%%
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 2001-2018. 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
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%% 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.
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%%
-module(guard_SUITE).
-include_lib("common_test/include/ct.hrl").
-export([all/0, suite/0,groups/0,init_per_suite/1, end_per_suite/1,
init_per_group/2,end_per_group/2,
misc/1,const_cond/1,basic_not/1,complex_not/1,nested_nots/1,
semicolon/1,complex_semicolon/1,comma/1,
or_guard/1,more_or_guards/1,
complex_or_guards/1,and_guard/1,
xor_guard/1,more_xor_guards/1,
old_guard_tests/1,complex_guard/1,
build_in_guard/1,gbif/1,
t_is_boolean/1,is_function_2/1,
tricky/1,rel_ops/1,rel_op_combinations/1,literal_type_tests/1,
basic_andalso_orelse/1,traverse_dcd/1,
check_qlc_hrl/1,andalso_semi/1,t_tuple_size/1,binary_part/1,
bad_constants/1,bad_guards/1,
guard_in_catch/1,beam_bool_SUITE/1,
repeated_type_tests/1]).
suite() -> [{ct_hooks,[ts_install_cth]}].
all() ->
[{group,p}].
groups() ->
[{p,[parallel],
[misc,const_cond,basic_not,complex_not,nested_nots,
semicolon,complex_semicolon,comma,or_guard,
more_or_guards,complex_or_guards,and_guard,xor_guard,
more_xor_guards,build_in_guard,
old_guard_tests,complex_guard,gbif,
t_is_boolean,is_function_2,tricky,
rel_ops,rel_op_combinations,
literal_type_tests,basic_andalso_orelse,traverse_dcd,
check_qlc_hrl,andalso_semi,t_tuple_size,binary_part,
bad_constants,bad_guards,guard_in_catch,beam_bool_SUITE,
repeated_type_tests]}].
init_per_suite(Config) ->
test_lib:recompile(?MODULE),
Config.
end_per_suite(_Config) ->
ok.
init_per_group(_GroupName, Config) ->
Config.
end_per_group(_GroupName, Config) ->
Config.
misc(Config) when is_list(Config) ->
42 = case id(42) of
X when -X -> ok;
X -> X
end,
{a,b,c} = misc_1([{{a,b,c}},{[4]},{[3]},{-2}]),
none = misc_1([{{a,b,c}},{[4]},{[3]},{-3}]),
none = misc_1([{{a,b,c}},{[4]},{[7]},{-2}]),
none = misc_1([{{a,b,c}},{[4]},{[3]},{[1,2,3]}]),
{ok,buf,<<>>} = get_data({o,true,raw}, 0, buf),
{ok,buf,<<>>} = get_data({o,true,raw}, 42, buf),
{ok,buf,<<>>} = get_data({o,false,raw}, 0, buf),
error = get_data({o,false,raw}, 42, buf),
{ok,buf,<<>>} = get_data({o,true,0}, 0, buf),
{ok,buf,<<>>} = get_data({o,true,0}, 42, buf),
{ok,buf,<<>>} = get_data({o,false,0}, 0, buf),
error = get_data({o,false,0}, 42, buf),
relief = misc_2(0),
error = misc_2(1),
error = misc_2(true),
if
is_integer(Config) =/= true ->
ok
end,
true = misc_3(1, 0),
true = misc_3(0, 0),
false = misc_3(0, 2),
%% Abuse of boolean values.
Zero = id(0),
One = id(1),
ok = if (Zero == 0) > false -> ok end,
ok = if (Zero == 0) =:= (One == 1) -> ok end,
ok = if (Zero == 0) =:= (One == 1) -> ok end,
ok = if is_atom(Zero > One) -> ok end,
error = if abs(Zero > One) -> ok; true -> error end,
ok = if is_integer(Zero) >= is_integer(One) -> ok end,
ok.
misc_1([{W},{X},{Y},{Z}]) ->
if
X > Y andalso abs(Z) =:= 2 ->
id(W);
true ->
none
end.
misc_2(0) -> relief;
misc_2(Adapter = 1) when Adapter -> franklin;
misc_2(_) -> error.
misc_3(LenUp, LenDw) ->
if
%% Cover handling of #k_alt{}.
LenUp >= 1 orelse ((LenDw >= 2) xor true) -> true;
true -> false
end.
get_data({o,Active,Raw}, BytesToRead, Buffer)
when Raw =:= raw; Raw =:= 0 ->
if
Active =/= false orelse BytesToRead =:= 0 ->
{ok,Buffer,<<>>};
true ->
error
end.
const_cond(Config) when is_list(Config) ->
ok = const_cond({}, 0),
ok = const_cond({a}, 1),
error = const_cond({a,b}, 3),
error = const_cond({a}, 0),
error = const_cond({a,b}, 1),
ok.
const_cond(T, Sz) ->
case T of
_X when false -> never;
_X when is_tuple(T), eq == eq, tuple_size(T) == Sz -> ok;
_X when is_tuple(T), eq == leq, tuple_size(T) =< Sz -> ok;
_X -> error
end.
basic_not(Config) when is_list(Config) ->
True = id(true),
False = id(false),
Glurf = id(glurf),
A = id(5),
B = id(37.5),
C = id(-1),
D = id(5),
ATuple = {False,True,Glurf},
check(fun() -> if not false -> ok; true -> error end end, ok),
check(fun() -> if not true -> ok; true -> error end end, error),
check(fun() -> if not False -> ok; true -> error end end, ok),
check(fun() -> if not True -> ok; true -> error end end, error),
check(fun() -> if A > B -> gt; A < B -> lt; A == B -> eq end end, lt),
check(fun() -> if A > C -> gt; A < C -> lt; A == C -> eq end end, gt),
check(fun() -> if A > D -> gt; A < D -> lt; A == D -> eq end end, eq),
check(fun() -> if not (7 > 453) -> le; not (7 < 453) -> ge;
not (7 == 453) -> ne; true -> eq end end, le),
check(fun() -> if not (7 > -8) -> le; not (7 < -8) -> ge;
not (7 == -8) -> ne; true -> eq end end, ge),
check(fun() -> if not (7 > 7) -> le; not (7 < 7) -> ge;
not (7 == 7) -> ne; true -> eq end end, le),
check(fun() -> if not (A > B) -> le; not (A < B) -> ge;
not (A == B) -> ne; true -> eq end end, le),
check(fun() -> if not (A > C) -> le; not (A < C) -> ge;
not (A == C) -> ne; true -> eq end end, ge),
check(fun() -> if not (A > D) -> le; not (A < D) -> ge;
not (A == D) -> ne; true -> eq end end, le),
check(fun() -> if not element(1, ATuple) -> ok; true -> error end end, ok),
check(fun() -> if not element(2, ATuple) -> ok; true -> error end end, error),
check(fun() -> if not element(3, ATuple) -> ok; true -> error end end, error),
check(fun() -> if not glurf -> ok; true -> error end end, error),
check(fun() -> if not Glurf -> ok; true -> error end end, error),
check(fun() -> if not (not true) -> broken end end, broken),
check(fun() -> if not (True xor True) -> ok end end, ok),
check(fun() -> if not (True xor False) -> ok;
true -> error end end, error),
ok.
complex_not(Config) when is_list(Config) ->
ATuple = id({false,true,gurka}),
check(fun() -> if not(element(1, ATuple)) -> ok; true -> error end end, ok),
check(fun() -> if not(element(2, ATuple)) -> ok; true -> error end end, error),
check(fun() -> if not(element(3, ATuple) == gurka) -> ok;
true -> error end end, error),
check(fun() -> if not(element(3, ATuple) =/= gurka) -> ok;
true -> error end end, ok),
check(fun() -> if {a,not(element(2, ATuple))} == {a,false} -> ok;
true -> error end end, ok),
check(fun() -> if {a,not(element(1, ATuple))} == {a,false} -> ok;
true -> error end end, error),
check(fun() -> if not(element(1, ATuple) or element(3, ATuple)) -> ok;
true -> error end end, error),
%% orelse
check(fun() -> if not(element(1, ATuple) orelse element(3, ATuple)) -> ok;
true -> error end end, error),
%% complex_not_1/4
ok = complex_not_1(1, 1, 1, a),
error = complex_not_1(1, 1, 1, []),
error = complex_not_1(1, 1, 3, a),
error = complex_not_1(1, 1, 3, []),
error = complex_not_1(1, 2, 1, a),
error = complex_not_1(1, 2, 1, []),
error = complex_not_1(1, 2, 3, a),
error = complex_not_1(1, 2, 3, []),
%% complex_not_2/4
ok = complex_not_2(1, 2, 0, x),
error = complex_not_2(1, 2, 0, []),
error = complex_not_2(1, 2, 3, x),
error = complex_not_2(1, 2, 3, []),
error = complex_not_2(1, 1, 0, x),
error = complex_not_2(1, 1, 0, []),
error = complex_not_2(1, 1, 3, x),
error = complex_not_2(1, 1, 3, []),
ok.
complex_not_1(A, B, C, D) ->
Res = complex_not_1a(A, B, C, D),
Res = complex_not_1b(A, B, C, D).
complex_not_1a(A, B, C, D)
when (not (A < B)) andalso (not (B < C)) andalso (not is_list(D)) ->
ok;
complex_not_1a(_, _, _, _) ->
error.
complex_not_1b(A, B, C, D)
when (not (A < B)) and (not (B < C)) and (not is_list(D)) ->
ok;
complex_not_1b(_, _, _, _) ->
error.
complex_not_2(A, B, C, D) ->
Res = complex_not_2a(A, B, C, D),
Res = complex_not_2b(A, B, C, D).
complex_not_2a(A, B, C, D)
when A < B andalso not (B < C) andalso not is_list(D) ->
ok;
complex_not_2a(_, _, _, _) ->
error.
complex_not_2b(A, B, C, D)
when A < B, not (B < C), not is_list(D) ->
ok;
complex_not_2b(_, _, _, _) ->
error.
nested_nots(Config) when is_list(Config) ->
true = nested_not_1(0, 0),
true = nested_not_1(0, 1),
true = nested_not_1(a, b),
true = nested_not_1(10, 0),
false = nested_not_1(z, a),
false = nested_not_1(3.4, {anything,goes}),
false = nested_not_1(3.4, atom),
true = nested_not_1(3.0, [list]),
true = nested_not_2(false, false, 42),
true = nested_not_2(false, true, 42),
true = nested_not_2(true, false, 42),
true = nested_not_2(true, true, 42),
true = nested_not_2(false, false, atom),
false = nested_not_2(false, true, atom),
false = nested_not_2(true, false, atom),
false = nested_not_2(true, true, atom),
ok.
nested_not_1(X, Y) ->
Res = nested_not_1a(X, Y),
Res = nested_not_1b(X, Y).
nested_not_1a(X, Y) when not (((X>Y) or not(is_atom(X))) and
(is_atom(Y) or (X==3.4))) ->
true;
nested_not_1a(_, _) ->
false.
nested_not_1b(X, Y) when not (((X>Y) orelse not(is_atom(X))) andalso
(is_atom(Y) orelse (X==3.4))) ->
true;
nested_not_1b(_, _) ->
false.
nested_not_2(X, Y, Z) ->
Res = nested_not_2a(X, Y, Z, true),
Res = nested_not_2b(X, Y, Z, true).
nested_not_2a(X, Y, Z, True)
when not(True and not((not(X) and not(Y)) or not(is_atom(Z)))) ->
true;
nested_not_2a(_, _, _, _) ->
false.
nested_not_2b(X, Y, Z, True)
when not(True andalso not((not(X) andalso not(Y)) orelse not(is_atom(Z)))) ->
true;
nested_not_2b(_, _, _, _) ->
false.
semicolon(Config) when is_list(Config) ->
%% True/false combined using ';' (literal atoms).
check(fun() -> if true; false -> ok end end, ok),
check(fun() -> if false; true -> ok end end, ok),
check(fun() -> if true; true -> ok end end, ok),
check(fun() -> if false; false -> ok; true -> error end end, error),
check(fun() ->
{'EXIT',{if_clause,_}} = (catch if false; false -> ok end),
exit
end, exit),
%% True/false combined used ';'.
True = id(true),
False = id(false),
check(fun() -> if True; False -> ok end end, ok),
check(fun() -> if False; True -> ok end end, ok),
check(fun() -> if True; True -> ok end end, ok),
check(fun() -> if False; False -> ok; true -> error end end, error),
check(fun() ->
{'EXIT',{if_clause,_}} = (catch if False; False -> ok end),
exit
end, exit),
%% Combine true/false with a non-boolean value.
Glurf = id(glurf),
check(fun() -> if True; Glurf -> ok end end, ok),
check(fun() -> if Glurf; True -> ok end end, ok),
check(fun() -> if Glurf; Glurf -> ok; true -> error end end, error),
check(fun() -> if False; Glurf -> ok; true -> error end end, error),
check(fun() -> if Glurf; False -> ok; true -> error end end, error),
check(fun() ->
{'EXIT',{if_clause,_}} = (catch if Glurf; Glurf -> ok end),
exit
end, exit),
%% Combine true/false with errors.
ATuple = id({false,true,gurka}),
check(fun() -> if True; element(42, ATuple) -> ok end end, ok),
check(fun() -> if element(42, ATuple); True -> ok end end, ok),
check(fun() -> if element(42, ATuple); element(42, ATuple) -> ok;
true -> error end end, error),
check(fun() -> if False; element(42, ATuple) -> ok;
true -> error end end, error),
check(fun() -> if element(42, ATuple);
False -> ok; true -> error end end, error),
check(fun() ->
{'EXIT',{if_clause,_}} =
(catch if element(42, ATuple);
element(42, ATuple) -> ok end),
exit
end, exit),
ok.
complex_semicolon(Config) when is_list(Config) ->
ok = csemi1(int, {blurf}),
ok = csemi1(string, {blurf}),
ok = csemi1(float, [a]),
error = csemi1(35, 42),
%% 2
ok = csemi2({}, {a,b,c}),
ok = csemi2({1,3.5}, {a,b,c}),
ok = csemi2(dum, {a,b,c}),
ok = csemi2({45,-19.3}, {}),
ok = csemi2({45,-19.3}, {dum}),
ok = csemi2({45,-19.3}, {dum,dum}),
error = csemi2({45}, {dum}),
error = csemi2([], {dum}),
error = csemi2({dum}, []),
error = csemi2([], []),
%% 3
csemi3(fun csemi3a/4),
csemi3(fun csemi3b/4),
csemi3(fun csemi3c/4),
%% 4
csemi4(fun csemi4a/4),
csemi4(fun csemi4b/4),
csemi4(fun csemi4c/4),
csemi4(fun csemi4d/4),
%% 4, 'orelse' instead of 'or'
csemi4_orelse(fun csemi4_orelse_a/4),
csemi4_orelse(fun csemi4_orelse_b/4),
csemi4_orelse(fun csemi4_orelse_c/4),
csemi4_orelse(fun csemi4_orelse_d/4),
%% 5
error = csemi5(0, 0),
ok = csemi5(5, 0),
ok = csemi5(4, -4),
ok = csemi5(10, -4),
%% 6
error = csemi6({a}, 0),
ok = csemi6({a,b}, 0),
ok = csemi6({}, 3),
ok = csemi6({a,b,c}, 3),
%% 7
error = csemi7(#{a=>1}, 1, 0),
error = csemi7(<<>>, 1, 0),
ok = csemi7(#{a=>1}, 3, 0),
ok = csemi7(#{a=>1}, 0, 3),
ok = csemi7(#{a=>1}, 3, 3),
ok = csemi7(#{a=>1, b=>3}, 0, 0),
%% 8: Make sure that funs cannot be copied into guards.
ok = csemi8(true),
error = csemi8(false),
error = csemi8(42),
ok.
csemi1(Type, Val) when is_list(Val), Type == float;
Type == int; Type == string -> ok;
csemi1(_, _) -> error.
csemi2(A, B) when tuple_size(A) > 1; tuple_size(B) > 2 -> ok;
csemi2(_, _) -> error.
csemi3(Csemi3) ->
ok = Csemi3({}, {a,b,c}, [0], [0]),
ok = Csemi3({1,3.5}, {a,b,c}, -1, -1),
ok = Csemi3(dum, {a,b,c}, 0.0, 0.0),
ok = Csemi3(dum, {c}, b, a),
ok = Csemi3(dum, <<1,2,3>>, 0.0, 0.0),
ok = Csemi3(<<3.5/float>>, {a,b,c}, -1, -1),
ok = Csemi3({45,-19.3}, {}, [], []),
ok = Csemi3({45,-19.3}, {dum}, 42, 42),
ok = Csemi3({45,-19.3}, {dum,dum}, 33, 33),
ok = Csemi3({45}, {dum}, 1.0, 0),
ok = Csemi3([a], {dum}, 1.0, 0),
ok = Csemi3({dum}, [], 1.0, 0),
ok = Csemi3([], [], 1.0, 0),
ok = Csemi3(blurf, {dum}, 1.0, 0),
ok = Csemi3({a}, blurf, 1.0, 0),
ok = Csemi3([a], [dum], 1.0, 0),
ok = Csemi3({dum}, [], 1.0, 0),
ok = Csemi3([], [], 1.0, 0),
error = Csemi3({45}, {dum}, 0, 0),
error = Csemi3([a], {dum}, 0, 0),
error = Csemi3({dum}, [], 0, 0),
error = Csemi3([], [], 0, 0),
ok.
csemi3a(A, B, X, Y) when X > Y; size(A) > 1; size(B) > 2 -> ok;
csemi3a(_, _, _, _) -> error.
csemi3b(A, B, X, Y) when size(A) > 1; X > Y; size(B) > 2 -> ok;
csemi3b(_, _, _, _) -> error.
csemi3c(A, B, X, Y) when size(A) > 1; size(B) > 2; X > Y -> ok;
csemi3c(_, _, _, _) -> error.
csemi4(Test) ->
ok = Test({a,b}, 2, {c,d}, 2),
ok = Test({1,2,3}, 0, [], 0),
ok = Test({}, 2, blurf, 0),
ok = Test({}, 2, {1}, 2),
error = Test([], 4, {}, 0),
error = Test({}, 0, [a,b], 4),
error = Test({}, 0, [a,b], 0),
error = Test([], 0, {}, 0),
error = Test({}, 0, {}, 0),
ok.
csemi4a(A, X, B, Y) when (tuple_size(A) > 1) or (X > 1);
(tuple_size(B) > 1) or (Y > 1) -> ok;
csemi4a(_, _, _, _) -> error.
csemi4b(A, X, B, Y) when (X > 1) or (tuple_size(A) > 1);
(tuple_size(B) > 1) or (Y > 1) -> ok;
csemi4b(_, _, _, _) -> error.
csemi4c(A, X, B, Y) when (tuple_size(A) > 1) or (X > 1);
(Y > 1) or (tuple_size(B) > 1) -> ok;
csemi4c(_, _, _, _) -> error.
csemi4d(A, X, B, Y) when (X > 1) or (tuple_size(A) > 1);
(Y > 1) or (tuple_size(B) > 1) -> ok;
csemi4d(_, _, _, _) -> error.
csemi4_orelse(Test) ->
ok = Test({a,b}, 2, {c,d}, 2),
ok = Test({1,2,3}, 0, [], 0),
ok = Test({}, 2, blurf, 0),
ok = Test({}, 2, {1}, 2),
error = Test([], 1, {}, 0),
ok.
csemi4_orelse_a(A, X, B, Y) when (tuple_size(A) > 1) orelse (X > 1);
(tuple_size(B) > 1) orelse (Y > 1) -> ok;
csemi4_orelse_a(_, _, _, _) -> error.
csemi4_orelse_b(A, X, B, Y) when (X > 1) orelse (tuple_size(A) > 1);
(tuple_size(B) > 1) orelse (Y > 1) -> ok;
csemi4_orelse_b(_, _, _, _) -> error.
csemi4_orelse_c(A, X, B, Y) when (tuple_size(A) > 1) orelse (X > 1);
(Y > 1) orelse (tuple_size(B) > 1) -> ok;
csemi4_orelse_c(_, _, _, _) -> error.
csemi4_orelse_d(A, X, B, Y) when (X > 1) or (tuple_size(A) > 1);
(Y > 1) or (tuple_size(B) > 1) -> ok;
csemi4_orelse_d(_, _, _, _) -> error.
csemi5(A, B) when hd([A+B]) > 1; abs(B) > 2 -> ok;
csemi5(_, _) -> error.
csemi6(A, B) when hd([tuple_size(A)]) > 1; abs(B) > 2 -> ok;
csemi6(_, _) -> error.
csemi7(A, B, C) when A#{a:=B} > #{a=>1}; abs(C) > 2 -> ok;
csemi7(_, _, _) -> error.
csemi8(Together) ->
case fun csemi8/1 of
Typically when Together; Typically, Together -> ok;
_ -> error
end.
comma(Config) when is_list(Config) ->
%% ',' combinations of literal true/false.
check(fun() -> if true, false -> ok; true -> error end end, error),
check(fun() -> if false, true -> ok; true -> error end end, error),
check(fun() -> if true, true -> ok end end, ok),
check(fun() -> if false, false -> ok; true -> error end end, error),
check(fun() ->
{'EXIT',{if_clause,_}} =
(catch if true, false -> ok;
false, true -> ok;
false, false -> ok
end),
exit
end, exit),
%% ',' combinations of true/false in variables.
True = id(true),
False = id(false),
check(fun() -> if True, False -> ok; true -> error end end, error),
check(fun() -> if False, True -> ok; true -> error end end, error),
check(fun() -> if True, True -> ok end end, ok),
check(fun() -> if False, False -> ok; true -> error end end, error),
check(fun() ->
{'EXIT',{if_clause,_}} =
(catch if True, False -> ok;
False, True -> ok;
False, False -> ok
end),
exit
end, exit),
%% ',' combinations of true/false, and non-boolean in variables.
Glurf = id(glurf),
check(fun() -> if True, Glurf -> ok; true -> error end end, error),
check(fun() -> if Glurf, True -> ok; true -> error end end, error),
check(fun() -> if True, True -> ok end end, ok),
check(fun() -> if Glurf, Glurf -> ok; true -> error end end, error),
check(fun() ->
{'EXIT',{if_clause,_}} =
(catch if True, Glurf -> ok;
Glurf, True -> ok;
Glurf, Glurf -> ok
end),
exit
end, exit),
%% ',' combinations of true/false with errors.
ATuple = id({a,b,c}),
check(fun() -> if True, element(42, ATuple) -> ok;
true -> error end end, error),
check(fun() -> if element(42, ATuple), True -> ok;
true -> error end end, error),
check(fun() -> if True, True -> ok end end, ok),
check(fun() -> if element(42, ATuple), element(42, ATuple) -> ok;
true -> error end end, error),
check(fun() ->
{'EXIT',{if_clause,_}} =
(catch if True, element(42, ATuple) -> ok;
element(42, ATuple), True -> ok;
element(42, ATuple), element(42, ATuple) -> ok
end),
exit
end, exit),
ok.
or_guard(Config) when is_list(Config) ->
True = id(true),
False = id(false),
Glurf = id(glurf),
%% 'or' combinations of literal true/false.
check(fun() -> if true or false -> ok end end, ok),
check(fun() -> if false or true -> ok end end, ok),
check(fun() -> if true or true -> ok end end, ok),
check(fun() -> if false or false -> ok; true -> error end end, error),
check(fun() -> if glurf or true -> ok; true -> error end end, error),
check(fun() -> if true or glurf -> ok; true -> error end end, error),
check(fun() -> if glurf or glurf -> ok; true -> error end end, error),
check(fun() ->
{'EXIT',{if_clause,_}} = (catch if false or false -> ok end),
exit
end, exit),
%% 'or' combinations using variables containing true/false.
check(fun() -> if True or False -> ok end end, ok),
check(fun() -> if False or True -> ok end end, ok),
check(fun() -> if True or True -> ok end end, ok),
check(fun() -> if False or False -> ok; true -> error end end, error),
check(fun() -> if True or Glurf -> ok; true -> error end end, error),
check(fun() -> if Glurf or True -> ok; true -> error end end, error),
check(fun() -> if Glurf or Glurf -> ok; true -> error end end, error),
check(fun() ->
{'EXIT',{if_clause,_}} = (catch if False or False -> ok end),
exit
end, exit),
ok.
more_or_guards(Config) when is_list(Config) ->
True = id(true),
False = id(false),
ATuple = id({false,true,gurka}),
check(fun() ->
if element(42, ATuple) or False -> ok;
true -> error end
end, error),
check(fun() ->
if False or element(42, ATuple) -> ok;
true -> error end
end, error),
check(fun() ->
if element(18, ATuple) or element(42, ATuple) -> ok;
true -> error end
end, error),
check(fun() ->
if True or element(42, ATuple) -> ok;
true -> error end
end, error),
check(fun() ->
if element(42, ATuple) or True -> ok;
true -> error end
end, error),
check(fun() ->
if element(1, ATuple) or element(42, ATuple) or True -> ok;
true -> error end
end, error),
check(fun() ->
if element(1, ATuple) or True or element(42, ATuple) -> ok;
true -> error end
end, error),
check(fun() ->
if
(<<False:8>> == <<0>>) or element(2, ATuple) -> ok;
true -> error end
end, error),
check(fun() ->
if
element(2, ATuple) or (<<True:8>> == <<1>>) -> ok;
true -> error end
end, error),
check(fun() ->
if element(2, ATuple) or element(42, ATuple) -> ok;
true -> error end
end, error),
check(fun() ->
if
element(1, ATuple) or
element(2, ATuple) or
element(19, ATuple) -> ok;
true -> error end
end, error),
ok.
complex_or_guards(Config) when is_list(Config) ->
%% complex_or_1/2
ok = complex_or_1({a,b,c,d}, {1,2,3}),
ok = complex_or_1({a,b,c,d}, {1}),
ok = complex_or_1({a}, {1,2,3}),
error = complex_or_1({a}, {1}),
error = complex_or_1(1, 2),
error = complex_or_1([], {a,b,c,d}),
error = complex_or_1({a,b,c,d}, []),
%% complex_or_2/1
ok = complex_or_2({true,{}}),
ok = complex_or_2({false,{a}}),
ok = complex_or_2({false,{a,b,c}}),
ok = complex_or_2({true,{a,b,c,d}}),
error = complex_or_2({blurf,{a,b,c}}),
error = complex_or_2({true}),
error = complex_or_2({true,no_tuple}),
error = complex_or_2({true,[]}),
%% complex_or_3/2
ok = complex_or_3({true}, {}),
ok = complex_or_3({false}, {a}),
ok = complex_or_3({false}, {a,b,c}),
ok = complex_or_3({true}, {a,b,c,d}),
ok = complex_or_3({false}, <<1,2,3>>),
ok = complex_or_3({true}, <<1,2,3,4>>),
error = complex_or_3(blurf, {a,b,c}),
error = complex_or_3({false}, <<1,2,3,4>>),
error = complex_or_3([], <<1,2>>),
error = complex_or_3({true}, 45),
error = complex_or_3(<<>>, <<>>),
%% complex_or_4/2
ok = complex_or_4(<<1,2,3>>, {true}),
ok = complex_or_4(<<1,2,3>>, {false}),
ok = complex_or_4(<<1,2,3>>, {true}),
ok = complex_or_4({1,2,3}, {true}),
error = complex_or_4({1,2,3,4}, {false}),
error = complex_or_4(<<1,2,3,4>>, []),
error = complex_or_4([], {true}),
%% complex_or_5/2
ok = complex_or_5(<<1>>, {false}),
ok = complex_or_5(<<1,2,3>>, {true}),
ok = complex_or_5(<<1,2,3,4>>, {false}),
ok = complex_or_5({1,2,3}, {false}),
ok = complex_or_5({1,2,3,4}, {false}),
error = complex_or_5(blurf, {false}),
error = complex_or_5(<<1>>, klarf),
error = complex_or_5(blurf, klarf),
%% complex_or_6/2
ok = complex_or_6({true,true}, {1,2,3,4}),
ok = complex_or_6({true,true}, <<1,2,3,4>>),
ok = complex_or_6({false,false}, <<1,2,3,4>>),
ok = complex_or_6({false,true}, <<1>>),
ok = complex_or_6({true,false}, {1}),
ok = complex_or_6({true,true}, {1}),
error = complex_or_6({false,false}, {1}),
error = complex_or_6({true}, {1,2,3,4}),
error = complex_or_6({}, {1,2,3,4}),
error = complex_or_6([], {1,2,3,4}),
error = complex_or_6([], {1,2,3,4}),
error = complex_or_6({true,false}, klurf),
ok.
complex_or_1(A, B) ->
if
((3 < tuple_size(A)) and (tuple_size(A) < 9)) or
((2 < tuple_size(B)) and (tuple_size(B) < 7)) -> ok;
true -> error
end.
complex_or_2(Tuple) ->
if
element(1, Tuple) or not (tuple_size(element(2, Tuple)) > 3) -> ok;
true -> error
end.
complex_or_3(A, B) ->
if
not (size(B) > 3) or element(1, A) -> ok;
true -> error
end.
complex_or_4(A, B) ->
if
not (is_tuple(A) and (size(A) > 3)) or element(1, B) -> ok;
true -> error
end.
complex_or_5(A, B) ->
if
not (is_tuple(A) or (size(A) > 3)) or not element(1, B) -> ok;
true -> error
end.
complex_or_6(A, B) ->
if
not (not element(1, A) and not element(2, A)) or
not (not (size(B) > 3)) -> ok;
true -> error
end.
and_guard(Config) when is_list(Config) ->
%% 'and' combinations of literal true/false.
check(fun() -> if true and false -> ok; true -> error end end, error),
check(fun() -> if false and true -> ok; true -> error end end, error),
check(fun() -> if true and true -> ok end end, ok),
check(fun() -> if false and false -> ok; true -> error end end, error),
check(fun() -> if glurf and true -> ok; true -> error end end, error),
check(fun() -> if true and glurf -> ok; true -> error end end, error),
check(fun() -> if glurf and glurf -> ok; true -> error end end, error),
check(fun() ->
{'EXIT',{if_clause,_}} =
(catch if true and false -> ok;
false and true -> ok;
false and false -> ok
end),
exit
end, exit),
%% 'and' combinations of true/false in variables.
True = id(true),
False = id(false),
check(fun() -> if True and False -> ok; true -> error end end, error),
check(fun() -> if False and True -> ok; true -> error end end, error),
check(fun() -> if True and True -> ok end end, ok),
check(fun() -> if False and False -> ok; true -> error end end, error),
check(fun() ->
{'EXIT',{if_clause,_}} =
(catch if True and False -> ok;
False and True -> ok;
False and False -> ok
end),
exit
end, exit),
%% 'and' combinations of true/false and a non-boolean in variables.
Glurf = id(glurf),
check(fun() -> if True and Glurf -> ok; true -> error end end, error),
check(fun() -> if Glurf and True -> ok; true -> error end end, error),
check(fun() -> if True and True -> ok end end, ok),
check(fun() -> if Glurf and Glurf -> ok; true -> error end end, error),
check(fun() ->
{'EXIT',{if_clause,_}} =
(catch if True and Glurf -> ok;
Glurf and True -> ok;
Glurf and Glurf -> ok
end),
exit
end, exit),
%% 'and' combinations of true/false with errors.
ATuple = id({a,b,c}),
check(fun() -> if True and element(42, ATuple) -> ok;
true -> error end end, error),
check(fun() -> if element(42, ATuple) and True -> ok;
true -> error end end, error),
check(fun() -> if True and True -> ok end end, ok),
check(fun() -> if element(42, ATuple) and element(42, ATuple) -> ok;
true -> error end end, error),
check(fun() ->
{'EXIT',{if_clause,_}} =
(catch if True and element(42, ATuple) -> ok;
element(42, ATuple) and True -> ok;
element(42, ATuple) and element(42, ATuple) -> ok
end),
exit
end, exit),
ok = relprod({'Set',a,b}, {'Set',a,b}),
ok = and_same_var(42),
{'EXIT',{if_clause,_}} = (catch and_same_var(x)),
ok.
and_same_var(V) ->
B = is_integer(V),
if
B or B -> ok
end.
relprod(R1, R2) when (erlang:size(R1) =:= 3) and (erlang:element(1,R1) =:= 'Set'), (erlang:size(R2) =:= 3) and (erlang:element(1,R2) =:= 'Set') ->
ok.
xor_guard(Config) when is_list(Config) ->
%% 'xor' combinations of literal true/false.
check(fun() -> if true xor false -> ok end end, ok),
check(fun() -> if false xor true -> ok end end, ok),
check(fun() -> if true xor true -> ok; true -> error end end, error),
check(fun() -> if false xor false -> ok; true -> error end end, error),
check(fun() ->
{'EXIT',{if_clause,_}} = (catch if false xor false -> ok end),
exit
end, exit),
check(fun() ->
{'EXIT',{if_clause,_}} = (catch if true xor true -> ok end),
exit
end, exit),
%% 'xor' combinations using variables containing true/false.
True = id(true),
False = id(false),
check(fun() -> if True xor False -> ok end end, ok),
check(fun() -> if False xor True -> ok end end, ok),
check(fun() -> if True xor True -> ok; true -> error end end, error),
check(fun() -> if False xor False -> ok; true -> error end end, error),
check(fun() ->
{'EXIT',{if_clause,_}} = (catch if False xor False -> ok end),
exit
end, exit),
check(fun() ->
{'EXIT',{if_clause,_}} = (catch if True xor True -> ok end),
exit
end, exit),
ok.
more_xor_guards(Config) when is_list(Config) ->
True = id(true),
False = id(false),
ATuple = id({false,true,gurka}),
check(fun() ->
if element(42, ATuple) xor False -> ok;
true -> error end
end, error),
check(fun() ->
if False xor element(42, ATuple) xor False -> ok;
true -> error end
end, error),
check(fun() ->
if element(18, ATuple) xor element(42, ATuple) -> ok;
true -> error end
end, error),
check(fun() ->
if True xor element(42, ATuple) -> ok;
true -> error end
end, error),
check(fun() ->
if element(42, ATuple) xor True -> ok;
true -> error end
end, error),
ok.
build_in_guard(Config) when is_list(Config) ->
SubBin = <<5.0/float>>,
B = <<1,SubBin/binary,3.5/float>>,
if
B =:= <<1,SubBin/binary,3.5/float>> -> ok
end.
old_guard_tests(Config) when list(Config) ->
%% Check that all the old guard tests are still recognized.
list = og(Config),
atom = og(an_atom),
binary = og(<<1,2>>),
float = og(3.14),
integer = og(43),
a_function = og(fun() -> ok end),
pid = og(self()),
reference = og(make_ref()),
tuple = og({}),
number = on(45.333),
number = on(-19),
ok.
og(V) when atom(V) -> atom;
og(V) when binary(V) -> binary;
og(V) when float(V) -> float;
og(V) when integer(V) -> integer;
og(V) when function(V) -> a_function;
og(V) when list(V) -> list;
og(V) when pid(V) -> pid;
og(V) when port(V) -> port;
og(V) when reference(V) -> reference;
og(V) when tuple(V) -> tuple;
og(_) -> what.
on(V) when number(V) -> number;
on(_) -> not_number.
complex_guard(_Config) ->
_ = [true = do_complex_guard(X, Y, Z) ||
X <- [4,5], Y <- [4,5], Z <- [4,5]],
_ = [true = do_complex_guard(X, Y, Z) ||
X <- [1,2,3], Y <- [1,2,3], Z <- [1,2,3]],
_ = [catch do_complex_guard(X, Y, Z) ||
X <- [1,2,3,4,5], Y <- [0,6], Z <- [1,2,3,4,5]],
ok.
do_complex_guard(X1, Y1, Z1) ->
if
((X1 =:= 4) or (X1 =:= 5)) and
((Y1 =:= 4) or (Y1 =:= 5)) and
((Z1 =:= 4) or (Z1 =:= 5)) or
((X1 =:= 1) or (X1 =:= 2) or (X1 =:= 3)) and
((Y1 =:= 1) or (Y1 =:= 2) or (Y1 =:= 3)) and
((Z1 =:= 1) or (Z1 =:= 2) or (Z1 =:= 3)) ->
true
end.
gbif(Config) when is_list(Config) ->
error = gbif_1(1, {false,true}),
ok = gbif_1(2, {false,true}),
ok.
gbif_1(P, T) when element(P, T) -> ok;
gbif_1(_, _) -> error.
t_is_boolean(Config) when is_list(Config) ->
true = is_boolean(true),
true = is_boolean(false),
true = is_boolean(id(true)),
true = is_boolean(id(false)),
false = is_boolean(glurf),
false = is_boolean(id(glurf)),
false = is_boolean([]),
false = is_boolean(id([])),
false = is_boolean(42),
false = is_boolean(id(-42)),
false = is_boolean(math:pi()),
false = is_boolean(384793478934378924978439789873478934897),
false = is_boolean(id(self())),
false = is_boolean(id({x,y,z})),
false = is_boolean(id([a,b,c])),
false = is_boolean(id(make_ref())),
false = is_boolean(id(<<1,2,3>>)),
false = is_boolean({id(x),y,z}),
false = is_boolean([id(a),b,c]),
ok = bool(true),
ok = bool(false),
ok = bool(id(true)),
ok = bool(id(false)),
error = bool(glurf),
error = bool(id(glurf)),
error = bool([]),
error = bool(id([])),
error = bool(42),
error = bool(id(-42)),
error = bool(math:pi()),
error = bool(384793478934378924978439789873478934897),
error = bool(id(self())),
error = bool(id({x,y,z})),
error = bool(id([a,b,c])),
error = bool(id(make_ref())),
error = bool(id(<<1,2,3>>)),
true = my_is_bool(true),
true = my_is_bool(false),
false = my_is_bool([]),
false = my_is_bool([1,2,3,4]),
false = my_is_bool({a,b,c}),
ok.
bool(X) when is_boolean(X) -> ok;
bool(_) -> error.
my_is_bool(V) ->
Res = my_is_bool_a(V),
Res = my_is_bool_b(V).
my_is_bool_a(V) ->
case V of
true -> true;
false -> true;
_ -> false
end.
my_is_bool_b(V) ->
case V of
false -> true;
true -> true;
_ -> false
end.
is_function_2(Config) when is_list(Config) ->
true = is_function(id(fun ?MODULE:all/1), 1),
true = is_function(id(fun() -> ok end), 0),
false = is_function(id(fun ?MODULE:all/1), 0),
false = is_function(id(fun() -> ok end), 1),
{'EXIT',{badarg,_}} =
(catch is_function(id(fun() -> ok end), -1) orelse error),
{'EXIT',{badarg,_}} =
(catch is_function(id(fun() -> ok end), '') orelse error),
F = fun(_) -> ok end,
if
is_function(F, 1) -> ok
end.
tricky(Config) when is_list(Config) ->
not_ok = tricky_1(1, 2),
not_ok = tricky_1(1, blurf),
not_ok = tricky_1(foo, 2),
not_ok = tricky_1(a, b),
error = tricky_2(0.5),
error = tricky_2(a),
error = tricky_2({a,b,c}),
false = rb(100000, [1], 42),
true = rb(100000, [], 42),
true = rb(555, [a,b,c], 19),
error = tricky_3(42),
error = tricky_3(42.0),
error = tricky_3(<<>>),
error = tricky_3(#{}),
error = tricky_3({a,b}),
ok.
tricky_1(X, Y) when abs((X == 1) or (Y == 2)) -> ok;
tricky_1(_, _) -> not_ok.
tricky_2(X) when float(X) or float(X) -> ok;
tricky_2(_) -> error.
tricky_3(X)
when abs(X) or bit_size(X) or byte_size(X) or ceil(X) or
float(X) or floor(X) or length(X) or
map_size(X) or node() or node(X) or round(X) or
self() or size(X) or tl(X) or trunc(X) or tuple_size(X) ->
ok;
tricky_3(_) ->
error.
%% From dets_v9:read_buckets/11, simplified.
rb(Size, ToRead, SoFar) when SoFar + Size < 81920; ToRead == [] -> true;
rb(_, _, _) -> false.
-define(T(Op,A,B),
ok = if A Op B -> ok; true -> error end,
ok = if not (A Op B) -> error; true -> ok end,
(fun(X, Y, True, False) ->
ok = if X Op Y -> ok; true -> error end,
ok = if False; X Op Y; False -> ok; true -> error end,
ok = if X Op Y, True -> ok; true -> error end,
ok = if not (X Op Y) -> error; true -> ok end,
ok = if False; not (X Op Y); False -> error; true -> ok end
end)(id(A), id(B), id(true), id(false))).
-define(F(Op,A,B),
ok = if A Op B -> error; true -> ok end,
ok = if not (A Op B) -> ok; true -> error end,
(fun(X, Y, True, False) ->
ok = if X Op Y -> error; true -> ok end,
ok = if False; X Op Y; False -> error; true -> ok end,
ok = if not (X Op Y); False -> ok; true -> error end,
ok = if not (X Op Y), True -> ok; true -> error end
end)(id(A), id(B), id(true), id(false))).
rel_ops(Config) when is_list(Config) ->
?T(=/=, 1, 1.0),
?F(=/=, 2, 2),
?F(=/=, {a}, {a}),
?F(/=, a, a),
?F(/=, 0, 0.0),
?T(/=, 0, 1),
?F(/=, {a}, {a}),
?T(==, 1, 1.0),
?F(==, a, {}),
?F(=:=, 1, 1.0),
?T(=:=, 42.0, 42.0),
?F(>, a, b),
?T(>, 42, 1.0),
?F(>, 42, 42.0),
?T(<, a, b),
?F(<, 42, 1.0),
?F(<, 42, 42.0),
?T(=<, 1.5, 5),
?F(=<, -9, -100.344),
?T(=<, 42, 42.0),
?T(>=, 42, 42.0),
?F(>=, a, b),
?T(>=, 1.0, 0),
%% Coverage of beam_block:is_exact_eq_ok/1 and collect/1.
true = any_atom /= id(42),
true = [] /= id(42),
%% Coverage of beam_utils:bif_to_test/3
Empty = id([]),
?T(==, [], Empty),
%% Cover beam_ssa_dead:turn_op('/=').
ok = (fun(A, B) when is_atom(A) ->
X = id(A /= B),
if
X -> ok;
true -> error
end
end)(a, b),
ok = (fun(A, B) when is_atom(A) ->
X = id(B /= A),
if
X -> ok;
true -> error
end
end)(a, b),
%% Cover beam_ssa_dead.
Arrow = fun([T1,T2]) when T1 == $>, T2 == $>;
T1 == $<, T2 == $| -> true;
(_) -> false
end,
true = Arrow(">>"),
true = Arrow("<|"),
false = Arrow("><"),
false = Arrow(""),
ok.
-undef(TestOp).
rel_op_combinations(Config) when is_list(Config) ->
Digits0 = lists:seq(16#0030, 16#0039) ++
lists:seq(16#0660, 16#0669) ++
lists:seq(16#06F0, 16#06F9),
Digits = gb_sets:from_list(Digits0),
rel_op_combinations_1(16#0700, Digits),
BrokenRange0 = lists:seq(3, 5) ++
lists:seq(10, 12) ++ lists:seq(14, 20),
BrokenRange = gb_sets:from_list(BrokenRange0),
rel_op_combinations_2(30, BrokenRange),
Red0 = [{I,2*I} || I <- lists:seq(0, 50)] ++
[{I,5*I} || I <- lists:seq(51, 80)],
Red = gb_trees:from_orddict(Red0),
rel_op_combinations_3(100, Red).
rel_op_combinations_1(0, _) ->
ok;
rel_op_combinations_1(N, Digits) ->
Bool = gb_sets:is_member(N, Digits),
Bool = is_digit_1(N),
Bool = is_digit_2(N),
Bool = is_digit_3(N),
Bool = is_digit_4(N),
Bool = is_digit_5(N),
Bool = is_digit_6(N),
Bool = is_digit_7(N),
Bool = is_digit_8(N),
Bool = is_digit_9(42, N),
Bool = is_digit_10(N, 0),
Bool = is_digit_11(N, 0),
rel_op_combinations_1(N-1, Digits).
is_digit_1(X) when 16#0660 =< X, X =< 16#0669 -> true;
is_digit_1(X) when 16#0030 =< X, X =< 16#0039 -> true;
is_digit_1(X) when 16#06F0 =< X, X =< 16#06F9 -> true;
is_digit_1(_) -> false.
is_digit_2(X) when (16#0030-1) < X, X =< 16#0039 -> true;
is_digit_2(X) when (16#0660-1) < X, X =< 16#0669 -> true;
is_digit_2(X) when (16#06F0-1) < X, X =< 16#06F9 -> true;
is_digit_2(_) -> false.
is_digit_3(X) when 16#0660 =< X, X < (16#0669+1) -> true;
is_digit_3(X) when 16#0030 =< X, X < (16#0039+1) -> true;
is_digit_3(X) when 16#06F0 =< X, X < (16#06F9+1) -> true;
is_digit_3(_) -> false.
is_digit_4(X) when (16#0660-1) < X, X < (16#0669+1) -> true;
is_digit_4(X) when (16#0030-1) < X, X < (16#0039+1) -> true;
is_digit_4(X) when (16#06F0-1) < X, X < (16#06F9+1) -> true;
is_digit_4(_) -> false.
is_digit_5(X) when X >= 16#0660, X =< 16#0669 -> true;
is_digit_5(X) when X >= 16#0030, X =< 16#0039 -> true;
is_digit_5(X) when X >= 16#06F0, X =< 16#06F9 -> true;
is_digit_5(_) -> false.
is_digit_6(X) when X > (16#0660-1), X =< 16#0669 -> true;
is_digit_6(X) when X > (16#0030-1), X =< 16#0039 -> true;
is_digit_6(X) when X > (16#06F0-1), X =< 16#06F9 -> true;
is_digit_6(_) -> false.
is_digit_7(X) when 16#0660 =< X, X =< 16#0669 -> true;
is_digit_7(X) when 16#0030 =< X, X =< 16#003A, X =/= 16#003A -> true;
is_digit_7(X) when 16#06F0 =< X, X =< 16#06F9 -> true;
is_digit_7(_) -> false.
is_digit_8(X) when X =< 16#0039, X > (16#0030-1) -> true;
is_digit_8(X) when X =< 16#06F9, X > (16#06F0-1) -> true;
is_digit_8(X) when X =< 16#0669, X > (16#0660-1) -> true;
is_digit_8(16#0670) -> false;
is_digit_8(_) -> false.
is_digit_9(A, 0) when A =:= 42 -> false;
is_digit_9(_, X) when X > 16#065F, X < 16#066A -> true;
is_digit_9(_, X) when 16#0030 =< X, X =< 16#0039 -> true;
is_digit_9(_, X) when 16#06F0 =< X, X =< 16#06F9 -> true;
is_digit_9(_, _) -> false.
is_digit_10(0, 0) -> false;
is_digit_10(X, _) when X < 16#066A, 16#0660 =< X -> true;
is_digit_10(X, _) when 16#0030 =< X, X =< 16#0039 -> true;
is_digit_10(X, _) when 16#06F0 =< X, X =< 16#06F9 -> true;
is_digit_10(_, _) -> false.
is_digit_11(0, 0) -> false;
is_digit_11(X, _) when X =< 16#0669, 16#0660 =< X -> true;
is_digit_11(X, _) when 16#0030 =< X, X =< 16#0039 -> true;
is_digit_11(X, _) when 16#06F0 =< X, X =< 16#06F9 -> true;
is_digit_11(_, _) -> false.
rel_op_combinations_2(0, _) ->
ok;
rel_op_combinations_2(N, Range) ->
Bool = gb_sets:is_member(N, Range),
Bool = broken_range_1(N),
Bool = broken_range_2(N),
Bool = broken_range_3(N),
Bool = broken_range_4(N),
Bool = broken_range_5(N),
Bool = broken_range_6(N),
Bool = broken_range_7(N),
Bool = broken_range_8(N),
Bool = broken_range_9(N),
Bool = broken_range_10(N),
Bool = broken_range_11(N),
Bool = broken_range_12(N),
Bool = broken_range_13(N),
rel_op_combinations_2(N-1, Range).
broken_range_1(X) when X >= 10, X =< 20, X =/= 13 -> true;
broken_range_1(X) when X >= 3, X =< 5 -> true;
broken_range_1(_) -> false.
broken_range_2(X) when X >= 10, X =< 12 -> true;
broken_range_2(X) when X >= 14, X =< 20 -> true;
broken_range_2(X) when X >= 3, X =< 5 -> true;
broken_range_2(_) -> false.
broken_range_3(X) when X >= 10, X =< 12 -> true;
broken_range_3(X) when X >= 14, X < 21 -> true;
broken_range_3(3) -> true;
broken_range_3(4) -> true;
broken_range_3(5) -> true;
broken_range_3(_) -> false.
broken_range_4(X) when X =< 5, X >= 3 -> true;
broken_range_4(X) when X >= 10, X =< 20, X =/= 13 -> true;
broken_range_4(X) when X =< 100 -> false;
broken_range_4(_) -> false.
broken_range_5(X) when X >= 10, X =< 20, X =/= 13 -> true;
broken_range_5(X) when X > 2, X =< 5 -> true;
broken_range_5(_) -> false.
broken_range_6(X) when X >= 10, X =< 20, X =/= 13 -> true;
broken_range_6(X) when X > 2, X < 6 -> true;
broken_range_6(_) -> false.
broken_range_7(X) when X > 2, X < 6 -> true;
broken_range_7(X) when X >= 10, X =< 20, X =/= 13 -> true;
broken_range_7(X) when X > 30 -> false;
broken_range_7(_) -> false.
broken_range_8(X) when X >= 10, X =< 20, X =/= 13 -> true;
broken_range_8(X) when X =:= 3 -> true;
broken_range_8(X) when X >= 3, X =< 5 -> true;
broken_range_8(_) -> false.
broken_range_9(X) when X >= 10, X =< 20, X =/= 13 -> true;
broken_range_9(X) when X =:= 13 -> false;
broken_range_9(X) when X >= 3, X =< 5 -> true;
broken_range_9(_) -> false.
broken_range_10(X) when X >= 3, X =< 5 -> true;
broken_range_10(X) when X >= 10, X =< 20, X =/= 13 -> true;
broken_range_10(X) when X =/= 13 -> false;
broken_range_10(_) -> false.
broken_range_11(X) when X >= 10, X =< 20, X =/= 13 -> true;
broken_range_11(X) when is_tuple(X), X =:= 10 -> true;
broken_range_11(X) when X >= 3, X =< 5 -> true;
broken_range_11(_) -> false.
broken_range_12(X) when X >= 3, X =< 5 -> true;
broken_range_12(X) when X >= 10, X =< 20, X =/= 13 -> true;
broken_range_12(X) when X < 30, X > 20 -> false;
broken_range_12(_) -> false.
broken_range_13(X) when X >= 10, X =< 20, 13 =/= X -> true;
broken_range_13(X) when X >= 3, X =< 5 -> true;
broken_range_13(_) -> false.
rel_op_combinations_3(0, _) ->
ok;
rel_op_combinations_3(N, Red) ->
Val = case gb_trees:lookup(N, Red) of
none -> none;
{value,V} -> V
end,
Val = redundant_1(N),
Val = redundant_2(N),
Val = redundant_3(N),
Val = redundant_4(N),
Val = redundant_5(N),
Val = redundant_6(N),
Val = redundant_7(N),
Val = redundant_8(N),
Val = redundant_9(N),
Val = redundant_10(N),
Val = redundant_11(N),
Val = redundant_11(N),
rel_op_combinations_3(N-1, Red).
redundant_1(X) when X >= 51, X =< 80 -> 5*X;
redundant_1(X) when X < 51 -> 2*X;
redundant_1(_) -> none.
redundant_2(X) when X < 51 -> 2*X;
redundant_2(X) when X >= 51, X =< 80 -> 5*X;
redundant_2(_) -> none.
redundant_3(X) when X < 51 -> 2*X;
redundant_3(X) when X =< 80, X >= 51 -> 5*X;
redundant_3(X) when X =/= 100 -> none;
redundant_3(_) -> none.
redundant_4(X) when X < 51 -> 2*X;
redundant_4(X) when X =< 80, X > 50 -> 5*X;
redundant_4(X) when X =/= 100 -> none;
redundant_4(_) -> none.
redundant_5(X) when X < 51 -> 2*X;
redundant_5(X) when X > 50, X < 81 -> 5*X;
redundant_5(X) when X =< 10 -> none;
redundant_5(_) -> none.
redundant_6(X) when X > 50, X =< 80 -> 5*X;
redundant_6(X) when X < 51 -> 2*X;
redundant_6(_) -> none.
redundant_7(X) when is_integer(X), X >= 51, X =< 80 -> 5*X;
redundant_7(X) when is_integer(X), X < 51 -> 2*X;
redundant_7(_) -> none.
redundant_8(X) when X >= 51, X =< 80 -> 5*X;
redundant_8(X) when X < 51 -> 2*X;
redundant_8(_) -> none.
redundant_9(X) when X >= 51, X =< 80 -> 5*X;
redundant_9(X) when X < 51 -> 2*X;
redundant_9(90) -> none;
redundant_9(X) when X =/= 90 -> none;
redundant_9(_) -> none.
redundant_10(X) when X >= 51, X =< 80 -> 5*X;
redundant_10(X) when X < 51 -> 2*X;
redundant_10(90) -> none;
redundant_10(X) when X =:= 90 -> none;
redundant_10(_) -> none.
redundant_11(X) when X < 51 -> 2*X;
redundant_11(X) when X =:= 10 -> 2*X;
redundant_11(X) when X >= 51, X =< 80 -> 5*X;
redundant_11(_) -> none.
redundant_12(X) when X >= 50, X =< 80 -> 2*X;
redundant_12(X) when X < 51 -> 5*X;
redundant_12(_) -> none.
%% Test type tests on literal values. (From emulator test suites.)
literal_type_tests(Config) when is_list(Config) ->
case ?MODULE of
guard_SUITE -> literal_type_tests_1(Config);
_ -> {skip,"Enough to run this case once."}
end.
literal_type_tests_1(Config) ->
%% Generate an Erlang module with all different type of type tests.
Tests = make_test([{T,L} || T <- type_tests(), L <- literals()] ++
[{is_function,L1,L2} ||
L1 <- literals(), L2 <- literals()]),
Mod = literal_test,
Anno = erl_anno:new(0),
Func = {function, Anno, test, 0, [{clause,Anno,[],[],Tests}]},
Form = [{attribute,Anno,module,Mod},
{attribute,Anno,compile,export_all},
Func, {eof,999}],
%% Print generated code for inspection.
lists:foreach(fun (F) -> io:put_chars([erl_pp:form(F),"\n"]) end, Form),
%% Test compile:form/1. This implies full optimization (default).
{ok,Mod,Code1} = compile:forms(Form),
smoke_disasm(Config, Mod, Code1),
{module,Mod} = code:load_binary(Mod, Mod, Code1),
Mod:test(),
true = code:delete(Mod),
code:purge(Mod),
%% Test compile:form/2. Turn off all optimizations.
{ok,Mod,Code2} = compile:forms(Form, [binary,report,time,
no_copt,no_postopt]),
smoke_disasm(Config, Mod, Code2),
{module,Mod} = code:load_binary(Mod, Mod, Code2),
Mod:test(),
true = code:delete(Mod),
code:purge(Mod),
ok.
make_test([{T,L1,L2}|Ts]) ->
[test(T, L1, L2)|make_test(Ts)];
make_test([{T,L}|Ts]) ->
[test(T, L)|make_test(Ts)];
make_test([]) -> [].
test(T, L) ->
S0 = io_lib:format("begin io:format(\"~~p~n\", [{~p,~p}]), if ~w(~w) -> true; true -> false end end. ", [T,L,T,L]),
S = lists:flatten(S0),
{ok,Toks,_Line} = erl_scan:string(S),
{ok,E} = erl_parse:parse_exprs(Toks),
{value,Val,_Bs} = erl_eval:exprs(E, []),
Anno = erl_anno:new(0),
{match,Anno,{atom,Anno,Val},hd(E)}.
test(T, L1, L2) ->
S0 = io_lib:format("begin io:format(\"~~p~n\", [{~p,~p,~p}]), if ~w(~w, ~w) -> true; true -> false end end. ", [T,L1,L2,T,L1,L2]),
S = lists:flatten(S0),
{ok,Toks,_Line} = erl_scan:string(S),
{ok,E} = erl_parse:parse_exprs(Toks),
{value,Val,_Bs} = erl_eval:exprs(E, []),
Anno = erl_anno:new(0),
{match,Anno,{atom,Anno,Val},hd(E)}.
smoke_disasm(Config, Mod, Bin) ->
Priv = proplists:get_value(priv_dir, Config),
File = filename:join(Priv, atom_to_list(Mod)++".beam"),
ok = file:write_file(File, Bin),
test_lib:smoke_disasm(File).
literals() ->
[42,
3.14,
-3,
32982724987789283473473838474,
[],
xxxx,
{a,b,c},
[a,list],
<<1,2,3>>,
<<42:17>>].
type_tests() ->
[is_boolean,
is_integer,
is_float,
is_number,
is_atom,
is_list,
is_tuple,
is_pid,
is_reference,
is_port,
is_binary,
is_bitstring,
is_function,
is_map].
basic_andalso_orelse(Config) when is_list(Config) ->
T = id({type,integers,23,42}),
65 = if
((element(1, T) =:= type) andalso (tuple_size(T) =:= 4) andalso
element(2, T)) == integers ->
element(3, T) + element(4, T);
true -> error
end,
65 = case [] of
[] when ((element(1, T) =:= type) andalso (tuple_size(T) =:= 4) andalso
element(2, T)) == integers ->
element(3, T) + element(4, T)
end,
42 = basic_rt({type,integers,40,2}),
5.0 = basic_rt({vector,{3.0,4.0}}),
20 = basic_rt(['+',3,7]),
{'Set',a,b} = basic_rt({{'Set',a,b},{'Set',a,b}}),
12 = basic_rt({klurf,4}),
error = basic_rt({type,integers,40,2,3}),
error = basic_rt({kalle,integers,40,2}),
error = basic_rt({kalle,integers,40,2}),
error = basic_rt({1,2}),
error = basic_rt([]),
RelProdBody =
fun(R1, R2) ->
if
(erlang:size(R1) =:= 3) andalso (erlang:element(1,R1) =:= 'Set'),
(erlang:size(R2) =:= 3) andalso (erlang:element(1,R2) =:= 'Set') ->
ok
end
end,
ok = RelProdBody({'Set',a,b}, {'Set',a,b}),
%% 'andalso'/'orelse' with calls known to fail already at compile time.
%% Used to crash the code generator.
error = (fun() ->
R = {vars,true},
if
is_record(R, vars, 2) andalso element(99, R) -> ok;
true -> error
end
end)(),
error = (fun(X) ->
L = {a,b,c},
if
is_list(X) andalso length(L) > 4 -> ok;
true -> error
end
end)([]),
ok.
basic_rt(T) when is_tuple(T) andalso tuple_size(T) =:= 4 andalso element(1, T) =:= type andalso
element(2, T) == integers ->
element(3, T) + element(4, T);
basic_rt(T) when is_tuple(T) andalso tuple_size(T) =:= 2 andalso element(1, T) =:= vector ->
{X,Y} = element(2, T),
if
is_float(X), is_float(Y) ->
math:sqrt(X*X+Y*Y)
end;
basic_rt(['+',A,B]) ->
2*id(A+B);
basic_rt({R1,R2}) when erlang:size(R1) =:= 3 andalso erlang:element(1,R1) =:= 'Set',
erlang:size(R2) =:= 3 andalso erlang:element(1,R2) =:= 'Set' ->
R1 = id(R1),
R2 = id(R2),
R1;
basic_rt(T) when is_tuple(T) andalso tuple_size(T) =:= 2 andalso element(1, T) =:= klurf ->
3*id(element(2, T));
basic_rt(_) ->
error.
traverse_dcd(Config) when is_list(Config) ->
L0 = [{log_header,dcd_log,"1.0",a,b,c},{log_header,dcd_log,"2.0",a,b,c},
{log_header,dcd_log,"0.0",a,b,c},blurf],
{cont,[{log_header,dcd_log,"0.0",a,b,c},blurf],log,funny} =
traverse_dcd({cont,L0}, log, funny),
L1 = [{log_header,dcd_log,"1.0"}],
{cont,L1,log,funny} = traverse_dcd({cont,L1}, log, funny),
L2 = [{a,tuple}],
{cont,L2,log,funny} = traverse_dcd({cont,L2}, log, funny),
ok.
%% The function starts out with 3 arguments in {x,0}, {x,1}, {x,2}.
%% The outer match of a two tuple will places the first element in {x,3} and
%% second in {x,4}. The guard for the first clause must make ensure that all of those
%% registers are restored before entering the second clause.
%%
%% (From mnesia_checkpoint.erl, modified.)
traverse_dcd({Cont,[LogH|Rest]},Log,Fun)
when is_tuple(LogH) andalso tuple_size(LogH) =:= 6 andalso element(1, LogH) =:= log_header
andalso erlang:element(2,LogH) == dcd_log,
is_tuple(LogH) andalso tuple_size(LogH) =:= 6 andalso element(1, LogH) =:= log_header
andalso erlang:element(3,LogH) >= "1.0" ->
traverse_dcd({Cont,Rest},Log,Fun);
traverse_dcd({Cont,Recs},Log,Fun) ->
{Cont,Recs,Log,Fun}.
check_qlc_hrl(Config) when is_list(Config) ->
St = {r1,false,dum},
foo = cqlc(qlc, q, [{lc,1,2,3}], St),
foo = cqlc(qlc, q, [{lc,1,2,3},b], St),
St = cqlc(qlc, q, [], St),
St = cqlc(qlc, blurf, [{lc,1,2,3},b], St),
St = cqlc(q, q, [{lc,1,2,3},b], St),
St = cqlc(qlc, q, [{lc,1,2,3},b,c], St),
St = cqlc(qlc, q, [a,b], St),
{r1,true,kalle} = cqlc(qlc, q, [{lc,1,2,3},b], {r1,true,kalle}),
ok.
%% From erl_lint.erl; original name was check_qlc_hrl/4.
cqlc(M, F, As, St) ->
Arity = length(As),
case As of
[{lc,_L,_E,_Qs}|_] when M =:= qlc, F =:= q,
Arity < 3,
not (((element(1, St) =:= r1) orelse fail) and (tuple_size(St) =:= 3) and element(2, St)) ->
foo;
_ ->
St
end.
%% OTP-7679: Thanks to Hunter Morris.
andalso_semi(Config) when is_list(Config) ->
ok = andalso_semi_foo(0),
ok = andalso_semi_foo(1),
fc(catch andalso_semi_foo(2)),
ok = andalso_semi_bar([a,b,c]),
ok = andalso_semi_bar(1),
fc(catch andalso_semi_bar([a,b])),
ok.
andalso_semi_foo(Bar) when is_integer(Bar) andalso Bar =:= 0; Bar =:= 1 ->
ok.
andalso_semi_bar(Bar) when is_list(Bar) andalso length(Bar) =:= 3; Bar =:= 1 ->
ok.
t_tuple_size(Config) when is_list(Config) ->
10 = do_tuple_size({1,2,3,4}),
fc(catch do_tuple_size({1,2,3})),
fc(catch do_tuple_size(42)),
error = ludicrous_tuple_size({a,b,c}),
error = ludicrous_tuple_size([a,b,c]),
good_ip({1,2,3,4}),
good_ip({1,2,3,4,5,6,7,8}),
error = validate_ip({42,11}),
error = validate_ip(atom),
ok.
do_tuple_size(T) when tuple_size(T) =:= 4 ->
{A,B,C,D} = T,
A+B+C+D.
ludicrous_tuple_size(T)
when tuple_size(T) =:= 16#7777777777777777777777777777777777 -> ok;
ludicrous_tuple_size(T)
when tuple_size(T) =:= 16#10000000000000000 -> ok;
ludicrous_tuple_size(T)
when tuple_size(T) =:= (1 bsl 64) - 1 -> ok;
ludicrous_tuple_size(T)
when tuple_size(T) =:= 16#FFFFFFFFFFFFFFFF -> ok;
ludicrous_tuple_size(_) -> error.
good_ip(IP) ->
IP = validate_ip(IP).
validate_ip(Value) when is_tuple(Value) andalso
((size(Value) =:= 4) orelse (size(Value) =:= 8)) ->
%% size/1 (converted to tuple_size) used more than once.
Value;
validate_ip(_) ->
error.
%%
%% The binary_part/2,3 guard BIFs
%%
-define(MASK_ERROR(EXPR),mask_error((catch (EXPR)))).
mask_error({'EXIT',{Err,_}}) ->
Err;
mask_error(Else) ->
Else.
%% Test the binary_part/2,3 guard (GC) BIFs.
binary_part(Config) when is_list(Config) ->
%% This is more or less a copy of what the guard_SUITE in emulator
%% does to cover the guard bif's
1 = bptest(<<1,2,3>>),
2 = bptest(<<2,1,3>>),
error = bptest(<<1>>),
error = bptest(<<>>),
error = bptest(apa),
3 = bptest(<<2,3,3>>),
% With one variable (pos)
1 = bptest(<<1,2,3>>,1),
2 = bptest(<<2,1,3>>,1),
error = bptest(<<1>>,1),
error = bptest(<<>>,1),
error = bptest(apa,1),
3 = bptest(<<2,3,3>>,1),
% With one variable (length)
1 = bptesty(<<1,2,3>>,1),
2 = bptesty(<<2,1,3>>,1),
error = bptesty(<<1>>,1),
error = bptesty(<<>>,1),
error = bptesty(apa,1),
3 = bptesty(<<2,3,3>>,2),
% With one variable (whole tuple)
1 = bptestx(<<1,2,3>>,{1,1}),
2 = bptestx(<<2,1,3>>,{1,1}),
error = bptestx(<<1>>,{1,1}),
error = bptestx(<<>>,{1,1}),
error = bptestx(apa,{1,1}),
3 = bptestx(<<2,3,3>>,{1,2}),
% With two variables
1 = bptest(<<1,2,3>>,1,1),
2 = bptest(<<2,1,3>>,1,1),
error = bptest(<<1>>,1,1),
error = bptest(<<>>,1,1),
error = bptest(apa,1,1),
3 = bptest(<<2,3,3>>,1,2),
% Direct (autoimported) call, these will be evaluated by the compiler...
<<2>> = binary_part(<<1,2,3>>,1,1),
<<1>> = binary_part(<<2,1,3>>,1,1),
% Compiler warnings due to constant evaluation expected (3)
badarg = ?MASK_ERROR(binary_part(<<1>>,1,1)),
badarg = ?MASK_ERROR(binary_part(<<>>,1,1)),
badarg = ?MASK_ERROR(binary_part(apa,1,1)),
<<3,3>> = binary_part(<<2,3,3>>,1,2),
% Direct call through apply
<<2>> = apply(erlang,binary_part,[<<1,2,3>>,1,1]),
<<1>> = apply(erlang,binary_part,[<<2,1,3>>,1,1]),
% Compiler warnings due to constant evaluation expected (3)
badarg = ?MASK_ERROR(apply(erlang,binary_part,[<<1>>,1,1])),
badarg = ?MASK_ERROR(apply(erlang,binary_part,[<<>>,1,1])),
badarg = ?MASK_ERROR(apply(erlang,binary_part,[apa,1,1])),
<<3,3>> = apply(erlang,binary_part,[<<2,3,3>>,1,2]),
% Constant propagation
Bin = <<1,2,3>>,
ok = if
binary_part(Bin,1,1) =:= <<2>> ->
ok;
%% Compiler warning, clause cannot match (expected)
true ->
error
end,
ok = if
binary_part(Bin,{1,1}) =:= <<2>> ->
ok;
%% Compiler warning, clause cannot match (expected)
true ->
error
end,
ok.
bptest(B) when length(B) =:= 1337 ->
1;
bptest(B) when binary_part(B,{1,1}) =:= <<2>> ->
1;
bptest(B) when erlang:binary_part(B,1,1) =:= <<1>> ->
2;
bptest(B) when erlang:binary_part(B,{1,2}) =:= <<3,3>> ->
3;
bptest(_) ->
error.
bptest(B,A) when length(B) =:= A ->
1;
bptest(B,A) when binary_part(B,{A,1}) =:= <<2>> ->
1;
bptest(B,A) when erlang:binary_part(B,A,1) =:= <<1>> ->
2;
bptest(B,A) when erlang:binary_part(B,{A,2}) =:= <<3,3>> ->
3;
bptest(_,_) ->
error.
bptestx(B,A) when length(B) =:= A ->
1;
bptestx(B,A) when binary_part(B,A) =:= <<2>> ->
1;
bptestx(B,A) when erlang:binary_part(B,A) =:= <<1>> ->
2;
bptestx(B,A) when erlang:binary_part(B,A) =:= <<3,3>> ->
3;
bptestx(_,_) ->
error.
bptesty(B,A) when length(B) =:= A ->
1;
bptesty(B,A) when binary_part(B,{1,A}) =:= <<2>> ->
1;
bptesty(B,A) when erlang:binary_part(B,1,A) =:= <<1>> ->
2;
bptesty(B,A) when erlang:binary_part(B,{1,A}) =:= <<3,3>> ->
3;
bptesty(_,_) ->
error.
bptest(B,A,_C) when length(B) =:= A ->
1;
bptest(B,A,C) when binary_part(B,{A,C}) =:= <<2>> ->
1;
bptest(B,A,C) when erlang:binary_part(B,A,C) =:= <<1>> ->
2;
bptest(B,A,C) when erlang:binary_part(B,{A,C}) =:= <<3,3>> ->
3;
bptest(_,_,_) ->
error.
-define(FAILING(C),
if
C -> ct:fail(should_fail);
true -> ok
end,
if
true, C -> ct:fail(should_fail);
true -> ok
end).
bad_constants(Config) when is_list(Config) ->
?FAILING(false),
?FAILING([]),
?FAILING([a]),
?FAILING([Config]),
?FAILING({a,b}),
?FAILING({a,Config}),
?FAILING(<<1>>),
?FAILING(42),
?FAILING(3.14),
ok.
bad_guards(Config) when is_list(Config) ->
if erlang:float(self()); true -> ok end,
fc(catch bad_guards_1(1, [])),
fc(catch bad_guards_1(1, [2])),
fc(catch bad_guards_1(atom, [2])),
fc(catch bad_guards_2(#{a=>0,b=>0}, [])),
fc(catch bad_guards_2(#{a=>0,b=>0}, [x])),
fc(catch bad_guards_2(not_a_map, [x])),
fc(catch bad_guards_2(42, [x])),
fc(catch bad_guards_3(#{a=>0,b=>0}, [])),
fc(catch bad_guards_3(#{a=>0,b=>0}, [x])),
fc(catch bad_guards_3(not_a_map, [x])),
fc(catch bad_guards_3(42, [x])),
fc(catch bad_guards_4()),
ok.
%% beam_bool used to produce GC BIF instructions whose
%% Live operands included uninitialized registers.
bad_guards_1(X, [_]) when {{X}}, -X ->
ok.
bad_guards_2(M, [_]) when M#{a := 0, b => 0}, map_size(M) ->
ok.
%% beam_type used to produce an GC BIF instruction whose Live operand
%% included uninitialized registers.
bad_guards_3(M, [_]) when is_map(M) andalso M#{a := 0, b => 0}, length(M) ->
ok.
%% v3_codegen would generate a jump to the failure label, but
%% without initializing x(0). The code at the failure label expected
%% x(0) to be initialized.
bad_guards_4() when not (error#{}); {not 0.0} -> freedom.
%% Building maps in a guard in a 'catch' would crash v3_codegen.
guard_in_catch(_Config) ->
{'EXIT',{if_clause,_}} = do_guard_in_catch_map_1(#{}),
{'EXIT',{if_clause,_}} = do_guard_in_catch_map_1(#{a=>b}),
{'EXIT',{if_clause,_}} = do_guard_in_catch_map_1(atom),
{'EXIT',{if_clause,_}} = do_guard_in_catch_map_2(#{}),
{'EXIT',{if_clause,_}} = do_guard_in_catch_map_2(#{a=>b}),
{'EXIT',{if_clause,_}} = do_guard_in_catch_map_2(atom),
{'EXIT',{if_clause,_}} = (catch do_guard_in_catch_map_3()),
{'EXIT',{if_clause,_}} = do_guard_in_catch_bin(42),
{'EXIT',{if_clause,_}} = do_guard_in_catch_bin(<<1,2,3>>),
{'EXIT',{if_clause,_}} = do_guard_in_catch_bin(atom),
{'EXIT',{if_clause,_}} = do_guard_in_catch_bin(#{}),
ok.
do_guard_in_catch_map_1(From) ->
catch
if
From#{[] => sufficient} ->
saint
end.
do_guard_in_catch_map_2(From) ->
catch
if
From#{From => sufficient} ->
saint
end.
do_guard_in_catch_map_3() ->
try
if [] -> solo end
catch
Friendly when Friendly#{0 => []} -> minutes
after
membership
end.
do_guard_in_catch_bin(From) ->
%% Would not crash v3_codegen, but there would be an unnecessary
%% 'move' to a Y register.
catch
if
<<From:32>> ->
saint
end.
%%%
%%% The beam_bool pass has been eliminated. Here are the tests from
%%% beam_bool_SUITE.
%%%
beam_bool_SUITE(_Config) ->
before_and_inside_if(),
scotland(),
y_registers(),
protected(),
maps(),
ok.
before_and_inside_if() ->
no = before_and_inside_if([a], [b], delete),
no = before_and_inside_if([a], [b], x),
no = before_and_inside_if([a], [], delete),
no = before_and_inside_if([a], [], x),
no = before_and_inside_if([], [], delete),
yes = before_and_inside_if([], [], x),
yes = before_and_inside_if([], [b], delete),
yes = before_and_inside_if([], [b], x),
{ch1,ch2} = before_and_inside_if_2([a], [b], blah),
{ch1,ch2} = before_and_inside_if_2([a], [b], xx),
{ch1,ch2} = before_and_inside_if_2([a], [], blah),
{ch1,ch2} = before_and_inside_if_2([a], [], xx),
{no,no} = before_and_inside_if_2([], [b], blah),
{no,no} = before_and_inside_if_2([], [b], xx),
{ch1,no} = before_and_inside_if_2([], [], blah),
{no,ch2} = before_and_inside_if_2([], [], xx),
ok.
%% Thanks to Simon Cornish and Kostis Sagonas.
%% Used to crash beam_bool.
before_and_inside_if(XDo1, XDo2, Do3) ->
Do1 = (XDo1 =/= []),
Do2 = (XDo2 =/= []),
if
%% This expression occurs in a try/catch (protected)
%% block, which cannot refer to variables outside of
%% the block that are boolean expressions.
Do1 =:= true;
Do1 =:= false, Do2 =:= false, Do3 =:= delete ->
no;
true ->
yes
end.
%% Thanks to Simon Cornish.
%% Used to generate code that would not set {y,0} on
%% all paths before its use (and therefore fail
%% validation by the beam_validator).
before_and_inside_if_2(XDo1, XDo2, Do3) ->
Do1 = (XDo1 =/= []),
Do2 = (XDo2 =/= []),
CH1 = if Do1 == true;
Do1 == false,Do2==false,Do3 == blah ->
ch1;
true ->
no
end,
CH2 = if Do1 == true;
Do1 == false,Do2==false,Do3 == xx ->
ch2;
true ->
no
end,
{CH1,CH2}.
%% beam_bool would remove the initialization of {y,0}.
%% (Thanks to Thomas Arts and QuickCheck.)
scotland() ->
million = do_scotland(placed),
{'EXIT',{{badmatch,placed},_}} = (catch do_scotland(false)),
{'EXIT',{{badmatch,placed},_}} = (catch do_scotland(true)),
{'EXIT',{{badmatch,placed},_}} = (catch do_scotland(echo)),
ok.
do_scotland(Echo) ->
found(case Echo of
Echo when true; Echo, Echo, Echo ->
Echo;
echo ->
[]
end,
Echo = placed).
found(_, _) -> million.
%% ERL-143: beam_bool could not handle Y registers as a destination.
y_registers() ->
{'EXIT',{badarith,[_|_]}} = (catch baker(valentine)),
{'EXIT',{badarith,[_|_]}} = (catch baker(clementine)),
{not_ok,true} = potter([]),
{ok,false} = potter([{encoding,any}]),
ok.
%% Thanks to Quickcheck.
baker(Baker) ->
(valentine == Baker) +
case Baker of
Baker when Baker; Baker ->
Baker;
Baker ->
[]
end.
%% Thanks to Jose Valim.
potter(Modes) ->
Raw = lists:keyfind(encoding, 1, Modes) == false,
Final = case Raw of
X when X == false; X == nil -> ok;
_ -> not_ok
end,
{Final,Raw}.
protected() ->
{'EXIT',{if_clause,_}} = (catch photographs({1, surprise, true}, opinions)),
{{true}} = welcome({perfect, true}),
{'EXIT',{if_clause,_}} = (catch welcome({perfect, false})),
ok.
photographs({_Violation, surprise, Deep}, opinions) ->
{if
0; "here", Deep ->
Deep = Deep
end}.
welcome({perfect, Profit}) ->
if
Profit, Profit, Profit; 0 ->
{id({Profit})}
end.
maps() ->
ok = evidence(#{0 => 42}).
%% Cover handling of put_map in in split_block_label_used/2.
evidence(#{0 := Charge}) when 0; #{[] => Charge} == #{[] => 42} ->
ok.
repeated_type_tests(_Config) ->
binary = repeated_type_test(<<42>>),
bitstring = repeated_type_test(<<1:1>>),
other = repeated_type_test(atom),
ok.
repeated_type_test(T) ->
%% Test for a bug in beam_ssa_dead.
if is_bitstring(T) ->
if is_binary(T) -> %This test would be optimized away.
binary;
true ->
bitstring
end;
true ->
other
end.
%% Call this function to turn off constant propagation.
id(I) -> I.
check(F, Result) ->
case F() of
Result -> ok;
Other ->
io:format("Expected: ~p\n", [Result]),
io:format(" Got: ~p\n", [Other]),
ct:fail(check_failed)
end.
fc({'EXIT',{function_clause,_}}) -> ok;
fc({'EXIT',{{case_clause,_},_}}) when ?MODULE =:= guard_inline_SUITE -> ok.