test/etap/020-btree-basics.t - couchdb - Git at Google

 #!/usr/bin/env escript
 %% -*- erlang -*-
 %%! -pa ./src/couchdb -sasl errlog_type error -boot start_sasl -noshell

 % 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.

 filename() -> test_util:build_file("test/etap/temp.020").
 rows() -> 250.

 -record(btree, {fd, root, extract_kv, assemble_kv, less, reduce}).

 main(_) ->
     test_util:init_code_path(),
     etap:plan(48),
     case (catch test()) of
         ok ->
             etap:end_tests();
         Other ->
             etap:diag(io_lib:format("Test died abnormally: ~p", [Other])),
             etap:bail()
     end,
     ok.

 %% @todo Determine if this number should be greater to see if the btree was
 %% broken into multiple nodes. AKA "How do we appropiately detect if multiple
 %% nodes were created."
 test()->
     Sorted = [{Seq, random:uniform()} || Seq <- lists:seq(1, rows())],
     etap:ok(test_kvs(Sorted), "Testing sorted keys"),
     etap:ok(test_kvs(lists:reverse(Sorted)), "Testing reversed sorted keys"),
     etap:ok(test_kvs(shuffle(Sorted)), "Testing shuffled keys."),
     ok.

 test_kvs(KeyValues) ->
     ReduceFun = fun
         (reduce, KVs) ->
             length(KVs);
         (rereduce, Reds) ->
             lists:sum(Reds)
     end,

     Keys = [K || {K, _} <- KeyValues],

     {ok, Fd} = couch_file:open(filename(), [create,overwrite]),
     {ok, Btree} = couch_btree:open(nil, Fd),
     etap:ok(is_record(Btree, btree), "Created btree is really a btree record"),
     etap:is(Btree#btree.fd, Fd, "Btree#btree.fd is set correctly."),
     etap:is(Btree#btree.root, nil, "Btree#btree.root is set correctly."),

     Btree1 = couch_btree:set_options(Btree, [{reduce, ReduceFun}]),
     etap:is(Btree1#btree.reduce, ReduceFun, "Reduce function was set"),
     {ok, _, EmptyRes} = couch_btree:foldl(Btree1, fun(_, X) -> {ok, X+1} end, 0),
     etap:is(EmptyRes, 0, "Folding over an empty btree"),

     {ok, Btree2} = couch_btree:add_remove(Btree1, KeyValues, []),
     etap:ok(test_btree(Btree2, KeyValues),
         "Adding all keys at once returns a complete btree."),

     etap:fun_is(
         fun
             ({ok, {kp_node, _}}) -> true;
             (_) -> false
         end,
         couch_file:pread_term(Fd, element(1, Btree2#btree.root)),
         "Btree root pointer is a kp_node."
     ),

     {ok, Btree3} = couch_btree:add_remove(Btree2, [], Keys),
     etap:ok(test_btree(Btree3, []),
         "Removing all keys at once returns an empty btree."),

     Btree4 = lists:foldl(fun(KV, BtAcc) ->
         {ok, BtAcc2} = couch_btree:add_remove(BtAcc, [KV], []),
         BtAcc2
     end, Btree3, KeyValues),
     etap:ok(test_btree(Btree4, KeyValues),
         "Adding all keys one at a time returns a complete btree."),

     Btree5 = lists:foldl(fun({K, _}, BtAcc) ->
         {ok, BtAcc2} = couch_btree:add_remove(BtAcc, [], [K]),
         BtAcc2
     end, Btree4, KeyValues),
     etap:ok(test_btree(Btree5, []),
         "Removing all keys one at a time returns an empty btree."),

     KeyValuesRev = lists:reverse(KeyValues),
     Btree6 = lists:foldl(fun(KV, BtAcc) ->
         {ok, BtAcc2} = couch_btree:add_remove(BtAcc, [KV], []),
         BtAcc2
     end, Btree5, KeyValuesRev),
     etap:ok(test_btree(Btree6, KeyValues),
         "Adding all keys in reverse order returns a complete btree."),

     {_, Rem2Keys0, Rem2Keys1} = lists:foldl(fun(X, {Count, Left, Right}) ->
         case Count rem 2 == 0 of
             true-> {Count+1, [X | Left], Right};
             false -> {Count+1, Left, [X | Right]}
         end
     end, {0, [], []}, KeyValues),

     etap:ok(test_add_remove(Btree6, Rem2Keys0, Rem2Keys1),
         "Add/Remove every other key."),

     etap:ok(test_add_remove(Btree6, Rem2Keys1, Rem2Keys0),
         "Add/Remove opposite every other key."),

     {ok, Btree7} = couch_btree:add_remove(Btree6, [], [K||{K,_}<-Rem2Keys1]),
     {ok, Btree8} = couch_btree:add_remove(Btree7, [], [K||{K,_}<-Rem2Keys0]),
     etap:ok(test_btree(Btree8, []),
         "Removing both halves of every other key returns an empty btree."),

     %% Third chunk (close out)
     etap:is(couch_file:close(Fd), ok, "closing out"),
     true.

 test_btree(Btree, KeyValues) ->
     ok = test_key_access(Btree, KeyValues),
     ok = test_lookup_access(Btree, KeyValues),
     ok = test_final_reductions(Btree, KeyValues),
     true.

 test_add_remove(Btree, OutKeyValues, RemainingKeyValues) ->
     Btree2 = lists:foldl(fun({K, _}, BtAcc) ->
         {ok, BtAcc2} = couch_btree:add_remove(BtAcc, [], [K]),
         BtAcc2
     end, Btree, OutKeyValues),
     true = test_btree(Btree2, RemainingKeyValues),

     Btree3 = lists:foldl(fun(KV, BtAcc) ->
         {ok, BtAcc2} = couch_btree:add_remove(BtAcc, [KV], []),
         BtAcc2
     end, Btree2, OutKeyValues),
     true = test_btree(Btree3, OutKeyValues ++ RemainingKeyValues).

 test_key_access(Btree, List) ->
     FoldFun = fun(Element, {[HAcc|TAcc], Count}) ->
         case Element == HAcc of
             true -> {ok, {TAcc, Count + 1}};
             _ -> {ok, {TAcc, Count + 1}}
         end
     end,
     Length = length(List),
     Sorted = lists:sort(List),
     {ok, _, {[], Length}} = couch_btree:foldl(Btree, FoldFun, {Sorted, 0}),
     {ok, _, {[], Length}} = couch_btree:fold(Btree, FoldFun, {Sorted, 0}, [{dir, rev}]),
     ok.

 test_lookup_access(Btree, KeyValues) ->
     FoldFun = fun({Key, Value}, {Key, Value}) -> {stop, true} end,
     lists:foreach(fun({Key, Value}) ->
         [{ok, {Key, Value}}] = couch_btree:lookup(Btree, [Key]),
         {ok, _, true} = couch_btree:foldl(Btree, FoldFun, {Key, Value}, [{start_key, Key}])
     end, KeyValues).

 test_final_reductions(Btree, KeyValues) ->
     KVLen = length(KeyValues),
     FoldLFun = fun(_X, LeadingReds, Acc) ->
         CountToStart = KVLen div 3 + Acc,
         CountToStart = couch_btree:final_reduce(Btree, LeadingReds),
         {ok, Acc+1}
     end,
     FoldRFun = fun(_X, LeadingReds, Acc) ->
         CountToEnd = KVLen - KVLen div 3 + Acc,
         CountToEnd = couch_btree:final_reduce(Btree, LeadingReds),
         {ok, Acc+1}
     end,
     {LStartKey, _} = case KVLen of
         0 -> {nil, nil};
         _ -> lists:nth(KVLen div 3 + 1, lists:sort(KeyValues))
     end,
     {RStartKey, _} = case KVLen of
         0 -> {nil, nil};
         _ -> lists:nth(KVLen div 3, lists:sort(KeyValues))
     end,
     {ok, _, FoldLRed} = couch_btree:foldl(Btree, FoldLFun, 0, [{start_key, LStartKey}]),
     {ok, _, FoldRRed} = couch_btree:fold(Btree, FoldRFun, 0, [{dir, rev}, {start_key, RStartKey}]),
     KVLen = FoldLRed + FoldRRed,
     ok.

 shuffle(List) ->
    randomize(round(math:log(length(List)) + 0.5), List).

 randomize(1, List) ->
    randomize(List);
 randomize(T, List) ->
     lists:foldl(fun(_E, Acc) ->
         randomize(Acc)
     end, randomize(List), lists:seq(1, (T - 1))).

 randomize(List) ->
     D = lists:map(fun(A) ->
         {random:uniform(), A}
     end, List),
     {_, D1} = lists:unzip(lists:keysort(1, D)),
     D1.
	#!/usr/bin/env escript
	%% -- erlang --
	%%! -pa ./src/couchdb -sasl errlog_type error -boot start_sasl -noshell

	% 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.

	filename() -> test_util:build_file("test/etap/temp.020").
	rows() -> 250.

	-record(btree, {fd, root, extract_kv, assemble_kv, less, reduce}).

	main(_) ->
	test_util:init_code_path(),
	etap:plan(48),
	case (catch test()) of
	ok ->
	etap:end_tests();
	Other ->
	etap:diag(io_lib:format("Test died abnormally: ~p", [Other])),
	etap:bail()
	end,
	ok.

	%% @todo Determine if this number should be greater to see if the btree was
	%% broken into multiple nodes. AKA "How do we appropiately detect if multiple
	%% nodes were created."
	test()->
	Sorted = [{Seq, random:uniform()} \|\| Seq <- lists:seq(1, rows())],
	etap:ok(test_kvs(Sorted), "Testing sorted keys"),
	etap:ok(test_kvs(lists:reverse(Sorted)), "Testing reversed sorted keys"),
	etap:ok(test_kvs(shuffle(Sorted)), "Testing shuffled keys."),
	ok.

	test_kvs(KeyValues) ->
	ReduceFun = fun
	(reduce, KVs) ->
	length(KVs);
	(rereduce, Reds) ->
	lists:sum(Reds)
	end,

	Keys = [K \|\| {K, _} <- KeyValues],

	{ok, Fd} = couch_file:open(filename(), [create,overwrite]),
	{ok, Btree} = couch_btree:open(nil, Fd),
	etap:ok(is_record(Btree, btree), "Created btree is really a btree record"),
	etap:is(Btree#btree.fd, Fd, "Btree#btree.fd is set correctly."),
	etap:is(Btree#btree.root, nil, "Btree#btree.root is set correctly."),

	Btree1 = couch_btree:set_options(Btree, [{reduce, ReduceFun}]),
	etap:is(Btree1#btree.reduce, ReduceFun, "Reduce function was set"),
	{ok, _, EmptyRes} = couch_btree:foldl(Btree1, fun(_, X) -> {ok, X+1} end, 0),
	etap:is(EmptyRes, 0, "Folding over an empty btree"),

	{ok, Btree2} = couch_btree:add_remove(Btree1, KeyValues, []),
	etap:ok(test_btree(Btree2, KeyValues),
	"Adding all keys at once returns a complete btree."),

	etap:fun_is(
	fun
	({ok, {kp_node, _}}) -> true;
	(_) -> false
	end,
	couch_file:pread_term(Fd, element(1, Btree2#btree.root)),
	"Btree root pointer is a kp_node."
	),

	{ok, Btree3} = couch_btree:add_remove(Btree2, [], Keys),
	etap:ok(test_btree(Btree3, []),
	"Removing all keys at once returns an empty btree."),

	Btree4 = lists:foldl(fun(KV, BtAcc) ->
	{ok, BtAcc2} = couch_btree:add_remove(BtAcc, [KV], []),
	BtAcc2
	end, Btree3, KeyValues),
	etap:ok(test_btree(Btree4, KeyValues),
	"Adding all keys one at a time returns a complete btree."),

	Btree5 = lists:foldl(fun({K, _}, BtAcc) ->
	{ok, BtAcc2} = couch_btree:add_remove(BtAcc, [], [K]),
	BtAcc2
	end, Btree4, KeyValues),
	etap:ok(test_btree(Btree5, []),
	"Removing all keys one at a time returns an empty btree."),

	KeyValuesRev = lists:reverse(KeyValues),
	Btree6 = lists:foldl(fun(KV, BtAcc) ->
	{ok, BtAcc2} = couch_btree:add_remove(BtAcc, [KV], []),
	BtAcc2
	end, Btree5, KeyValuesRev),
	etap:ok(test_btree(Btree6, KeyValues),
	"Adding all keys in reverse order returns a complete btree."),

	{_, Rem2Keys0, Rem2Keys1} = lists:foldl(fun(X, {Count, Left, Right}) ->
	case Count rem 2 == 0 of
	true-> {Count+1, [X \| Left], Right};
	false -> {Count+1, Left, [X \| Right]}
	end
	end, {0, [], []}, KeyValues),

	etap:ok(test_add_remove(Btree6, Rem2Keys0, Rem2Keys1),
	"Add/Remove every other key."),

	etap:ok(test_add_remove(Btree6, Rem2Keys1, Rem2Keys0),
	"Add/Remove opposite every other key."),

	{ok, Btree7} = couch_btree:add_remove(Btree6, [], [K\|\|{K,_}<-Rem2Keys1]),
	{ok, Btree8} = couch_btree:add_remove(Btree7, [], [K\|\|{K,_}<-Rem2Keys0]),
	etap:ok(test_btree(Btree8, []),
	"Removing both halves of every other key returns an empty btree."),

	%% Third chunk (close out)
	etap:is(couch_file:close(Fd), ok, "closing out"),
	true.

	test_btree(Btree, KeyValues) ->
	ok = test_key_access(Btree, KeyValues),
	ok = test_lookup_access(Btree, KeyValues),
	ok = test_final_reductions(Btree, KeyValues),
	true.

	test_add_remove(Btree, OutKeyValues, RemainingKeyValues) ->
	Btree2 = lists:foldl(fun({K, _}, BtAcc) ->
	{ok, BtAcc2} = couch_btree:add_remove(BtAcc, [], [K]),
	BtAcc2
	end, Btree, OutKeyValues),
	true = test_btree(Btree2, RemainingKeyValues),

	Btree3 = lists:foldl(fun(KV, BtAcc) ->
	{ok, BtAcc2} = couch_btree:add_remove(BtAcc, [KV], []),
	BtAcc2
	end, Btree2, OutKeyValues),
	true = test_btree(Btree3, OutKeyValues ++ RemainingKeyValues).

	test_key_access(Btree, List) ->
	FoldFun = fun(Element, {[HAcc\|TAcc], Count}) ->
	case Element == HAcc of
	true -> {ok, {TAcc, Count + 1}};
	_ -> {ok, {TAcc, Count + 1}}
	end
	end,
	Length = length(List),
	Sorted = lists:sort(List),
	{ok, _, {[], Length}} = couch_btree:foldl(Btree, FoldFun, {Sorted, 0}),
	{ok, _, {[], Length}} = couch_btree:fold(Btree, FoldFun, {Sorted, 0}, [{dir, rev}]),
	ok.

	test_lookup_access(Btree, KeyValues) ->
	FoldFun = fun({Key, Value}, {Key, Value}) -> {stop, true} end,
	lists:foreach(fun({Key, Value}) ->
	[{ok, {Key, Value}}] = couch_btree:lookup(Btree, [Key]),
	{ok, _, true} = couch_btree:foldl(Btree, FoldFun, {Key, Value}, [{start_key, Key}])
	end, KeyValues).

	test_final_reductions(Btree, KeyValues) ->
	KVLen = length(KeyValues),
	FoldLFun = fun(_X, LeadingReds, Acc) ->
	CountToStart = KVLen div 3 + Acc,
	CountToStart = couch_btree:final_reduce(Btree, LeadingReds),
	{ok, Acc+1}
	end,
	FoldRFun = fun(_X, LeadingReds, Acc) ->
	CountToEnd = KVLen - KVLen div 3 + Acc,
	CountToEnd = couch_btree:final_reduce(Btree, LeadingReds),
	{ok, Acc+1}
	end,
	{LStartKey, _} = case KVLen of
	0 -> {nil, nil};
	_ -> lists:nth(KVLen div 3 + 1, lists:sort(KeyValues))
	end,
	{RStartKey, _} = case KVLen of
	0 -> {nil, nil};
	_ -> lists:nth(KVLen div 3, lists:sort(KeyValues))
	end,
	{ok, _, FoldLRed} = couch_btree:foldl(Btree, FoldLFun, 0, [{start_key, LStartKey}]),
	{ok, _, FoldRRed} = couch_btree:fold(Btree, FoldRFun, 0, [{dir, rev}, {start_key, RStartKey}]),
	KVLen = FoldLRed + FoldRRed,
	ok.

	shuffle(List) ->
	randomize(round(math:log(length(List)) + 0.5), List).

	randomize(1, List) ->
	randomize(List);
	randomize(T, List) ->
	lists:foldl(fun(_E, Acc) ->
	randomize(Acc)
	end, randomize(List), lists:seq(1, (T - 1))).

	randomize(List) ->
	D = lists:map(fun(A) ->
	{random:uniform(), A}
	end, List),
	{_, D1} = lists:unzip(lists:keysort(1, D)),
	D1.