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mirror of https://github.com/processone/ejabberd.git synced 2024-11-28 16:34:13 +01:00
xmpp.chapril.org-ejabberd/src/acl.erl
2019-01-08 22:53:27 +01:00

765 lines
26 KiB
Erlang

%%%----------------------------------------------------------------------
%%% File : acl.erl
%%% Author : Alexey Shchepin <alexey@process-one.net>
%%% Purpose : ACL support
%%% Created : 18 Jan 2003 by Alexey Shchepin <alexey@process-one.net>
%%%
%%%
%%% ejabberd, Copyright (C) 2002-2019 ProcessOne
%%%
%%% This program is free software; you can redistribute it and/or
%%% modify it under the terms of the GNU General Public License as
%%% published by the Free Software Foundation; either version 2 of the
%%% License, or (at your option) any later version.
%%%
%%% This program 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
%%% General Public License for more details.
%%%
%%% You should have received a copy of the GNU General Public License along
%%% with this program; if not, write to the Free Software Foundation, Inc.,
%%% 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
%%%
%%%----------------------------------------------------------------------
-module(acl).
-behaviour(gen_server).
-behaviour(ejabberd_config).
-author('alexey@process-one.net').
-export([add_access/3, clear/0]).
-export([start_link/0, add/3, add_list/3, add_local/3, add_list_local/3,
load_from_config/0, reload_from_config/0, match_rule/3,
any_rules_allowed/3, transform_options/1, opt_type/1,
acl_rule_matches/3, acl_rule_verify/1, access_matches/3,
transform_access_rules_config/1,
parse_ip_netmask/1, ip_matches_mask/3,
access_rules_validator/1, shaper_rules_validator/1,
normalize_spec/1, resolve_access/2]).
%% gen_server callbacks
-export([init/1, handle_call/3, handle_cast/2, handle_info/2,
terminate/2, code_change/3]).
-include("logger.hrl").
-include("jid.hrl").
-record(acl, {aclname, aclspec}).
-record(access, {name :: aclname(),
rules = [] :: [access_rule()]}).
-record(state, {}).
-type regexp() :: binary().
-type iprange() :: {inet:ip_address(), integer()} | binary().
-type glob() :: binary().
-type access_name() :: atom().
-type access_rule() :: {atom(), any()}.
-type host() :: binary().
-type aclname() :: {atom(), binary() | global}.
-type aclspec() :: all | none |
{user, {binary(), host()} | binary()} |
{server, binary()} |
{resource, binary()} |
{user_regexp, {regexp(), host()} | regexp()} |
{shared_group, {binary(), host()} | binary()} |
{user_regexp, {regexp(), host()} | regexp()} |
{server_regexp, regexp()} |
{resource_regexp, regexp()} |
{node_regexp, {regexp(), regexp()}} |
{user_glob, {glob(), host()} | glob()} |
{server_glob, glob()} |
{resource_glob, glob()} |
{ip, iprange()} |
{node_glob, {glob(), glob()}}.
-type acl() :: #acl{aclname :: aclname(),
aclspec :: aclspec()}.
-export_type([acl/0]).
start_link() ->
gen_server:start_link({local, ?MODULE}, ?MODULE, [], []).
init([]) ->
ejabberd_mnesia:create(?MODULE, acl,
[{ram_copies, [node()]}, {type, bag},
{local_content, true},
{attributes, record_info(fields, acl)}]),
ejabberd_mnesia:create(?MODULE, access,
[{ram_copies, [node()]},
{local_content, true},
{attributes, record_info(fields, access)}]),
ejabberd_hooks:add(config_reloaded, ?MODULE, reload_from_config, 20),
load_from_config(),
{ok, #state{}}.
handle_call(_Request, _From, State) ->
Reply = ok,
{reply, Reply, State}.
handle_cast(_Msg, State) ->
{noreply, State}.
handle_info(_Info, State) ->
{noreply, State}.
terminate(_Reason, _State) ->
ok.
code_change(_OldVsn, State, _Extra) ->
{ok, State}.
-spec add(binary(), aclname(), aclspec()) -> ok | {error, any()}.
add(Host, ACLName, ACLSpec) ->
{ResL, BadNodes} = ejabberd_cluster:multicall(
?MODULE, add_local,
[Host, ACLName, ACLSpec]),
case lists:keyfind(aborted, 1, ResL) of
false when BadNodes == [] ->
ok;
false ->
{error, {failed_nodes, BadNodes}};
Err ->
{error, Err}
end.
add_local(Host, ACLName, ACLSpec) ->
F = fun () ->
mnesia:write(#acl{aclname = {ACLName, Host},
aclspec = normalize_spec(ACLSpec)})
end,
case mnesia:transaction(F) of
{atomic, ok} ->
ok;
Err ->
Err
end.
-spec add_list(binary(), [acl()], boolean()) -> ok | {error, any()}.
add_list(Host, ACLs, Clear) ->
{ResL, BadNodes} = ejabberd_cluster:multicall(
?MODULE, add_list_local,
[Host, ACLs, Clear]),
case lists:keyfind(aborted, 1, ResL) of
false when BadNodes == [] ->
ok;
false ->
{error, {failed_nodes, BadNodes}};
Err ->
{error, Err}
end.
add_list_local(Host, ACLs, Clear) ->
F = fun () ->
if Clear ->
Ks = mnesia:select(acl,
[{{acl, {'$1', Host}, '$2'}, [],
['$1']}]),
lists:foreach(fun (K) -> mnesia:delete({acl, {K, Host}})
end,
Ks);
true -> ok
end,
lists:foreach(fun (ACL) ->
case ACL of
#acl{aclname = ACLName,
aclspec = ACLSpec} ->
mnesia:write(#acl{aclname =
{ACLName,
Host},
aclspec =
normalize_spec(ACLSpec)})
end
end,
ACLs)
end,
mnesia:transaction(F).
-spec add_access(binary() | global,
access_name(), [access_rule()]) -> ok | {error, any()}.
add_access(Host, Access, Rules) ->
Obj = #access{name = {Access, Host}, rules = Rules},
case mnesia:transaction(fun() -> mnesia:write(Obj) end) of
{atomic, ok} ->
ok;
Err ->
{error, Err}
end.
-spec load_from_config() -> ok.
load_from_config() ->
Hosts = [global|ejabberd_config:get_myhosts()],
lists:foreach(
fun(Host) ->
ACLs = ejabberd_config:get_option(
{acl, Host}, []),
AccessRules = ejabberd_config:get_option(
{access, Host}, []),
AccessRulesNew = ejabberd_config:get_option(
{access_rules, Host}, []),
ShaperRules = ejabberd_config:get_option(
{shaper_rules, Host}, []),
lists:foreach(
fun({ACLName, SpecList}) ->
lists:foreach(
fun({ACLType, ACLSpecs}) when is_list(ACLSpecs) ->
lists:foreach(
fun(ACLSpec) ->
add(Host, ACLName,
{ACLType, ACLSpec})
end, lists:flatten(ACLSpecs));
({ACLType, ACLSpecs}) ->
add(Host, ACLName, {ACLType, ACLSpecs})
end, lists:flatten(SpecList))
end, ACLs),
lists:foreach(
fun({Access, Rules}) ->
NRules = lists:map(fun({ACL, Type}) ->
{Type, [{acl, ACL}]}
end, Rules),
add_access(Host, Access, NRules ++ [{deny, [all]}])
end, AccessRules),
lists:foreach(
fun({Access, Rules}) ->
add_access(Host, Access, Rules)
end, AccessRulesNew),
lists:foreach(
fun({Access, Rules}) ->
add_access(Host, Access, Rules)
end, ShaperRules)
end, Hosts).
-spec reload_from_config() -> ok.
reload_from_config() ->
clear(),
load_from_config().
%% Delete all previous set ACLs and Access rules
clear() ->
mnesia:clear_table(acl),
mnesia:clear_table(access),
ok.
b(S) ->
iolist_to_binary(S).
nodeprep(S) ->
jid:nodeprep(b(S)).
nameprep(S) ->
jid:nameprep(b(S)).
resourceprep(S) ->
jid:resourceprep(b(S)).
split_user_server(Str, NormFunUsr, NormFunSrv) ->
case binary:split(Str, <<"@">>) of
[U, S] ->
{NormFunUsr(U), NormFunSrv(S)};
_ ->
NormFunUsr(Str)
end.
normalize_spec(Spec) ->
case Spec of
all -> all;
none -> none;
{acl, N} when is_atom(N) ->
{acl, N};
{user, {U, S}} when is_binary(U), is_binary(S) ->
{user, {nodeprep(U), nameprep(S)}};
{user, U} when is_binary(U) ->
{user, split_user_server(U, fun nodeprep/1, fun nameprep/1)};
{shared_group, {G, H}} when is_binary(G), is_binary(H) ->
{shared_group, {b(G), nameprep(H)}};
{shared_group, G} when is_binary(G) ->
{shared_group, split_user_server(G, fun b/1, fun nameprep/1)};
{user_regexp, {UR, S}} when is_binary(UR), is_binary(S) ->
{user_regexp, {b(UR), nameprep(S)}};
{user_regexp, UR} when is_binary(UR) ->
{user_regexp, split_user_server(UR, fun b/1, fun nameprep/1)};
{node_regexp, {UR, SR}} when is_binary(UR), is_binary(SR) ->
{node_regexp, {b(UR), b(SR)}};
{user_glob, {UR, S}} when is_binary(UR), is_binary(S) ->
{user_glob, {b(UR), nameprep(S)}};
{user_glob, UR} when is_binary(UR) ->
{user_glob, split_user_server(UR, fun b/1, fun nameprep/1)};
{node_glob, {UR, SR}} when is_binary(UR), is_binary(SR) ->
{node_glob, {b(UR), b(SR)}};
{server, S} when is_binary(S) ->
{server, nameprep(S)};
{resource, R} when is_binary(R) ->
{resource, resourceprep(R)};
{server_regexp, SR} when is_binary(SR) ->
{server_regexp, b(SR)};
{resource_regexp, R} when is_binary(R) ->
{resource_regexp, b(R)};
{server_glob, S} when is_binary(S) ->
{server_glob, b(S)};
{resource_glob, R} when is_binary(R) ->
{resource_glob, b(R)};
{ip, {Net, Mask}} when is_binary(Net), is_integer(Mask) ->
{ip, {Net, Mask}};
{ip, S} ->
case parse_ip_netmask(b(S)) of
{ok, Net, Mask} ->
{ip, {Net, Mask}};
error ->
?WARNING_MSG("Invalid network address: ~p", [S]),
none
end;
BadVal ->
throw({<<"Invalid acl value">>, BadVal})
end.
-spec any_rules_allowed(global | binary(), [access_name()],
jid() | ljid() | inet:ip_address()) -> boolean().
any_rules_allowed(Host, Access, Entity) ->
lists:any(fun (Rule) ->
allow == acl:match_rule(Host, Rule, Entity)
end,
Access).
-spec match_rule(global | binary(), access_name(),
jid() | ljid() | inet:ip_address()) -> any().
match_rule(Host, Access, IP) when tuple_size(IP) == 4;
tuple_size(IP) == 8 ->
access_matches(Access, #{ip => IP}, Host);
match_rule(Host, Access, JID) ->
access_matches(Access, #{usr => jid:tolower(JID)}, Host).
-spec acl_rule_verify(aclspec()) -> boolean().
acl_rule_verify(all) ->
true;
acl_rule_verify(none) ->
true;
acl_rule_verify({ip, {{A,B,C,D}, Mask}})
when is_integer(A), is_integer(B), is_integer(C), is_integer(D),
A >= 0, A =< 255, B >= 0, B =< 255, C >= 0, C =< 255, D >= 0, D =< 255,
is_integer(Mask), Mask >= 0, Mask =< 32 ->
true;
acl_rule_verify({ip, {{A,B,C,D,E,F,G,H}, Mask}}) when
is_integer(A), is_integer(B), is_integer(C), is_integer(D),
is_integer(E), is_integer(F), is_integer(G), is_integer(H),
A >= 0, A =< 65535, B >= 0, B =< 65535, C >= 0, C =< 65535, D >= 0, D =< 65535,
E >= 0, E =< 65535, F >= 0, F =< 65535, G >= 0, G =< 65535, H >= 0, H =< 65535,
is_integer(Mask), Mask >= 0, Mask =< 64 ->
true;
acl_rule_verify({user, {U, S}}) when is_binary(U), is_binary(S) ->
true;
acl_rule_verify({user, U}) when is_binary(U) ->
true;
acl_rule_verify({server, S}) when is_binary(S) ->
true;
acl_rule_verify({resource, R}) when is_binary(R) ->
true;
acl_rule_verify({shared_group, {G, H}}) when is_binary(G), is_binary(H) ->
true;
acl_rule_verify({shared_group, G}) when is_binary(G) ->
true;
acl_rule_verify({user_regexp, {UR, S}}) when is_binary(UR), is_binary(S) ->
true;
acl_rule_verify({user_regexp, UR}) when is_binary(UR) ->
true;
acl_rule_verify({server_regexp, SR}) when is_binary(SR) ->
true;
acl_rule_verify({resource_regexp, RR}) when is_binary(RR) ->
true;
acl_rule_verify({node_regexp, {UR, SR}}) when is_binary(UR), is_binary(SR) ->
true;
acl_rule_verify({user_glob, {UR, S}}) when is_binary(UR), is_binary(S) ->
true;
acl_rule_verify({user_glob, UR}) when is_binary(UR) ->
true;
acl_rule_verify({server_glob, SR}) when is_binary(SR) ->
true;
acl_rule_verify({resource_glob, RR}) when is_binary(RR) ->
true;
acl_rule_verify({node_glob, {UR, SR}}) when is_binary(UR), is_binary(SR) ->
true;
acl_rule_verify(_Spec) ->
false.
invalid_syntax(Msg, Data) ->
throw({invalid_syntax, (str:format(Msg, Data))}).
acl_rules_verify([{acl, Name} | Rest], true) when is_atom(Name) ->
acl_rules_verify(Rest, true);
acl_rules_verify([{acl, Name} = Rule | _Rest], false) when is_atom(Name) ->
invalid_syntax(<<"Using acl: rules not allowed: ~p">>, [Rule]);
acl_rules_verify([Rule | Rest], AllowAcl) ->
case acl_rule_verify(Rule) of
false ->
invalid_syntax(<<"Invalid rule: ~p">>, [Rule]);
true ->
acl_rules_verify(Rest, AllowAcl)
end;
acl_rules_verify([], _AllowAcl) ->
true;
acl_rules_verify(Rules, _AllowAcl) ->
invalid_syntax(<<"Not a acl rules list: ~p">>, [Rules]).
all_acl_rules_matches([], _Data, _Host) ->
false;
all_acl_rules_matches(Rules, Data, Host) ->
all_acl_rules_matches2(Rules, Data, Host).
all_acl_rules_matches2([Rule | Tail], Data, Host) ->
case acl_rule_matches(Rule, Data, Host) of
true ->
all_acl_rules_matches2(Tail, Data, Host);
false ->
false
end;
all_acl_rules_matches2([], _Data, _Host) ->
true.
any_acl_rules_matches([], _Data, _Host) ->
false;
any_acl_rules_matches([Rule|Tail], Data, Host) ->
case acl_rule_matches(Rule, Data, Host) of
true ->
true;
false ->
any_acl_rules_matches(Tail, Data, Host)
end.
-spec acl_rule_matches(aclspec(), any(), global|binary()) -> boolean().
acl_rule_matches(all, _Data, _Host) ->
true;
acl_rule_matches({acl, all}, _Data, _Host) ->
true;
acl_rule_matches({acl, Name}, Data, Host) ->
ACLs = get_aclspecs(Name, Host),
RawACLs = lists:map(fun(#acl{aclspec = R}) -> R end, ACLs),
any_acl_rules_matches(RawACLs, Data, Host);
acl_rule_matches({ip, {Net, Mask}}, #{ip := {IP, _Port}}, _Host) ->
ip_matches_mask(IP, Net, Mask);
acl_rule_matches({ip, {Net, Mask}}, #{ip := IP}, _Host) ->
ip_matches_mask(IP, Net, Mask);
acl_rule_matches({user, {U, S}}, #{usr := {U, S, _}}, _Host) ->
true;
acl_rule_matches({user, U}, #{usr := {U, S, _}}, _Host) ->
lists:member(S, ejabberd_config:get_myhosts());
acl_rule_matches({server, S}, #{usr := {_, S, _}}, _Host) ->
true;
acl_rule_matches({resource, R}, #{usr := {_, _, R}}, _Host) ->
true;
acl_rule_matches({shared_group, {G, H}}, #{usr := {U, S, _}}, _Host) ->
Mod = loaded_shared_roster_module(H),
Mod:is_user_in_group({U, S}, G, H);
acl_rule_matches({shared_group, G}, #{usr := {U, S, _}}, Host) ->
Mod = loaded_shared_roster_module(Host),
Mod:is_user_in_group({U, S}, G, Host);
acl_rule_matches({user_regexp, {UR, S}}, #{usr := {U, S, _}}, _Host) ->
is_regexp_match(U, UR);
acl_rule_matches({user_regexp, UR}, #{usr := {U, S, _}}, _Host) ->
lists:member(S, ejabberd_config:get_myhosts()) andalso is_regexp_match(U, UR);
acl_rule_matches({server_regexp, SR}, #{usr := {_, S, _}}, _Host) ->
is_regexp_match(S, SR);
acl_rule_matches({resource_regexp, RR}, #{usr := {_, _, R}}, _Host) ->
is_regexp_match(R, RR);
acl_rule_matches({node_regexp, {UR, SR}}, #{usr := {U, S, _}}, _Host) ->
is_regexp_match(U, UR) andalso is_regexp_match(S, SR);
acl_rule_matches({user_glob, {UR, S}}, #{usr := {U, S, _}}, _Host) ->
is_glob_match(U, UR);
acl_rule_matches({user_glob, UR}, #{usr := {U, S, _}}, _Host) ->
lists:member(S, ejabberd_config:get_myhosts()) andalso is_glob_match(U, UR);
acl_rule_matches({server_glob, SR}, #{usr := {_, S, _}}, _Host) ->
is_glob_match(S, SR);
acl_rule_matches({resource_glob, RR}, #{usr := {_, _, R}}, _Host) ->
is_glob_match(R, RR);
acl_rule_matches({node_glob, {UR, SR}}, #{usr := {U, S, _}}, _Host) ->
is_glob_match(U, UR) andalso is_glob_match(S, SR);
acl_rule_matches(_ACL, _Data, _Host) ->
false.
resolve_access(all, _Host) ->
all;
resolve_access(none, _Host) ->
none;
resolve_access(Name, Host) when is_atom(Name) ->
GAccess = mnesia:dirty_read(access, {Name, global}),
LAccess =
if Host /= global -> mnesia:dirty_read(access, {Name, Host});
true -> []
end,
case GAccess ++ LAccess of
[] ->
[];
AccessList ->
lists:flatmap(
fun(#access{rules = Rs}) ->
Rs
end, AccessList)
end;
resolve_access(Rules, _Host) when is_list(Rules) ->
Rules.
-spec access_matches(atom()|list(), any(), global|binary()) -> allow|deny|atom()|integer().
access_matches(Rules, Data, Host) ->
case resolve_access(Rules, Host) of
all -> allow;
none -> deny;
RRules -> access_rules_matches(RRules, Data, Host)
end.
-spec access_rules_matches(list(), any(), global|binary()) -> any().
access_rules_matches(AR, Data, Host) ->
access_rules_matches(AR, Data, Host, deny).
access_rules_matches([{Type, Acls} | Rest], Data, Host, Default) ->
case all_acl_rules_matches(Acls, Data, Host) of
false ->
access_rules_matches(Rest, Data, Host, Default);
true ->
Type
end;
access_rules_matches([], _Data, _Host, Default) ->
Default.
get_aclspecs(ACL, Host) ->
mnesia:dirty_read(acl, {ACL, Host}) ++ mnesia:dirty_read(acl, {ACL, global}).
is_regexp_match(String, RegExp) ->
case ejabberd_regexp:run(String, RegExp) of
nomatch -> false;
match -> true;
{error, ErrDesc} ->
?ERROR_MSG("Wrong regexp ~p in ACL: ~p",
[RegExp, ErrDesc]),
false
end.
is_glob_match(String, Glob) ->
is_regexp_match(String,
ejabberd_regexp:sh_to_awk(Glob)).
ip_matches_mask({_, _, _, _} = IP, {_, _, _, _} = Net, Mask) ->
IPInt = ip_to_integer(IP),
NetInt = ip_to_integer(Net),
M = bnot (1 bsl (32 - Mask) - 1),
IPInt band M =:= NetInt band M;
ip_matches_mask({_, _, _, _, _, _, _, _} = IP,
{_, _, _, _, _, _, _, _} = Net, Mask) ->
IPInt = ip_to_integer(IP),
NetInt = ip_to_integer(Net),
M = bnot (1 bsl (128 - Mask) - 1),
IPInt band M =:= NetInt band M;
ip_matches_mask({_, _, _, _} = IP,
{0, 0, 0, 0, 0, 16#FFFF, _, _} = Net, Mask) ->
IPInt = ip_to_integer({0, 0, 0, 0, 0, 16#FFFF, 0, 0}) + ip_to_integer(IP),
NetInt = ip_to_integer(Net),
M = bnot (1 bsl (128 - Mask) - 1),
IPInt band M =:= NetInt band M;
ip_matches_mask({0, 0, 0, 0, 0, 16#FFFF, _, _} = IP,
{_, _, _, _} = Net, Mask) ->
IPInt = ip_to_integer(IP) - ip_to_integer({0, 0, 0, 0, 0, 16#FFFF, 0, 0}),
NetInt = ip_to_integer(Net),
M = bnot (1 bsl (32 - Mask) - 1),
IPInt band M =:= NetInt band M;
ip_matches_mask(_, _, _) ->
false.
ip_to_integer({IP1, IP2, IP3, IP4}) ->
IP1 bsl 8 bor IP2 bsl 8 bor IP3 bsl 8 bor IP4;
ip_to_integer({IP1, IP2, IP3, IP4, IP5, IP6, IP7,
IP8}) ->
IP1 bsl 16 bor IP2 bsl 16 bor IP3 bsl 16 bor IP4 bsl 16
bor IP5
bsl 16
bor IP6
bsl 16
bor IP7
bsl 16
bor IP8.
loaded_shared_roster_module(Host) ->
case gen_mod:is_loaded(Host, mod_shared_roster_ldap) of
true -> mod_shared_roster_ldap;
false -> mod_shared_roster
end.
parse_ip_netmask(S) ->
case str:tokens(S, <<"/">>) of
[IPStr] ->
case inet_parse:address(binary_to_list(IPStr)) of
{ok, {_, _, _, _} = IP} -> {ok, IP, 32};
{ok, {_, _, _, _, _, _, _, _} = IP} -> {ok, IP, 128};
_ -> error
end;
[IPStr, MaskStr] ->
case catch binary_to_integer(MaskStr) of
Mask when is_integer(Mask), Mask >= 0 ->
case inet_parse:address(binary_to_list(IPStr)) of
{ok, {_, _, _, _} = IP} when Mask =< 32 ->
{ok, IP, Mask};
{ok, {_, _, _, _, _, _, _, _} = IP} when Mask =< 128 ->
{ok, IP, Mask};
_ -> error
end;
_ -> error
end;
_ -> error
end.
transform_access_rules_config(Config) when is_list(Config) ->
lists:map(fun transform_access_rules_config2/1, lists:flatten(Config));
transform_access_rules_config(Config) ->
transform_access_rules_config([Config]).
transform_access_rules_config2(Type) when is_integer(Type); is_atom(Type) ->
{Type, [all]};
transform_access_rules_config2({Type, ACL}) when is_atom(ACL) ->
{Type, [{acl, ACL}]};
transform_access_rules_config2({Res, Rules}) when is_list(Rules) ->
T = lists:map(fun({Type, Args}) when is_list(Args) ->
normalize_spec({Type, hd(lists:flatten(Args))});
(V) -> normalize_spec(V)
end, lists:flatten(Rules)),
{Res, T};
transform_access_rules_config2({Res, Rule}) ->
{Res, [Rule]}.
access_rules_validator(Name) when is_atom(Name) ->
Name;
access_rules_validator(Rules0) ->
Rules = transform_access_rules_config(Rules0),
access_shaper_rules_validator(Rules, fun(allow) -> true;
(deny) -> true;
(_) -> false
end),
Rules.
shaper_rules_validator(Name) when is_atom(Name) ->
Name;
shaper_rules_validator(Rules0) ->
Rules = transform_access_rules_config(Rules0),
access_shaper_rules_validator(Rules, fun(V) when is_atom(V) -> true;
(V2) when is_integer(V2) -> true;
(_) -> false
end),
Rules.
access_shaper_rules_validator([{Type, Acls} = Rule | Rest], RuleTypeCheck) ->
case RuleTypeCheck(Type) of
true ->
case acl_rules_verify(Acls, true) of
true ->
access_shaper_rules_validator(Rest, RuleTypeCheck);
Err ->
Err
end;
false ->
invalid_syntax(<<"Invalid rule type: ~p in rule ~p">>, [Type, Rule])
end;
access_shaper_rules_validator([], _RuleTypeCheck) ->
true;
access_shaper_rules_validator(Value, _RuleTypeCheck) ->
invalid_syntax(<<"Not a rule definition: ~p">>, [Value]).
transform_options(Opts) ->
Opts1 = lists:foldl(fun transform_options/2, [], Opts),
{ACLOpts, Opts2} = lists:mapfoldl(
fun({acl, Os}, Acc) ->
{Os, Acc};
(O, Acc) ->
{[], [O|Acc]}
end, [], Opts1),
{AccessOpts, Opts3} = lists:mapfoldl(
fun({access, Os}, Acc) ->
{Os, Acc};
(O, Acc) ->
{[], [O|Acc]}
end, [], Opts2),
{NewAccessOpts, Opts4} = lists:mapfoldl(
fun({access_rules, Os}, Acc) ->
{Os, Acc};
(O, Acc) ->
{[], [O|Acc]}
end, [], Opts3),
{ShaperOpts, Opts5} = lists:mapfoldl(
fun({shaper_rules, Os}, Acc) ->
{Os, Acc};
(O, Acc) ->
{[], [O|Acc]}
end, [], Opts4),
ACLOpts1 = ejabberd_config:collect_options(lists:flatten(ACLOpts)),
AccessOpts1 = case ejabberd_config:collect_options(
lists:flatten(AccessOpts)) of
[] -> [];
L1 -> [{access, L1}]
end,
ACLOpts2 = case lists:map(
fun({ACLName, Os}) ->
{ACLName, ejabberd_config:collect_options(Os)}
end, ACLOpts1) of
[] -> [];
L2 -> [{acl, L2}]
end,
NewAccessOpts1 = case lists:map(
fun({NAName, Os}) ->
{NAName, transform_access_rules_config(Os)}
end, lists:flatten(NewAccessOpts)) of
[] -> [];
L3 -> [{access_rules, L3}]
end,
ShaperOpts1 = case lists:map(
fun({SName, Ss}) ->
{SName, transform_access_rules_config(Ss)}
end, lists:flatten(ShaperOpts)) of
[] -> [];
L4 -> [{shaper_rules, L4}]
end,
ACLOpts2 ++ AccessOpts1 ++ NewAccessOpts1 ++ ShaperOpts1 ++ Opts5.
transform_options({acl, Name, Type}, Opts) ->
T = case Type of
all -> all;
none -> none;
{user, U} -> {user, [b(U)]};
{user, U, S} -> {user, [[{b(U), b(S)}]]};
{shared_group, G} -> {shared_group, [b(G)]};
{shared_group, G, H} -> {shared_group, [[{b(G), b(H)}]]};
{user_regexp, UR} -> {user_regexp, [b(UR)]};
{user_regexp, UR, S} -> {user_regexp, [[{b(UR), b(S)}]]};
{node_regexp, UR, SR} -> {node_regexp, [[{b(UR), b(SR)}]]};
{user_glob, UR} -> {user_glob, [b(UR)]};
{user_glob, UR, S} -> {user_glob, [[{b(UR), b(S)}]]};
{node_glob, UR, SR} -> {node_glob, [[{b(UR), b(SR)}]]};
{server, S} -> {server, [b(S)]};
{resource, R} -> {resource, [b(R)]};
{server_regexp, SR} -> {server_regexp, [b(SR)]};
{server_glob, S} -> {server_glob, [b(S)]};
{ip, S} -> {ip, [b(S)]};
{resource_glob, R} -> {resource_glob, [b(R)]};
{resource_regexp, R} -> {resource_regexp, [b(R)]}
end,
[{acl, [{Name, [T]}]}|Opts];
transform_options({access, Name, Rules}, Opts) ->
NewRules = [{ACL, Action} || {Action, ACL} <- Rules],
[{access, [{Name, NewRules}]}|Opts];
transform_options(Opt, Opts) ->
[Opt|Opts].
opt_type(access) -> fun (V) -> V end;
opt_type(access_rules) -> fun (V) -> V end;
opt_type(shaper_rules) -> fun (V) -> V end;
opt_type(acl) -> fun (V) -> V end;
opt_type(_) -> [access, acl, access_rules, shaper_rules].