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|
%%
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 2015-2017. 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%
%%
%% =====================================================================
%% Multiple PRNG module for Erlang/OTP
%% Copyright (c) 2015-2016 Kenji Rikitake
%%
%% exrop (xoroshiro116+) added and statistical distribution
%% improvements by the Erlang/OTP team 2017
%% =====================================================================
-module(rand).
-export([seed_s/1, seed_s/2, seed/1, seed/2,
export_seed/0, export_seed_s/1,
uniform/0, uniform/1, uniform_s/1, uniform_s/2,
jump/0, jump/1,
normal/0, normal_s/1
]).
-compile({inline, [exs64_next/1, exsplus_next/1,
exs1024_next/1, exs1024_calc/2,
exrop_next/1, exrop_next_s/2,
get_52/1, normal_kiwi/1]}).
-define(DEFAULT_ALG_HANDLER, exrop).
-define(SEED_DICT, rand_seed).
%% =====================================================================
%% Bit fiddling macros
%% =====================================================================
-define(BIT(Bits), (1 bsl (Bits))).
-define(MASK(Bits), (?BIT(Bits) - 1)).
-define(MASK(Bits, X), ((X) band ?MASK(Bits))).
-define(
BSL(Bits, X, N),
%% N is evaluated 2 times
(?MASK((Bits)-(N), (X)) bsl (N))).
-define(
ROTL(Bits, X, N),
%% Bits is evaluated 2 times
%% X is evaluated 2 times
%% N i evaluated 3 times
(?BSL((Bits), (X), (N)) bor ((X) bsr ((Bits)-(N))))).
%%-define(TWO_POW_MINUS53, (math:pow(2, -53))).
-define(TWO_POW_MINUS53, 1.11022302462515657e-16).
%% =====================================================================
%% Types
%% =====================================================================
-type uint64() :: 0..?MASK(64).
-type uint58() :: 0..?MASK(58).
%% This depends on the algorithm handler function
-type alg_state() ::
exs64_state() | exsplus_state() | exs1024_state() |
exrop_state() | term().
%% This is the algorithm handling definition within this module,
%% and the type to use for plugins.
%%
%% The 'type' field must be recognized by the module that implements
%% the algorithm, to interpret an exported state.
%%
%% The 'bits' field indicates how many bits the integer
%% returned from 'next' has got, i.e 'next' shall return
%% an random integer in the range 0..(2^Bits - 1).
%% At least 53 bits is required for the floating point
%% producing fallbacks. This field is only used when
%% the 'uniform' or 'uniform_n' fields are not defined.
%%
%% The fields 'next', 'uniform' and 'uniform_n'
%% implement the algorithm. If 'uniform' or 'uinform_n'
%% is not present there is a fallback using 'next' and either
%% 'bits' or the deprecated 'max'.
%%
-type alg_handler() ::
#{type := alg(),
bits => non_neg_integer(),
weak_low_bits => non_neg_integer(),
max => non_neg_integer(), % Deprecated
next :=
fun ((alg_state()) -> {non_neg_integer(), alg_state()}),
uniform =>
fun ((state()) -> {float(), state()}),
uniform_n =>
fun ((pos_integer(), state()) -> {pos_integer(), state()}),
jump =>
fun ((state()) -> state())}.
%% Algorithm state
-type state() :: {alg_handler(), alg_state()}.
-type builtin_alg() :: exs64 | exsplus | exsp | exs1024 | exs1024s | exrop.
-type alg() :: builtin_alg() | atom().
-type export_state() :: {alg(), alg_state()}.
-export_type(
[builtin_alg/0, alg/0, alg_handler/0, alg_state/0,
state/0, export_state/0]).
-export_type(
[exs64_state/0, exsplus_state/0, exs1024_state/0, exrop_state/0]).
%% =====================================================================
%% Range macro and helper
%% =====================================================================
-define(
uniform_range(Range, Alg, R, V, MaxMinusRange, I),
if
0 =< (MaxMinusRange) ->
if
%% Really work saving in odd cases;
%% large ranges in particular
(V) < (Range) ->
{(V) + 1, {(Alg), (R)}};
true ->
(I) = (V) rem (Range),
if
(V) - (I) =< (MaxMinusRange) ->
{(I) + 1, {(Alg), (R)}};
true ->
%% V in the truncated top range
%% - try again
?FUNCTION_NAME((Range), {(Alg), (R)})
end
end;
true ->
uniform_range((Range), (Alg), (R), (V))
end).
%% For ranges larger than the algorithm bit size
uniform_range(Range, #{next:=Next, bits:=Bits} = Alg, R, V) ->
WeakLowBits =
case Alg of
#{weak_low_bits:=WLB} -> WLB;
#{} -> 0
end,
%% Maybe waste the lowest bit(s) when shifting in new bits
Shift = Bits - WeakLowBits,
ShiftMask = bnot ?MASK(WeakLowBits),
RangeMinus1 = Range - 1,
if
(Range band RangeMinus1) =:= 0 -> % Power of 2
%% Generate at least the number of bits for the range
{V1, R1, _} =
uniform_range(
Range bsr Bits, Next, R, V, ShiftMask, Shift, Bits),
{(V1 band RangeMinus1) + 1, {Alg, R1}};
true ->
%% Generate a value with at least two bits more than the range
%% and try that for a fit, otherwise recurse
%%
%% Just one bit more should ensure that the generated
%% number range is at least twice the size of the requested
%% range, which would make the probability to draw a good
%% number better than 0.5. And repeating that until
%% success i guess would take 2 times statistically amortized.
%% But since the probability for fairly many attemtpts
%% is not that low, use two bits more than the range which
%% should make the probability to draw a bad number under 0.25,
%% which decreases the bad case probability a lot.
{V1, R1, B} =
uniform_range(
Range bsr (Bits - 2), Next, R, V, ShiftMask, Shift, Bits),
I = V1 rem Range,
if
(V1 - I) =< (1 bsl B) - Range ->
{I + 1, {Alg, R1}};
true ->
%% V1 drawn from the truncated top range
%% - try again
{V2, R2} = Next(R1),
uniform_range(Range, Alg, R2, V2)
end
end.
%%
uniform_range(Range, Next, R, V, ShiftMask, Shift, B) ->
if
Range =< 1 ->
{V, R, B};
true ->
{V1, R1} = Next(R),
%% Waste the lowest bit(s) when shifting in new bits
uniform_range(
Range bsr Shift, Next, R1,
((V band ShiftMask) bsl Shift) bor V1,
ShiftMask, Shift, B + Shift)
end.
%% =====================================================================
%% API
%% =====================================================================
%% Return algorithm and seed so that RNG state can be recreated with seed/1
-spec export_seed() -> undefined | export_state().
export_seed() ->
case get(?SEED_DICT) of
{#{type:=Alg}, Seed} -> {Alg, Seed};
_ -> undefined
end.
-spec export_seed_s(State :: state()) -> export_state().
export_seed_s({#{type:=Alg}, Seed}) -> {Alg, Seed}.
%% seed(Alg) seeds RNG with runtime dependent values
%% and return the NEW state
%% seed({Alg,Seed}) setup RNG with a previously exported seed
%% and return the NEW state
-spec seed(
AlgOrStateOrExpState :: builtin_alg() | state() | export_state()) ->
state().
seed(Alg) ->
seed_put(seed_s(Alg)).
-spec seed_s(
AlgOrStateOrExpState :: builtin_alg() | state() | export_state()) ->
state().
seed_s({AlgHandler, _Seed} = State) when is_map(AlgHandler) ->
State;
seed_s({Alg0, Seed}) ->
{Alg,_SeedFun} = mk_alg(Alg0),
{Alg, Seed};
seed_s(Alg) ->
seed_s(Alg, {erlang:phash2([{node(),self()}]),
erlang:system_time(),
erlang:unique_integer()}).
%% seed/2: seeds RNG with the algorithm and given values
%% and returns the NEW state.
-spec seed(
Alg :: builtin_alg(), Seed :: {integer(), integer(), integer()}) ->
state().
seed(Alg0, S0) ->
seed_put(seed_s(Alg0, S0)).
-spec seed_s(
Alg :: builtin_alg(), Seed :: {integer(), integer(), integer()}) ->
state().
seed_s(Alg0, S0 = {_, _, _}) ->
{Alg, Seed} = mk_alg(Alg0),
AS = Seed(S0),
{Alg, AS}.
%%% uniform/0, uniform/1, uniform_s/1, uniform_s/2 are all
%%% uniformly distributed random numbers.
%% uniform/0: returns a random float X where 0.0 < X < 1.0,
%% updating the state in the process dictionary.
-spec uniform() -> X :: float().
uniform() ->
{X, Seed} = uniform_s(seed_get()),
_ = seed_put(Seed),
X.
%% uniform/1: given an integer N >= 1,
%% uniform/1 returns a random integer X where 1 =< X =< N,
%% updating the state in the process dictionary.
-spec uniform(N :: pos_integer()) -> X :: pos_integer().
uniform(N) ->
{X, Seed} = uniform_s(N, seed_get()),
_ = seed_put(Seed),
X.
%% uniform_s/1: given a state, uniform_s/1
%% returns a random float X where 0.0 < X < 1.0,
%% and a new state.
-spec uniform_s(State :: state()) -> {X :: float(), NewState :: state()}.
uniform_s(State = {#{uniform:=Uniform}, _}) ->
Uniform(State);
uniform_s({#{bits:=Bits, next:=Next} = Alg, R0}) ->
{V, R1} = Next(R0),
%% Produce floats on the form N * 2^(-53)
{(V bsr (Bits - 53)) * ?TWO_POW_MINUS53, {Alg, R1}};
uniform_s({#{max:=Max, next:=Next} = Alg, R0}) ->
{V, R1} = Next(R0),
%% Old broken algorithm with non-uniform density
{V / (Max + 1), {Alg, R1}}.
%% uniform_s/2: given an integer N >= 1 and a state, uniform_s/2
%% uniform_s/2 returns a random integer X where 1 =< X =< N,
%% and a new state.
-spec uniform_s(N :: pos_integer(), State :: state()) ->
{X :: pos_integer(), NewState :: state()}.
uniform_s(N, State = {#{uniform_n:=UniformN}, _})
when is_integer(N), 1 =< N ->
UniformN(N, State);
uniform_s(N, {#{bits:=Bits, next:=Next} = Alg, R0})
when is_integer(N), 1 =< N ->
{V, R1} = Next(R0),
MaxMinusN = ?BIT(Bits) - N,
?uniform_range(N, Alg, R1, V, MaxMinusN, I);
uniform_s(N, {#{max:=Max, next:=Next} = Alg, R0})
when is_integer(N), 1 =< N ->
%% Old broken algorithm with skewed probability
%% and gap in ranges > Max
{V, R1} = Next(R0),
if
N =< Max ->
{(V rem N) + 1, {Alg, R1}};
true ->
F = V / (Max + 1),
{trunc(F * N) + 1, {Alg, R1}}
end.
%% jump/1: given a state, jump/1
%% returns a new state which is equivalent to that
%% after a large number of call defined for each algorithm.
%% The large number is algorithm dependent.
-spec jump(state()) -> NewState :: state().
jump(State = {#{jump:=Jump}, _}) ->
Jump(State);
jump({#{}, _}) ->
erlang:error(not_implemented).
%% jump/0: read the internal state and
%% apply the jump function for the state as in jump/1
%% and write back the new value to the internal state,
%% then returns the new value.
-spec jump() -> NewState :: state().
jump() ->
seed_put(jump(seed_get())).
%% normal/0: returns a random float with standard normal distribution
%% updating the state in the process dictionary.
-spec normal() -> float().
normal() ->
{X, Seed} = normal_s(seed_get()),
_ = seed_put(Seed),
X.
%% normal_s/1: returns a random float with standard normal distribution
%% The Ziggurat Method for generating random variables - Marsaglia and Tsang
%% Paper and reference code: http://www.jstatsoft.org/v05/i08/
-spec normal_s(State :: state()) -> {float(), NewState :: state()}.
normal_s(State0) ->
{Sign, R, State} = get_52(State0),
Idx = ?MASK(8, R),
Idx1 = Idx+1,
{Ki, Wi} = normal_kiwi(Idx1),
X = R * Wi,
case R < Ki of
%% Fast path 95% of the time
true when Sign =:= 0 -> {X, State};
true -> {-X, State};
%% Slow path
false when Sign =:= 0 -> normal_s(Idx, Sign, X, State);
false -> normal_s(Idx, Sign, -X, State)
end.
%% =====================================================================
%% Internal functions
-spec seed_put(state()) -> state().
seed_put(Seed) ->
put(?SEED_DICT, Seed),
Seed.
seed_get() ->
case get(?SEED_DICT) of
undefined -> seed(?DEFAULT_ALG_HANDLER);
Old -> Old % no type checking here
end.
%% Setup alg record
mk_alg(exs64) ->
{#{type=>exs64, max=>?MASK(64), next=>fun exs64_next/1},
fun exs64_seed/1};
mk_alg(exsplus) ->
{#{type=>exsplus, max=>?MASK(58), next=>fun exsplus_next/1,
jump=>fun exsplus_jump/1},
fun exsplus_seed/1};
mk_alg(exsp) ->
{#{type=>exsp, bits=>58, weak_low_bits=>1, next=>fun exsplus_next/1,
uniform=>fun exsp_uniform/1, uniform_n=>fun exsp_uniform/2,
jump=>fun exsplus_jump/1},
fun exsplus_seed/1};
mk_alg(exs1024) ->
{#{type=>exs1024, max=>?MASK(64), next=>fun exs1024_next/1,
jump=>fun exs1024_jump/1},
fun exs1024_seed/1};
mk_alg(exs1024s) ->
{#{type=>exs1024s, bits=>64, weak_low_bits=>3, next=>fun exs1024_next/1,
jump=>fun exs1024_jump/1},
fun exs1024_seed/1};
mk_alg(exrop) ->
{#{type=>exrop, bits=>58, weak_low_bits=>1, next=>fun exrop_next/1,
uniform=>fun exrop_uniform/1, uniform_n=>fun exrop_uniform/2,
jump=>fun exrop_jump/1},
fun exrop_seed/1}.
%% =====================================================================
%% exs64 PRNG: Xorshift64*
%% Algorithm by Sebastiano Vigna
%% Reference URL: http://xorshift.di.unimi.it/
%% =====================================================================
-opaque exs64_state() :: uint64().
exs64_seed({A1, A2, A3}) ->
{V1, _} = exs64_next((?MASK(32, A1) * 4294967197 + 1)),
{V2, _} = exs64_next((?MASK(32, A2) * 4294967231 + 1)),
{V3, _} = exs64_next((?MASK(32, A3) * 4294967279 + 1)),
((V1 * V2 * V3) rem (?MASK(64) - 1)) + 1.
%% Advance xorshift64* state for one step and generate 64bit unsigned integer
-spec exs64_next(exs64_state()) -> {uint64(), exs64_state()}.
exs64_next(R) ->
R1 = R bxor (R bsr 12),
R2 = R1 bxor ?BSL(64, R1, 25),
R3 = R2 bxor (R2 bsr 27),
{?MASK(64, R3 * 2685821657736338717), R3}.
%% =====================================================================
%% exsplus PRNG: Xorshift116+
%% Algorithm by Sebastiano Vigna
%% Reference URL: http://xorshift.di.unimi.it/
%% 58 bits fits into an immediate on 64bits erlang and is thus much faster.
%% Modification of the original Xorshift128+ algorithm to 116
%% by Sebastiano Vigna, a lot of thanks for his help and work.
%% =====================================================================
-opaque exsplus_state() :: nonempty_improper_list(uint58(), uint58()).
-dialyzer({no_improper_lists, exsplus_seed/1}).
exsplus_seed({A1, A2, A3}) ->
{_, R1} = exsplus_next(
[?MASK(58, (A1 * 4294967197) + 1)|
?MASK(58, (A2 * 4294967231) + 1)]),
{_, R2} = exsplus_next(
[?MASK(58, (A3 * 4294967279) + 1)|
tl(R1)]),
R2.
-dialyzer({no_improper_lists, exsplus_next/1}).
%% Advance xorshift116+ state for one step and generate 58bit unsigned integer
-spec exsplus_next(exsplus_state()) -> {uint58(), exsplus_state()}.
exsplus_next([S1|S0]) ->
%% Note: members s0 and s1 are swapped here
S11 = S1 bxor ?BSL(58, S1, 24),
S12 = S11 bxor S0 bxor (S11 bsr 11) bxor (S0 bsr 41),
{?MASK(58, S0 + S12), [S0|S12]}.
exsp_uniform({Alg, R0}) ->
{I, R1} = exsplus_next(R0),
%% Waste the lowest bit since it is of lower
%% randomness quality than the others
{(I bsr (58-53)) * ?TWO_POW_MINUS53, {Alg, R1}}.
exsp_uniform(Range, {Alg, R}) ->
{V, R1} = exsplus_next(R),
MaxMinusRange = ?BIT(58) - Range,
?uniform_range(Range, Alg, R1, V, MaxMinusRange, I).
%% This is the jump function for the exsplus generator, equivalent
%% to 2^64 calls to next/1; it can be used to generate 2^52
%% non-overlapping subsequences for parallel computations.
%% Note: the jump function takes 116 times of the execution time of
%% next/1.
%% -define(JUMPCONST, 16#000d174a83e17de2302f8ea6bc32c797).
%% split into 58-bit chunks
%% and two iterative executions
-define(JUMPCONST1, 16#02f8ea6bc32c797).
-define(JUMPCONST2, 16#345d2a0f85f788c).
-define(JUMPELEMLEN, 58).
-dialyzer({no_improper_lists, exsplus_jump/1}).
-spec exsplus_jump(state()) -> state().
exsplus_jump({Alg, S}) ->
{S1, AS1} = exsplus_jump(S, [0|0], ?JUMPCONST1, ?JUMPELEMLEN),
{_, AS2} = exsplus_jump(S1, AS1, ?JUMPCONST2, ?JUMPELEMLEN),
{Alg, AS2}.
-dialyzer({no_improper_lists, exsplus_jump/4}).
exsplus_jump(S, AS, _, 0) ->
{S, AS};
exsplus_jump(S, [AS0|AS1], J, N) ->
{_, NS} = exsplus_next(S),
case ?MASK(1, J) of
1 ->
[S0|S1] = S,
exsplus_jump(NS, [(AS0 bxor S0)|(AS1 bxor S1)], J bsr 1, N-1);
0 ->
exsplus_jump(NS, [AS0|AS1], J bsr 1, N-1)
end.
%% =====================================================================
%% exs1024 PRNG: Xorshift1024*
%% Algorithm by Sebastiano Vigna
%% Reference URL: http://xorshift.di.unimi.it/
%% =====================================================================
-opaque exs1024_state() :: {list(uint64()), list(uint64())}.
exs1024_seed({A1, A2, A3}) ->
B1 = ?MASK(21, (?MASK(21, A1) + 1) * 2097131),
B2 = ?MASK(21, (?MASK(21, A2) + 1) * 2097133),
B3 = ?MASK(21, (?MASK(21, A3) + 1) * 2097143),
{exs1024_gen1024((B1 bsl 43) bor (B2 bsl 22) bor (B3 bsl 1) bor 1),
[]}.
%% Generate a list of 16 64-bit element list
%% of the xorshift64* random sequence
%% from a given 64-bit seed.
%% Note: dependent on exs64_next/1
-spec exs1024_gen1024(uint64()) -> list(uint64()).
exs1024_gen1024(R) ->
exs1024_gen1024(16, R, []).
exs1024_gen1024(0, _, L) ->
L;
exs1024_gen1024(N, R, L) ->
{X, R2} = exs64_next(R),
exs1024_gen1024(N - 1, R2, [X|L]).
%% Calculation of xorshift1024*.
%% exs1024_calc(S0, S1) -> {X, NS1}.
%% X: random number output
-spec exs1024_calc(uint64(), uint64()) -> {uint64(), uint64()}.
exs1024_calc(S0, S1) ->
S11 = S1 bxor ?BSL(64, S1, 31),
S12 = S11 bxor (S11 bsr 11),
S01 = S0 bxor (S0 bsr 30),
NS1 = S01 bxor S12,
{?MASK(64, NS1 * 1181783497276652981), NS1}.
%% Advance xorshift1024* state for one step and generate 64bit unsigned integer
-spec exs1024_next(exs1024_state()) -> {uint64(), exs1024_state()}.
exs1024_next({[S0,S1|L3], RL}) ->
{X, NS1} = exs1024_calc(S0, S1),
{X, {[NS1|L3], [S0|RL]}};
exs1024_next({[H], RL}) ->
NL = [H|lists:reverse(RL)],
exs1024_next({NL, []}).
%% This is the jump function for the exs1024 generator, equivalent
%% to 2^512 calls to next(); it can be used to generate 2^512
%% non-overlapping subsequences for parallel computations.
%% Note: the jump function takes ~2000 times of the execution time of
%% next/1.
%% Jump constant here split into 58 bits for speed
-define(JUMPCONSTHEAD, 16#00242f96eca9c41d).
-define(JUMPCONSTTAIL,
[16#0196e1ddbe5a1561,
16#0239f070b5837a3c,
16#03f393cc68796cd2,
16#0248316f404489af,
16#039a30088bffbac2,
16#02fea70dc2d9891f,
16#032ae0d9644caec4,
16#0313aac17d8efa43,
16#02f132e055642626,
16#01ee975283d71c93,
16#00552321b06f5501,
16#00c41d10a1e6a569,
16#019158ecf8aa1e44,
16#004e9fc949d0b5fc,
16#0363da172811fdda,
16#030e38c3b99181f2,
16#0000000a118038fc]).
-define(JUMPTOTALLEN, 1024).
-define(RINGLEN, 16).
-spec exs1024_jump(state()) -> state().
exs1024_jump({Alg, {L, RL}}) ->
P = length(RL),
AS = exs1024_jump({L, RL},
[0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0],
?JUMPCONSTTAIL, ?JUMPCONSTHEAD, ?JUMPELEMLEN, ?JUMPTOTALLEN),
{ASL, ASR} = lists:split(?RINGLEN - P, AS),
{Alg, {ASL, lists:reverse(ASR)}}.
exs1024_jump(_, AS, _, _, _, 0) ->
AS;
exs1024_jump(S, AS, [H|T], _, 0, TN) ->
exs1024_jump(S, AS, T, H, ?JUMPELEMLEN, TN);
exs1024_jump({L, RL}, AS, JL, J, N, TN) ->
{_, NS} = exs1024_next({L, RL}),
case ?MASK(1, J) of
1 ->
AS2 = lists:zipwith(fun(X, Y) -> X bxor Y end,
AS, L ++ lists:reverse(RL)),
exs1024_jump(NS, AS2, JL, J bsr 1, N-1, TN-1);
0 ->
exs1024_jump(NS, AS, JL, J bsr 1, N-1, TN-1)
end.
%% =====================================================================
%% exrop PRNG: Xoroshiro116+
%%
%% Reference URL: http://xorshift.di.unimi.it/
%%
%% 58 bits fits into an immediate on 64bits Erlang and is thus much faster.
%% In fact, an immediate number is 60 bits signed in Erlang so you can
%% add two positive 58 bit numbers and get a 59 bit number that still is
%% a positive immediate, which is a property we utilize here...
%%
%% Modification of the original Xororhiro128+ algorithm to 116 bits
%% by Sebastiano Vigna. A lot of thanks for his help and work.
%% =====================================================================
%% (a, b, c) = (24, 2, 35)
%% JUMP Polynomial = 0x9863200f83fcd4a11293241fcb12a (116 bit)
%%
%% From http://xoroshiro.di.unimi.it/xoroshiro116plus.c:
%% ---------------------------------------------------------------------
%% /* Written in 2017 by Sebastiano Vigna (vigna@acm.org).
%%
%% To the extent possible under law, the author has dedicated all copyright
%% and related and neighboring rights to this software to the public domain
%% worldwide. This software is distributed without any warranty.
%%
%% See <http://creativecommons.org/publicdomain/zero/1.0/>. */
%%
%% #include <stdint.h>
%%
%% #define UINT58MASK (uint64_t)((UINT64_C(1) << 58) - 1)
%%
%% uint64_t s[2];
%%
%% static inline uint64_t rotl58(const uint64_t x, int k) {
%% return (x << k) & UINT58MASK | (x >> (58 - k));
%% }
%%
%% uint64_t next(void) {
%% uint64_t s1 = s[1];
%% const uint64_t s0 = s[0];
%% const uint64_t result = (s0 + s1) & UINT58MASK;
%%
%% s1 ^= s0;
%% s[0] = rotl58(s0, 24) ^ s1 ^ ((s1 << 2) & UINT58MASK); // a, b
%% s[1] = rotl58(s1, 35); // c
%% return result;
%% }
%%
%% void jump(void) {
%% static const uint64_t JUMP[] =
%% { 0x4a11293241fcb12a, 0x0009863200f83fcd };
%%
%% uint64_t s0 = 0;
%% uint64_t s1 = 0;
%% for(int i = 0; i < sizeof JUMP / sizeof *JUMP; i++)
%% for(int b = 0; b < 64; b++) {
%% if (JUMP[i] & UINT64_C(1) << b) {
%% s0 ^= s[0];
%% s1 ^= s[1];
%% }
%% next();
%% }
%% s[0] = s0;
%% s[1] = s1;
%% }
-opaque exrop_state() :: nonempty_improper_list(uint58(), uint58()).
-dialyzer({no_improper_lists, exrop_seed/1}).
exrop_seed({A1, A2, A3}) ->
[_|S1] =
exrop_next_s(
?MASK(58, (A1 * 4294967197) + 1),
?MASK(58, (A2 * 4294967231) + 1)),
exrop_next_s(?MASK(58, (A3 * 4294967279) + 1), S1).
-dialyzer({no_improper_lists, exrop_next_s/2}).
%% Advance xoroshiro116+ state one step
%% [a, b, c] = [24, 2, 35]
-define(
exrop_next_s(S0, S1, S1_a),
begin
S1_a = S1 bxor S0,
[?ROTL(58, S0, 24) bxor S1_a bxor ?BSL(58, S1_a, 2)| % a, b
?ROTL(58, S1_a, 35)] % c
end).
exrop_next_s(S0, S1) ->
?exrop_next_s(S0, S1, S1_a).
-dialyzer({no_improper_lists, exrop_next/1}).
%% Advance xoroshiro116+ state one step, generate 58 bit unsigned integer,
%% and waste the lowest bit since it is of lower randomness quality
exrop_next([S0|S1]) ->
{?MASK(58, S0 + S1), ?exrop_next_s(S0, S1, S1_a)}.
exrop_uniform({Alg, R}) ->
{V, R1} = exrop_next(R),
%% Waste the lowest bit since it is of lower
%% randomness quality than the others
{(V bsr (58-53)) * ?TWO_POW_MINUS53, {Alg, R1}}.
exrop_uniform(Range, {Alg, R}) ->
{V, R1} = exrop_next(R),
MaxMinusRange = ?BIT(58) - Range,
?uniform_range(Range, Alg, R1, V, MaxMinusRange, I).
%% Split a 116 bit constant into two '1'++58 bit words,
%% the top '1' marks the top of the word
-define(
JUMP_116(Jump),
[?BIT(58) bor ?MASK(58, (Jump)),?BIT(58) bor ((Jump) bsr 58)]).
%%
exrop_jump({Alg,S}) ->
[J|Js] = ?JUMP_116(16#9863200f83fcd4a11293241fcb12a),
{Alg, exrop_jump(S, 0, 0, J, Js)}.
%%
-dialyzer({no_improper_lists, exrop_jump/5}).
exrop_jump(_S, S0, S1, 1, []) -> % End of jump constant
[S0|S1];
exrop_jump(S, S0, S1, 1, [J|Js]) -> % End of the word
exrop_jump(S, S0, S1, J, Js);
exrop_jump([S__0|S__1] = _S, S0, S1, J, Js) ->
case ?MASK(1, J) of
1 ->
NewS = exrop_next_s(S__0, S__1),
exrop_jump(NewS, S0 bxor S__0, S1 bxor S__1, J bsr 1, Js);
0 ->
NewS = exrop_next_s(S__0, S__1),
exrop_jump(NewS, S0, S1, J bsr 1, Js)
end.
%% =====================================================================
%% Ziggurat cont
%% =====================================================================
-define(NOR_R, 3.6541528853610087963519472518).
-define(NOR_INV_R, 1/?NOR_R).
%% return a {sign, Random51bits, State}
get_52({Alg=#{bits:=Bits, next:=Next}, S0}) ->
%% Use the high bits
{Int,S1} = Next(S0),
{?BIT(Bits - 51 - 1) band Int, Int bsr (Bits - 51), {Alg, S1}};
get_52({Alg=#{next:=Next}, S0}) ->
{Int,S1} = Next(S0),
{?BIT(51) band Int, ?MASK(51, Int), {Alg, S1}}.
%% Slow path
normal_s(0, Sign, X0, State0) ->
{U0, S1} = uniform_s(State0),
X = -?NOR_INV_R*math:log(U0),
{U1, S2} = uniform_s(S1),
Y = -math:log(U1),
case Y+Y > X*X of
false ->
normal_s(0, Sign, X0, S2);
true when Sign =:= 0 ->
{?NOR_R + X, S2};
true ->
{-?NOR_R - X, S2}
end;
normal_s(Idx, _Sign, X, State0) ->
Fi2 = normal_fi(Idx+1),
{U0, S1} = uniform_s(State0),
case ((normal_fi(Idx) - Fi2)*U0 + Fi2) < math:exp(-0.5*X*X) of
true -> {X, S1};
false -> normal_s(S1)
end.
%% Tables for generating normal_s
%% ki is zipped with wi (slightly faster)
normal_kiwi(Indx) ->
element(Indx,
{{2104047571236786,1.736725412160263e-15}, {0,9.558660351455634e-17},
{1693657211986787,1.2708704834810623e-16},{1919380038271141,1.4909740962495474e-16},
{2015384402196343,1.6658733631586268e-16},{2068365869448128,1.8136120810119029e-16},
{2101878624052573,1.9429720153135588e-16},{2124958784102998,2.0589500628482093e-16},
{2141808670795147,2.1646860576895422e-16},{2154644611568301,2.2622940392218116e-16},
{2164744887587275,2.353271891404589e-16},{2172897953696594,2.438723455742877e-16},
{2179616279372365,2.5194879829274225e-16},{2185247251868649,2.5962199772528103e-16},
{2190034623107822,2.6694407473648285e-16},{2194154434521197,2.7395729685142446e-16},
{2197736978774660,2.8069646002484804e-16},{2200880740891961,2.871905890411393e-16},
{2203661538010620,2.9346417484728883e-16},{2206138681109102,2.9953809336782113e-16},
{2208359231806599,3.054303000719244e-16},{2210361007258210,3.111563633892157e-16},
{2212174742388539,3.1672988018581815e-16},{2213825672704646,3.2216280350549905e-16},
{2215334711002614,3.274657040793975e-16},{2216719334487595,3.326479811684171e-16},
{2217994262139172,3.377180341735323e-16},{2219171977965032,3.4268340353119356e-16},
{2220263139538712,3.475508873172976e-16},{2221276900117330,3.523266384600203e-16},
{2222221164932930,3.5701624633953494e-16},{2223102796829069,3.616248057159834e-16},
{2223927782546658,3.661569752965354e-16},{2224701368170060,3.7061702777236077e-16},
{2225428170204312,3.75008892787478e-16},{2226112267248242,3.7933619401549554e-16},
{2226757276105256,3.836022812967728e-16},{2227366415328399,3.8781025861250247e-16},
{2227942558554684,3.919630085325768e-16},{2228488279492521,3.9606321366256378e-16},
{2229005890047222,4.001133755254669e-16},{2229497472775193,4.041158312414333e-16},
{2229964908627060,4.080727683096045e-16},{2230409900758597,4.119862377480744e-16},
{2230833995044585,4.1585816580828064e-16},{2231238597816133,4.1969036444740733e-16},
{2231624991250191,4.234845407152071e-16},{2231994346765928,4.272423051889976e-16},
{2232347736722750,4.309651795716294e-16},{2232686144665934,4.346546035512876e-16},
{2233010474325959,4.383119410085457e-16},{2233321557544881,4.4193848564470665e-16},
{2233620161276071,4.455354660957914e-16},{2233906993781271,4.491040505882875e-16},
{2234182710130335,4.52645351185714e-16},{2234447917093496,4.561604276690038e-16},
{2234703177503020,4.596502910884941e-16},{2234949014150181,4.631159070208165e-16},
{2235185913274316,4.665581985600875e-16},{2235414327692884,4.699780490694195e-16},
{2235634679614920,4.733763047158324e-16},{2235847363174595,4.767537768090853e-16},
{2236052746716837,4.8011124396270155e-16},{2236251174862869,4.834494540935008e-16},
{2236442970379967,4.867691262742209e-16},{2236628435876762,4.900709524522994e-16},
{2236807855342765,4.933555990465414e-16},{2236981495548562,4.966237084322178e-16},
{2237149607321147,4.998759003240909e-16},{2237312426707209,5.031127730659319e-16},
{2237470176035652,5.0633490483427195e-16},{2237623064889403,5.095428547633892e-16},
{2237771290995388,5.127371639978797e-16},{2237915041040597,5.159183566785736e-16},
{2238054491421305,5.190869408670343e-16},{2238189808931712,5.222434094134042e-16},
{2238321151397660,5.253882407719454e-16},{2238448668260432,5.285218997682382e-16},
{2238572501115169,5.316448383216618e-16},{2238692784207942,5.34757496126473e-16},
{2238809644895133,5.378603012945235e-16},{2238923204068402,5.409536709623993e-16},
{2239033576548190,5.440380118655467e-16},{2239140871448443,5.471137208817361e-16},
{2239245192514958,5.501811855460336e-16},{2239346638439541,5.532407845392784e-16},
{2239445303151952,5.56292888151909e-16},{2239541276091442,5.593378587248462e-16},
{2239634642459498,5.623760510690043e-16},{2239725483455293,5.65407812864896e-16},
{2239813876495186,5.684334850436814e-16},{2239899895417494,5.714534021509204e-16},
{2239983610673676,5.744678926941961e-16},{2240065089506935,5.774772794756965e-16},
{2240144396119183,5.804818799107686e-16},{2240221591827230,5.834820063333892e-16},
{2240296735208969,5.864779662894365e-16},{2240369882240293,5.894700628185872e-16},
{2240441086423386,5.924585947256134e-16},{2240510398907004,5.95443856841806e-16},
{2240577868599305,5.984261402772028e-16},{2240643542273726,6.014057326642664e-16},
{2240707464668391,6.043829183936125e-16},{2240769678579486,6.073579788423606e-16},
{2240830224948980,6.103311925956439e-16},{2240889142947082,6.133028356617911e-16},
{2240946470049769,6.162731816816596e-16},{2241002242111691,6.192425021325847e-16},
{2241056493434746,6.222110665273788e-16},{2241109256832602,6.251791426088e-16},
{2241160563691400,6.281469965398895e-16},{2241210444026879,6.311148930905604e-16},
{2241258926538122,6.34083095820806e-16},{2241306038658137,6.370518672608815e-16},
{2241351806601435,6.400214690888025e-16},{2241396255408788,6.429921623054896e-16},
{2241439408989313,6.459642074078832e-16},{2241481290160038,6.489378645603397e-16},
{2241521920683062,6.519133937646159e-16},{2241561321300462,6.548910550287415e-16},
{2241599511767028,6.578711085350741e-16},{2241636510880960,6.608538148078259e-16},
{2241672336512612,6.638394348803506e-16},{2241707005631362,6.668282304624746e-16},
{2241740534330713,6.698204641081558e-16},{2241772937851689,6.728163993837531e-16},
{2241804230604585,6.758163010371901e-16},{2241834426189161,6.78820435168298e-16},
{2241863537413311,6.818290694006254e-16},{2241891576310281,6.848424730550038e-16},
{2241918554154466,6.878609173251664e-16},{2241944481475843,6.908846754557169e-16},
{2241969368073071,6.939140229227569e-16},{2241993223025298,6.969492376174829e-16},
{2242016054702685,6.999906000330764e-16},{2242037870775710,7.030383934552151e-16},
{2242058678223225,7.060929041565482e-16},{2242078483339331,7.091544215954873e-16},
{2242097291739040,7.122232386196779e-16},{2242115108362774,7.152996516745303e-16},
{2242131937479672,7.183839610172063e-16},{2242147782689725,7.214764709364707e-16},
{2242162646924736,7.245774899788387e-16},{2242176532448092,7.276873311814693e-16},
{2242189440853337,7.308063123122743e-16},{2242201373061537,7.339347561177405e-16},
{2242212329317416,7.370729905789831e-16},{2242222309184237,7.4022134917658e-16},
{2242231311537397,7.433801711647648e-16},{2242239334556717,7.465498018555889e-16},
{2242246375717369,7.497305929136979e-16},{2242252431779415,7.529229026624058e-16},
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{2242238647326615,7.956484300529366e-16},{2242230132832625,7.99044201715713e-16},
{2242220486690076,8.024579184921259e-16},{2242209691384458,8.058900995272657e-16},
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{2242057301132135,8.377040521420222e-16},{2242033761687079,8.413529986798028e-16},
{2242008788768107,8.450272519724097e-16},{2241982346215682,8.487275610186155e-16},
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{2241376894317345,9.079616903740068e-16},{2241319774977817,9.122071683134846e-16},
{2241260098640860,9.164968996219135e-16},{2241197758920538,9.208324163262308e-16},
{2241132642244704,9.252153239095693e-16},{2241064627262652,9.296473063086417e-16},
{2240993584191742,9.341301313425265e-16},{2240919374095536,9.38665656618666e-16},
{2240841848084890,9.432558359676707e-16},{2240760846432232,9.479027264651738e-16},
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{2239842221996530,9.926785548807976e-16},{2239714417896699,9.980350026183645e-16},
{2239580280957725,1.003480452143618e-15},{2239439398282193,1.0090190861637457e-15},
{2239291317986196,1.0146553831467086e-15},{2239135544468203,1.0203941464683124e-15},
{2238971532964979,1.0262405372613567e-15},{2238798683265269,1.0322001115486456e-15},
{2238616332424351,1.03827886235154e-15},{2238423746288095,1.044483267600047e-15},
{2238220109591890,1.0508203448355195e-15},{2238004514345216,1.057297713900989e-15},
{2237775946143212,1.06392366906768e-15},{2237533267957822,1.0707072623632994e-15},
{2237275200846753,1.0776584002668106e-15},{2237000300869952,1.0847879564403425e-15},
{2236706931309099,1.0921079038149563e-15},{2236393229029147,1.0996314701785628e-15},
{2236057063479501,1.1073733224935752e-15},{2235695986373246,1.1153497865853155e-15},
{2235307169458859,1.1235791107110833e-15},{2234887326941578,1.1320817840164846e-15},
{2234432617919447,1.140880924258278e-15},{2233938522519765,1.1500027537839792e-15},
{2233399683022677,1.159477189144919e-15},{2232809697779198,1.169338578691096e-15},
{2232160850599817,1.17962663529558e-15},{2231443750584641,1.190387629928289e-15},
{2230646845562170,1.2016759392543819e-15},{2229755753817986,1.2135560818666897e-15},
{2228752329126533,1.2261054417450561e-15},{2227613325162504,1.2394179789163251e-15},
{2226308442121174,1.2536093926602567e-15},{2224797391720399,1.268824481425501e-15},
{2223025347823832,1.2852479319096109e-15},{2220915633329809,1.3031206634689985e-15},
{2218357446087030,1.3227655770195326e-15},{2215184158448668,1.3446300925011171e-15},
{2211132412537369,1.3693606835128518e-15},{2205758503851065,1.397943667277524e-15},
{2198248265654987,1.4319989869661328e-15},{2186916352102141,1.4744848603597596e-15},
{2167562552481814,1.5317872741611144e-15},{2125549880839716,1.6227698675312968e-15}}).
normal_fi(Indx) ->
element(Indx,
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1.2602859304985975e-03}).
|