
Node :: node(),
Fun :: function(),
Options :: [spawn_opt_option()].
spawn_opt(N, F, O) when N =:= erlang:node() ->
spawn_opt(F, O);
spawn_opt(N, F, O) when erlang:is_function(F) ->
spawn_opt(N, erlang, apply, [F, []], O);
spawn_opt(N, {M,F}=MF, O) when erlang:is_atom(M), erlang:is_atom(F) ->
spawn_opt(N, erlang, apply, [MF, []], O);
spawn_opt(N, F, O) ->
erlang:error(badarg, [N, F, O]).
%% Spawns with MFA
-spec spawn(Node, Module, Function, Args) -> pid() when
Node :: node(),
Module :: module(),
Function :: atom(),
Args :: [term()].
spawn(N,M,F,A) when N =:= erlang:node(),
erlang:is_atom(M),
erlang:is_atom(F),
erlang:is_list(A) ->
erlang:spawn(M,F,A);
spawn(N,M,F,A) when erlang:is_atom(N),
erlang:is_atom(M),
erlang:is_atom(F) ->
case is_well_formed_list(A) of
true ->
ok;
false ->
erlang:error(badarg, [N, M, F, A])
end,
case catch gen_server:call({net_kernel,N},
{spawn,M,F,A,erlang:group_leader()},
infinity) of
Pid when erlang:is_pid(Pid) ->
Pid;
Error ->
case remote_spawn_error(Error, {no_link, N, M, F, A, []}) of
{fault, Fault} ->
erlang:error(Fault, [N, M, F, A]);
Pid ->
Pid
end
end;
spawn(N,M,F,A) ->
erlang:error(badarg, [N, M, F, A]).
-spec spawn_link(Node, Module, Function, Args) -> pid() when
Node :: node(),
Module :: module(),
Function :: atom(),
Args :: [term()].
spawn_link(N,M,F,A) when N =:= erlang:node(),
erlang:is_atom(M),
erlang:is_atom(F),
erlang:is_list(A) ->
erlang:spawn_link(M,F,A);
spawn_link(N,M,F,A) when erlang:is_atom(N),
erlang:is_atom(M),
erlang:is_atom(F) ->
case is_well_formed_list(A) of
true ->
ok;
_ ->
erlang:error(badarg, [N, M, F, A])
end,
case catch gen_server:call({net_kernel,N},
{spawn_link,M,F,A,erlang:group_leader()},
infinity) of
Pid when erlang:is_pid(Pid) ->
Pid;
Error ->
case remote_spawn_error(Error, {link, N, M, F, A, []}) of
{fault, Fault} ->
erlang:error(Fault, [N, M, F, A]);
Pid ->
Pid
end
end;
spawn_link(N,M,F,A) ->
erlang:error(badarg, [N, M, F, A]).
-spec spawn_opt(Module, Function, Args, Options) ->
pid() | {pid(), reference()} when
Module :: module(),
Function :: atom(),
Args :: [term()],
Options :: [spawn_opt_option()].
spawn_opt(M, F, A, Opts) ->
case catch erlang:spawn_opt({M,F,A,Opts}) of
{'EXIT',{Reason,_}} ->
erlang:error(Reason, [M,F,A,Opts]);
Res ->
Res
end.
-spec spawn_opt(Node, Module, Function, Args, Options) ->
pid() | {pid(), reference()} when
Node :: node(),
Module :: module(),
Function :: atom(),
Args :: [term()],
Options :: [spawn_opt_option()].
spawn_opt(N, M, F, A, O) when N =:= erlang:node(),
erlang:is_atom(M), erlang:is_atom(F),
erlang:is_list(A), erlang:is_list(O) ->
spawn_opt(M, F, A, O);
spawn_opt(N, M, F, A, O) when erlang:is_atom(N),
erlang:is_atom(M),
erlang:is_atom(F) ->
case {is_well_formed_list(A), is_well_formed_list(O)} of
{true, true} ->
ok;
_ ->
erlang:error(badarg, [N, M, F, A, O])
end,
case lists:member(monitor, O) of
false -> ok;
true -> erlang:error(badarg, [N, M, F, A, O])
end,
{L,NO} = lists:foldl(fun (link, {_, NewOpts}) ->
{link, NewOpts};
(Opt, {LO, NewOpts}) ->
{LO, [Opt|NewOpts]}
end,
{no_link,[]},
O),
case catch gen_server:call({net_kernel,N},
{spawn_opt,M,F,A,NO,L,erlang:group_leader()},
infinity) of
Pid when erlang:is_pid(Pid) ->
Pid;
Error ->
case remote_spawn_error(Error, {L, N, M, F, A, NO}) of
{fault, Fault} ->
erlang:error(Fault, [N, M, F, A, O]);
Pid ->
Pid
end
end;
spawn_opt(N,M,F,A,O) ->
erlang:error(badarg, [N,M,F,A,O]).
remote_spawn_error({'EXIT', {{nodedown,N}, _}}, {L, N, M, F, A, O}) ->
{Opts, LL} = case L =:= link of
true ->
{[link|O], [link]};
false ->
{O, []}
end,
spawn_opt(erlang,crasher,[N,M,F,A,Opts,noconnection], LL);
remote_spawn_error({'EXIT', {Reason, _}}, _) ->
{fault, Reason};
remote_spawn_error({'EXIT', Reason}, _) ->
{fault, Reason};
remote_spawn_error(Other, _) ->
{fault, Other}.
is_well_formed_list([]) ->
true;
is_well_formed_list([_|Rest]) ->
is_well_formed_list(Rest);
is_well_formed_list(_) ->
false.
crasher(Node,Mod,Fun,Args,[],Reason) ->
error_logger:warning_msg("** Can not start ~w:~w,~w on ~w **~n",
[Mod,Fun,Args,Node]),
erlang:exit(Reason);
crasher(Node,Mod,Fun,Args,Opts,Reason) ->
error_logger:warning_msg("** Can not start ~w:~w,~w (~w) on ~w **~n",
[Mod,Fun,Args,Opts,Node]),
erlang:exit(Reason).
-spec erlang:yield() -> 'true'.
yield() ->
erlang:yield().
-spec nodes() -> Nodes when
Nodes :: [node()].
nodes() ->
erlang:nodes(visible).
-spec disconnect_node(Node) -> boolean() | ignored when
Node :: node().
disconnect_node(Node) ->
net_kernel:disconnect(Node).
-spec erlang:fun_info(Fun) -> [{Item, Info}] when
Fun :: function(),
Item :: arity | env | index | name
| module | new_index | new_uniq | pid | type | uniq,
Info :: term().
fun_info(Fun) when erlang:is_function(Fun) ->
Keys = [type,env,arity,name,uniq,index,new_uniq,new_index,module,pid],
fun_info_1(Keys, Fun, []).
fun_info_1([K|Ks], Fun, A) ->
case erlang:fun_info(Fun, K) of
{K,undefined} -> fun_info_1(Ks, Fun, A);
{K,_}=P -> fun_info_1(Ks, Fun, [P|A])
end;
fun_info_1([], _, A) -> A.
-type dst() :: pid()
| port()
| (RegName :: atom())
| {RegName :: atom(), Node :: node()}.
-spec erlang:send_nosuspend(Dest, Msg) -> boolean() when
Dest :: dst(),
Msg :: term().
send_nosuspend(Pid, Msg) ->
send_nosuspend(Pid, Msg, []).
-spec erlang:send_nosuspend(Dest, Msg, Options) -> boolean() when
Dest :: dst(),
Msg :: term(),
Options :: [noconnect].
send_nosuspend(Pid, Msg, Opts) ->
case erlang:send(Pid, Msg, [nosuspend|Opts]) of
ok -> true;
_ -> false
end.
-spec erlang:localtime_to_universaltime(Localtime) -> Universaltime when
Localtime :: calendar:datetime(),
Universaltime :: calendar:datetime().
localtime_to_universaltime(Localtime) ->
erlang:localtime_to_universaltime(Localtime, undefined).
-spec erlang:suspend_process(Suspendee) -> 'true' when
Suspendee :: pid().
suspend_process(P) ->
case catch erlang:suspend_process(P, []) of
{'EXIT', {Reason, _}} -> erlang:error(Reason, [P]);
{'EXIT', Reason} -> erlang:error(Reason, [P]);
Res -> Res
end.
%%
%% Port BIFs
%%
%% Currently all port BIFs calls the corresponding
%% erts_internal:port_*() native function which perform
%% most of the actual work. These native functions should
%% *never* be called directly by other functionality. The
%% native functions may be changed, or removed without any
%% notice whatsoever!
%%
%% IMPORTANT NOTE:
%% When the erts_internal:port_*() native functions return
%% a reference, they have also internally prepared the
%% message queue of the caller for a receive that will
%% unconditionally wait for a message containing this
%% reference. If the erlang code calling these native
%% functions do not do this, subsequent receives will not
%% work as expected! That is, it is of *vital importance*
%% that the receive is performed as described above!
%%
-spec port_command(Port, Data) -> 'true' when
Port :: port() | atom(),
Data :: iodata().
port_command(Port, Data) ->
case case erts_internal:port_command(Port, Data, []) of
Ref when erlang:is_reference(Ref) -> receive {Ref, Res} -> Res end;
Res -> Res
end of
true -> true;
Error -> erlang:error(Error, [Port, Data])
end.
-spec port_command(Port, Data, OptionList) -> boolean() when
Port :: port() | atom(),
Data :: iodata(),
Option :: force | nosuspend,
OptionList :: [Option].
port_command(Port, Data, Flags) ->
case case erts_internal:port_command(Port, Data, Flags) of
Ref when erlang:is_reference(Ref) -> receive {Ref, Res} -> Res end;
Res -> Res
end of
Bool when Bool == true; Bool == false -> Bool;
Error -> erlang:error(Error, [Port, Data, Flags])
end.
-spec port_connect(Port, Pid) -> 'true' when
Port :: port() | atom(),
Pid :: pid().
port_connect(Port, Pid) ->
case case erts_internal:port_connect(Port, Pid) of
Ref when erlang:is_reference(Ref) -> receive {Ref, Res} -> Res end;
Res -> Res
end of
true -> true;
Error -> erlang:error(Error, [Port, Pid])
end.
-spec port_close(Port) -> 'true' when
Port :: port() | atom().
port_close(Port) ->
case case erts_internal:port_close(Port) of
Ref when erlang:is_reference(Ref) -> receive {Ref, Res} -> Res end;
Res -> Res
end of
true -> true;
Error -> erlang:error(Error, [Port])
end.
-spec port_control(Port, Operation, Data) -> iodata() | binary() when
Port :: port() | atom(),
Operation :: integer(),
Data :: iodata().
port_control(Port, Operation, Data) ->
case case erts_internal:port_control(Port, Operation, Data) of
Ref when erlang:is_reference(Ref) -> receive {Ref, Res} -> Res end;
Res -> Res
end of
badarg -> erlang:error(badarg, [Port, Operation, Data]);
Result -> Result
end.
-spec erlang:port_call(Port, Data) -> term() when
Port :: port() | atom(),
Data :: term().
port_call(Port, Data) ->
case case erts_internal:port_call(Port, 0, Data) of
Ref when erlang:is_reference(Ref) -> receive {Ref, Res} -> Res end;
Res -> Res
end of
{ok, Result} -> Result;
Error -> erlang:error(Error, [Port, Data])
end.
-spec erlang:port_call(Port, Operation, Data) -> term() when
Port :: port() | atom(),
Operation :: integer(),
Data :: term().
port_call(Port, Operation, Data) ->
case case erts_internal:port_call(Port, Operation, Data) of
Ref when erlang:is_reference(Ref) -> receive {Ref, Res} -> Res end;
Res -> Res
end of
{ok, Result} -> Result;
Error -> erlang:error(Error, [Port, Operation, Data])
end.
-spec erlang:port_info(Port) -> Result when
Port :: port() | atom(),
ResultItem :: {registered_name, RegisteredName :: atom()}
| {id, Index :: non_neg_integer()}
| {connected, Pid :: pid()}
| {links, Pids :: [pid()]}
| {name, String :: string()}
| {input, Bytes :: non_neg_integer()}
| {output, Bytes :: non_neg_integer()}
| {os_pid, OsPid :: non_neg_integer() | 'undefined'},
Result :: [ResultItem] | 'undefined'.
port_info(Port) ->
case case erts_internal:port_info(Port) of
Ref when erlang:is_reference(Ref) -> receive {Ref, Res} -> Res end;
Res -> Res
end of
badarg -> erlang:error(badarg, [Port]);
Result -> Result
end.
-spec erlang:port_info(Port, connected) -> {connected, Pid} | 'undefined' when
Port :: port() | atom(),
Pid :: pid();
(Port, id) -> {id, Index} | 'undefined' when
Port :: port() | atom(),
Index :: non_neg_integer();
(Port, input) -> {input, Bytes} | 'undefined' when
Port :: port() | atom(),
Bytes :: non_neg_integer();
(Port, links) -> {links, Pids} | 'undefined' when
Port :: port() | atom(),
Pids :: [pid()];
(Port, locking) -> {locking, Locking} | 'undefined' when
Port :: port() | atom(),
Locking :: 'false' | 'port_level' | 'driver_level';
(Port, memory) -> {memory, Bytes} | 'undefined' when
Port :: port() | atom(),
Bytes :: non_neg_integer();
(Port, monitors) -> {monitors, Monitors} | 'undefined' when
Port :: port() | atom(),
Monitors :: [{process, pid()}];
(Port, monitored_by) -> {monitored_by, MonitoredBy} | 'undefined' when
Port :: port() | atom(),
MonitoredBy :: [pid()];
(Port, name) -> {name, Name} | 'undefined' when
Port :: port() | atom(),
Name :: string();
(Port, os_pid) -> {os_pid, OsPid} | 'undefined' when
Port :: port() | atom(),
OsPid :: non_neg_integer() | 'undefined';
(Port, output) -> {output, Bytes} | 'undefined' when
Port :: port() | atom(),
Bytes :: non_neg_integer();
(Port, parallelism) -> {parallelism, Boolean} | 'undefined' when
Port :: port() | atom(),
Boolean :: boolean();
(Port, queue_size) -> {queue_size, Bytes} | 'undefined' when
Port :: port() | atom(),
Bytes :: non_neg_integer();
(Port, registered_name) -> {registered_name, RegisteredName} | [] | 'undefined' when
Port :: port() | atom(),
RegisteredName :: atom().
port_info(Port, Item) ->
case case erts_internal:port_info(Port, Item) of
Ref when erlang:is_reference(Ref) -> receive {Ref, Res} -> Res end;
Res -> Res
end of
badarg -> erlang:error(badarg, [Port, Item]);
Result -> Result
end.
-spec erlang:port_set_data(Port, Data) -> 'true' when
Port :: port() | atom(),
Data :: term().
port_set_data(_Port, _Data) ->
erlang:nif_error(undefined).
-spec erlang:port_get_data(Port) -> term() when
Port :: port() | atom().
port_get_data(_Port) ->
erlang:nif_error(undefined).
%%
%% If the emulator wants to perform a distributed command and
%% a connection is not established to the actual node the following
%% functions are called in order to set up the connection and then
%% reactivate the command.
%%
-spec erlang:dlink(pid() | port()) -> 'true'.
dlink(Pid) ->
case net_kernel:connect(erlang:node(Pid)) of
true -> erlang:link(Pid);
false -> erlang:dist_exit(erlang:self(), noconnection, Pid), true
end.
%% Can this ever happen?
-spec erlang:dunlink(identifier()) -> 'true'.
dunlink(Pid) ->
case net_kernel:connect(erlang:node(Pid)) of
true -> erlang:unlink(Pid);
false -> true
end.
dmonitor_node(Node, Flag, []) ->
case net_kernel:connect(Node) of
true -> erlang:monitor_node(Node, Flag, []);
false -> erlang:self() ! {nodedown, Node}, true
end;
dmonitor_node(Node, Flag, Opts) ->
case lists:member(allow_passive_connect, Opts) of
true ->
case net_kernel:passive_cnct(Node) of
true -> erlang:monitor_node(Node, Flag, Opts);
false -> erlang:self() ! {nodedown, Node}, true
end;
_ ->
dmonitor_node(Node,Flag,[])
end.
dgroup_leader(Leader, Pid) ->
case net_kernel:connect(erlang:node(Pid)) of
true -> erlang:group_leader(Leader, Pid);
false -> true %% bad arg ?
end.
dexit(Pid, Reason) ->
case net_kernel:connect(erlang:node(Pid)) of
true -> erlang:exit(Pid, Reason);
false -> true
end.
dsend(Pid, Msg) when erlang:is_pid(Pid) ->
case net_kernel:connect(erlang:node(Pid)) of
true -> erlang:send(Pid, Msg);
false -> Msg
end;
dsend(Port, Msg) when erlang:is_port(Port) ->
case net_kernel:connect(erlang:node(Port)) of
true -> erlang:send(Port, Msg);
false -> Msg
end;
dsend({Name, Node}, Msg) ->
case net_kernel:connect(Node) of
true -> erlang:send({Name,Node}, Msg);
false -> Msg;
ignored -> Msg % Not distributed.
end.
dsend(Pid, Msg, Opts) when erlang:is_pid(Pid) ->
case net_kernel:connect(erlang:node(Pid)) of
true -> erlang:send(Pid, Msg, Opts);
false -> ok
end;
dsend(Port, Msg, Opts) when erlang:is_port(Port) ->
case net_kernel:connect(erlang:node(Port)) of
true -> erlang:send(Port, Msg, Opts);
false -> ok
end;
dsend({Name, Node}, Msg, Opts) ->
case net_kernel:connect(Node) of
true -> erlang:send({Name,Node}, Msg, Opts);
false -> ok;
ignored -> ok % Not distributed.
end.
-spec erlang:dmonitor_p('process', pid() | {atom(),atom()}) -> reference().
dmonitor_p(process, ProcSpec) ->
%% ProcSpec = pid() | {atom(),atom()}
%% ProcSpec CANNOT be an atom because a locally registered process
%% is never handled here.
Node = case ProcSpec of
{S,N} when erlang:is_atom(S),
erlang:is_atom(N),
N =/= erlang:node() -> N;
_ when erlang:is_pid(ProcSpec) -> erlang:node(ProcSpec)
end,
case net_kernel:connect(Node) of
true ->
erlang:monitor(process, ProcSpec);
false ->
Ref = erlang:make_ref(),
erlang:self() ! {'DOWN', Ref, process, ProcSpec, noconnection},
Ref
end.
%%
%% Trap function used when modified timing has been enabled.
%%
-spec erlang:delay_trap(Result, timeout()) -> Result.
delay_trap(Result, 0) -> erlang:yield(), Result;
delay_trap(Result, Timeout) -> receive after Timeout -> Result end.
%%
%% The business with different in and out cookies represented
%% everywhere is discarded.
%% A node has a cookie, connections/messages to that node use that cookie.
%% Messages to us use our cookie. IF we change our cookie, other nodes
%% have to reflect that, which we cannot forsee.
%%
-spec erlang:set_cookie(Node, Cookie) -> true when
Node :: node(),
Cookie :: atom().
set_cookie(Node, C) when Node =/= nonode@nohost, erlang:is_atom(Node) ->
case erlang:is_atom(C) of
true ->
auth:set_cookie(Node, C);
false ->
erlang:error(badarg)
end.
-spec erlang:get_cookie() -> Cookie | nocookie when
Cookie :: atom().
get_cookie() ->
auth:get_cookie().
-spec integer_to_list(Integer, Base) -> string() when
Integer :: integer(),
Base :: 2..36.
integer_to_list(I, 10) ->
erlang:integer_to_list(I);
integer_to_list(I, Base)
when erlang:is_integer(I), erlang:is_integer(Base),
Base >= 2, Base =< 1+$Z-$A+10 ->
if I < 0 ->
[$-|integer_to_list(-I, Base, [])];
true ->
integer_to_list(I, Base, [])
end;
integer_to_list(I, Base) ->
erlang:error(badarg, [I, Base]).
integer_to_list(I0, Base, R0) ->
D = I0 rem Base,
I1 = I0 div Base,
R1 = if D >= 10 ->
[D-10+$A|R0];
true ->
[D+$0|R0]
end,
if I1 =:= 0 ->
R1;
true ->
integer_to_list(I1, Base, R1)
end.
-spec integer_to_binary(Integer, Base) -> binary() when
Integer :: integer(),
Base :: 2..36.
integer_to_binary(I, 10) ->
erlang:integer_to_binary(I);
integer_to_binary(I, Base)
when erlang:is_integer(I), erlang:is_integer(Base),
Base >= 2, Base =< 1+$Z-$A+10 ->
if I < 0 ->
<<$-,(integer_to_binary(-I, Base, <<>>))/binary>>;
true ->
integer_to_binary(I, Base, <<>>)
end;
integer_to_binary(I, Base) ->
erlang:error(badarg, [I, Base]).
integer_to_binary(I0, Base, R0) ->
D = I0 rem Base,
I1 = I0 div Base,
R1 = if
D >= 10 -> <<(D-10+$A),R0/binary>>;
true -> <<(D+$0),R0/binary>>
end,
if
I1 =:= 0 -> R1;
true -> integer_to_binary(I1, Base, R1)
end.
-record(cpu, {node = -1,
processor = -1,
processor_node = -1,
core = -1,
thread = -1,
logical = -1}).
%% erlang:set_cpu_topology/1 is for internal use only!
%%
%% erlang:system_flag(cpu_topology, CpuTopology) traps to
%% erlang:set_cpu_topology(CpuTopology).
set_cpu_topology(CpuTopology) ->
try format_cpu_topology(erlang:system_flag(internal_cpu_topology,
cput_e2i(CpuTopology)))
catch
Class:Exception when Class =/= error; Exception =/= internal_error ->
erlang:error(badarg, [CpuTopology])
end.
cput_e2i_clvl({logical, _}, _PLvl) ->
#cpu.logical;
cput_e2i_clvl([E | _], PLvl) ->
case erlang:element(1, E) of
node -> case PLvl of
0 -> #cpu.node;
#cpu.processor -> #cpu.processor_node
end;
processor -> case PLvl of
0 -> #cpu.node;
#cpu.node -> #cpu.processor
end;
core -> #cpu.core;
thread -> #cpu.thread
end.
cput_e2i(undefined) ->
undefined;
cput_e2i(E) ->
rvrs(cput_e2i(E, -1, -1, #cpu{}, 0, cput_e2i_clvl(E, 0), [])).
cput_e2i([], _NId, _PId, _IS, _PLvl, _Lvl, Res) ->
Res;
cput_e2i([E|Es], NId0, PId, IS, PLvl, Lvl, Res0) ->
case cput_e2i(E, NId0, PId, IS, PLvl, Lvl, Res0) of
[] ->
cput_e2i(Es, NId0, PId, IS, PLvl, Lvl, Res0);
[#cpu{node = N,
processor = P,
processor_node = PN} = CPU|_] = Res1 ->
NId1 = case N > PN of
true -> N;
false -> PN
end,
cput_e2i(Es, NId1, P, CPU, PLvl, Lvl, Res1)
end;
cput_e2i({Tag, [], TagList}, Nid, PId, CPU, PLvl, Lvl, Res) ->
%% Currently [] is the only valid InfoList
cput_e2i({Tag, TagList}, Nid, PId, CPU, PLvl, Lvl, Res);
cput_e2i({node, NL}, Nid0, PId, _CPU, 0, #cpu.node, Res) ->
Nid1 = Nid0+1,
Lvl = cput_e2i_clvl(NL, #cpu.node),
cput_e2i(NL, Nid1, PId, #cpu{node = Nid1}, #cpu.node, Lvl, Res);
cput_e2i({processor, PL}, Nid, PId0, _CPU, 0, #cpu.node, Res) ->
PId1 = PId0+1,
Lvl = cput_e2i_clvl(PL, #cpu.processor),
cput_e2i(PL, Nid, PId1, #cpu{processor = PId1}, #cpu.processor, Lvl, Res);
cput_e2i({processor, PL}, Nid, PId0, CPU, PLvl, CLvl, Res)
when PLvl < #cpu.processor, CLvl =< #cpu.processor ->
PId1 = PId0+1,
Lvl = cput_e2i_clvl(PL, #cpu.processor),
cput_e2i(PL, Nid, PId1, CPU#cpu{processor = PId1,
processor_node = -1,
core = -1,
thread = -1}, #cpu.processor, Lvl, Res);
cput_e2i({node, NL}, Nid0, PId, CPU, #cpu.processor, #cpu.processor_node,
Res) ->
Nid1 = Nid0+1,
Lvl = cput_e2i_clvl(NL, #cpu.processor_node),
cput_e2i(NL, Nid1, PId, CPU#cpu{processor_node = Nid1},
#cpu.processor_node, Lvl, Res);
cput_e2i({core, CL}, Nid, PId, #cpu{core = C0} = CPU, PLvl, #cpu.core, Res)
when PLvl < #cpu.core ->
Lvl = cput_e2i_clvl(CL, #cpu.core),
cput_e2i(CL, Nid, PId, CPU#cpu{core = C0+1, thread = -1}, #cpu.core, Lvl,
Res);
cput_e2i({thread, TL}, Nid, PId, #cpu{thread = T0} = CPU, PLvl, #cpu.thread,
Res) when PLvl < #cpu.thread ->
Lvl = cput_e2i_clvl(TL, #cpu.thread),
cput_e2i(TL, Nid, PId, CPU#cpu{thread = T0+1}, #cpu.thread, Lvl, Res);
cput_e2i({logical, ID}, _Nid, PId, #cpu{processor=P, core=C, thread=T} = CPU,
PLvl, #cpu.logical, Res)
when PLvl < #cpu.logical, erlang:is_integer(ID), 0 =< ID, ID < 65536 ->
[CPU#cpu{processor = case P of -1 -> PId+1; _ -> P end,
core = case C of -1 -> 0; _ -> C end,
thread = case T of -1 -> 0; _ -> T end,
logical = ID} | Res].
%% erlang:format_cpu_topology/1 is for internal use only!
%%
%% erlang:system_info(cpu_topology),
%% and erlang:system_info({cpu_topology, Which}) traps to
%% erlang:format_cpu_topology(InternalCpuTopology).
format_cpu_topology(InternalCpuTopology) ->
try cput_i2e(InternalCpuTopology)
catch _ : _ -> erlang:error(internal_error, [InternalCpuTopology])
end.
cput_i2e(undefined) -> undefined;
cput_i2e(Is) -> cput_i2e(Is, true, #cpu.node, cput_i2e_tag_map()).
cput_i2e([], _Frst, _Lvl, _TM) ->
[];
cput_i2e([#cpu{logical = LID}| _], _Frst, Lvl, _TM) when Lvl == #cpu.logical ->
{logical, LID};
cput_i2e([#cpu{} = I | Is], Frst, Lvl, TM) ->
cput_i2e(erlang:element(Lvl, I), Frst, Is, [I], Lvl, TM).
cput_i2e(V, Frst, [I | Is], SameV, Lvl, TM) when V =:= erlang:element(Lvl, I) ->
cput_i2e(V, Frst, Is, [I | SameV], Lvl, TM);
cput_i2e(-1, true, [], SameV, Lvl, TM) ->
cput_i2e(rvrs(SameV), true, Lvl+1, TM);
cput_i2e(_V, true, [], SameV, Lvl, TM) when Lvl =/= #cpu.processor,
Lvl =/= #cpu.processor_node ->
cput_i2e(rvrs(SameV), true, Lvl+1, TM);
cput_i2e(-1, _Frst, Is, SameV, #cpu.node, TM) ->
cput_i2e(rvrs(SameV), true, #cpu.processor, TM)
++ cput_i2e(Is, false, #cpu.node, TM);
cput_i2e(_V, _Frst, Is, SameV, Lvl, TM) ->
[{cput_i2e_tag(Lvl, TM), cput_i2e(rvrs(SameV), true, Lvl+1, TM)}
| cput_i2e(Is, false, Lvl, TM)].
cput_i2e_tag_map() -> erlang:list_to_tuple([cpu | record_info(fields, cpu)]).
cput_i2e_tag(Lvl, TM) ->
case erlang:element(Lvl, TM) of processor_node -> node; Other -> Other end.
rvrs([_] = L) -> L;
rvrs(Xs) -> rvrs(Xs, []).
rvrs([],Ys) -> Ys;
rvrs([X|Xs],Ys) -> rvrs(Xs, [X|Ys]).
%% erlang:await_proc_exit/3 is for internal use only!
%%
%% BIFs that need to await a specific process exit before
%% returning traps to erlang:await_proc_exit/3.
%%
%% NOTE: This function is tightly coupled to
%% the implementation of the
%% erts_bif_prep_await_proc_exit_*()
%% functions in bif.c. Do not make
%% any changes to it without reading
%% the comment about them in bif.c!
-spec erlang:await_proc_exit(dst(), 'apply' | 'data' | 'reason', term()) -> term().
await_proc_exit(Proc, Op, Data) ->
Mon = erlang:monitor(process, Proc),
receive
{'DOWN', Mon, process, _Proc, Reason} ->
case Op of
apply ->
{M, F, A} = Data,
erlang:apply(M, F, A);
data ->
Data;
reason ->
Reason
end
end.
-spec min(Term1, Term2) -> Minimum when
Term1 :: term(),
Term2 :: term(),
Minimum :: term().
min(A, B) when A > B -> B;
min(A, _) -> A.
-spec max(Term1, Term2) -> Maximum when
Term1 :: term(),
Term2 :: term(),
Maximum :: term().
max(A, B) when A < B -> B;
max(A, _) -> A.
%%
%% erlang:memory/[0,1]
%%
%% NOTE! When updating these functions, make sure to also update
%% erts_memory() in $ERL_TOP/erts/emulator/beam/erl_alloc.c
%%
-type memory_type() :: 'total' | 'processes' | 'processes_used' | 'system'
| 'atom' | 'atom_used' | 'binary' | 'code' | 'ets'
| 'low' | 'maximum'.
-define(CARRIER_ALLOCS, [mseg_alloc]).
-define(LOW_ALLOCS, [ll_low_alloc, std_low_alloc]).
-define(ALL_NEEDED_ALLOCS, (erlang:system_info(alloc_util_allocators)
-- ?CARRIER_ALLOCS)).
-record(memory, {total = 0,
processes = 0,
processes_used = 0,
system = 0,
atom = 0,
atom_used = 0,
binary = 0,
code = 0,
ets = 0,
low = 0,
maximum = 0}).
-spec erlang:memory() -> [{Type, Size}] when
Type :: memory_type(),
Size :: non_neg_integer().
memory() ->
case aa_mem_data(au_mem_data(?ALL_NEEDED_ALLOCS)) of
notsup ->
erlang:error(notsup);
Mem ->
InstrTail = case Mem#memory.maximum of
0 -> [];
_ -> [{maximum, Mem#memory.maximum}]
end,
Tail = case Mem#memory.low of
0 -> InstrTail;
_ -> [{low, Mem#memory.low} | InstrTail]
end,
[{total, Mem#memory.total},
{processes, Mem#memory.processes},
{processes_used, Mem#memory.processes_used},
{system, Mem#memory.system},
{atom, Mem#memory.atom},
{atom_used, Mem#memory.atom_used},
{binary, Mem#memory.binary},
{code, Mem#memory.code},
{ets, Mem#memory.ets} | Tail]
end.
-spec erlang:memory(Type :: memory_type()) -> non_neg_integer();
(TypeList :: [memory_type()]) -> [{memory_type(), non_neg_integer()}].
memory(Type) when erlang:is_atom(Type) ->
{AA, ALCU, ChkSup, BadArgZero} = need_mem_info(Type),
case get_mem_data(ChkSup, ALCU, AA) of
notsup ->
erlang:error(notsup, [Type]);
Mem ->
Value = get_memval(Type, Mem),
case {BadArgZero, Value} of
{true, 0} -> erlang:error(badarg, [Type]);
_ -> Value
end
end;
memory(Types) when erlang:is_list(Types) ->
{AA, ALCU, ChkSup, BadArgZeroList} = need_mem_info_list(Types),
case get_mem_data(ChkSup, ALCU, AA) of
notsup ->
erlang:error(notsup, [Types]);
Mem ->
case memory_result_list(Types, BadArgZeroList, Mem) of
badarg -> erlang:error(badarg, [Types]);
Result -> Result
end
end.
memory_result_list([], [], _Mem) ->
[];
memory_result_list([T|Ts], [BAZ|BAZs], Mem) ->
case memory_result_list(Ts, BAZs, Mem) of
badarg -> badarg;
TVs ->
V = get_memval(T, Mem),
case {BAZ, V} of
{true, 0} -> badarg;
_ -> [{T, V}| TVs]
end
end.
get_mem_data(true, AlcUAllocs, NeedAllocatedAreas) ->
case memory_is_supported() of
false -> notsup;
true -> get_mem_data(false, AlcUAllocs, NeedAllocatedAreas)
end;
get_mem_data(false, AlcUAllocs, NeedAllocatedAreas) ->
AlcUMem = case AlcUAllocs of
[] -> #memory{};
_ ->
au_mem_data(AlcUAllocs)
end,
case NeedAllocatedAreas of
true -> aa_mem_data(AlcUMem);
false -> AlcUMem
end.
need_mem_info_list([]) ->
{false, [], false, []};
need_mem_info_list([T|Ts]) ->
{MAA, MALCU, MChkSup, MBadArgZero} = need_mem_info_list(Ts),
{AA, ALCU, ChkSup, BadArgZero} = need_mem_info(T),
{case AA of
true -> true;
_ -> MAA
end,
ALCU ++ (MALCU -- ALCU),
case ChkSup of
true -> true;
_ -> MChkSup
end,
[BadArgZero|MBadArgZero]}.
need_mem_info(Type) when Type == total;
Type == system ->
{true, ?ALL_NEEDED_ALLOCS, false, false};
need_mem_info(Type) when Type == processes;
Type == processes_used ->
{true, [eheap_alloc, fix_alloc], true, false};
need_mem_info(Type) when Type == atom;
Type == atom_used;
Type == code ->
{true, [], true, false};
need_mem_info(binary) ->
{false, [binary_alloc], true, false};
need_mem_info(ets) ->
{true, [ets_alloc], true, false};
need_mem_info(low) ->
LowAllocs = ?LOW_ALLOCS -- ?CARRIER_ALLOCS,
{_, _, FeatureList, _} = erlang:system_info(allocator),
AlcUAllocs = case LowAllocs -- FeatureList of
[] -> LowAllocs;
_ -> []
end,
{false, AlcUAllocs, true, true};
need_mem_info(maximum) ->
{true, [], true, true};
need_mem_info(_) ->
{false, [], false, true}.
get_memval(total, #memory{total = V}) -> V;
get_memval(processes, #memory{processes = V}) -> V;
get_memval(processes_used, #memory{processes_used = V}) -> V;
get_memval(system, #memory{system = V}) -> V;
get_memval(atom, #memory{atom = V}) -> V;
get_memval(atom_used, #memory{atom_used = V}) -> V;
get_memval(binary, #memory{binary = V}) -> V;
get_memval(code, #memory{code = V}) -> V;
get_memval(ets, #memory{ets = V}) -> V;
get_memval(low, #memory{low = V}) -> V;
get_memval(maximum, #memory{maximum = V}) -> V;
get_memval(_, #memory{}) -> 0.
memory_is_supported() ->
{_, _, FeatureList, _} = erlang:system_info(allocator),
case ((erlang:system_info(alloc_util_allocators)
-- ?CARRIER_ALLOCS)
-- FeatureList) of
[] -> true;
_ -> false
end.
get_blocks_size([{blocks_size, Sz, _, _} | Rest], Acc) ->
get_blocks_size(Rest, Acc+Sz);
get_blocks_size([{_, _, _, _} | Rest], Acc) ->
get_blocks_size(Rest, Acc);
get_blocks_size([{blocks_size, Sz} | Rest], Acc) ->
get_blocks_size(Rest, Acc+Sz);
get_blocks_size([{_, _} | Rest], Acc) ->
get_blocks_size(Rest, Acc);
get_blocks_size([], Acc) ->
Acc.
blocks_size([{Carriers, SizeList} | Rest], Acc) when Carriers == mbcs;
Carriers == mbcs_pool;
Carriers == sbcs ->
blocks_size(Rest, get_blocks_size(SizeList, Acc));
blocks_size([_ | Rest], Acc) ->
blocks_size(Rest, Acc);
blocks_size([], Acc) ->
Acc.
get_fix_proc([{ProcType, A1, U1}| Rest], {A0, U0}) when ProcType == proc;
ProcType == monitor_sh;
ProcType == nlink_sh;
ProcType == msg_ref;
ProcType == ll_ptimer;
ProcType == hl_ptimer;
ProcType == bif_timer;
ProcType == accessor_bif_timer ->
get_fix_proc(Rest, {A0+A1, U0+U1});
get_fix_proc([_|Rest], Acc) ->
get_fix_proc(Rest, Acc);
get_fix_proc([], Acc) ->
Acc.
fix_proc([{fix_types, SizeList} | _Rest], Acc) ->
get_fix_proc(SizeList, Acc);
fix_proc([{fix_types, Mask, SizeList} | _Rest], Acc) ->
{A, U} = get_fix_proc(SizeList, Acc),
{Mask, A, U};
fix_proc([_ | Rest], Acc) ->
fix_proc(Rest, Acc);
fix_proc([], Acc) ->
Acc.
is_low_alloc(_A, []) ->
false;
is_low_alloc(A, [A|_As]) ->
true;
is_low_alloc(A, [_A|As]) ->
is_low_alloc(A, As).
is_low_alloc(A) ->
is_low_alloc(A, ?LOW_ALLOCS).
au_mem_data(notsup, _) ->
notsup;
au_mem_data(_, [{_, false} | _]) ->
notsup;
au_mem_data(#memory{total = Tot,
processes = Proc,
processes_used = ProcU} = Mem,
[{eheap_alloc, _, Data} | Rest]) ->
Sz = blocks_size(Data, 0),
au_mem_data(Mem#memory{total = Tot+Sz,
processes = Proc+Sz,
processes_used = ProcU+Sz},
Rest);
au_mem_data(#memory{total = Tot,
system = Sys,
ets = Ets} = Mem,
[{ets_alloc, _, Data} | Rest]) ->
Sz = blocks_size(Data, 0),
au_mem_data(Mem#memory{total = Tot+Sz,
system = Sys+Sz,
ets = Ets+Sz},
Rest);
au_mem_data(#memory{total = Tot,
system = Sys,
binary = Bin} = Mem,
[{binary_alloc, _, Data} | Rest]) ->
Sz = blocks_size(Data, 0),
au_mem_data(Mem#memory{total = Tot+Sz,
system = Sys+Sz,
binary = Bin+Sz},
Rest);
au_mem_data(#memory{total = Tot,
processes = Proc,
processes_used = ProcU,
system = Sys} = Mem,
[{fix_alloc, _, Data} | Rest]) ->
Sz = blocks_size(Data, 0),
case fix_proc(Data, {0, 0}) of
{A, U} ->
au_mem_data(Mem#memory{total = Tot+Sz,
processes = Proc+A,
processes_used = ProcU+U,
system = Sys+Sz-A},
Rest);
{Mask, A, U} ->
au_mem_data(Mem#memory{total = Tot+Sz,
processes = Mask band (Proc+A),
processes_used = Mask band (ProcU+U),
system = Mask band (Sys+Sz-A)},
Rest)
end;
au_mem_data(#memory{total = Tot,
system = Sys,
low = Low} = Mem,
[{A, _, Data} | Rest]) ->
Sz = blocks_size(Data, 0),
au_mem_data(Mem#memory{total = Tot+Sz,
system = Sys+Sz,
low = case is_low_alloc(A) of
true -> Low+Sz;
false -> Low
end},
Rest);
au_mem_data(EMD, []) ->
EMD.
au_mem_data(Allocs) ->
Ref = erlang:make_ref(),
erlang:system_info({memory_internal, Ref, Allocs}),
receive_emd(Ref).
receive_emd(_Ref, EMD, 0) ->
EMD;
receive_emd(Ref, EMD, N) ->
receive
{Ref, _, Data} ->
receive_emd(Ref, au_mem_data(EMD, Data), N-1)
end.
receive_emd(Ref) ->
receive_emd(Ref, #memory{}, erlang:system_info(schedulers)).
aa_mem_data(#memory{} = Mem,
[{maximum, Max} | Rest]) ->
aa_mem_data(Mem#memory{maximum = Max},
Rest);
aa_mem_data(#memory{} = Mem,
[{total, Tot} | Rest]) ->
aa_mem_data(Mem#memory{total = Tot,
system = 0}, % system will be adjusted later
Rest);
aa_mem_data(#memory{atom = Atom,
atom_used = AtomU} = Mem,
[{atom_space, Alloced, Used} | Rest]) ->
aa_mem_data(Mem#memory{atom = Atom+Alloced,
atom_used = AtomU+Used},
Rest);
aa_mem_data(#memory{atom = Atom,
atom_used = AtomU} = Mem,
[{atom_table, Sz} | Rest]) ->
aa_mem_data(Mem#memory{atom = Atom+Sz,
atom_used = AtomU+Sz},
Rest);
aa_mem_data(#memory{ets = Ets} = Mem,
[{ets_misc, Sz} | Rest]) ->
aa_mem_data(Mem#memory{ets = Ets+Sz},
Rest);
aa_mem_data(#memory{processes = Proc,
processes_used = ProcU,
system = Sys} = Mem,
[{ProcData, Sz} | Rest]) when ProcData == bif_timer;
ProcData == link_lh;
ProcData == process_table ->
aa_mem_data(Mem#memory{processes = Proc+Sz,
processes_used = ProcU+Sz,
system = Sys-Sz},
Rest);
aa_mem_data(#memory{code = Code} = Mem,
[{CodeData, Sz} | Rest]) when CodeData == module_table;
CodeData == export_table;
CodeData == export_list;
CodeData == fun_table;
CodeData == module_refs;
CodeData == loaded_code ->
aa_mem_data(Mem#memory{code = Code+Sz},
Rest);
aa_mem_data(EMD, [{_, _} | Rest]) ->
aa_mem_data(EMD, Rest);
aa_mem_data(#memory{total = Tot,
processes = Proc,
system = Sys} = Mem,
[]) when Sys =< 0 ->
%% Instrumented runtime system -> Sys = Tot - Proc
Mem#memory{system = Tot - Proc};
aa_mem_data(EMD, []) ->
EMD.
aa_mem_data(notsup) ->
notsup;
aa_mem_data(EMD) ->
aa_mem_data(EMD, erlang:system_info(allocated_areas)).
%%
%% alloc_info/1 and alloc_sizes/1 are for internal use only (used by
%% erlang:system_info({allocator|allocator_sizes, _})).
%%
alloc_info(Allocs) ->
get_alloc_info(allocator, Allocs).
alloc_sizes(Allocs) ->
get_alloc_info(allocator_sizes, Allocs).
get_alloc_info(Type, AAtom) when erlang:is_atom(AAtom) ->
[{AAtom, Result}] = get_alloc_info(Type, [AAtom]),
Result;
get_alloc_info(Type, AList) when erlang:is_list(AList) ->
Ref = erlang:make_ref(),
erlang:system_info({Type, Ref, AList}),
receive_allocator(Ref,
erlang:system_info(schedulers),
mk_res_list(AList)).
mk_res_list([]) ->
[];
mk_res_list([Alloc | Rest]) ->
[{Alloc, []} | mk_res_list(Rest)].
insert_instance(I, N, Rest) when erlang:is_atom(N) ->
[{N, I} | Rest];
insert_instance(I, N, []) ->
[{instance, N, I}];
insert_instance(I, N, [{instance, M, _}|_] = Rest) when N < M ->
[{instance, N, I} | Rest];
insert_instance(I, N, [Prev|Rest]) ->
[Prev | insert_instance(I, N, Rest)].
insert_info([], Ys) ->
Ys;
insert_info([{A, false}|Xs], [{A, _IList}|Ys]) ->
insert_info(Xs, [{A, false}|Ys]);
insert_info([{A, N, I}|Xs], [{A, IList}|Ys]) ->
insert_info(Xs, [{A, insert_instance(I, N, IList)}|Ys]);
insert_info([{A1, _}|_] = Xs, [{A2, _} = Y | Ys]) when A1 /= A2 ->
[Y | insert_info(Xs, Ys)];
insert_info([{A1, _, _}|_] = Xs, [{A2, _} = Y | Ys]) when A1 /= A2 ->
[Y | insert_info(Xs, Ys)].
receive_allocator(_Ref, 0, Acc) ->
Acc;
receive_allocator(Ref, N, Acc) ->
receive
{Ref, _, InfoList} ->
receive_allocator(Ref, N-1, insert_info(InfoList, Acc))
end.
-spec erlang:await_sched_wall_time_modifications(Ref, Result) -> boolean() when
Ref :: reference(),
Result :: boolean().
await_sched_wall_time_modifications(Ref, Result) ->
sched_wall_time(Ref, erlang:system_info(schedulers)),
Result.
-spec erlang:gather_sched_wall_time_result(Ref) -> [{pos_integer(),
non_neg_integer(),
non_neg_integer()}] when
Ref :: reference().
gather_sched_wall_time_result(Ref) when erlang:is_reference(Ref) ->
sched_wall_time(Ref, erlang:system_info(schedulers), []).
sched_wall_time(_Ref, 0) ->
ok;
sched_wall_time(Ref, N) ->
receive Ref -> sched_wall_time(Ref, N-1) end.
sched_wall_time(_Ref, 0, Acc) ->
Acc;
sched_wall_time(Ref, N, undefined) ->
receive {Ref, _} -> sched_wall_time(Ref, N-1, undefined) end;
sched_wall_time(Ref, N, Acc) ->
receive
{Ref, undefined} -> sched_wall_time(Ref, N-1, undefined);
{Ref, SWTL} when erlang:is_list(SWTL) -> sched_wall_time(Ref, N-1, Acc ++ SWTL);
{Ref, SWT} -> sched_wall_time(Ref, N-1, [SWT|Acc])
end.
-spec erlang:gather_gc_info_result(Ref) ->
{number(),number(),0} when Ref :: reference().
gather_gc_info_result(Ref) when erlang:is_reference(Ref) ->
gc_info(Ref, erlang:system_info(schedulers), {0,0}).
gc_info(_Ref, 0, {Colls,Recl}) ->
{Colls,Recl,0};
gc_info(Ref, N, {OrigColls,OrigRecl}) ->
receive
{Ref, {_,Colls, Recl}} ->
gc_info(Ref, N-1, {Colls+OrigColls,Recl+OrigRecl})
end.