Supervised user whitelists: Cleanup
[chromium-blink-merge.git] / sync / engine / apply_control_data_updates.cc
blob9b4b837f43cc8645743b27f4488f3bb81004ddec
1 // Copyright 2012 The Chromium Authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file.
5 #include "sync/engine/apply_control_data_updates.h"
7 #include "base/metrics/histogram.h"
8 #include "sync/engine/conflict_resolver.h"
9 #include "sync/engine/conflict_util.h"
10 #include "sync/engine/syncer_util.h"
11 #include "sync/syncable/directory.h"
12 #include "sync/syncable/mutable_entry.h"
13 #include "sync/syncable/nigori_handler.h"
14 #include "sync/syncable/nigori_util.h"
15 #include "sync/syncable/syncable_write_transaction.h"
16 #include "sync/util/cryptographer.h"
18 namespace syncer {
20 using syncable::GET_TYPE_ROOT;
21 using syncable::IS_UNAPPLIED_UPDATE;
22 using syncable::IS_UNSYNCED;
23 using syncable::SERVER_SPECIFICS;
24 using syncable::SPECIFICS;
25 using syncable::SYNCER;
27 void ApplyControlDataUpdates(syncable::Directory* dir) {
28 syncable::WriteTransaction trans(FROM_HERE, SYNCER, dir);
30 std::vector<int64> handles;
31 dir->GetUnappliedUpdateMetaHandles(
32 &trans, ToFullModelTypeSet(ControlTypes()), &handles);
34 // First, go through and manually apply any new top level datatype nodes (so
35 // that we don't have to worry about hitting a CONFLICT_HIERARCHY with an
36 // entry because we haven't applied its parent yet).
37 // TODO(sync): if at some point we support control datatypes with actual
38 // hierarchies we'll need to revisit this logic.
39 ModelTypeSet control_types = ControlTypes();
40 for (ModelTypeSet::Iterator iter = control_types.First(); iter.Good();
41 iter.Inc()) {
42 syncable::MutableEntry entry(&trans, syncable::GET_TYPE_ROOT, iter.Get());
43 if (!entry.good())
44 continue;
45 if (!entry.GetIsUnappliedUpdate())
46 continue;
48 ModelType type = entry.GetServerModelType();
49 if (type == NIGORI) {
50 // Nigori node applications never fail.
51 ApplyNigoriUpdate(&trans,
52 &entry,
53 dir->GetCryptographer(&trans));
54 } else {
55 ApplyControlUpdate(&trans,
56 &entry,
57 dir->GetCryptographer(&trans));
61 // Go through the rest of the unapplied control updates, skipping over any
62 // top level folders.
63 for (std::vector<int64>::const_iterator iter = handles.begin();
64 iter != handles.end(); ++iter) {
65 syncable::MutableEntry entry(&trans, syncable::GET_BY_HANDLE, *iter);
66 CHECK(entry.good());
67 ModelType type = entry.GetServerModelType();
68 CHECK(ControlTypes().Has(type));
69 if (!entry.GetUniqueServerTag().empty()) {
70 // We should have already applied all top level control nodes.
71 DCHECK(!entry.GetIsUnappliedUpdate());
72 continue;
75 ApplyControlUpdate(&trans,
76 &entry,
77 dir->GetCryptographer(&trans));
81 // Update the nigori handler with the server's nigori node.
83 // If we have a locally modified nigori node, we merge them manually. This
84 // handles the case where two clients both set a different passphrase. The
85 // second client to attempt to commit will go into a state of having pending
86 // keys, unioned the set of encrypted types, and eventually re-encrypt
87 // everything with the passphrase of the first client and commit the set of
88 // merged encryption keys. Until the second client provides the pending
89 // passphrase, the cryptographer will preserve the encryption keys based on the
90 // local passphrase, while the nigori node will preserve the server encryption
91 // keys.
92 void ApplyNigoriUpdate(syncable::WriteTransaction* const trans,
93 syncable::MutableEntry* const entry,
94 Cryptographer* cryptographer) {
95 DCHECK(entry->GetIsUnappliedUpdate());
97 // We apply the nigori update regardless of whether there's a conflict or
98 // not in order to preserve any new encrypted types or encryption keys.
99 // TODO(zea): consider having this return a bool reflecting whether it was a
100 // valid update or not, and in the case of invalid updates not overwrite the
101 // local data.
102 const sync_pb::NigoriSpecifics& nigori =
103 entry->GetServerSpecifics().nigori();
104 trans->directory()->GetNigoriHandler()->ApplyNigoriUpdate(nigori, trans);
106 // Make sure any unsynced changes are properly encrypted as necessary.
107 // We only perform this if the cryptographer is ready. If not, these are
108 // re-encrypted at SetDecryptionPassphrase time (via ReEncryptEverything).
109 // This logic covers the case where the nigori update marked new datatypes
110 // for encryption, but didn't change the passphrase.
111 if (cryptographer->is_ready()) {
112 // Note that we don't bother to encrypt any data for which IS_UNSYNCED
113 // == false here. The machine that turned on encryption should know about
114 // and re-encrypt all synced data. It's possible it could get interrupted
115 // during this process, but we currently reencrypt everything at startup
116 // as well, so as soon as a client is restarted with this datatype marked
117 // for encryption, all the data should be updated as necessary.
119 // If this fails, something is wrong with the cryptographer, but there's
120 // nothing we can do about it here.
121 DVLOG(1) << "Received new nigori, encrypting unsynced changes.";
122 syncable::ProcessUnsyncedChangesForEncryption(trans);
125 if (!entry->GetIsUnsynced()) { // Update only.
126 UpdateLocalDataFromServerData(trans, entry);
127 } else { // Conflict.
128 const sync_pb::EntitySpecifics& server_specifics =
129 entry->GetServerSpecifics();
130 const sync_pb::NigoriSpecifics& server_nigori = server_specifics.nigori();
131 const sync_pb::EntitySpecifics& local_specifics =
132 entry->GetSpecifics();
133 const sync_pb::NigoriSpecifics& local_nigori = local_specifics.nigori();
135 // We initialize the new nigori with the server state, and will override
136 // it as necessary below.
137 sync_pb::EntitySpecifics new_specifics = entry->GetServerSpecifics();
138 sync_pb::NigoriSpecifics* new_nigori = new_specifics.mutable_nigori();
140 // If the cryptographer is not ready, another client set a new encryption
141 // passphrase. If we had migrated locally, we will re-migrate when the
142 // pending keys are provided. If we had set a new custom passphrase locally
143 // the user will have another chance to set a custom passphrase later
144 // (assuming they hadn't set a custom passphrase on the other client).
145 // Therefore, we only attempt to merge the nigori nodes if the cryptographer
146 // is ready.
147 // Note: we only update the encryption keybag if we're sure that we aren't
148 // invalidating the keystore_decryptor_token (i.e. we're either
149 // not migrated or we copying over all local state).
150 if (cryptographer->is_ready()) {
151 if (local_nigori.has_passphrase_type() &&
152 server_nigori.has_passphrase_type()) {
153 // They're both migrated, preserve the local nigori if the passphrase
154 // type is more conservative.
155 if (server_nigori.passphrase_type() ==
156 sync_pb::NigoriSpecifics::KEYSTORE_PASSPHRASE &&
157 local_nigori.passphrase_type() !=
158 sync_pb::NigoriSpecifics::KEYSTORE_PASSPHRASE) {
159 DCHECK(local_nigori.passphrase_type() ==
160 sync_pb::NigoriSpecifics::FROZEN_IMPLICIT_PASSPHRASE ||
161 local_nigori.passphrase_type() ==
162 sync_pb::NigoriSpecifics::CUSTOM_PASSPHRASE);
163 new_nigori->CopyFrom(local_nigori);
164 cryptographer->GetKeys(new_nigori->mutable_encryption_keybag());
166 } else if (!local_nigori.has_passphrase_type() &&
167 !server_nigori.has_passphrase_type()) {
168 // Set the explicit passphrase based on the local state. If the server
169 // had set an explict passphrase, we should have pending keys, so
170 // should not reach this code.
171 // Because neither side is migrated, we don't have to worry about the
172 // keystore decryptor token.
173 new_nigori->set_keybag_is_frozen(local_nigori.keybag_is_frozen());
174 cryptographer->GetKeys(new_nigori->mutable_encryption_keybag());
175 } else if (local_nigori.has_passphrase_type()) {
176 // Local is migrated but server is not. Copy over the local migrated
177 // data.
178 new_nigori->CopyFrom(local_nigori);
179 cryptographer->GetKeys(new_nigori->mutable_encryption_keybag());
180 } // else leave the new nigori with the server state.
183 // Always update to the safest set of encrypted types.
184 trans->directory()->GetNigoriHandler()->UpdateNigoriFromEncryptedTypes(
185 new_nigori,
186 trans);
188 entry->PutSpecifics(new_specifics);
189 DVLOG(1) << "Resolving simple conflict, merging nigori nodes: "
190 << entry;
192 conflict_util::OverwriteServerChanges(entry);
194 UMA_HISTOGRAM_ENUMERATION("Sync.ResolveSimpleConflict",
195 ConflictResolver::NIGORI_MERGE,
196 ConflictResolver::CONFLICT_RESOLUTION_SIZE);
200 void ApplyControlUpdate(syncable::WriteTransaction* const trans,
201 syncable::MutableEntry* const entry,
202 Cryptographer* cryptographer) {
203 DCHECK_NE(entry->GetServerModelType(), NIGORI);
204 DCHECK(entry->GetIsUnappliedUpdate());
205 if (entry->GetIsUnsynced()) {
206 // We just let the server win all conflicts with control types.
207 DVLOG(1) << "Ignoring local changes for control update.";
208 conflict_util::IgnoreLocalChanges(entry);
209 UMA_HISTOGRAM_ENUMERATION("Sync.ResolveSimpleConflict",
210 ConflictResolver::OVERWRITE_LOCAL,
211 ConflictResolver::CONFLICT_RESOLUTION_SIZE);
214 UpdateAttemptResponse response = AttemptToUpdateEntry(
215 trans, entry, cryptographer);
216 DCHECK_EQ(SUCCESS, response);
219 } // namespace syncer