zulip/zerver/transaction_tests/test_user_groups.py

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user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
2023-06-17 04:39:52 +02:00
import threading
from typing import Any, List, Optional
from unittest import mock
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
2023-06-17 04:39:52 +02:00
import orjson
from django.db import OperationalError, connections, transaction
from django.http import HttpRequest
from typing_extensions import override
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
2023-06-17 04:39:52 +02:00
from zerver.actions.user_groups import add_subgroups_to_user_group, check_add_user_group
from zerver.lib.exceptions import JsonableError
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
2023-06-17 04:39:52 +02:00
from zerver.lib.test_classes import ZulipTransactionTestCase
from zerver.lib.test_helpers import HostRequestMock
from zerver.lib.user_groups import access_user_group_by_id
from zerver.models import NamedUserGroup, Realm, UserGroup, UserProfile
from zerver.models.realms import get_realm
from zerver.views.user_groups import update_subgroups_of_user_group
BARRIER: Optional[threading.Barrier] = None
def dev_update_subgroups(
request: HttpRequest,
user_profile: UserProfile,
user_group_id: int,
) -> Optional[str]:
# The test is expected to set up the barrier before accessing this endpoint.
assert BARRIER is not None
try:
with transaction.atomic(), mock.patch(
"zerver.lib.user_groups.access_user_group_by_id"
) as m:
def wait_after_recursive_query(*args: Any, **kwargs: Any) -> UserGroup:
# When updating the subgroups, we access the supergroup group
# only after finishing the recursive query.
BARRIER.wait()
return access_user_group_by_id(*args, **kwargs)
m.side_effect = wait_after_recursive_query
update_subgroups_of_user_group(request, user_profile, user_group_id=user_group_id)
except OperationalError as err:
msg = str(err)
if "deadlock detected" in msg:
return "Deadlock detected"
else:
assert "could not obtain lock" in msg
# This error is possible when nowait is set the True, which only
# applies to the recursive query on the subgroups. Because the
# recursive query fails, this thread must have not waited on the
# barrier yet.
BARRIER.wait()
return "Busy lock detected"
except (
threading.BrokenBarrierError
): # nocoverage # This is only possible when timeout happens or there is a programming error
raise JsonableError(
"Broken barrier. The tester should make sure that the exact number of parties have waited on the barrier set by the previous immediate set_sync_after_first_lock call"
)
return None
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
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class UserGroupRaceConditionTestCase(ZulipTransactionTestCase):
created_user_groups: List[UserGroup] = []
counter = 0
CHAIN_LENGTH = 3
@override
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
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def tearDown(self) -> None:
# Clean up the user groups created to minimize leakage
with transaction.atomic():
for group in self.created_user_groups:
group.delete()
transaction.on_commit(self.created_user_groups.clear)
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
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super().tearDown()
def create_user_group_chain(self, realm: Realm) -> List[NamedUserGroup]:
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
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"""Build a user groups forming a chain through group-group memberships
returning a list where each group is the supergroup of its subsequent group.
"""
groups = [
check_add_user_group(realm, f"chain #{self.counter + i}", [], acting_user=None)
for i in range(self.CHAIN_LENGTH)
]
self.counter += self.CHAIN_LENGTH
self.created_user_groups.extend(groups)
prev_group = groups[0]
for group in groups[1:]:
add_subgroups_to_user_group(prev_group, [group], acting_user=None)
prev_group = group
return groups
def test_lock_subgroups_with_respect_to_supergroup(self) -> None:
realm = get_realm("zulip")
self.login("iago")
iago = self.example_user("iago")
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
2023-06-17 04:39:52 +02:00
class RacingThread(threading.Thread):
def __init__(
self,
subgroup_ids: List[int],
supergroup_id: int,
) -> None:
threading.Thread.__init__(self)
self.response: Optional[str] = None
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
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self.subgroup_ids = subgroup_ids
self.supergroup_id = supergroup_id
@override
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
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def run(self) -> None:
try:
self.response = dev_update_subgroups(
HostRequestMock({"add": orjson.dumps(self.subgroup_ids).decode()}),
iago,
user_group_id=self.supergroup_id,
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
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)
finally:
# Close all thread-local database connections
connections.close_all()
def assert_thread_success_count(
t1: RacingThread,
t2: RacingThread,
*,
success_count: int,
error_message: str = "",
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
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) -> None:
help_msg = """We access the test endpoint that wraps around the
real subgroup update endpoint by synchronizing them after the acquisition of the
first lock in the critical region. Though unlikely, this test might fail as we
have no control over the scheduler when the barrier timeouts.
""".strip()
global BARRIER
BARRIER = threading.Barrier(parties=2, timeout=3)
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
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t1.start()
t2.start()
succeeded = 0
for t in [t1, t2]:
t.join()
response = t.response
if response is None:
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
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succeeded += 1
continue
self.assertEqual(response, error_message)
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
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# Race condition resolution should only allow one thread to succeed
self.assertEqual(
succeeded,
success_count,
f"Exactly {success_count} thread(s) should succeed.\n{help_msg}",
)
foo_chain = self.create_user_group_chain(realm)
bar_chain = self.create_user_group_chain(realm)
# These two threads are conflicting because a cycle would be formed if
# both of them succeed. There is a deadlock in such circular dependency.
assert_thread_success_count(
RacingThread(
subgroup_ids=[foo_chain[0].id],
supergroup_id=bar_chain[-1].id,
),
RacingThread(
subgroup_ids=[bar_chain[-1].id],
supergroup_id=foo_chain[0].id,
),
success_count=1,
error_message="Deadlock detected",
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
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)
foo_chain = self.create_user_group_chain(realm)
bar_chain = self.create_user_group_chain(realm)
# These two requests would succeed if they didn't race with each other.
# However, both threads will attempt to grab a lock on overlapping rows
# when they first do the recursive query for subgroups. In this case, we
# expect that one of the threads fails due to nowait=True for the
# .select_for_update() call.
assert_thread_success_count(
RacingThread(
subgroup_ids=[foo_chain[0].id],
supergroup_id=bar_chain[-1].id,
),
RacingThread(
subgroup_ids=[foo_chain[1].id],
supergroup_id=bar_chain[-1].id,
),
success_count=1,
error_message="Busy lock detected",
user_groups: Make locks required for updating user group memberships. **Background** User groups are expected to comply with the DAG constraint for the many-to-many inter-group membership. The check for this constraint has to be performed recursively so that we can find all direct and indirect subgroups of the user group to be added. This kind of check is vulnerable to phantom reads which is possible at the default read committed isolation level because we cannot guarantee that the check is still valid when we are adding the subgroups to the user group. **Solution** To avoid having another transaction concurrently update one of the to-be-subgroup after the recursive check is done, and before the subgroup is added, we use SELECT FOR UPDATE to lock the user group rows. The lock needs to be acquired before a group membership change is about to occur before any check has been conducted. Suppose that we are adding subgroup B to supergroup A, the locking protocol is specified as follows: 1. Acquire a lock for B and all its direct and indirect subgroups. 2. Acquire a lock for A. For the removal of user groups, we acquire a lock for the user group to be removed with all its direct and indirect subgroups. This is the special case A=B, which is still complaint with the protocol. **Error handling** We currently rely on Postgres' deadlock detection to abort transactions and show an error for the users. In the future, we might need some recovery mechanism or at least better error handling. **Notes** An important note is that we need to reuse the recursive CTE query that finds the direct and indirect subgroups when applying the lock on the rows. And the lock needs to be acquired the same way for the addition and removal of direct subgroups. User membership change (as opposed to user group membership) is not affected. Read-only queries aren't either. The locks only protect critical regions where the user group dependency graph might violate the DAG constraint, where users are not participating. **Testing** We implement a transaction test case targeting some typical scenarios when an internal server error is expected to happen (this means that the user group view makes the correct decision to abort the transaction when something goes wrong with locks). To achieve this, we add a development view intended only for unit tests. It has a global BARRIER that can be shared across threads, so that we can synchronize them to consistently reproduce certain potential race conditions prevented by the database locks. The transaction test case lanuches pairs of threads initiating possibly conflicting requests at the same time. The tests are set up such that exactly N of them are expected to succeed with a certain error message (while we don't know each one). **Security notes** get_recursive_subgroups_for_groups will no longer fetch user groups from other realms. As a result, trying to add/remove a subgroup from another realm results in a UserGroup not found error response. We also implement subgroup-specific checks in has_user_group_access to keep permission managing in a single place. Do note that the API currently don't have a way to violate that check because we are only checking the realm ID now.
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)
foo_chain = self.create_user_group_chain(realm)
bar_chain = self.create_user_group_chain(realm)
baz_chain = self.create_user_group_chain(realm)
# Adding non-conflicting subgroups should succeed.
assert_thread_success_count(
RacingThread(
subgroup_ids=[foo_chain[1].id, foo_chain[2].id, baz_chain[2].id],
supergroup_id=baz_chain[0].id,
),
RacingThread(
subgroup_ids=[bar_chain[1].id, bar_chain[2].id],
supergroup_id=baz_chain[0].id,
),
success_count=2,
)