%%%
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 1998-2016. All Rights Reserved.
%%
%% Licensed under the Apache License, Version 2.0 (the "License");
%% you may not use this file except in compliance with the License.
%% You may obtain a copy of the License at
%%
%% http://www.apache.org/licenses/LICENSE-2.0
%%
%% Unless required by applicable law or agreed to in writing, software
%% distributed under the License is distributed on an "AS IS" BASIS,
%% WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
%% See the License for the specific language governing permissions and
%% limitations under the License.
%%
%% %CopyrightEnd%
%%
%%%
%%%----------------------------------------------------------------------
%%% Purpose : Support tables so large that they need
%%% to be divided into several fragments.
%%%----------------------------------------------------------------------
%header_doc_include
-module(mnesia_frag).
%% Callback functions when accessed within an activity
-export([
lock/4,
write/5, delete/5, delete_object/5,
read/5, match_object/5, all_keys/4,
select/5,select/6,select_cont/3,
index_match_object/6, index_read/6,
foldl/6, foldr/6, table_info/4,
first/3, next/4, prev/4, last/3,
clear_table/4
]).
%header_doc_include
%% -behaviour(mnesia_access).
-export([
change_table_frag/2,
remove_node/2,
expand_cstruct/1,
lookup_frag_hash/1,
lookup_foreigners/1,
frag_names/1,
set_frag_hash/2,
local_select/4,
remote_select/4
]).
-include("mnesia.hrl").
-define(OLD_HASH_MOD, mnesia_frag_old_hash).
-define(DEFAULT_HASH_MOD, mnesia_frag_hash).
%%-define(DEFAULT_HASH_MOD, ?OLD_HASH_MOD). %% BUGBUG: New should be default
-record(frag_state,
{foreign_key,
n_fragments,
hash_module,
hash_state}).
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Access functions
%impl_doc_include
%% Callback functions which provides transparent
%% access of fragmented tables from any activity
%% access context.
lock(ActivityId, Opaque, {table , Tab}, LockKind) ->
case frag_names(Tab) of
[Tab] ->
mnesia:lock(ActivityId, Opaque, {table, Tab}, LockKind);
Frags ->
DeepNs = [mnesia:lock(ActivityId, Opaque, {table, F}, LockKind) ||
F <- Frags],
mnesia_lib:uniq(lists:append(DeepNs))
end;
lock(ActivityId, Opaque, LockItem, LockKind) ->
mnesia:lock(ActivityId, Opaque, LockItem, LockKind).
write(ActivityId, Opaque, Tab, Rec, LockKind) ->
Frag = record_to_frag_name(Tab, Rec),
mnesia:write(ActivityId, Opaque, Frag, Rec, LockKind).
delete(ActivityId, Opaque, Tab, Key, LockKind) ->
Frag = key_to_frag_name(Tab, Key),
mnesia:delete(ActivityId, Opaque, Frag, Key, LockKind).
delete_object(ActivityId, Opaque, Tab, Rec, LockKind) ->
Frag = record_to_frag_name(Tab, Rec),
mnesia:delete_object(ActivityId, Opaque, Frag, Rec, LockKind).
read(ActivityId, Opaque, Tab, Key, LockKind) ->
Frag = key_to_frag_name(Tab, Key),
mnesia:read(ActivityId, Opaque, Frag, Key, LockKind).
match_object(ActivityId, Opaque, Tab, HeadPat, LockKind) ->
MatchSpec = [{HeadPat, [], ['$_']}],
select(ActivityId, Opaque, Tab, MatchSpec, LockKind).
select(ActivityId, Opaque, Tab, MatchSpec, LockKind) ->
do_select(ActivityId, Opaque, Tab, MatchSpec, LockKind).
select(ActivityId, Opaque, Tab, MatchSpec, Limit, LockKind) ->
init_select(ActivityId, Opaque, Tab, MatchSpec, Limit, LockKind).
all_keys(ActivityId, Opaque, Tab, LockKind) ->
Match = [mnesia:all_keys(ActivityId, Opaque, Frag, LockKind)
|| Frag <- frag_names(Tab)],
lists:append(Match).
clear_table(ActivityId, Opaque, Tab, Obj) ->
[mnesia:clear_table(ActivityId, Opaque, Frag, Obj) || Frag <- frag_names(Tab)],
ok.
index_match_object(ActivityId, Opaque, Tab, Pat, Attr, LockKind) ->
Match =
[mnesia:index_match_object(ActivityId, Opaque, Frag, Pat, Attr, LockKind)
|| Frag <- frag_names(Tab)],
lists:append(Match).
index_read(ActivityId, Opaque, Tab, Key, Attr, LockKind) ->
Match =
[mnesia:index_read(ActivityId, Opaque, Frag, Key, Attr, LockKind)
|| Frag <- frag_names(Tab)],
lists:append(Match).
foldl(ActivityId, Opaque, Fun, Acc, Tab, LockKind) ->
Fun2 = fun(Frag, A) ->
mnesia:foldl(ActivityId, Opaque, Fun, A, Frag, LockKind)
end,
lists:foldl(Fun2, Acc, frag_names(Tab)).
foldr(ActivityId, Opaque, Fun, Acc, Tab, LockKind) ->
Fun2 = fun(Frag, A) ->
mnesia:foldr(ActivityId, Opaque, Fun, A, Frag, LockKind)
end,
lists:foldr(Fun2, Acc, frag_names(Tab)).
table_info(ActivityId, Opaque, {Tab, Key}, Item) ->
Frag = key_to_frag_name(Tab, Key),
table_info2(ActivityId, Opaque, Tab, Frag, Item);
table_info(ActivityId, Opaque, Tab, Item) ->
table_info2(ActivityId, Opaque, Tab, Tab, Item).
table_info2(ActivityId, Opaque, Tab, Frag, Item) ->
case Item of
size ->
SumFun = fun({_, Size}, Acc) -> Acc + Size end,
lists:foldl(SumFun, 0, frag_size(ActivityId, Opaque, Tab));
memory ->
SumFun = fun({_, Size}, Acc) -> Acc + Size end,
lists:foldl(SumFun, 0, frag_memory(ActivityId, Opaque, Tab));
base_table ->
lookup_prop(Tab, base_table);
node_pool ->
lookup_prop(Tab, node_pool);
n_fragments ->
FH = lookup_frag_hash(Tab),
FH#frag_state.n_fragments;
foreign_key ->
FH = lookup_frag_hash(Tab),
FH#frag_state.foreign_key;
foreigners ->
lookup_foreigners(Tab);
n_ram_copies ->
length(val({Tab, ram_copies}));
n_disc_copies ->
length(val({Tab, disc_copies}));
n_disc_only_copies ->
length(val({Tab, disc_only_copies}));
n_external_copies ->
length(val({Tab, external_copies}));
frag_names ->
frag_names(Tab);
frag_dist ->
frag_dist(Tab);
frag_size ->
frag_size(ActivityId, Opaque, Tab);
frag_memory ->
frag_memory(ActivityId, Opaque, Tab);
_ ->
mnesia:table_info(ActivityId, Opaque, Frag, Item)
end.
first(ActivityId, Opaque, Tab) ->
case ?catch_val({Tab, frag_hash}) of
{'EXIT', _} ->
mnesia:first(ActivityId, Opaque, Tab);
FH ->
FirstFrag = Tab,
case mnesia:first(ActivityId, Opaque, FirstFrag) of
'$end_of_table' ->
search_first(ActivityId, Opaque, Tab, 1, FH);
Next ->
Next
end
end.
search_first(ActivityId, Opaque, Tab, N, FH) when N < FH#frag_state.n_fragments ->
NextN = N + 1,
NextFrag = n_to_frag_name(Tab, NextN),
case mnesia:first(ActivityId, Opaque, NextFrag) of
'$end_of_table' ->
search_first(ActivityId, Opaque, Tab, NextN, FH);
Next ->
Next
end;
search_first(_ActivityId, _Opaque, _Tab, _N, _FH) ->
'$end_of_table'.
last(ActivityId, Opaque, Tab) ->
case ?catch_val({Tab, frag_hash}) of
{'EXIT', _} ->
mnesia:last(ActivityId, Opaque, Tab);
FH ->
LastN = FH#frag_state.n_fragments,
search_last(ActivityId, Opaque, Tab, LastN, FH)
end.
search_last(ActivityId, Opaque, Tab, N, FH) when N >= 1 ->
Frag = n_to_frag_name(Tab, N),
case mnesia:last(ActivityId, Opaque, Frag) of
'$end_of_table' ->
PrevN = N - 1,
search_last(ActivityId, Opaque, Tab, PrevN, FH);
Prev ->
Prev
end;
search_last(_ActivityId, _Opaque, _Tab, _N, _FH) ->
'$end_of_table'.
prev(ActivityId, Opaque, Tab, Key) ->
case ?catch_val({Tab, frag_hash}) of
{'EXIT', _} ->
mnesia:prev(ActivityId, Opaque, Tab, Key);
FH ->
N = key_to_n(FH, Key),
Frag = n_to_frag_name(Tab, N),
case mnesia:prev(ActivityId, Opaque, Frag, Key) of
'$end_of_table' ->
search_prev(ActivityId, Opaque, Tab, N);
Prev ->
Prev
end
end.
search_prev(ActivityId, Opaque, Tab, N) when N > 1 ->
PrevN = N - 1,
PrevFrag = n_to_frag_name(Tab, PrevN),
case mnesia:last(ActivityId, Opaque, PrevFrag) of
'$end_of_table' ->
search_prev(ActivityId, Opaque, Tab, PrevN);
Prev ->
Prev
end;
search_prev(_ActivityId, _Opaque, _Tab, _N) ->
'$end_of_table'.
next(ActivityId, Opaque, Tab, Key) ->
case ?catch_val({Tab, frag_hash}) of
{'EXIT', _} ->
mnesia:next(ActivityId, Opaque, Tab, Key);
FH ->
N = key_to_n(FH, Key),
Frag = n_to_frag_name(Tab, N),
case mnesia:next(ActivityId, Opaque, Frag, Key) of
'$end_of_table' ->
search_next(ActivityId, Opaque, Tab, N, FH);
Prev ->
Prev
end
end.
search_next(ActivityId, Opaque, Tab, N, FH) when N < FH#frag_state.n_fragments ->
NextN = N + 1,
NextFrag = n_to_frag_name(Tab, NextN),
case mnesia:first(ActivityId, Opaque, NextFrag) of
'$end_of_table' ->
search_next(ActivityId, Opaque, Tab, NextN, FH);
Next ->
Next
end;
search_next(_ActivityId, _Opaque, _Tab, _N, _FH) ->
'$end_of_table'.
%impl_doc_include
frag_size(ActivityId, Opaque, Tab) ->
[{F, remote_table_info(ActivityId, Opaque, F, size)} || F <- frag_names(Tab)].
frag_memory(ActivityId, Opaque, Tab) ->
[{F, remote_table_info(ActivityId, Opaque, F, memory)} || F <- frag_names(Tab)].
remote_table_info(ActivityId, Opaque, Tab, Item) ->
N = val({Tab, where_to_read}),
case rpc:call(N, mnesia, table_info, [ActivityId, Opaque, Tab, Item]) of
{badrpc, _} ->
mnesia:abort({no_exists, Tab, Item});
Info ->
Info
end.
init_select(Tid,Opaque,Tab,Pat,Limit,LockKind) ->
case ?catch_val({Tab, frag_hash}) of
{'EXIT', _} ->
mnesia:select(Tid, Opaque, Tab, Pat, Limit,LockKind);
FH ->
FragNumbers = verify_numbers(FH,Pat),
Fun = fun(Num) ->
Name = n_to_frag_name(Tab, Num),
Node = val({Name, where_to_read}),
Storage = mnesia_lib:storage_type_at_node(Node, Name),
mnesia:lock(Tid, Opaque, {table, Name}, LockKind),
{Name, Node, Storage}
end,
[{FTab,Node,Type}|NameNodes] = lists:map(Fun, FragNumbers),
InitFun = fun(FixedSpec) -> mnesia:dirty_sel_init(Node,FTab,FixedSpec,Limit,Type) end,
Res = mnesia:fun_select(Tid,Opaque,FTab,Pat,LockKind,FTab,InitFun,Limit,Node,Type),
frag_sel_cont(Res, NameNodes, {Pat,LockKind,Limit})
end.
select_cont(_Tid,_,{frag_cont, '$end_of_table', [],_}) -> '$end_of_table';
select_cont(Tid,Ts,{frag_cont, '$end_of_table', [{Tab,Node,Type}|Rest],Args}) ->
{Spec,LockKind,Limit} = Args,
InitFun = fun(FixedSpec) -> mnesia:dirty_sel_init(Node,Tab,FixedSpec,Limit,Type) end,
Res = mnesia:fun_select(Tid,Ts,Tab,Spec,LockKind,Tab,InitFun,Limit,Node,Type),
frag_sel_cont(Res, Rest, Args);
select_cont(Tid,Ts,{frag_cont, Cont, TabL, Args}) ->
frag_sel_cont(mnesia:select_cont(Tid,Ts,Cont),TabL,Args);
select_cont(Tid,Ts,Else) -> %% Not a fragmented table
mnesia:select_cont(Tid,Ts,Else).
frag_sel_cont('$end_of_table', [],_) ->
'$end_of_table';
frag_sel_cont('$end_of_table', TabL,Args) ->
{[], {frag_cont, '$end_of_table', TabL,Args}};
frag_sel_cont({Recs,Cont}, TabL,Args) ->
{Recs, {frag_cont, Cont, TabL,Args}}.
do_select(ActivityId, Opaque, Tab, MatchSpec, LockKind) ->
case ?catch_val({Tab, frag_hash}) of
{'EXIT', _} ->
mnesia:select(ActivityId, Opaque, Tab, MatchSpec, LockKind);
FH ->
FragNumbers = verify_numbers(FH,MatchSpec),
Fun = fun(Num) ->
Name = n_to_frag_name(Tab, Num),
Node = val({Name, where_to_read}),
mnesia:lock(ActivityId, Opaque, {table, Name}, LockKind),
{Name, Node}
end,
NameNodes = lists:map(Fun, FragNumbers),
SelectAllFun =
fun(PatchedMatchSpec) ->
Match = [mnesia:dirty_select(Name, PatchedMatchSpec)
|| {Name, _Node} <- NameNodes],
lists:append(Match)
end,
case [{Name, Node} || {Name, Node} <- NameNodes, Node /= node()] of
[] ->
%% All fragments are local
mnesia:fun_select(ActivityId, Opaque, Tab, MatchSpec, none, '_', SelectAllFun);
RemoteNameNodes ->
Type = val({Tab,setorbag}),
SelectFun =
fun(PatchedMatchSpec) ->
Ref = make_ref(),
Args = [self(), Ref, RemoteNameNodes, PatchedMatchSpec],
Pid = spawn_link(?MODULE, local_select, Args),
LocalMatch0 = [mnesia:dirty_select(Name, PatchedMatchSpec)
|| {Name, Node} <- NameNodes, Node == node()],
LocalMatch = case Type of
ordered_set -> lists:merge(LocalMatch0);
_ -> lists:append(LocalMatch0)
end,
OldSelectFun = fun() -> SelectAllFun(PatchedMatchSpec) end,
local_collect(Ref, Pid, Type, LocalMatch, OldSelectFun)
end,
mnesia:fun_select(ActivityId, Opaque, Tab, MatchSpec, none, '_', SelectFun)
end
end.
verify_numbers(FH,MatchSpec) ->
HashState = FH#frag_state.hash_state,
FragNumbers =
case FH#frag_state.hash_module of
HashMod when HashMod == ?DEFAULT_HASH_MOD ->
?DEFAULT_HASH_MOD:match_spec_to_frag_numbers(HashState, MatchSpec);
HashMod ->
HashMod:match_spec_to_frag_numbers(HashState, MatchSpec)
end,
N = FH#frag_state.n_fragments,
VerifyFun = fun(F) when is_integer(F), F >= 1, F =< N -> false;
(_F) -> true
end,
try
Frags = lists:filter(VerifyFun, FragNumbers),
Frags == [] orelse error(Frags),
FragNumbers
catch error:BadFrags ->
mnesia:abort({"match_spec_to_frag_numbers: Fragment numbers out of range",
BadFrags, {range, 1, N}})
end.
local_select(ReplyTo, Ref, RemoteNameNodes, MatchSpec) ->
RemoteNodes = mnesia_lib:uniq([Node || {_Name, Node} <- RemoteNameNodes]),
Args = [ReplyTo, Ref, RemoteNameNodes, MatchSpec],
{Replies, BadNodes} = rpc:multicall(RemoteNodes, ?MODULE, remote_select, Args),
case mnesia_lib:uniq(Replies) -- [ok] of
[] when BadNodes == [] ->
ReplyTo ! {local_select, Ref, ok};
_ when BadNodes /= [] ->
ReplyTo ! {local_select, Ref, {error, {node_not_running, hd(BadNodes)}}};
[{badrpc, {'EXIT', Reason}} | _] ->
ReplyTo ! {local_select, Ref, {error, Reason}};
[Reason | _] ->
ReplyTo ! {local_select, Ref, {error, Reason}}
end,
unlink(ReplyTo),
exit(normal).
remote_select(ReplyTo, Ref, NameNodes, MatchSpec) ->
do_remote_select(ReplyTo, Ref, NameNodes, MatchSpec).
do_remote_select(ReplyTo, Ref, [{Name, Node} | NameNodes], MatchSpec) ->
if
Node == node() ->
Res = ?CATCH({ok, mnesia:dirty_select(Name, MatchSpec)}),
ReplyTo ! {remote_select, Ref, Node, Res},
do_remote_select(ReplyTo, Ref, NameNodes, MatchSpec);
true ->
do_remote_select(ReplyTo, Ref, NameNodes, MatchSpec)
end;
do_remote_select(_ReplyTo, _Ref, [], _MatchSpec) ->
ok.
local_collect(Ref, Pid, Type, LocalMatch, OldSelectFun) ->
receive
{local_select, Ref, ok} ->
remote_collect_ok(Ref, Type, LocalMatch, OldSelectFun);
{local_select, Ref, {error, Reason}} ->
remote_collect_error(Ref, Type, Reason, OldSelectFun);
{'EXIT', Pid, Reason} ->
remote_collect_error(Ref, Type, Reason, OldSelectFun)
end.
remote_collect_ok(Ref, Type, Acc, OldSelectFun) ->
receive
{remote_select, Ref, Node, RemoteRes} ->
case RemoteRes of
{ok, RemoteMatch} ->
Matches = case Type of
ordered_set -> lists:merge(RemoteMatch, Acc);
_ -> RemoteMatch ++ Acc
end,
remote_collect_ok(Ref, Type, Matches, OldSelectFun);
_ ->
Reason = {node_not_running, Node},
remote_collect_error(Ref, Type, Reason, OldSelectFun)
end
after 0 ->
Acc
end.
remote_collect_error(Ref, Type, Reason, OldSelectFun) ->
receive
{remote_select, Ref, _Node, _RemoteRes} ->
remote_collect_error(Ref, Type, Reason, OldSelectFun)
after 0 ->
mnesia:abort({error, Reason})
end.
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Returns a list of cstructs
expand_cstruct(Cs) ->
expand_cstruct(Cs, create).
expand_cstruct(Cs, Mode) ->
Tab = Cs#cstruct.name,
Props = Cs#cstruct.frag_properties,
mnesia_schema:verify({alt, [nil, list]}, mnesia_lib:etype(Props),
{badarg, Tab, Props}),
%% Verify keys
ValidKeys = [foreign_key, n_fragments, node_pool,
n_ram_copies, n_disc_copies, n_disc_only_copies,
n_external_copies, hash_module, hash_state],
Keys = mnesia_schema:check_keys(Tab, Props, ValidKeys),
mnesia_schema:check_duplicates(Tab, Keys),
%% Pick fragmentation props
ForeignKey = mnesia_schema:pick(Tab, foreign_key, Props, undefined),
{ForeignKey2, N, Pool, DefaultNR, DefaultND, DefaultNDO, DefaultNExt} =
pick_props(Tab, Cs, ForeignKey),
%% Verify node_pool
BadPool = {bad_type, Tab, {node_pool, Pool}},
mnesia_schema:verify(list, mnesia_lib:etype(Pool), BadPool),
NotAtom = fun(A) when is_atom(A) -> false;
(_A) -> true
end,
mnesia_schema:verify([], [P || P <- Pool, NotAtom(P)], BadPool),
NR = mnesia_schema:pick(Tab, n_ram_copies, Props, 0),
ND = mnesia_schema:pick(Tab, n_disc_copies, Props, 0),
NDO = mnesia_schema:pick(Tab, n_disc_only_copies, Props, 0),
NExt = mnesia_schema:pick(Tab, n_external_copies, Props, 0),
PosInt = fun(I) when is_integer(I), I >= 0 -> true;
(_I) -> false
end,
mnesia_schema:verify(true, PosInt(NR),
{bad_type, Tab, {n_ram_copies, NR}}),
mnesia_schema:verify(true, PosInt(ND),
{bad_type, Tab, {n_disc_copies, ND}}),
mnesia_schema:verify(true, PosInt(NDO),
{bad_type, Tab, {n_disc_only_copies, NDO}}),
mnesia_schema:verify(true, PosInt(NExt),
{bad_type, Tab, {n_external_copies, NDO}}),
%% Verify n_fragments
Cs2 = verify_n_fragments(N, Cs, Mode),
%% Verify hash callback
HashMod = mnesia_schema:pick(Tab, hash_module, Props, ?DEFAULT_HASH_MOD),
HashState = mnesia_schema:pick(Tab, hash_state, Props, undefined),
HashState2 = HashMod:init_state(Tab, HashState), %% BUGBUG: Catch?
FH = #frag_state{foreign_key = ForeignKey2,
n_fragments = 1,
hash_module = HashMod,
hash_state = HashState2},
if
NR == 0, ND == 0, NDO == 0, NExt == 0 ->
do_expand_cstruct(Cs2, FH, N, Pool, DefaultNR, DefaultND, DefaultNDO, DefaultNExt, Mode);
true ->
do_expand_cstruct(Cs2, FH, N, Pool, NR, ND, NDO, NExt, Mode)
end.
do_expand_cstruct(Cs, FH, N, Pool, NR, ND, NDO, NExt, Mode) ->
Tab = Cs#cstruct.name,
LC = Cs#cstruct.local_content,
mnesia_schema:verify(false, LC,
{combine_error, Tab, {local_content, LC}}),
Snmp = Cs#cstruct.snmp,
mnesia_schema:verify([], Snmp,
{combine_error, Tab, {snmp, Snmp}}),
%% Add empty fragments
CommonProps = [{base_table, Tab}],
Cs2 = Cs#cstruct{frag_properties = lists:sort(CommonProps)},
expand_frag_cstructs(N, NR, ND, NDO, NExt, Cs2, Pool, Pool, FH, Mode).
verify_n_fragments(N, Cs, Mode) when is_integer(N), N >= 1 ->
case Mode of
create ->
Cs#cstruct{ram_copies = [],
disc_copies = [],
disc_only_copies = [],
external_copies = []};
activate ->
Reason = {combine_error, Cs#cstruct.name, {n_fragments, N}},
mnesia_schema:verify(1, N, Reason),
Cs
end;
verify_n_fragments(N, Cs, _Mode) ->
mnesia:abort({bad_type, Cs#cstruct.name, {n_fragments, N}}).
pick_props(Tab, Cs, {ForeignTab, Attr}) ->
mnesia_schema:verify(true, ForeignTab /= Tab,
{combine_error, Tab, {ForeignTab, Attr}}),
Props = Cs#cstruct.frag_properties,
Attrs = Cs#cstruct.attributes,
ForeignKey = lookup_prop(ForeignTab, foreign_key),
ForeignN = lookup_prop(ForeignTab, n_fragments),
ForeignPool = lookup_prop(ForeignTab, node_pool),
N = mnesia_schema:pick(Tab, n_fragments, Props, ForeignN),
Pool = mnesia_schema:pick(Tab, node_pool, Props, ForeignPool),
mnesia_schema:verify(ForeignN, N,
{combine_error, Tab, {n_fragments, N},
ForeignTab, {n_fragments, ForeignN}}),
mnesia_schema:verify(ForeignPool, Pool,
{combine_error, Tab, {node_pool, Pool},
ForeignTab, {node_pool, ForeignPool}}),
mnesia_schema:verify(undefined, ForeignKey,
{combine_error, Tab,
"Multiple levels of foreign_key dependencies",
{ForeignTab, Attr}, ForeignKey}),
Key = {ForeignTab, mnesia_schema:attr_to_pos(Attr, Attrs)},
DefaultNR = length(val({ForeignTab, ram_copies})),
DefaultND = length(val({ForeignTab, disc_copies})),
DefaultNDO = length(val({ForeignTab, disc_only_copies})),
DefaultNExt = length(val({ForeignTab, external_copies})),
{Key, N, Pool, DefaultNR, DefaultND, DefaultNDO, DefaultNExt};
pick_props(Tab, Cs, undefined) ->
Props = Cs#cstruct.frag_properties,
DefaultN = 1,
DefaultPool = mnesia:system_info(db_nodes),
N = mnesia_schema:pick(Tab, n_fragments, Props, DefaultN),
Pool = mnesia_schema:pick(Tab, node_pool, Props, DefaultPool),
DefaultNR = 1,
DefaultND = 0,
DefaultNDO = 0,
DefaultNExt = 0,
{undefined, N, Pool, DefaultNR, DefaultND, DefaultNDO, DefaultNExt};
pick_props(Tab, _Cs, BadKey) ->
mnesia:abort({bad_type, Tab, {foreign_key, BadKey}}).
expand_frag_cstructs(N, NR, ND, NDO, NExt, CommonCs, Dist, Pool, FH, Mode)
when N > 1, Mode == create ->
Frag = n_to_frag_name(CommonCs#cstruct.name, N),
Cs = CommonCs#cstruct{name = Frag},
{Cs2, RevModDist, RestDist} = set_frag_nodes(NR, ND, NDO, NExt, Cs, Dist, []),
ModDist = lists:reverse(RevModDist),
Dist2 = rearrange_dist(Cs, ModDist, RestDist, Pool),
%% Adjusts backwards, but it doesn't matter.
{FH2, _FromFrags, _AdditionalWriteFrags} = adjust_before_split(FH),
CsList = expand_frag_cstructs(N - 1, NR, ND, NDO, NExt, CommonCs, Dist2, Pool, FH2, Mode),
[Cs2 | CsList];
expand_frag_cstructs(1, NR, ND, NDO, NExt, CommonCs, Dist, Pool, FH, Mode) ->
BaseProps = CommonCs#cstruct.frag_properties ++
[{foreign_key, FH#frag_state.foreign_key},
{hash_module, FH#frag_state.hash_module},
{hash_state, FH#frag_state.hash_state},
{n_fragments, FH#frag_state.n_fragments},
{node_pool, Pool}
],
BaseCs = CommonCs#cstruct{frag_properties = lists:sort(BaseProps)},
case Mode of
activate ->
[BaseCs];
create ->
{BaseCs2, _, _} = set_frag_nodes(NR, ND, NDO, NExt, BaseCs, Dist, []),
[BaseCs2]
end.
set_frag_nodes(NR, ND, NDO, NExt, Cs, [Head | Tail], Acc) when NR > 0 ->
Pos = #cstruct.ram_copies,
{Cs2, Head2} = set_frag_node(Cs, Pos, Head),
set_frag_nodes(NR - 1, ND, NDO, NExt, Cs2, Tail, [Head2 | Acc]);
set_frag_nodes(NR, ND, NDO, NExt, Cs, [Head | Tail], Acc) when ND > 0 ->
Pos = #cstruct.disc_copies,
{Cs2, Head2} = set_frag_node(Cs, Pos, Head),
set_frag_nodes(NR, ND - 1, NDO, NExt, Cs2, Tail, [Head2 | Acc]);
set_frag_nodes(NR, ND, NDO, NExt, Cs, [Head | Tail], Acc) when NDO > 0 ->
Pos = #cstruct.disc_only_copies,
{Cs2, Head2} = set_frag_node(Cs, Pos, Head),
set_frag_nodes(NR, ND, NDO - 1, NExt, Cs2, Tail, [Head2 | Acc]);
set_frag_nodes(NR, ND, NDO, NExt, Cs, [Head | Tail], Acc) when NExt > 0 ->
Pos = #cstruct.external_copies,
{Cs2, Head2} = set_frag_node(Cs, Pos, Head),
set_frag_nodes(NR, ND, NDO, NExt - 1, Cs2, Tail, [Head2 | Acc]);
set_frag_nodes(0, 0, 0, 0, Cs, RestDist, ModDist) ->
{Cs, ModDist, RestDist};
set_frag_nodes(_, _, _, _, Cs, [], _) ->
mnesia:abort({combine_error, Cs#cstruct.name, "Too few nodes in node_pool"}).
set_frag_node(Cs, Pos, Head) ->
Ns = element(Pos, Cs),
{Node, Count2} =
case Head of
{N, Count} when is_atom(N), is_integer(Count), Count >= 0 ->
{N, Count + 1};
N when is_atom(N) ->
{N, 1};
BadNode ->
mnesia:abort({bad_type, Cs#cstruct.name, BadNode})
end,
mnesia_schema:verify(true,
lists:member(Node, val({current,db_nodes})),
{not_active, Cs#cstruct.name, Node}),
Cs2 = setelement(Pos, Cs, [Node | Ns]),
{Cs2, {Node, Count2}}.
rearrange_dist(Cs, [{Node, Count} | ModDist], Dist, Pool) ->
Dist2 = insert_dist(Cs, Node, Count, Dist, Pool),
rearrange_dist(Cs, ModDist, Dist2, Pool);
rearrange_dist(_Cs, [], Dist, _) ->
Dist.
insert_dist(Cs, Node, Count, [Head | Tail], Pool) ->
case Head of
{Node2, Count2} when is_atom(Node2), is_integer(Count2), Count2 >= 0 ->
case node_diff(Node, Count, Node2, Count2, Pool) of
less ->
[{Node, Count}, Head | Tail];
greater ->
[Head | insert_dist(Cs, Node, Count, Tail, Pool)]
end;
Node2 when is_atom(Node2) ->
insert_dist(Cs, Node, Count, [{Node2, 0} | Tail], Pool);
BadNode ->
mnesia:abort({bad_type, Cs#cstruct.name, BadNode})
end;
insert_dist(_Cs, Node, Count, [], _Pool) ->
[{Node, Count}];
insert_dist(_Cs, _Node, _Count, Dist, _Pool) ->
mnesia:abort({bad_type, Dist}).
node_diff(_Node, Count, _Node2, Count2, _Pool) when Count < Count2 ->
less;
node_diff(Node, Count, Node2, Count2, Pool) when Count == Count2 ->
Pos = list_pos(Node, Pool, 1),
Pos2 = list_pos(Node2, Pool, 1),
if
Pos < Pos2 ->
less;
Pos > Pos2 ->
greater
end;
node_diff(_Node, Count, _Node2, Count2, _Pool) when Count > Count2 ->
greater.
%% Returns position of element in list
list_pos(H, [H | _T], Pos) ->
Pos;
list_pos(E, [_H | T], Pos) ->
list_pos(E, T, Pos + 1).
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Switch function for changing of table fragmentation
%%
%% Returns a list of lists of schema ops
change_table_frag(Tab, {activate, FragProps}) ->
make_activate(Tab, FragProps);
change_table_frag(Tab, deactivate) ->
make_deactivate(Tab);
change_table_frag(Tab, {add_frag, SortedNodes}) ->
make_multi_add_frag(Tab, SortedNodes);
change_table_frag(Tab, del_frag) ->
make_multi_del_frag(Tab);
change_table_frag(Tab, {add_node, Node}) ->
make_multi_add_node(Tab, Node);
change_table_frag(Tab, {del_node, Node}) ->
make_multi_del_node(Tab, Node);
change_table_frag(Tab, Change) ->
mnesia:abort({bad_type, Tab, Change}).
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Turn a normal table into a fragmented table
%%
%% The storage type must be the same on all nodes
make_activate(Tab, Props) ->
Cs = mnesia_schema:incr_version(val({Tab, cstruct})),
mnesia_schema:ensure_active(Cs),
case Cs#cstruct.frag_properties of
[] ->
Cs2 = Cs#cstruct{frag_properties = Props},
[Cs3] = expand_cstruct(Cs2, activate),
TabDef = mnesia_schema:vsn_cs2list(Cs3),
Op = {op, change_table_frag, activate, TabDef},
[[Op]];
BadProps ->
mnesia:abort({already_exists, Tab, {frag_properties, BadProps}})
end.
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Turn a table into a normal defragmented table
make_deactivate(Tab) ->
Cs = mnesia_schema:incr_version(val({Tab, cstruct})),
mnesia_schema:ensure_active(Cs),
Foreigners = lookup_foreigners(Tab),
BaseTab = lookup_prop(Tab, base_table),
FH = lookup_frag_hash(Tab),
if
BaseTab /= Tab ->
mnesia:abort({combine_error, Tab, "Not a base table"});
Foreigners /= [] ->
mnesia:abort({combine_error, Tab, "Too many foreigners", Foreigners});
FH#frag_state.n_fragments > 1 ->
mnesia:abort({combine_error, Tab, "Too many fragments"});
true ->
Cs2 = Cs#cstruct{frag_properties = []},
TabDef = mnesia_schema:vsn_cs2list(Cs2),
Op = {op, change_table_frag, deactivate, TabDef},
[[Op]]
end.
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Add a fragment to a fragmented table and fill it with half of
%% the records from one of the old fragments
make_multi_add_frag(Tab, SortedNs) when is_list(SortedNs) ->
verify_multi(Tab),
Ops = make_add_frag(Tab, SortedNs),
%% Propagate to foreigners
MoreOps = [make_add_frag(T, SortedNs) || T <- lookup_foreigners(Tab)],
[Ops | MoreOps];
make_multi_add_frag(Tab, SortedNs) ->
mnesia:abort({bad_type, Tab, SortedNs}).
verify_multi(Tab) ->
FH = lookup_frag_hash(Tab),
ForeignKey = FH#frag_state.foreign_key,
mnesia_schema:verify(undefined, ForeignKey,
{combine_error, Tab,
"Op only allowed via foreign table",
{foreign_key, ForeignKey}}).
make_frag_names_and_acquire_locks(Tab, N, FragIndecies, DoNotLockN) ->
mnesia_schema:get_tid_ts_and_lock(Tab, write),
Fun = fun(Index, FN) ->
if
DoNotLockN == true, Index == N ->
Name = n_to_frag_name(Tab, Index),
setelement(Index, FN, Name);
true ->
Name = n_to_frag_name(Tab, Index),
mnesia_schema:get_tid_ts_and_lock(Name, write),
setelement(Index , FN, Name)
end
end,
FragNames = erlang:make_tuple(N, undefined),
lists:foldl(Fun, FragNames, FragIndecies).
make_add_frag(Tab, SortedNs) ->
Cs = mnesia_schema:incr_version(val({Tab, cstruct})),
mnesia_schema:ensure_active(Cs),
FH = lookup_frag_hash(Tab),
{FH2, FromIndecies, WriteIndecies} = adjust_before_split(FH),
N = FH2#frag_state.n_fragments,
FragNames = make_frag_names_and_acquire_locks(Tab, N, WriteIndecies, true),
NewFrag = element(N, FragNames),
NR = length(Cs#cstruct.ram_copies),
ND = length(Cs#cstruct.disc_copies),
NDO = length(Cs#cstruct.disc_only_copies),
NExt = length(Cs#cstruct.external_copies),
NewCs = Cs#cstruct{name = NewFrag,
frag_properties = [{base_table, Tab}],
ram_copies = [],
disc_copies = [],
disc_only_copies = [],
external_copies = []},
{NewCs2, _, _} = set_frag_nodes(NR, ND, NDO, NExt, NewCs, SortedNs, []),
[NewOp] = mnesia_schema:make_create_table(NewCs2),
SplitOps = split(Tab, FH2, FromIndecies, FragNames, []),
Cs2 = replace_frag_hash(Cs, FH2),
TabDef = mnesia_schema:vsn_cs2list(Cs2),
BaseOp = {op, change_table_frag, {add_frag, SortedNs}, TabDef},
[BaseOp, NewOp | SplitOps].
replace_frag_hash(Cs, FH) when is_record(FH, frag_state) ->
Fun = fun(Prop) ->
case Prop of
{n_fragments, _} ->
{true, {n_fragments, FH#frag_state.n_fragments}};
{hash_module, _} ->
{true, {hash_module, FH#frag_state.hash_module}};
{hash_state, _} ->
{true, {hash_state, FH#frag_state.hash_state}};
{next_n_to_split, _} ->
false;
{n_doubles, _} ->
false;
_ ->
true
end
end,
Props = lists:zf(Fun, Cs#cstruct.frag_properties),
Cs#cstruct{frag_properties = Props}.
%% Adjust table info before split
adjust_before_split(FH) ->
HashState = FH#frag_state.hash_state,
{HashState2, FromFrags, AdditionalWriteFrags} =
case FH#frag_state.hash_module of
HashMod when HashMod == ?DEFAULT_HASH_MOD ->
?DEFAULT_HASH_MOD:add_frag(HashState);
HashMod ->
HashMod:add_frag(HashState)
end,
N = FH#frag_state.n_fragments + 1,
VerifyFun = fun(F) when is_integer(F), F >= 1, F =< N -> false;
(_F) -> true
end,
try
FromFrags2 = lists:sort(FromFrags),
UnionFrags = lists:merge(FromFrags2, lists:sort(AdditionalWriteFrags)),
Frags = lists:filter(VerifyFun, UnionFrags),
Frags == [] orelse error(Frags),
FH2 = FH#frag_state{n_fragments = N,
hash_state = HashState2},
{FH2, FromFrags2, UnionFrags}
catch error:BadFrags ->
mnesia:abort({"add_frag: Fragment numbers out of range",
BadFrags, {range, 1, N}})
end.
split(Tab, FH, [SplitN | SplitNs], FragNames, Ops) ->
SplitFrag = element(SplitN, FragNames),
Pat = mnesia:table_info(SplitFrag, wild_pattern),
{_Mod, Tid, Ts} = mnesia_schema:get_tid_ts_and_lock(Tab, none),
Recs = mnesia:match_object(Tid, Ts, SplitFrag, Pat, read),
Ops2 = do_split(FH, SplitN, FragNames, Recs, Ops),
split(Tab, FH, SplitNs, FragNames, Ops2);
split(_Tab, _FH, [], _FragNames, Ops) ->
Ops.
%% Perform the split of the table
do_split(FH, OldN, FragNames, [Rec | Recs], Ops) ->
Pos = key_pos(FH),
HashKey = element(Pos, Rec),
case key_to_n(FH, HashKey) of
NewN when NewN == OldN ->
%% Keep record in the same fragment. No need to move it.
do_split(FH, OldN, FragNames, Recs, Ops);
NewN ->
case element(NewN, FragNames) of
NewFrag when NewFrag /= undefined ->
OldFrag = element(OldN, FragNames),
Key = element(2, Rec),
NewOid = {NewFrag, Key},
OldOid = {OldFrag, Key},
Ops2 = [{op, rec, unknown, {NewOid, [Rec], write}},
{op, rec, unknown, {OldOid, [OldOid], delete}} | Ops],
do_split(FH, OldN, FragNames, Recs, Ops2);
_NewFrag ->
%% Tried to move record to fragment that not is locked
mnesia:abort({"add_frag: Fragment not locked", NewN})
end
end;
do_split(_FH, _OldN, _FragNames, [], Ops) ->
Ops.
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Delete a fragment from a fragmented table
%% and merge its records with another fragment
make_multi_del_frag(Tab) ->
verify_multi(Tab),
Ops = make_del_frag(Tab),
%% Propagate to foreigners
MoreOps = [make_del_frag(T) || T <- lookup_foreigners(Tab)],
[Ops | MoreOps].
make_del_frag(Tab) ->
FH = lookup_frag_hash(Tab),
case FH#frag_state.n_fragments of
N when N > 1 ->
Cs = mnesia_schema:incr_version(val({Tab, cstruct})),
mnesia_schema:ensure_active(Cs),
{FH2, FromIndecies, WriteIndecies} = adjust_before_merge(FH),
FragNames = make_frag_names_and_acquire_locks(Tab, N, WriteIndecies, false),
MergeOps = merge(Tab, FH2, FromIndecies, FragNames, []),
LastFrag = element(N, FragNames),
[LastOp] = mnesia_schema:make_delete_table(LastFrag, single_frag),
Cs2 = replace_frag_hash(Cs, FH2),
TabDef = mnesia_schema:vsn_cs2list(Cs2),
BaseOp = {op, change_table_frag, del_frag, TabDef},
[BaseOp, LastOp | MergeOps];
_ ->
%% Cannot remove the last fragment
mnesia:abort({no_exists, Tab})
end.
%% Adjust tab info before merge
adjust_before_merge(FH) ->
HashState = FH#frag_state.hash_state,
{HashState2, FromFrags, AdditionalWriteFrags} =
case FH#frag_state.hash_module of
HashMod when HashMod == ?DEFAULT_HASH_MOD ->
?DEFAULT_HASH_MOD:del_frag(HashState);
HashMod ->
HashMod:del_frag(HashState)
end,
N = FH#frag_state.n_fragments,
VerifyFun = fun(F) when is_integer(F), F >= 1, F =< N -> false;
(_F) -> true
end,
try
FromFrags2 = lists:sort(FromFrags),
UnionFrags = lists:merge(FromFrags2, lists:sort(AdditionalWriteFrags)),
Frags = lists:filter(VerifyFun, UnionFrags),
[] == Frags orelse error(Frags),
case lists:member(N, FromFrags2) of
true ->
FH2 = FH#frag_state{n_fragments = N - 1,
hash_state = HashState2},
{FH2, FromFrags2, UnionFrags};
false ->
mnesia:abort({"del_frag: Last fragment number not included", N})
end
catch error:BadFrags ->
mnesia:abort({"del_frag: Fragment numbers out of range",
BadFrags, {range, 1, N}})
end.
merge(Tab, FH, [FromN | FromNs], FragNames, Ops) ->
FromFrag = element(FromN, FragNames),
Pat = mnesia:table_info(FromFrag, wild_pattern),
{_Mod, Tid, Ts} = mnesia_schema:get_tid_ts_and_lock(Tab, none),
Recs = mnesia:match_object(Tid, Ts, FromFrag, Pat, read),
Ops2 = do_merge(FH, FromN, FragNames, Recs, Ops),
merge(Tab, FH, FromNs, FragNames, Ops2);
merge(_Tab, _FH, [], _FragNames, Ops) ->
Ops.
%% Perform the merge of the table
do_merge(FH, OldN, FragNames, [Rec | Recs], Ops) ->
Pos = key_pos(FH),
LastN = FH#frag_state.n_fragments + 1,
HashKey = element(Pos, Rec),
case key_to_n(FH, HashKey) of
NewN when NewN == LastN ->
%% Tried to leave a record in the fragment that is to be deleted
mnesia:abort({"del_frag: Fragment number out of range",
NewN, {range, 1, LastN}});
NewN when NewN == OldN ->
%% Keep record in the same fragment. No need to move it.
do_merge(FH, OldN, FragNames, Recs, Ops);
NewN when OldN == LastN ->
%% Move record from the fragment that is to be deleted
%% No need to create a delete op for each record.
case element(NewN, FragNames) of
NewFrag when NewFrag /= undefined ->
Key = element(2, Rec),
NewOid = {NewFrag, Key},
Ops2 = [{op, rec, unknown, {NewOid, [Rec], write}} | Ops],
do_merge(FH, OldN, FragNames, Recs, Ops2);
_NewFrag ->
%% Tried to move record to fragment that not is locked
mnesia:abort({"del_frag: Fragment not locked", NewN})
end;
NewN ->
case element(NewN, FragNames) of
NewFrag when NewFrag /= undefined ->
OldFrag = element(OldN, FragNames),
Key = element(2, Rec),
NewOid = {NewFrag, Key},
OldOid = {OldFrag, Key},
Ops2 = [{op, rec, unknown, {NewOid, [Rec], write}},
{op, rec, unknown, {OldOid, [OldOid], delete}} | Ops],
do_merge(FH, OldN, FragNames, Recs, Ops2);
_NewFrag ->
%% Tried to move record to fragment that not is locked
mnesia:abort({"del_frag: Fragment not locked", NewN})
end
end;
do_merge(_FH, _OldN, _FragNames, [], Ops) ->
Ops.
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Add a node to the node pool of a fragmented table
make_multi_add_node(Tab, Node) ->
verify_multi(Tab),
Ops = make_add_node(Tab, Node),
%% Propagate to foreigners
MoreOps = [make_add_node(T, Node) || T <- lookup_foreigners(Tab)],
[Ops | MoreOps].
make_add_node(Tab, Node) when is_atom(Node) ->
Pool = lookup_prop(Tab, node_pool),
case lists:member(Node, Pool) of
false ->
Cs = mnesia_schema:incr_version(val({Tab, cstruct})),
Pool2 = Pool ++ [Node],
Props = Cs#cstruct.frag_properties,
Props2 = lists:keyreplace(node_pool, 1, Props, {node_pool, Pool2}),
Cs2 = Cs#cstruct{frag_properties = Props2},
TabDef = mnesia_schema:vsn_cs2list(Cs2),
Op = {op, change_table_frag, {add_node, Node}, TabDef},
[Op];
true ->
mnesia:abort({already_exists, Tab, Node})
end;
make_add_node(Tab, Node) ->
mnesia:abort({bad_type, Tab, Node}).
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Delet a node from the node pool of a fragmented table
make_multi_del_node(Tab, Node) ->
verify_multi(Tab),
Ops = make_del_node(Tab, Node),
%% Propagate to foreigners
MoreOps = [make_del_node(T, Node) || T <- lookup_foreigners(Tab)],
[Ops | MoreOps].
make_del_node(Tab, Node) when is_atom(Node) ->
Cs = mnesia_schema:incr_version(val({Tab, cstruct})),
mnesia_schema:ensure_active(Cs),
Pool = lookup_prop(Tab, node_pool),
case lists:member(Node, Pool) of
true ->
Pool2 = Pool -- [Node],
Props = lists:keyreplace(node_pool, 1, Cs#cstruct.frag_properties, {node_pool, Pool2}),
Cs2 = Cs#cstruct{frag_properties = Props},
TabDef = mnesia_schema:vsn_cs2list(Cs2),
Op = {op, change_table_frag, {del_node, Node}, TabDef},
[Op];
false ->
mnesia:abort({no_exists, Tab, Node})
end;
make_del_node(Tab, Node) ->
mnesia:abort({bad_type, Tab, Node}).
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Special case used to remove all references to a node during
%% mnesia:del_table_copy(schema, Node)
remove_node(Node, Cs) ->
Tab = Cs#cstruct.name,
case ?catch_val({Tab, frag_hash}) of
{'EXIT', _} ->
{Cs, false};
_ ->
Pool = lookup_prop(Tab, node_pool),
case lists:member(Node, Pool) of
true ->
Pool2 = Pool -- [Node],
Props = lists:keyreplace(node_pool, 1,
Cs#cstruct.frag_properties,
{node_pool, Pool2}),
{Cs#cstruct{frag_properties = Props}, true};
false ->
{Cs, false}
end
end.
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%% Helpers
val(Var) ->
case ?catch_val(Var) of
{'EXIT', _} -> mnesia_lib:other_val(Var);
Value -> Value
end.
set_frag_hash(Tab, Props) ->
case props_to_frag_hash(Tab, Props) of
FH when is_record(FH, frag_state) ->
mnesia_lib:set({Tab, frag_hash}, FH);
no_hash ->
mnesia_lib:unset({Tab, frag_hash})
end.
props_to_frag_hash(_Tab, []) ->
no_hash;
props_to_frag_hash(Tab, Props) ->
case mnesia_schema:pick(Tab, base_table, Props, undefined) of
T when T == Tab ->
Foreign = mnesia_schema:pick(Tab, foreign_key, Props, must),
N = mnesia_schema:pick(Tab, n_fragments, Props, must),
case mnesia_schema:pick(Tab, hash_module, Props, undefined) of
undefined ->
Split = mnesia_schema:pick(Tab, next_n_to_split, Props, must),
Doubles = mnesia_schema:pick(Tab, n_doubles, Props, must),
FH = {frag_hash, Foreign, N, Split, Doubles},
HashState = ?OLD_HASH_MOD:init_state(Tab, FH),
#frag_state{foreign_key = Foreign,
n_fragments = N,
hash_module = ?OLD_HASH_MOD,
hash_state = HashState};
HashMod ->
HashState = mnesia_schema:pick(Tab, hash_state, Props, must),
#frag_state{foreign_key = Foreign,
n_fragments = N,
hash_module = HashMod,
hash_state = HashState}
%% Old style. Kept for backwards compatibility.
end;
_ ->
no_hash
end.
lookup_prop(Tab, Prop) ->
Props = val({Tab, frag_properties}),
case lists:keysearch(Prop, 1, Props) of
{value, {Prop, Val}} ->
Val;
false ->
mnesia:abort({no_exists, Tab, Prop, {frag_properties, Props}})
end.
lookup_frag_hash(Tab) ->
case ?catch_val({Tab, frag_hash}) of
FH when is_record(FH, frag_state) ->
FH;
{frag_hash, K, N, _S, _D} = FH ->
%% Old style. Kept for backwards compatibility.
HashState = ?OLD_HASH_MOD:init_state(Tab, FH),
#frag_state{foreign_key = K,
n_fragments = N,
hash_module = ?OLD_HASH_MOD,
hash_state = HashState};
{'EXIT', _} ->
mnesia:abort({no_exists, Tab, frag_properties, frag_hash})
end.
%% Returns a list of tables
lookup_foreigners(Tab) ->
%% First field in HashPat is either frag_hash or frag_state
HashPat = {'_', {Tab, '_'}, '_', '_', '_'},
[T || [T] <- ?ets_match(mnesia_gvar, {{'$1', frag_hash}, HashPat})].
%% Returns name of fragment table
record_to_frag_name(Tab, Rec) ->
case ?catch_val({Tab, frag_hash}) of
{'EXIT', _} ->
Tab;
FH ->
Pos = key_pos(FH),
Key = element(Pos, Rec),
N = key_to_n(FH, Key),
n_to_frag_name(Tab, N)
end.
key_pos(FH) ->
case FH#frag_state.foreign_key of
undefined ->
2;
{_ForeignTab, Pos} ->
Pos
end.
%% Returns name of fragment table
key_to_frag_name({BaseTab, _} = Tab, Key) ->
N = key_to_frag_number(Tab, Key),
n_to_frag_name(BaseTab, N);
key_to_frag_name(Tab, Key) ->
N = key_to_frag_number(Tab, Key),
n_to_frag_name(Tab, N).
%% Returns name of fragment table
n_to_frag_name(Tab, 1) ->
Tab;
n_to_frag_name(Tab, N) when is_atom(Tab), is_integer(N) ->
list_to_atom(atom_to_list(Tab) ++ "_frag" ++ integer_to_list(N));
n_to_frag_name(Tab, N) ->
mnesia:abort({bad_type, Tab, N}).
%% Returns name of fragment table
key_to_frag_number({Tab, ForeignKey}, _Key) ->
FH = val({Tab, frag_hash}),
case FH#frag_state.foreign_key of
{_ForeignTab, _Pos} ->
key_to_n(FH, ForeignKey);
undefined ->
mnesia:abort({combine_error, Tab, frag_properties,
{foreign_key, undefined}})
end;
key_to_frag_number(Tab, Key) ->
case ?catch_val({Tab, frag_hash}) of
{'EXIT', _} ->
1;
FH ->
key_to_n(FH, Key)
end.
%% Returns fragment number
key_to_n(FH, Key) ->
HashState = FH#frag_state.hash_state,
N =
case FH#frag_state.hash_module of
HashMod when HashMod == ?DEFAULT_HASH_MOD ->
?DEFAULT_HASH_MOD:key_to_frag_number(HashState, Key);
HashMod ->
HashMod:key_to_frag_number(HashState, Key)
end,
if
is_integer(N), N >= 1, N =< FH#frag_state.n_fragments ->
N;
true ->
mnesia:abort({"key_to_frag_number: Fragment number out of range",
N, {range, 1, FH#frag_state.n_fragments}})
end.
%% Returns a list of frament table names
frag_names(Tab) ->
case ?catch_val({Tab, frag_hash}) of
{'EXIT', _} ->
[Tab];
FH ->
N = FH#frag_state.n_fragments,
frag_names(Tab, N, [])
end.
frag_names(Tab, 1, Acc) ->
[Tab | Acc];
frag_names(Tab, N, Acc) ->
Frag = n_to_frag_name(Tab, N),
frag_names(Tab, N - 1, [Frag | Acc]).
%% Returns a list of {Node, FragCount} tuples
%% sorted on FragCounts
frag_dist(Tab) ->
Pool = lookup_prop(Tab, node_pool),
Dist = [{good, Node, 0} || Node <- Pool],
Dist2 = count_frag(frag_names(Tab), Dist),
sort_dist(Dist2).
count_frag([Frag | Frags], Dist) ->
Dist2 = incr_nodes(val({Frag, ram_copies}), Dist),
Dist3 = incr_nodes(val({Frag, disc_copies}), Dist2),
Dist4 = incr_nodes(val({Frag, disc_only_copies}), Dist3),
Dist5 = incr_nodes(val({Frag, external_copies}), Dist4),
count_frag(Frags, Dist5);
count_frag([], Dist) ->
Dist.
incr_nodes([Node | Nodes], Dist) ->
Dist2 = incr_node(Node, Dist),
incr_nodes(Nodes, Dist2);
incr_nodes([], Dist) ->
Dist.
incr_node(Node, [{Kind, Node, Count} | Tail]) ->
[{Kind, Node, Count + 1} | Tail];
incr_node(Node, [Head | Tail]) ->
[Head | incr_node(Node, Tail)];
incr_node(Node, []) ->
[{bad, Node, 1}].
%% Sorts dist according in decreasing count order
sort_dist(Dist) ->
Dist2 = deep_dist(Dist, []),
Dist3 = lists:keysort(1, Dist2),
shallow_dist(Dist3).
deep_dist([Head | Tail], Deep) ->
{Kind, _Node, Count} = Head,
{Tag, Same, Other} = pick_count(Kind, Count, [Head | Tail]),
deep_dist(Other, [{Tag, Same} | Deep]);
deep_dist([], Deep) ->
Deep.
pick_count(Kind, Count, [{Kind2, Node2, Count2} | Tail]) ->
Head = {Node2, Count2},
{_, Same, Other} = pick_count(Kind, Count, Tail),
if
Kind == bad ->
{bad, [Head | Same], Other};
Kind2 == bad ->
{Count, Same, [{Kind2, Node2, Count2} | Other]};
Count == Count2 ->
{Count, [Head | Same], Other};
true ->
{Count, Same, [{Kind2, Node2, Count2} | Other]}
end;
pick_count(_Kind, Count, []) ->
{Count, [], []}.
shallow_dist([{_Tag, Shallow} | Deep]) ->
Shallow ++ shallow_dist(Deep);
shallow_dist([]) ->
[].