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|
%% This library is free software; you can redistribute it and/or modify
%% it under the terms of the GNU Lesser General Public License as
%% published by the Free Software Foundation; either version 2 of the
%% License, or (at your option) any later version.
%%
%% This library is distributed in the hope that it will be useful, but
%% WITHOUT ANY WARRANTY; without even the implied warranty of
%% MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
%% Lesser General Public License for more details.
%%
%% You should have received a copy of the GNU Lesser General Public
%% License along with this library; if not, write to the Free Software
%% Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307
%% USA
%%
%% $Id: eunit_lib.erl 339 2009-04-05 14:10:47Z rcarlsson $
%%
%% @copyright 2004-2007 Micka�l R�mond, Richard Carlsson
%% @author Micka�l R�mond <[email protected]>
%% [http://www.process-one.net/]
%% @author Richard Carlsson <[email protected]>
%% [http://user.it.uu.se/~richardc/]
%% @private
%% @see eunit
%% @doc Utility functions for eunit
-module(eunit_lib).
-include("eunit.hrl").
-include("eunit_internal.hrl").
-export([dlist_next/1, uniq/1, fun_parent/1, is_string/1, command/1,
command/2, command/3, trie_new/0, trie_store/2, trie_match/2,
split_node/1, consult_file/1, list_dir/1, format_exit_term/1,
format_exception/1, format_exception/2, format_error/1]).
%% Type definitions for describing exceptions
%%
%% @type exception() = {exceptionClass(), Reason::term(), stackTrace()}
%%
%% @type exceptionClass() = error | exit | throw
%%
%% @type stackTrace() = [{moduleName(), functionName(),
%% arity() | argList()}]
%%
%% @type moduleName() = atom()
%% @type functionName() = atom()
%% @type arity() = integer()
%% @type mfa() = {moduleName(), functionName(), arity()}
%% @type argList() = [term()]
%% @type fileName() = string()
%% ---------------------------------------------------------------------
%% Formatting of error descriptors
format_exception(Exception) ->
format_exception(Exception, 20).
format_exception({Class,Term,Trace}, Depth)
when is_atom(Class), is_list(Trace) ->
case is_stacktrace(Trace) of
true ->
io_lib:format("~w:~P\n~s",
[Class, Term, Depth, format_stacktrace(Trace)]);
false ->
format_term(Term, Depth)
end;
format_exception(Term, Depth) ->
format_term(Term, Depth).
format_term(Term, Depth) ->
io_lib:format("~P\n", [Term, Depth]).
format_exit_term(Term) ->
{Reason, Trace} = analyze_exit_term(Term),
io_lib:format("~P~s", [Reason, 15, Trace]).
analyze_exit_term({Reason, [_|_]=Trace}=Term) ->
case is_stacktrace(Trace) of
true ->
{Reason, format_stacktrace(Trace)};
false ->
{Term, ""}
end;
analyze_exit_term(Term) ->
{Term, ""}.
is_stacktrace([]) ->
true;
is_stacktrace([{M,F,A}|Fs]) when is_atom(M), is_atom(F), is_integer(A) ->
is_stacktrace(Fs);
is_stacktrace([{M,F,As}|Fs]) when is_atom(M), is_atom(F), is_list(As) ->
is_stacktrace(Fs);
is_stacktrace(_) ->
false.
format_stacktrace(Trace) ->
format_stacktrace(Trace, "in function", "in call from").
format_stacktrace([{M,F,A}|Fs], Pre, Pre1) when is_integer(A) ->
[io_lib:fwrite(" ~s ~w:~w/~w\n", [Pre, M, F, A])
| format_stacktrace(Fs, Pre1, Pre1)];
format_stacktrace([{M,F,As}|Fs], Pre, Pre1) when is_list(As) ->
A = length(As),
C = case is_op(M,F,A) of
true when A =:= 1 ->
[A1] = As,
io_lib:fwrite("~s ~s", [F,format_arg(A1)]);
true when A =:= 2 ->
[A1, A2] = As,
io_lib:fwrite("~s ~s ~s",
[format_arg(A1),F,format_arg(A2)]);
false ->
io_lib:fwrite("~w(~s)", [F,format_arglist(As)])
end,
[io_lib:fwrite(" ~s ~w:~w/~w\n called as ~s\n",
[Pre,M,F,A,C])
| format_stacktrace(Fs,Pre1,Pre1)];
format_stacktrace([],_Pre,_Pre1) ->
"".
format_arg(A) ->
io_lib:format("~P",[A,15]).
format_arglist([A]) ->
format_arg(A);
format_arglist([A|As]) ->
[io_lib:format("~P,",[A,15]) | format_arglist(As)];
format_arglist([]) ->
"".
is_op(erlang, F, A) ->
erl_internal:arith_op(F, A)
orelse erl_internal:bool_op(F, A)
orelse erl_internal:comp_op(F, A)
orelse erl_internal:list_op(F, A)
orelse erl_internal:send_op(F, A);
is_op(_M, _F, _A) ->
false.
format_error({bad_test, Term}) ->
error_msg("bad test descriptor", "~P", [Term, 15]);
format_error({generator_failed, Exception}) ->
error_msg("test generator failed", "~s",
[format_exception(Exception)]);
format_error({no_such_function, {M,F,A}})
when is_atom(M), is_atom(F), is_integer(A) ->
error_msg(io_lib:format("no such function: ~w:~w/~w", [M,F,A]),
"", []);
format_error({module_not_found, M}) ->
error_msg("test module not found", "~p", [M]);
format_error({application_not_found, A}) when is_atom(A) ->
error_msg("application not found", "~w", [A]);
format_error({file_read_error, {_R, Msg, F}}) ->
error_msg("error reading file", "~s: ~s", [Msg, F]);
format_error({setup_failed, Exception}) ->
error_msg("context setup failed", "~s",
[format_exception(Exception)]);
format_error({cleanup_failed, Exception}) ->
error_msg("context cleanup failed", "~s",
[format_exception(Exception)]);
format_error({instantiation_failed, Exception}) ->
error_msg("instantiation of subtests failed", "~s",
[format_exception(Exception)]).
error_msg(Title, Fmt, Args) ->
Msg = io_lib:format("::"++Fmt, Args), % gets indentation right
io_lib:fwrite("*** ~s ***\n~s\n\n", [Title, Msg]).
%% ---------------------------------------------------------------------
%% Deep list iterator; accepts improper lists/sublists, and also accepts
%% non-lists on the top level. Nonempty strings (not deep strings) are
%% recognized as separate elements, even on the top level. (It is not
%% recommended to include integers in the deep list, since a list of
%% integers is likely to be interpreted as a string.). The result is
%% always presented as a list (which may be improper), which is either
%% empty or otherwise has a non-list head element.
dlist_next([X | Xs] = Xs0) when is_list(X) ->
case is_nonempty_string(X) of
true -> Xs0;
false -> dlist_next(X, Xs)
end;
dlist_next([_|_] = Xs) ->
case is_nonempty_string(Xs) of
true -> [Xs];
false -> Xs
end;
dlist_next([]) ->
[];
dlist_next(X) ->
[X].
%% the first two clauses avoid pushing empty lists on the stack
dlist_next([X], Ys) when is_list(X) ->
case is_nonempty_string(X) of
true -> [X | Ys];
false -> dlist_next(X, Ys)
end;
dlist_next([X], Ys) ->
[X | Ys];
dlist_next([X | Xs], Ys) when is_list(X) ->
case is_nonempty_string(X) of
true -> [X | [Xs | Ys]];
false -> dlist_next(X, [Xs | Ys])
end;
dlist_next([X | Xs], Ys) ->
[X | [Xs | Ys]];
dlist_next([], Xs) ->
dlist_next(Xs).
-ifdef(TEST).
dlist_test_() ->
{"deep list traversal",
[{"non-list term -> singleton list",
?_test([any] = dlist_next(any))},
{"empty list -> empty list",
?_test([] = dlist_next([]))},
{"singleton list -> singleton list",
?_test([any] = dlist_next([any]))},
{"taking the head of a flat list",
?_test([a,b,c] = dlist_next([a,b,c]))},
{"skipping an initial empty list",
?_test([a,b,c] = dlist_next([[],a,b,c]))},
{"skipping nested initial empty lists",
?_test([a,b,c] = dlist_next([[[[]]],a,b,c]))},
{"skipping a final empty list",
?_test([] = dlist_next([[]]))},
{"skipping nested final empty lists",
?_test([] = dlist_next([[[[]]]]))},
{"the first element is in a sublist",
?_test([a,b,c] = dlist_next([[a],b,c]))},
{"recognizing a naked string",
?_test(["abc"] = dlist_next("abc"))},
{"recognizing a wrapped string",
?_test(["abc"] = dlist_next(["abc"]))},
{"recognizing a leading string",
?_test(["abc",a,b,c] = dlist_next(["abc",a,b,c]))},
{"recognizing a nested string",
?_test(["abc"] = dlist_next([["abc"]]))},
{"recognizing a leading string in a sublist",
?_test(["abc",a,b,c] = dlist_next([["abc"],a,b,c]))},
{"traversing an empty list",
?_test([] = dlist_flatten([]))},
{"traversing a flat list",
?_test([a,b,c] = dlist_flatten([a,b,c]))},
{"traversing a deep list",
?_test([a,b,c] = dlist_flatten([[],[a,[b,[]],c],[]]))},
{"traversing a deep but empty list",
?_test([] = dlist_flatten([[],[[[]]],[]]))}
]}.
%% test support
dlist_flatten(Xs) ->
case dlist_next(Xs) of
[X | Xs1] -> [X | dlist_flatten(Xs1)];
[] -> []
end.
-endif.
%% ---------------------------------------------------------------------
%% Check for proper Unicode-stringness.
is_string([C | Cs]) when is_integer(C), C >= 0, C =< 16#10ffff ->
is_string(Cs);
is_string([_ | _]) ->
false;
is_string([]) ->
true;
is_string(_) ->
false.
is_nonempty_string([]) -> false;
is_nonempty_string(Cs) -> is_string(Cs).
-ifdef(TEST).
is_string_test_() ->
{"is_string",
[{"no non-lists", ?_assert(not is_string($A))},
{"no non-integer lists", ?_assert(not is_string([true]))},
{"empty string", ?_assert(is_string(""))},
{"ascii string", ?_assert(is_string(lists:seq(0, 127)))},
{"latin-1 string", ?_assert(is_string(lists:seq(0, 255)))},
{"unicode string",
?_assert(is_string([0, $A, 16#10fffe, 16#10ffff]))},
{"not above unicode range",
?_assert(not is_string([0, $A, 16#110000]))},
{"no negative codepoints", ?_assert(not is_string([$A, -1, 0]))}
]}.
-endif.
%% ---------------------------------------------------------------------
%% Splitting a full node name into basename and hostname,
%% using 'localhost' as the default hostname
split_node(N) when is_atom(N) -> split_node(atom_to_list(N));
split_node(Cs) -> split_node_1(Cs, []).
split_node_1([$@ | Cs], As) -> split_node_2(As, Cs);
split_node_1([C | Cs], As) -> split_node_1(Cs, [C | As]);
split_node_1([], As) -> split_node_2(As, "localhost").
split_node_2(As, Cs) ->
{list_to_atom(lists:reverse(As)), list_to_atom(Cs)}.
%% ---------------------------------------------------------------------
%% Get the name of the containing function for a fun. (This is encoded
%% in the name of the generated function that implements the fun.)
fun_parent(F) ->
{module, M} = erlang:fun_info(F, module),
{name, N} = erlang:fun_info(F, name),
case erlang:fun_info(F, type) of
{type, external} ->
{arity, A} = erlang:fun_info(F, arity),
{M, N, A};
{type, local} ->
[$-|S] = atom_to_list(N),
C1 = string:chr(S, $/),
C2 = string:chr(S, $-),
{M, list_to_atom(string:sub_string(S, 1, C1 - 1)),
list_to_integer(string:sub_string(S, C1 + 1, C2 - 1))}
end.
-ifdef(TEST).
fun_parent_test() ->
{?MODULE,fun_parent_test,0} = fun_parent(fun () -> ok end).
-endif.
%% ---------------------------------------------------------------------
%% Ye olde uniq function
uniq([X, X | Xs]) -> uniq([X | Xs]);
uniq([X | Xs]) -> [X | uniq(Xs)];
uniq([]) -> [].
-ifdef(TEST).
uniq_test_() ->
{"uniq",
[?_assertError(function_clause, uniq(ok)),
?_assertError(function_clause, uniq([1|2])),
?_test([] = uniq([])),
?_test([1,2,3] = uniq([1,2,3])),
?_test([1,2,3] = uniq([1,2,2,3])),
?_test([1,2,3,2,1] = uniq([1,2,2,3,2,2,1])),
?_test([1,2,3] = uniq([1,1,1,2,2,2,3,3,3])),
?_test(["1","2","3"] = uniq(["1","1","2","2","3","3"]))
]}.
-endif.
%% ---------------------------------------------------------------------
%% Replacement for os:cmd
%% TODO: Better cmd support, especially on Windows (not much tested)
%% TODO: Can we capture stderr separately somehow?
command(Cmd) ->
command(Cmd, "").
command(Cmd, Dir) ->
command(Cmd, Dir, []).
command(Cmd, Dir, Env) ->
CD = if Dir =:= "" -> [];
true -> [{cd, Dir}]
end,
SetEnv = if Env =:= [] -> [];
true -> [{env, Env}]
end,
Opt = CD ++ SetEnv ++ [stream, exit_status, use_stdio,
stderr_to_stdout, in, eof],
P = open_port({spawn, Cmd}, Opt),
get_data(P, []).
get_data(P, D) ->
receive
{P, {data, D1}} ->
get_data(P, [D1|D]);
{P, eof} ->
port_close(P),
receive
{P, {exit_status, N}} ->
{N, normalize(lists:flatten(lists:reverse(D)))}
end
end.
normalize([$\r, $\n | Cs]) ->
[$\n | normalize(Cs)];
normalize([$\r | Cs]) ->
[$\n | normalize(Cs)];
normalize([C | Cs]) ->
[C | normalize(Cs)];
normalize([]) ->
[].
-ifdef(TEST).
cmd_test_() ->
([?_test({0, "hello\n"} = ?_cmd_("echo hello"))]
++ case os:type() of
{unix, _} ->
unix_cmd_tests();
{win32, _} ->
win32_cmd_tests();
_ ->
[]
end).
unix_cmd_tests() ->
[{"command execution, status, and output",
[?_cmd("echo hello"),
?_assertCmdStatus(0, "true"),
?_assertCmdStatus(1, "false"),
?_assertCmd("true"),
?_assertCmdOutput("hello\n", "echo hello"),
?_assertCmdOutput("hello", "echo -n hello")
]},
{"file setup and cleanup",
setup,
fun () -> ?cmd("mktemp tmp.XXXXXXXX") end,
fun (File) -> ?cmd("rm " ++ File) end,
fun (File) ->
[?_assertCmd("echo xyzzy >" ++ File),
?_assertCmdOutput("xyzzy\n", "cat " ++ File)]
end}
].
win32_cmd_tests() ->
[{"command execution, status, and output",
[?_cmd("echo hello"),
?_assertCmdOutput("hello\n", "echo hello")
]}
].
-endif. % TEST
%% ---------------------------------------------------------------------
%% Wrapper around file:path_consult
%% @throws {file_read_error, {Reason::atom(), Message::string(),
%% fileName()}}
consult_file(File) ->
case file:path_consult(["."]++code:get_path(), File) of
{ok, Data, _Path} ->
Data;
{error, Reason} ->
Msg = file:format_error(Reason),
throw({file_read_error, {Reason, Msg, File}})
end.
%% ---------------------------------------------------------------------
%% Wrapper around file:list_dir
%% @throws {file_read_error, {Reason::atom(), Message::string(),
%% fileName()}}
list_dir(Dir) ->
case file:list_dir(Dir) of
{ok, Fs} ->
Fs;
{error, Reason} ->
Msg = file:format_error(Reason),
throw({file_read_error, {Reason, Msg, Dir}})
end.
%% ---------------------------------------------------------------------
%% A trie for remembering and checking least specific cancelled events
%% (an empty list `[]' simply represents a stored empty list, i.e., all
%% events will match, while an empty tree means that no events match).
trie_new() ->
gb_trees:empty().
trie_store([_ | _], []) ->
[];
trie_store([E | Es], T) ->
case gb_trees:lookup(E, T) of
none ->
if Es =:= [] ->
gb_trees:insert(E, [], T);
true ->
gb_trees:insert(E, trie_store(Es, gb_trees:empty()),
T)
end;
{value, []} ->
T; %% prefix already stored
{value, T1} ->
gb_trees:update(E, trie_store(Es, T1), T)
end;
trie_store([], _T) ->
[].
trie_match([_ | _], []) ->
prefix;
trie_match([E | Es], T) ->
case gb_trees:lookup(E, T) of
none ->
no;
{value, []} ->
if Es =:= [] -> exact;
true -> prefix
end;
{value, T1} ->
trie_match(Es, T1)
end;
trie_match([], []) ->
exact;
trie_match([], _T) ->
no.
-ifdef(TEST).
trie_test_() ->
[{"basic representation",
[?_assert(trie_new() =:= gb_trees:empty()),
?_assert(trie_store([1], trie_new())
=:= gb_trees:insert(1, [], gb_trees:empty())),
?_assert(trie_store([1,2], trie_new())
=:= gb_trees:insert(1,
gb_trees:insert(2, [],
gb_trees:empty()),
gb_trees:empty())),
?_assert([] =:= trie_store([1], [])),
?_assert([] =:= trie_store([], gb_trees:empty()))
]},
{"basic storing and matching",
[?_test(no = trie_match([], trie_new())),
?_test(exact = trie_match([], trie_store([], trie_new()))),
?_test(no = trie_match([], trie_store([1], trie_new()))),
?_test(exact = trie_match([1], trie_store([1], trie_new()))),
?_test(prefix = trie_match([1,2], trie_store([1], trie_new()))),
?_test(no = trie_match([1], trie_store([1,2], trie_new()))),
?_test(no = trie_match([1,3], trie_store([1,2], trie_new()))),
?_test(exact = trie_match([1,2,3,4,5],
trie_store([1,2,3,4,5], trie_new()))),
?_test(prefix = trie_match([1,2,3,4,5],
trie_store([1,2,3], trie_new()))),
?_test(no = trie_match([1,2,2,4,5],
trie_store([1,2,3], trie_new())))
]},
{"matching with partially overlapping patterns",
setup,
fun () ->
trie_store([1,3,2], trie_store([1,2,3], trie_new()))
end,
fun (T) ->
[?_test(no = trie_match([], T)),
?_test(no = trie_match([1], T)),
?_test(no = trie_match([1,2], T)),
?_test(no = trie_match([1,3], T)),
?_test(exact = trie_match([1,2,3], T)),
?_test(exact = trie_match([1,3,2], T)),
?_test(no = trie_match([1,2,2], T)),
?_test(no = trie_match([1,3,3], T)),
?_test(prefix = trie_match([1,2,3,4], T)),
?_test(prefix = trie_match([1,3,2,1], T))]
end},
{"matching with more general pattern overriding less general",
setup,
fun () -> trie_store([1], trie_store([1,2,3], trie_new())) end,
fun (_) -> ok end,
fun (T) ->
[?_test(no = trie_match([], T)),
?_test(exact = trie_match([1], T)),
?_test(prefix = trie_match([1,2], T)),
?_test(prefix = trie_match([1,2,3], T)),
?_test(prefix = trie_match([1,2,3,4], T))]
end}
].
-endif. % TEST
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