%%
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 2000-2013. 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%
%%
%%
%% Verifying erlang:phash/2. And now also phash2/2, to some extent.
%% Test the hashing algorithm for integer numbers in 2 ways:
%% 1 Test that numbers in diferent sequences get sufficiently spread
%% in a "bit pattern" way (modulo 256 etc).
%% 2 Test that numbers are correctly hashed compared to a reference implementation,
%% regardless of their internal representation. The hashing algorithm should never
%% change.
%% The hashing of other datatypes is tested with a few samples, so that we are sure
%% it does not change across versions.
%% Also tests that the limit can be between 0 and 16#FFFFFFFF.
%%
-module(hash_SUITE).
-export([basic_test/0,cmp_test/1,range_test/0,spread_test/1,
phash2_test/0, otp_5292_test/0,
otp_7127_test/0]).
-compile({nowarn_deprecated_function, {erlang,hash,2}}).
%%
%% Define to run outside of test server
%%
%-define(STANDALONE,1).
%%
%% Define for debug output
%%
%-define(debug,1).
-ifdef(STANDALONE).
-define(config(A,B),config(A,B)).
-export([config/2]).
-else.
-include_lib("common_test/include/ct.hrl").
-endif.
-ifdef(debug).
-ifdef(STANDALONE).
-define(line, erlang:display({?MODULE,?LINE}), ).
-endif.
-define(dbgformat(A,B),io:format(A,B)).
-else.
-ifdef(STANDALONE).
-define(line, noop, ).
-endif.
-define(dbgformat(A,B),noop).
-endif.
-ifdef(STANDALONE).
config(priv_dir,_) ->
".".
-else.
%% When run in test server.
-export([all/0, suite/0,
test_basic/1,test_cmp/1,test_range/1,test_spread/1,
test_phash2/1,otp_5292/1,bit_level_binaries/1,otp_7127/1,
test_hash_zero/1]).
suite() ->
[{ct_hooks,[ts_install_cth]},
{timetrap, {minutes, 10}}].
all() ->
[test_basic, test_cmp, test_range, test_spread,
test_phash2, otp_5292, bit_level_binaries, otp_7127,
test_hash_zero].
%% Tests basic functionality of erlang:phash and that the
%% hashes has not changed (neither hash nor phash)
test_basic(Config) when is_list(Config) ->
basic_test().
%% Compares integer hashes made by erlang:phash with those of a reference implementation
test_cmp(Config) when is_list(Config) ->
cmp_test(10000).
%% Tests ranges on erlang:phash from 1 to 2^32
test_range(Config) when is_list(Config) ->
range_test().
%% Tests that the hashes are spread ok
test_spread(Config) when is_list(Config) ->
spread_test(10).
%% Tests phash2
test_phash2(Config) when is_list(Config) ->
phash2_test().
%% Tests hash, phash and phash2 regarding integers.
otp_5292(Config) when is_list(Config) ->
otp_5292_test().
%% Test hashing bit-level binaries.
bit_level_binaries(Config) when is_list(Config) ->
bit_level_binaries_do().
%% Tests phash2/1.
otp_7127(Config) when is_list(Config) ->
otp_7127_test().
test_hash_zero(Config) when is_list(Config) ->
hash_zero_test().
-endif.
%%
%% Here are the real tests, they can be run without test_server,
%% define -DSTANDALONE when compiling.
%%
basic_test() ->
685556714 = erlang:phash({a,b,c},16#FFFFFFFF),
14468079 = erlang:hash({a,b,c},16#7FFFFFF),
37442646 = erlang:phash([a,b,c,{1,2,3},c:pid(0,2,3),
16#77777777777777],16#FFFFFFFF),
Comment = case erlang:hash([a,b,c,{1,2,3},c:pid(0,2,3),
16#77777777777777],16#7FFFFFF) of
102727602 ->
big = erlang:system_info(endian),
"Big endian machine";
105818829 ->
little = erlang:system_info(endian),
"Little endian machine"
end,
ExternalReference = <<131,114,0,3,100,0,13,110,111,110,111,100,101,64,
110,111,104,111,115,116,0,0,0,0,122,0,0,0,0,0,0,0,0>>,
1113403635 = erlang:phash(binary_to_term(ExternalReference),
16#FFFFFFFF),
123 = erlang:hash(binary_to_term(ExternalReference),
16#7FFFFFF),
ExternalFun = <<131,117,0,0,0,3,103,100,0,13,110,111,110,111,100,101,64,
110,111,104,111,115,116,0,0,0,38,0,0,0,0,0,100,0,8,101,
114,108,95,101,118,97,108,97,20,98,5,182,139,98,108,0,0,
0,3,104,2,100,0,1,66,109,0,0,0,33,131,114,0,3,100,0,13,
110,111,110,111,100,101,64,110,111,104,111,115,116,0,0,
0,0,122,0,0,0,0,0,0,0,0,104,2,100,0,1,76,107,0,33,131,
114,0,3,100,0,13,110,111,110,111,100,101,64,110,111,104,
111,115,116,0,0,0,0,122,0,0,0,0,0,0,0,0,104,2,100,0,1,82,
114,0,3,100,0,13,110,111,110,111,100,101,64,110,111,104,
111,115,116,0,0,0,0,122,0,0,0,0,0,0,0,0,106,108,0,0,0,1,
104,5,100,0,6,99,108,97,117,115,101,97,1,106,106,108,0,0,
0,1,104,3,100,0,7,105,110,116,101,103,101,114,97,1,97,1,
106,106,104,3,100,0,4,101,118,97,108,104,2,100,0,5,115,
104,101,108,108,100,0,10,108,111,99,97,108,95,102,117,
110,99,108,0,0,0,1,103,100,0,13,110,111,110,111,100,101,
64,110,111,104,111,115,116,0,0,0,22,0,0,0,0,0,106>>,
170987488 = erlang:phash(binary_to_term(ExternalFun),
16#FFFFFFFF),
124460689 = erlang:hash(binary_to_term(ExternalFun),
16#7FFFFFF),
case (catch erlang:phash(1,0)) of
{'EXIT',{badarg, _}} ->
{comment, Comment};
_ ->
exit(phash_accepted_zero_as_range)
end.
range_test() ->
F = fun(From,From,_FF) ->
ok;
(From,To,FF) ->
R = rand:uniform(16#FFFFFFFFFFFFFFFF),
X = erlang:phash(R, From),
Y = erlang:phash(R, 16#100000000) - 1,
Z = (Y rem From) + 1,
case X =:= Z of
true ->
FF(From*2,To,FF);
_ ->
exit({range_test_failed, hash_on, R, range, From})
end
end,
F(1,16#100000000,F).
spread_test(N) ->
test_fun(N,{erlang,phash},16#50000000000,fun(X) ->
X
end),
test_fun(N,{erlang,phash},0,fun(X) ->
X
end),
test_fun(N,{erlang,phash},16#123456789ABCDEF123456789ABCDEF,fun(X) ->
X
end),
test_fun(N,{erlang,phash},16#50000000000,fun(X) ->
integer_to_list(X)
end),
test_fun(N,{erlang,phash},16#50000000000,fun(X) ->
integer_to_bytelist(X,[])
end),
test_fun(N,{erlang,phash},16#50000000000,fun(X) ->
integer_to_binary_value(X)
end).
cmp_test(N) ->
do_cmp_hashes(N,8).
do_cmp_hashes(0,_) ->
ok;
do_cmp_hashes(N,Steps) ->
R0 = rand:uniform(1 bsl Steps - 1) + rand:uniform(16#FFFFFFFF),
R = case rand:uniform(2) of
1 ->
R0;
_ ->
-R0
end,
NSteps = case N rem 10 of
0 ->
case (Steps + 8) rem 1024 of
0 ->
8;
OK ->
OK
end;
_ ->
Steps
end,
X = erlang:phash(R,16#FFFFFFFF),
Y = make_hash(R,16#FFFFFFFF),
case X =:= Y of
true ->
do_cmp_hashes(N - 1, NSteps);
_ ->
exit({missmatch_on_input, R, phash, X, make_hash, Y})
end.
phash2_test() ->
Max = 1 bsl 32,
BPort = <<131,102,100,0,13,110,111,110,111,100,101,64,110,111,104,
111,115,116,0,0,0,1,0>>,
Port = binary_to_term(BPort),
BXPort = <<131,102,100,0,11,97,112,97,64,108,101,103,111,108,97,115,
0,0,0,24,3>>,
XPort = binary_to_term(BXPort),
BRef = <<131,114,0,3,100,0,13,110,111,110,111,100,101,64,110,111,104,
111,115,116,0,0,0,1,255,0,0,0,0,0,0,0,0>>,
Ref = binary_to_term(BRef),
BXRef = <<131,114,0,3,100,0,11,97,112,97,64,108,101,103,111,108,97,115,
2,0,0,0,155,0,0,0,0,0,0,0,0>>,
XRef = binary_to_term(BXRef),
BXPid = <<131,103,100,0,11,97,112,97,64,108,101,103,111,108,97,115,
0,0,0,36,0,0,0,0,1>>,
XPid = binary_to_term(BXPid),
%% X = f1(), Y = f2(), Z = f3(X, Y),
%% F1 = fun f1/0, % -> abc
B1 = <<131,112,0,0,0,66,0,215,206,77,69,249,50,170,17,129,47,21,98,
13,196,76,242,0,0,0,1,0,0,0,0,100,0,1,116,97,1,98,2,195,126,
58,103,100,0,13,110,111,110,111,100,101,64,110,111,104,111,
115,116,0,0,0,112,0,0,0,0,0>>,
F1 = binary_to_term(B1),
%% F2 = fun f2/0, % -> abd
B2 = <<131,112,0,0,0,66,0,215,206,77,69,249,50,170,17,129,47,21,98,
13,196,76,242,0,0,0,2,0,0,0,0,100,0,1,116,97,2,98,3,130,152,
185,103,100,0,13,110,111,110,111,100,101,64,110,111,104,111,
115,116,0,0,0,112,0,0,0,0,0>>,
F2 = binary_to_term(B2),
%% F3 = fun f3/2, % -> {abc, abd}
B3 = <<131,112,0,0,0,66,2,215,206,77,69,249,50,170,17,129,47,21,98,
13,196,76,242,0,0,0,3,0,0,0,0,100,0,1,116,97,3,98,7,168,160,
93,103,100,0,13,110,111,110,111,100,101,64,110,111,104,111,
115,116,0,0,0,112,0,0,0,0,0>>,
F3 = binary_to_term(B3),
%% F4 = fun () -> 123456789012345678901234567 end,
B4 = <<131,112,0,0,0,66,0,215,206,77,69,249,50,170,17,129,47,21,98,
13,196,76,242,0,0,0,4,0,0,0,0,100,0,1,116,97,4,98,2,230,21,
171,103,100,0,13,110,111,110,111,100,101,64,110,111,104,111,
115,116,0,0,0,112,0,0,0,0,0>>,
F4 = binary_to_term(B4),
%% F5 = fun() -> {X,Y,Z} end,
B5 = <<131,112,0,0,0,92,0,215,206,77,69,249,50,170,17,129,47,21,98,
13,196,76,242,0,0,0,5,0,0,0,3,100,0,1,116,97,5,98,0,99,101,
130,103,100,0,13,110,111,110,111,100,101,64,110,111,104,111,
115,116,0,0,0,112,0,0,0,0,0,100,0,3,97,98,99,100,0,3,97,98,
100,104,2,100,0,3,97,98,99,100,0,3,97,98,100>>,
F5 = binary_to_term(B5),
Chars = lists:seq(32,127),
NotAHeapBin = list_to_binary(lists:flatten(lists:duplicate(500,Chars))),
<<_:128,SubBin/binary>> = NotAHeapBin,
L = [%% nil
{[], 3468870702},
%% atom :( not very good ):
%% (cannot use block_hash due to compatibility issues...)
{abc,26499},
{abd,26500},
{'åäö', 62518},
%% 81 runes as an atom, 'ᚠᚡᚢᚣᚤᚥᚦᚧᚨᚩᚪᚫᚬᚭᚮᚯᚰᚱᚲᚳᚴᚵᚶᚷᚸᚹᚺᚻᚼᚽᚾᚿᛀᛁᛂᛃᛄᛅᛆᛇᛈᛉᛊᛋᛌᛍᛎᛏᛐᛑᛒᛓᛔᛕᛖᛗᛘᛙᛚᛛᛜᛝᛞᛟᛠᛡᛢᛣᛤᛥᛦᛧᛨᛩᛪ᛫᛬᛭ᛮᛯᛰ'
{erlang:binary_to_term(<<131, 118, 0, 243, (unicode:characters_to_binary(lists:seq(5792, 5872)))/binary >>), 241561024},
%% åäö dynamic
{erlang:binary_to_term(<<131, 118, 0, 6, 195, 165, 195, 164, 195, 182>>),62518},
%% the atom '゙゚゛゜ゝゞゟ゠ァアィイゥウェエォオカガキギクグケゲコゴサザシジスズ'
{erlang:binary_to_term(<<131, 118, 0, 102, (unicode:characters_to_binary(lists:seq(12441, 12542)))/binary>>), 246053818},
%% the atom, '😃'
{erlang:binary_to_term(<<131, 118, 0, 4, 240, 159, 152, 131>>), 1026307},
%% small
{0,3175731469},
{1, 539485162},
{-1, 1117813597},
{1 bsl 20, 1477815345},
{-(1 bsl 20), 3076904293},
%% bignum
{4294967296, 2108323275},
{-4294967296, 2586067094},
{981494972710656, 1622082818},
{-981494972710656, 3367191372},
{36893488147419103232, 2545846594},
{-36893488147419103232, 1649047068},
{1606938044258990275541962092341162602522202993782792835301376,
2573322433},
{-1606938044258990275541962092341162602522202993782792835301376,
2288753377},
%% binary
{<<>>, 147926629},
{<<0:8>>, 2914887855},
{<<0:32>>, 2014511533},
{<<"abc">>, 1306188027},
{<<"12345678901234567890">>, 3021061640},
{NotAHeapBin,2644086993},
{SubBin,3575839236},
%% unaligned sub binaries
{unaligned_sub_bin(<<>>), 147926629},
{unaligned_sub_bin(<<0:8>>), 2914887855},
{unaligned_sub_bin(<<0:32>>), 2014511533},
{unaligned_sub_bin(<<"abc">>), 1306188027},
{unaligned_sub_bin(<<"12345678901234567890">>), 3021061640},
{unaligned_sub_bin(NotAHeapBin),2644086993},
{unaligned_sub_bin(SubBin),3575839236},
%% bit-level binaries
{<<0:7>>, 1055790816},
{<<"abc",13:4>>, 670412287},
{<<5:3,"12345678901234567890">>, 289973273},
%% fun
{F1, 3826013332},
{F2, 126009152},
{F3, 3482452479},
{F4, 633704783},
{F5, 1241537408},
%% module fun
{fun lists:map/2, 840287883},
{fun lists:map/3, 2318478565},
{fun lists:filter/2, 635165125},
{fun lists:filter/3, 3824649396},
{fun xxx:map/2, 2630071865},
{fun xxx:map/3, 4237970519},
%% pid
{c:pid(0,0,0), 2858162279},
{c:pid(0,1,0), 2870503209},
{c:pid(0,2,0), 1707788908},
{XPid, 1290188489},
%% port
{Port,1954394636},
{XPort,274735},
%% ref
{Ref, 1675501484},
{XRef, 3845846926},
%% float
{0.0, 423528920},
{3.14, 3731709215},
{-3.14, 1827518724},
%% list
{[0.0], 167906877},
{[{}], 4050867804},
{[<<>>], 440873397},
{[[]], 499070068},
{[abc], 3112446404},
{[a,b,c], 1505666924},
{[a,b|c], 433753489},
{"abc", 519996486},
{"abc"++[1009], 290369864},
{"abc"++[1009]++"de", 4134369195},
{"1234567890123456", 963649519},
%% tuple
{{}, 221703996},
{{{}}, 2165044361},
{{<<>>}, 682464809},
{{0.0}, 688441152},
{{[]}, 1775079505},
{{abc}, 2032039329},
{{a,1,{},-3.14}, 1364396939},
{{c:pid(0,2,0)}, 686997880},
{{F4}, 2279632930},
{{a,<<>>}, 2724468891},
{{b,<<>>}, 2702508511}
],
SpecFun = fun(S) -> sofs:no_elements(S) > 1 end,
F = sofs:relation_to_family(sofs:converse(sofs:relation(L))),
D = sofs:to_external(sofs:family_specification(SpecFun, F)),
[] = D,
[] = [{E,H,H2} || {E,H} <- L, (H2 = erlang:phash2(E, Max)) =/= H],
ok.
-ifdef(FALSE).
f1() ->
abc.
f2() ->
abd.
f3(X, Y) ->
{X, Y}.
-endif.
otp_5292_test() ->
H = fun(E) -> [erlang:hash(E, 16#7FFFFFF),
erlang:hash(-E, 16#7FFFFFF)]
end,
S1 = md5([md5(hash_int(S, E, H)) || {Start, N, Sz} <- d(),
{S, E} <- int(Start, N, Sz)]),
PH = fun(E) -> [erlang:phash(E, 1 bsl 32),
erlang:phash(-E, 1 bsl 32),
erlang:phash2(E, 1 bsl 32),
erlang:phash2(-E, 1 bsl 32)]
end,
S2 = md5([md5(hash_int(S, E, PH)) || {Start, N, Sz} <- d(),
{S, E} <- int(Start, N, Sz)]),
Comment = case S1 of
<<4,248,208,156,200,131,7,1,173,13,239,173,112,81,16,174>> ->
big = erlang:system_info(endian),
"Big endian machine";
<<180,28,33,231,239,184,71,125,76,47,227,241,78,184,176,233>> ->
little = erlang:system_info(endian),
"Little endian machine"
end,
<<124,81,198,121,174,233,19,137,10,83,33,80,226,111,238,99>> = S2,
2 = erlang:hash(1, (1 bsl 27) -1),
{'EXIT', _} = (catch erlang:hash(1, (1 bsl 27))),
{comment, Comment}.
d() ->
[%% Start, NumOfIntervals, SizeOfInterval
{(1 bsl I)-100, 2, 100} || I <- lists:seq(1, 1000)].
int(Start, N, Sz) ->
{_, R} = lists:mapfoldl(fun(S, Acc) ->
{S + Sz, [{S,S+Sz-1} | Acc]}
end, [], lists:seq(Start, Start+(N-1)*Sz, Sz)),
lists:reverse(R).
hash_int(Start, End, F) ->
HL = lists:flatmap(fun(E) -> F(E) end, lists:seq(Start, End)),
{Start, End, md5(HL)}.
md5(T) ->
erlang:md5(term_to_binary(T)).
bit_level_binaries_do() ->
[3511317,7022633,14044578,28087749,56173436,112344123,90467083|_] =
bit_level_all_different(fun erlang:hash/2),
[3511317,7022633,14044578,28087749,56173436,112344123,90467083|_] =
bit_level_all_different(fun erlang:phash/2),
[102233154,19716,102133857,4532024,123369135,24565730,109558721|_] =
bit_level_all_different(fun erlang:phash2/2),
13233341 = test_hash_phash(<<42:7>>, 16#7FFFFFF),
79121243 = test_hash_phash(<<99:7>>, 16#7FFFFFF),
95517726 = test_hash_phash(<<16#378ABF73:31>>, 16#7FFFFFF),
64409098 = test_phash2(<<99:7>>, 16#7FFFFFF),
55555814 = test_phash2(<<123,19:2>>, 16#7FFFFFF),
83868582 = test_phash2(<<123,45,6:3>>, 16#7FFFFFF),
2123204 = test_phash2(<<123,45,7:3>>, 16#7FFFFFF),
ok.
bit_level_all_different(Hash) ->
{name,Name} = erlang:fun_info(Hash, name),
Seq = lists:seq(1, 32),
Hashes0 = [Hash(<<1:Sz>>, 16#7FFFFFF) || Sz <- Seq],
io:format("~p/2 ~p", [Name,Hashes0]),
Hashes0 = [Hash(unaligned_sub_bitstr(<<1:Sz>>), 16#7FFFFFF) || Sz <- Seq],
32 = length(lists:usort(Hashes0)),
Hashes1 = [Hash(<<(1 bsl (Sz-1)):Sz>>, 16#7FFFFFF) || Sz <- Seq],
io:format("~p/2 ~p", [Name,Hashes1]),
Hashes1 = [Hash(unaligned_sub_bitstr(<<(1 bsl (Sz-1)):Sz>>), 16#7FFFFFF) ||
Sz <- Seq],
32 = length(lists:usort(Hashes1)),
Hashes2 = [Hash(<<0:Sz>>, 16#7FFFFFF) || Sz <- Seq],
io:format("~p/2 ~p", [Name,Hashes2]),
Hashes2 = [Hash(unaligned_sub_bitstr(<<0:Sz>>), 16#7FFFFFF) || Sz <- Seq],
32 = length(lists:usort(Hashes2)),
Hashes1.
test_hash_phash(Bitstr, Rem) ->
Hash = erlang:hash(Bitstr, Rem),
Hash = erlang:phash(Bitstr, Rem),
Hash = erlang:hash(unaligned_sub_bitstr(Bitstr), Rem),
Hash = erlang:phash(unaligned_sub_bitstr(Bitstr), Rem).
test_phash2(Bitstr, Rem) ->
Hash = erlang:phash2(Bitstr, Rem),
Hash = erlang:phash2(unaligned_sub_bitstr(Bitstr), Rem).
otp_7127_test() ->
%% Used to return 2589127136.
38990304 = erlang:phash2(<<"Scott9">>),
ok.
hash_zero_test() ->
Zs = [0.0, -0.0, 0/-1, 0.0/-1, 0/-(1 bsl 65),
binary_to_term(<<131,70,0,0,0,0,0,0,0,0>>), %% +0.0
binary_to_term(<<131,70,128,0,0,0,0,0,0,0>>)], %% -0.0
ok = hash_zero_test(Zs,fun(T) -> erlang:phash2(T, 1 bsl 32) end),
ok = hash_zero_test(Zs,fun(T) -> erlang:phash(T, 1 bsl 32) end),
ok = hash_zero_test(Zs,fun(T) -> erlang:hash(T, (1 bsl 27) - 1) end),
ok.
hash_zero_test([Z|Zs],F) ->
hash_zero_test(Zs,Z,F(Z),F).
hash_zero_test([Z|Zs],Z0,V,F) ->
true = Z0 =:= Z, %% assert exact equal
Z0 = Z, %% assert matching
V = F(Z), %% assert hash
hash_zero_test(Zs,Z0,V,F);
hash_zero_test([],_,_,_) ->
ok.
%%
%% Reference implementation of integer hashing
%%
%%
%% These are primes just above 2^28 that will never be changed, they are also in
%% utils.c.
%%
-define(FN2,268439161).
-define(FN3,268435459).
-define(FN4,268436141).
make_hash(N,M) ->
Prime1 = ?FN2,
{Prime2, BL0} = to_bytes(N),
BL = pad(BL0),
(integer_hash(BL, Prime1, Prime2) rem M) + 1.
to_bytes(N) when N < 0 ->
{?FN4,to_bytes(-N,[])};
to_bytes(N) ->
{?FN3,to_bytes(N,[])}.
to_bytes(0,Acc) ->
Acc;
to_bytes(N,Acc) ->
to_bytes(N bsr 8, [N band 16#FF | Acc]).
pad([]) ->
[0,0,0,0];
pad(L) ->
case 4 - (length(L) rem 4) of
4 ->
L;
N ->
lists:duplicate(N,0) ++ L
end.
integer_hash(BL,P1,P2) ->
(do_ihash(0,lists:reverse(BL),P1) * P2) band 16#FFFFFFFF.
do_ihash(Hash,[],_) ->
Hash;
do_ihash(Hash, [H|T], P) ->
do_ihash((((Hash * P) band 16#FFFFFFFF) + H) band 16#FFFFFFFF, T, P).
%%
%% Utilities for the test of "spreading"
%%
-ifdef(debug).
hex(N) ->
hex(0,N,[]).
hex(X,0,Acc) when X >= 8 ->
[$0, $x | Acc];
hex(X,N,Acc) ->
hex(X+1,N bsr 4, [trans(N band 16#F) | Acc]).
trans(N) when N < 10 ->
N + $0;
trans(10) ->
$A;
trans(11) ->
$B;
trans(12) ->
$C;
trans(13) ->
$D;
trans(14) ->
$E;
trans(15) ->
$F.
-endif.
gen_keys(N, Template, BP,Fun) ->
Ratio = (1 bsl (BP * 8)),
Low = Template + Ratio,
High = Template + (N*Ratio),
?dbgformat("N = ~p, BP = ~p, Template = ~p, Low = ~s, High = ~s~n",
[hex(N),hex(BP),hex(Template),hex(Low),hex(High-1)]),
Fun(Template),
gen_keys2(Low, High,Ratio,Fun).
gen_keys2(High,High2,_,_) when High >= High2 ->
[];
gen_keys2(Low,High,R,Fun) ->
Fun(Low),
gen_keys2(Low + R,High,R,Fun).
test_fun(N,{HM,HF}, Template, Fun) ->
init_table(),
test_fun_1(0,1,N+1,{HM,HF},Template,Fun).
test_fun_1(_,To,To,_,_,_) ->
ok;
test_fun_1(A,X,To,Y,Z,W) when A > To ->
?dbgformat("~p:~p(~p,~p,~p,~p,~p,~p)~n",[?MODULE,test_fun_1,To,X,To,Y,Z,W]),
test_fun_1(0,X+1,To,Y,Z,W);
test_fun_1(Pos,Siz,To,{HM,HF},Template,Fun) when 1 bsl (Siz*8) =< 65536 ->
io:format("Byte: ~p, Size: ~p~n",[Pos,Siz]),
N = 1 bsl (Siz*8),
gen_keys(N,Template,Pos,fun (X) ->
P = HM:HF(Fun(X),N),
ets:insert(?MODULE,{P})
end
),
Hits = collect_hits(),
io:format(
"Hashing of ~p values spread over ~p buckets~n",
[N,Hits]),
case (N div Hits) > 2 of
true ->
exit({not_spread_enough, Hits, on, N});
_ ->
test_fun_1(Pos + Siz, Siz, To,{HM,HF},Template,Fun)
end;
test_fun_1(_,_,_,_,_,_) ->
ok.
init_table() ->
(catch ets:delete(?MODULE)),
ets:new(?MODULE,[ordered_set,named_table]).
collect_hits() ->
N = ets:info(?MODULE,size),
init_table(),
N.
integer_to_binary_value(N) ->
list_to_binary(lists:reverse(integer_to_bytelist(N,[]))).
integer_to_bytelist(0,Acc) ->
Acc;
integer_to_bytelist(N,Acc) ->
integer_to_bytelist(N bsr 8, [N band 16#FF | Acc]).
unaligned_sub_bin(Bin0) when is_binary(Bin0) ->
Bin1 = <<42:6,Bin0/binary,3:2>>,
Sz = size(Bin0),
<<42:6,Bin:Sz/binary,3:2>> = id(Bin1),
Bin.
unaligned_sub_bitstr(Bin0) when is_bitstring(Bin0) ->
Bin1 = <<(-1):4,Bin0/bits,(-1):64>>,
Bits = bit_size(Bin0),
<<_:4,Bin:Bits/bits,_:64>> = id(Bin1),
Bin.
id(I) -> I.