1 /*
2  * Copyright (C) 2018 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *      http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 
17 #include "liblp/builder.h"
18 
19 #include <string.h>
20 
21 #include <algorithm>
22 #include <limits>
23 
24 #include <android-base/unique_fd.h>
25 
26 #include "liblp/liblp.h"
27 #include "liblp/property_fetcher.h"
28 #include "reader.h"
29 #include "utility.h"
30 
31 namespace android {
32 namespace fs_mgr {
33 
operator <<(std::ostream & os,const Extent & extent)34 std::ostream& operator<<(std::ostream& os, const Extent& extent) {
35     switch (extent.GetExtentType()) {
36         case ExtentType::kZero: {
37             os << "type: Zero";
38             break;
39         }
40         case ExtentType::kLinear: {
41             auto linear_extent = static_cast<const LinearExtent*>(&extent);
42             os << "type: Linear, physical sectors: " << linear_extent->physical_sector()
43                << ", end sectors: " << linear_extent->end_sector();
44             break;
45         }
46     }
47     return os;
48 }
49 
AddTo(LpMetadata * out) const50 bool LinearExtent::AddTo(LpMetadata* out) const {
51     if (device_index_ >= out->block_devices.size()) {
52         LERROR << "Extent references unknown block device.";
53         return false;
54     }
55     out->extents.emplace_back(
56             LpMetadataExtent{num_sectors_, LP_TARGET_TYPE_LINEAR, physical_sector_, device_index_});
57     return true;
58 }
59 
operator ==(const android::fs_mgr::Extent & other) const60 bool LinearExtent::operator==(const android::fs_mgr::Extent& other) const {
61     if (other.GetExtentType() != ExtentType::kLinear) {
62         return false;
63     }
64 
65     auto other_ptr = static_cast<const LinearExtent*>(&other);
66     return num_sectors_ == other_ptr->num_sectors_ &&
67            physical_sector_ == other_ptr->physical_sector_ &&
68            device_index_ == other_ptr->device_index_;
69 }
70 
OverlapsWith(const LinearExtent & other) const71 bool LinearExtent::OverlapsWith(const LinearExtent& other) const {
72     if (device_index_ != other.device_index()) {
73         return false;
74     }
75     return physical_sector() < other.end_sector() && other.physical_sector() < end_sector();
76 }
77 
OverlapsWith(const Interval & interval) const78 bool LinearExtent::OverlapsWith(const Interval& interval) const {
79     if (device_index_ != interval.device_index) {
80         return false;
81     }
82     return physical_sector() < interval.end && interval.start < end_sector();
83 }
84 
AsInterval() const85 Interval LinearExtent::AsInterval() const {
86     return Interval(device_index(), physical_sector(), end_sector());
87 }
88 
AddTo(LpMetadata * out) const89 bool ZeroExtent::AddTo(LpMetadata* out) const {
90     out->extents.emplace_back(LpMetadataExtent{num_sectors_, LP_TARGET_TYPE_ZERO, 0, 0});
91     return true;
92 }
93 
operator ==(const android::fs_mgr::Extent & other) const94 bool ZeroExtent::operator==(const android::fs_mgr::Extent& other) const {
95     return other.GetExtentType() == ExtentType::kZero && num_sectors_ == other.num_sectors();
96 }
97 
Partition(std::string_view name,std::string_view group_name,uint32_t attributes)98 Partition::Partition(std::string_view name, std::string_view group_name, uint32_t attributes)
99     : name_(name), group_name_(group_name), attributes_(attributes), size_(0) {}
100 
AddExtent(std::unique_ptr<Extent> && extent)101 void Partition::AddExtent(std::unique_ptr<Extent>&& extent) {
102     size_ += extent->num_sectors() * LP_SECTOR_SIZE;
103 
104     if (LinearExtent* new_extent = extent->AsLinearExtent()) {
105         if (!extents_.empty() && extents_.back()->AsLinearExtent()) {
106             LinearExtent* prev_extent = extents_.back()->AsLinearExtent();
107             if (prev_extent->end_sector() == new_extent->physical_sector() &&
108                 prev_extent->device_index() == new_extent->device_index()) {
109                 // If the previous extent can be merged into this new one, do so
110                 // to avoid creating unnecessary extents.
111                 extent = std::make_unique<LinearExtent>(
112                         prev_extent->num_sectors() + new_extent->num_sectors(),
113                         prev_extent->device_index(), prev_extent->physical_sector());
114                 extents_.pop_back();
115             }
116         }
117     }
118     extents_.push_back(std::move(extent));
119 }
120 
RemoveExtents()121 void Partition::RemoveExtents() {
122     size_ = 0;
123     extents_.clear();
124 }
125 
ShrinkTo(uint64_t aligned_size)126 void Partition::ShrinkTo(uint64_t aligned_size) {
127     if (aligned_size == 0) {
128         RemoveExtents();
129         return;
130     }
131 
132     // Remove or shrink extents of any kind until the total partition size is
133     // equal to the requested size.
134     uint64_t sectors_to_remove = (size_ - aligned_size) / LP_SECTOR_SIZE;
135     while (sectors_to_remove) {
136         Extent* extent = extents_.back().get();
137         if (extent->num_sectors() > sectors_to_remove) {
138             size_ -= sectors_to_remove * LP_SECTOR_SIZE;
139             extent->set_num_sectors(extent->num_sectors() - sectors_to_remove);
140             break;
141         }
142         size_ -= (extent->num_sectors() * LP_SECTOR_SIZE);
143         sectors_to_remove -= extent->num_sectors();
144         extents_.pop_back();
145     }
146     DCHECK(size_ == aligned_size);
147 }
148 
GetBeginningExtents(uint64_t aligned_size) const149 Partition Partition::GetBeginningExtents(uint64_t aligned_size) const {
150     Partition p(name_, group_name_, attributes_);
151     for (const auto& extent : extents_) {
152         auto le = extent->AsLinearExtent();
153         if (le) {
154             p.AddExtent(std::make_unique<LinearExtent>(*le));
155         } else {
156             p.AddExtent(std::make_unique<ZeroExtent>(extent->num_sectors()));
157         }
158     }
159     p.ShrinkTo(aligned_size);
160     return p;
161 }
162 
BytesOnDisk() const163 uint64_t Partition::BytesOnDisk() const {
164     uint64_t sectors = 0;
165     for (const auto& extent : extents_) {
166         if (!extent->AsLinearExtent()) {
167             continue;
168         }
169         sectors += extent->num_sectors();
170     }
171     return sectors * LP_SECTOR_SIZE;
172 }
173 
New(const IPartitionOpener & opener,const std::string & super_partition,uint32_t slot_number)174 std::unique_ptr<MetadataBuilder> MetadataBuilder::New(const IPartitionOpener& opener,
175                                                       const std::string& super_partition,
176                                                       uint32_t slot_number) {
177     std::unique_ptr<LpMetadata> metadata = ReadMetadata(opener, super_partition, slot_number);
178     if (!metadata) {
179         return nullptr;
180     }
181     return New(*metadata.get(), &opener);
182 }
183 
New(const std::string & super_partition,uint32_t slot_number)184 std::unique_ptr<MetadataBuilder> MetadataBuilder::New(const std::string& super_partition,
185                                                       uint32_t slot_number) {
186     return New(PartitionOpener(), super_partition, slot_number);
187 }
188 
New(const std::vector<BlockDeviceInfo> & block_devices,const std::string & super_partition,uint32_t metadata_max_size,uint32_t metadata_slot_count)189 std::unique_ptr<MetadataBuilder> MetadataBuilder::New(
190         const std::vector<BlockDeviceInfo>& block_devices, const std::string& super_partition,
191         uint32_t metadata_max_size, uint32_t metadata_slot_count) {
192     std::unique_ptr<MetadataBuilder> builder(new MetadataBuilder());
193     if (!builder->Init(block_devices, super_partition, metadata_max_size, metadata_slot_count)) {
194         return nullptr;
195     }
196     return builder;
197 }
198 
New(const LpMetadata & metadata,const IPartitionOpener * opener)199 std::unique_ptr<MetadataBuilder> MetadataBuilder::New(const LpMetadata& metadata,
200                                                       const IPartitionOpener* opener) {
201     std::unique_ptr<MetadataBuilder> builder(new MetadataBuilder());
202     if (!builder->Init(metadata)) {
203         return nullptr;
204     }
205     if (opener) {
206         for (size_t i = 0; i < builder->block_devices_.size(); i++) {
207             std::string partition_name = builder->GetBlockDevicePartitionName(i);
208             BlockDeviceInfo device_info;
209             if (opener->GetInfo(partition_name, &device_info)) {
210                 builder->UpdateBlockDeviceInfo(i, device_info);
211             }
212         }
213     }
214     return builder;
215 }
216 
NewForUpdate(const IPartitionOpener & opener,const std::string & source_partition,uint32_t source_slot_number,uint32_t target_slot_number,bool always_keep_source_slot)217 std::unique_ptr<MetadataBuilder> MetadataBuilder::NewForUpdate(const IPartitionOpener& opener,
218                                                                const std::string& source_partition,
219                                                                uint32_t source_slot_number,
220                                                                uint32_t target_slot_number,
221                                                                bool always_keep_source_slot) {
222     auto metadata = ReadMetadata(opener, source_partition, source_slot_number);
223     if (!metadata) {
224         return nullptr;
225     }
226 
227     // On retrofit DAP devices, modify the metadata so that it is suitable for being written
228     // to the target slot later. We detect retrofit DAP devices by checking the super partition
229     // name and system properties.
230     // See comments for UpdateMetadataForOtherSuper.
231     auto super_device = GetMetadataSuperBlockDevice(*metadata.get());
232     if (android::fs_mgr::GetBlockDevicePartitionName(*super_device) != "super" &&
233         IsRetrofitDynamicPartitionsDevice()) {
234         if (!UpdateMetadataForOtherSuper(metadata.get(), source_slot_number, target_slot_number)) {
235             return nullptr;
236         }
237     }
238 
239     if (IPropertyFetcher::GetInstance()->GetBoolProperty("ro.virtual_ab.enabled", false)) {
240         if (always_keep_source_slot) {
241             // always_keep_source_slot implies the target build does not support snapshots.
242             // Clear unsupported attributes.
243             SetMetadataHeaderV0(metadata.get());
244         } else {
245             // !always_keep_source_slot implies the target build supports snapshots. Do snapshot
246             // updates.
247             if (!UpdateMetadataForInPlaceSnapshot(metadata.get(), source_slot_number,
248                                                   target_slot_number)) {
249                 return nullptr;
250             }
251         }
252     }
253 
254     return New(*metadata.get(), &opener);
255 }
256 
257 // For retrofit DAP devices, there are (conceptually) two super partitions. We'll need to translate
258 // block device and group names to update their slot suffixes.
259 // (On the other hand, On non-retrofit DAP devices there is only one location for metadata: the
260 // super partition. update_engine will remove and resize partitions as needed.)
UpdateMetadataForOtherSuper(LpMetadata * metadata,uint32_t source_slot_number,uint32_t target_slot_number)261 bool MetadataBuilder::UpdateMetadataForOtherSuper(LpMetadata* metadata, uint32_t source_slot_number,
262                                                   uint32_t target_slot_number) {
263     // Clear partitions and extents, since they have no meaning on the target
264     // slot. We also clear groups since they are re-added during OTA.
265     metadata->partitions.clear();
266     metadata->extents.clear();
267     metadata->groups.clear();
268 
269     std::string source_slot_suffix = SlotSuffixForSlotNumber(source_slot_number);
270     std::string target_slot_suffix = SlotSuffixForSlotNumber(target_slot_number);
271 
272     // Translate block devices.
273     auto source_block_devices = std::move(metadata->block_devices);
274     for (const auto& source_block_device : source_block_devices) {
275         std::string partition_name =
276                 android::fs_mgr::GetBlockDevicePartitionName(source_block_device);
277         std::string slot_suffix = GetPartitionSlotSuffix(partition_name);
278         if (slot_suffix.empty() || slot_suffix != source_slot_suffix) {
279             // This should never happen. It means that the source metadata
280             // refers to a target or unknown block device.
281             LERROR << "Invalid block device for slot " << source_slot_suffix << ": "
282                    << partition_name;
283             return false;
284         }
285         std::string new_name =
286                 partition_name.substr(0, partition_name.size() - slot_suffix.size()) +
287                 target_slot_suffix;
288 
289         auto new_device = source_block_device;
290         if (!UpdateBlockDevicePartitionName(&new_device, new_name)) {
291             LERROR << "Partition name too long: " << new_name;
292             return false;
293         }
294         metadata->block_devices.emplace_back(new_device);
295     }
296 
297     return true;
298 }
299 
MetadataBuilder()300 MetadataBuilder::MetadataBuilder() : auto_slot_suffixing_(false) {
301     memset(&geometry_, 0, sizeof(geometry_));
302     geometry_.magic = LP_METADATA_GEOMETRY_MAGIC;
303     geometry_.struct_size = sizeof(geometry_);
304 
305     memset(&header_, 0, sizeof(header_));
306     header_.magic = LP_METADATA_HEADER_MAGIC;
307     header_.major_version = LP_METADATA_MAJOR_VERSION;
308     header_.minor_version = LP_METADATA_MINOR_VERSION_MIN;
309     header_.header_size = sizeof(LpMetadataHeaderV1_0);
310     header_.partitions.entry_size = sizeof(LpMetadataPartition);
311     header_.extents.entry_size = sizeof(LpMetadataExtent);
312     header_.groups.entry_size = sizeof(LpMetadataPartitionGroup);
313     header_.block_devices.entry_size = sizeof(LpMetadataBlockDevice);
314 }
315 
Init(const LpMetadata & metadata)316 bool MetadataBuilder::Init(const LpMetadata& metadata) {
317     geometry_ = metadata.geometry;
318     block_devices_ = metadata.block_devices;
319 
320     // Bump the version as necessary to copy any newer fields.
321     if (metadata.header.minor_version >= LP_METADATA_VERSION_FOR_EXPANDED_HEADER) {
322         RequireExpandedMetadataHeader();
323         header_.flags = metadata.header.flags;
324     }
325 
326     for (const auto& group : metadata.groups) {
327         std::string group_name = GetPartitionGroupName(group);
328         if (!AddGroup(group_name, group.maximum_size)) {
329             return false;
330         }
331     }
332 
333     for (const auto& partition : metadata.partitions) {
334         std::string group_name = GetPartitionGroupName(metadata.groups[partition.group_index]);
335         Partition* builder =
336                 AddPartition(GetPartitionName(partition), group_name, partition.attributes);
337         if (!builder) {
338             return false;
339         }
340         ImportExtents(builder, metadata, partition);
341     }
342     return true;
343 }
344 
ImportExtents(Partition * dest,const LpMetadata & metadata,const LpMetadataPartition & source)345 void MetadataBuilder::ImportExtents(Partition* dest, const LpMetadata& metadata,
346                                     const LpMetadataPartition& source) {
347     for (size_t i = 0; i < source.num_extents; i++) {
348         const LpMetadataExtent& extent = metadata.extents[source.first_extent_index + i];
349         if (extent.target_type == LP_TARGET_TYPE_LINEAR) {
350             auto copy = std::make_unique<LinearExtent>(extent.num_sectors, extent.target_source,
351                                                        extent.target_data);
352             dest->AddExtent(std::move(copy));
353         } else if (extent.target_type == LP_TARGET_TYPE_ZERO) {
354             auto copy = std::make_unique<ZeroExtent>(extent.num_sectors);
355             dest->AddExtent(std::move(copy));
356         }
357     }
358 }
359 
VerifyDeviceProperties(const BlockDeviceInfo & device_info)360 static bool VerifyDeviceProperties(const BlockDeviceInfo& device_info) {
361     if (device_info.logical_block_size == 0) {
362         LERROR << "Block device " << device_info.partition_name
363                << " logical block size must not be zero.";
364         return false;
365     }
366     if (device_info.logical_block_size % LP_SECTOR_SIZE != 0) {
367         LERROR << "Block device " << device_info.partition_name
368                << " logical block size must be a multiple of 512.";
369         return false;
370     }
371     if (device_info.size % device_info.logical_block_size != 0) {
372         LERROR << "Block device " << device_info.partition_name
373                << " size must be a multiple of its block size.";
374         return false;
375     }
376     if (device_info.alignment_offset % LP_SECTOR_SIZE != 0) {
377         LERROR << "Block device " << device_info.partition_name
378                << " alignment offset is not sector-aligned.";
379         return false;
380     }
381     if (device_info.alignment % LP_SECTOR_SIZE != 0) {
382         LERROR << "Block device " << device_info.partition_name
383                << " partition alignment is not sector-aligned.";
384         return false;
385     }
386     return true;
387 }
388 
Init(const std::vector<BlockDeviceInfo> & block_devices,const std::string & super_partition,uint32_t metadata_max_size,uint32_t metadata_slot_count)389 bool MetadataBuilder::Init(const std::vector<BlockDeviceInfo>& block_devices,
390                            const std::string& super_partition, uint32_t metadata_max_size,
391                            uint32_t metadata_slot_count) {
392     if (metadata_max_size < sizeof(LpMetadataHeader)) {
393         LERROR << "Invalid metadata maximum size.";
394         return false;
395     }
396     if (metadata_slot_count == 0) {
397         LERROR << "Invalid metadata slot count.";
398         return false;
399     }
400     if (block_devices.empty()) {
401         LERROR << "No block devices were specified.";
402         return false;
403     }
404 
405     // Align the metadata size up to the nearest sector.
406     if (!AlignTo(metadata_max_size, LP_SECTOR_SIZE, &metadata_max_size)) {
407         LERROR << "Max metadata size " << metadata_max_size << " is too large.";
408         return false;
409     }
410 
411     // Validate and build the block device list.
412     uint32_t logical_block_size = 0;
413     for (const auto& device_info : block_devices) {
414         if (!VerifyDeviceProperties(device_info)) {
415             return false;
416         }
417 
418         if (!logical_block_size) {
419             logical_block_size = device_info.logical_block_size;
420         }
421         if (logical_block_size != device_info.logical_block_size) {
422             LERROR << "All partitions must have the same logical block size.";
423             return false;
424         }
425 
426         LpMetadataBlockDevice out = {};
427         out.alignment = device_info.alignment;
428         out.alignment_offset = device_info.alignment_offset;
429         out.size = device_info.size;
430         if (device_info.partition_name.size() > sizeof(out.partition_name)) {
431             LERROR << "Partition name " << device_info.partition_name << " exceeds maximum length.";
432             return false;
433         }
434         strncpy(out.partition_name, device_info.partition_name.c_str(), sizeof(out.partition_name));
435 
436         // In the case of the super partition, this field will be adjusted
437         // later. For all partitions, the first 512 bytes are considered
438         // untouched to be compatible code that looks for an MBR. Thus we
439         // start counting free sectors at sector 1, not 0.
440         uint64_t free_area_start = LP_SECTOR_SIZE;
441         bool ok;
442         if (out.alignment) {
443             ok = AlignTo(free_area_start, out.alignment, &free_area_start);
444         } else {
445             ok = AlignTo(free_area_start, logical_block_size, &free_area_start);
446         }
447         if (!ok) {
448             LERROR << "Integer overflow computing free area start";
449             return false;
450         }
451         out.first_logical_sector = free_area_start / LP_SECTOR_SIZE;
452 
453         // There must be one logical block of space available.
454         uint64_t minimum_size = out.first_logical_sector * LP_SECTOR_SIZE + logical_block_size;
455         if (device_info.size < minimum_size) {
456             LERROR << "Block device " << device_info.partition_name
457                    << " is too small to hold any logical partitions.";
458             return false;
459         }
460 
461         // The "root" of the super partition is always listed first.
462         if (device_info.partition_name == super_partition) {
463             block_devices_.emplace(block_devices_.begin(), out);
464         } else {
465             block_devices_.emplace_back(out);
466         }
467     }
468     if (GetBlockDevicePartitionName(0) != super_partition) {
469         LERROR << "No super partition was specified.";
470         return false;
471     }
472 
473     LpMetadataBlockDevice& super = block_devices_[0];
474 
475     // We reserve a geometry block (4KB) plus space for each copy of the
476     // maximum size of a metadata blob. Then, we double that space since
477     // we store a backup copy of everything.
478     uint64_t total_reserved = GetTotalMetadataSize(metadata_max_size, metadata_slot_count);
479     if (super.size < total_reserved) {
480         LERROR << "Attempting to create metadata on a block device that is too small.";
481         return false;
482     }
483 
484     // Compute the first free sector, factoring in alignment.
485     uint64_t free_area_start = total_reserved;
486     bool ok;
487     if (super.alignment) {
488         ok = AlignTo(free_area_start, super.alignment, &free_area_start);
489     } else {
490         ok = AlignTo(free_area_start, logical_block_size, &free_area_start);
491     }
492     if (!ok) {
493         LERROR << "Integer overflow computing free area start";
494         return false;
495     }
496     super.first_logical_sector = free_area_start / LP_SECTOR_SIZE;
497 
498     // There must be one logical block of free space remaining (enough for one partition).
499     uint64_t minimum_disk_size = (super.first_logical_sector * LP_SECTOR_SIZE) + logical_block_size;
500     if (super.size < minimum_disk_size) {
501         LERROR << "Device must be at least " << minimum_disk_size << " bytes, only has "
502                << super.size;
503         return false;
504     }
505 
506     geometry_.metadata_max_size = metadata_max_size;
507     geometry_.metadata_slot_count = metadata_slot_count;
508     geometry_.logical_block_size = logical_block_size;
509 
510     if (!AddGroup(std::string(kDefaultGroup), 0)) {
511         return false;
512     }
513     return true;
514 }
515 
AddGroup(std::string_view group_name,uint64_t maximum_size)516 bool MetadataBuilder::AddGroup(std::string_view group_name, uint64_t maximum_size) {
517     if (FindGroup(group_name)) {
518         LERROR << "Group already exists: " << group_name;
519         return false;
520     }
521     groups_.push_back(std::make_unique<PartitionGroup>(group_name, maximum_size));
522     return true;
523 }
524 
AddPartition(const std::string & name,uint32_t attributes)525 Partition* MetadataBuilder::AddPartition(const std::string& name, uint32_t attributes) {
526     return AddPartition(name, kDefaultGroup, attributes);
527 }
528 
AddPartition(std::string_view name,std::string_view group_name,uint32_t attributes)529 Partition* MetadataBuilder::AddPartition(std::string_view name, std::string_view group_name,
530                                          uint32_t attributes) {
531     if (name.empty()) {
532         LERROR << "Partition must have a non-empty name.";
533         return nullptr;
534     }
535     if (FindPartition(name)) {
536         LERROR << "Attempting to create duplication partition with name: " << name;
537         return nullptr;
538     }
539     if (!FindGroup(group_name)) {
540         LERROR << "Could not find partition group: " << group_name;
541         return nullptr;
542     }
543     partitions_.push_back(std::make_unique<Partition>(name, group_name, attributes));
544     return partitions_.back().get();
545 }
546 
FindPartition(std::string_view name) const547 Partition* MetadataBuilder::FindPartition(std::string_view name) const {
548     for (const auto& partition : partitions_) {
549         if (partition->name() == name) {
550             return partition.get();
551         }
552     }
553     return nullptr;
554 }
555 
FindGroup(std::string_view group_name) const556 PartitionGroup* MetadataBuilder::FindGroup(std::string_view group_name) const {
557     for (const auto& group : groups_) {
558         if (group->name() == group_name) {
559             return group.get();
560         }
561     }
562     return nullptr;
563 }
564 
TotalSizeOfGroup(PartitionGroup * group) const565 uint64_t MetadataBuilder::TotalSizeOfGroup(PartitionGroup* group) const {
566     uint64_t total = 0;
567     for (const auto& partition : partitions_) {
568         if (partition->group_name() != group->name()) {
569             continue;
570         }
571         total += partition->BytesOnDisk();
572     }
573     return total;
574 }
575 
RemovePartition(std::string_view name)576 void MetadataBuilder::RemovePartition(std::string_view name) {
577     for (auto iter = partitions_.begin(); iter != partitions_.end(); iter++) {
578         if ((*iter)->name() == name) {
579             partitions_.erase(iter);
580             return;
581         }
582     }
583 }
584 
ExtentsToFreeList(const std::vector<Interval> & extents,std::vector<Interval> * free_regions) const585 void MetadataBuilder::ExtentsToFreeList(const std::vector<Interval>& extents,
586                                         std::vector<Interval>* free_regions) const {
587     // Convert the extent list into a list of gaps between the extents; i.e.,
588     // the list of ranges that are free on the disk.
589     for (size_t i = 1; i < extents.size(); i++) {
590         const Interval& previous = extents[i - 1];
591         const Interval& current = extents[i];
592         DCHECK(previous.device_index == current.device_index);
593 
594         uint64_t aligned;
595         if (!AlignSector(block_devices_[current.device_index], previous.end, &aligned)) {
596             LERROR << "Sector " << previous.end << " caused integer overflow.";
597             continue;
598         }
599         if (aligned >= current.start) {
600             // There is no gap between these two extents, try the next one.
601             // Note that we check with >= instead of >, since alignment may
602             // bump the ending sector past the beginning of the next extent.
603             continue;
604         }
605 
606         // The new interval represents the free space starting at the end of
607         // the previous interval, and ending at the start of the next interval.
608         free_regions->emplace_back(current.device_index, aligned, current.start);
609     }
610 }
611 
GetFreeRegions() const612 auto MetadataBuilder::GetFreeRegions() const -> std::vector<Interval> {
613     std::vector<Interval> free_regions;
614 
615     // Collect all extents in the partition table, per-device, then sort them
616     // by starting sector.
617     std::vector<std::vector<Interval>> device_extents(block_devices_.size());
618     for (const auto& partition : partitions_) {
619         for (const auto& extent : partition->extents()) {
620             LinearExtent* linear = extent->AsLinearExtent();
621             if (!linear) {
622                 continue;
623             }
624             CHECK(linear->device_index() < device_extents.size());
625             auto& extents = device_extents[linear->device_index()];
626             extents.emplace_back(linear->device_index(), linear->physical_sector(),
627                                  linear->physical_sector() + extent->num_sectors());
628         }
629     }
630 
631     // Add 0-length intervals for the first and last sectors. This will cause
632     // ExtentToFreeList() to treat the space in between as available.
633     for (size_t i = 0; i < device_extents.size(); i++) {
634         auto& extents = device_extents[i];
635         const auto& block_device = block_devices_[i];
636 
637         uint64_t first_sector = block_device.first_logical_sector;
638         uint64_t last_sector = block_device.size / LP_SECTOR_SIZE;
639         extents.emplace_back(i, first_sector, first_sector);
640         extents.emplace_back(i, last_sector, last_sector);
641 
642         std::sort(extents.begin(), extents.end());
643         ExtentsToFreeList(extents, &free_regions);
644     }
645     return free_regions;
646 }
647 
ValidatePartitionSizeChange(Partition * partition,uint64_t old_size,uint64_t new_size,bool force_check)648 bool MetadataBuilder::ValidatePartitionSizeChange(Partition* partition, uint64_t old_size,
649                                                   uint64_t new_size, bool force_check) {
650     PartitionGroup* group = FindGroup(partition->group_name());
651     CHECK(group);
652 
653     if (!force_check && new_size <= old_size) {
654         return true;
655     }
656 
657     // Figure out how much we need to allocate, and whether our group has
658     // enough space remaining.
659     uint64_t space_needed = new_size - old_size;
660     if (group->maximum_size() > 0) {
661         uint64_t group_size = TotalSizeOfGroup(group);
662         if (group_size >= group->maximum_size() ||
663             group->maximum_size() - group_size < space_needed) {
664             LERROR << "Partition " << partition->name() << " is part of group " << group->name()
665                    << " which does not have enough space free (" << space_needed << " requested, "
666                    << group_size << " used out of " << group->maximum_size() << ")";
667             return false;
668         }
669     }
670     return true;
671 }
672 
Intersect(const Interval & a,const Interval & b)673 Interval Interval::Intersect(const Interval& a, const Interval& b) {
674     Interval ret = a;
675     if (a.device_index != b.device_index) {
676         ret.start = ret.end = a.start;  // set length to 0 to indicate no intersection.
677         return ret;
678     }
679     ret.start = std::max(a.start, b.start);
680     ret.end = std::max(ret.start, std::min(a.end, b.end));
681     return ret;
682 }
683 
Intersect(const std::vector<Interval> & a,const std::vector<Interval> & b)684 std::vector<Interval> Interval::Intersect(const std::vector<Interval>& a,
685                                           const std::vector<Interval>& b) {
686     std::vector<Interval> ret;
687     for (const Interval& a_interval : a) {
688         for (const Interval& b_interval : b) {
689             auto intersect = Intersect(a_interval, b_interval);
690             if (intersect.length() > 0) ret.emplace_back(std::move(intersect));
691         }
692     }
693     return ret;
694 }
695 
AsExtent() const696 std::unique_ptr<Extent> Interval::AsExtent() const {
697     return std::make_unique<LinearExtent>(length(), device_index, start);
698 }
699 
GrowPartition(Partition * partition,uint64_t aligned_size,const std::vector<Interval> & free_region_hint)700 bool MetadataBuilder::GrowPartition(Partition* partition, uint64_t aligned_size,
701                                     const std::vector<Interval>& free_region_hint) {
702     uint64_t space_needed = aligned_size - partition->size();
703     uint64_t sectors_needed = space_needed / LP_SECTOR_SIZE;
704     DCHECK(sectors_needed * LP_SECTOR_SIZE == space_needed);
705 
706     std::vector<Interval> free_regions = GetFreeRegions();
707     if (!free_region_hint.empty())
708         free_regions = Interval::Intersect(free_regions, free_region_hint);
709 
710     const uint64_t sectors_per_block = geometry_.logical_block_size / LP_SECTOR_SIZE;
711     CHECK_NE(sectors_per_block, 0);
712     CHECK(sectors_needed % sectors_per_block == 0);
713 
714     if (IsABDevice() && ShouldHalveSuper() && GetPartitionSlotSuffix(partition->name()) == "_b") {
715         // Allocate "a" partitions top-down and "b" partitions bottom-up, to
716         // minimize fragmentation during OTA.
717         free_regions = PrioritizeSecondHalfOfSuper(free_regions);
718     }
719 
720     // Note we store new extents in a temporary vector, and only commit them
721     // if we are guaranteed enough free space.
722     std::vector<std::unique_ptr<LinearExtent>> new_extents;
723 
724     // If the last extent in the partition has a size < alignment, then the
725     // difference is unallocatable due to being misaligned. We peek for that
726     // case here to avoid wasting space.
727     if (auto extent = ExtendFinalExtent(partition, free_regions, sectors_needed)) {
728         sectors_needed -= extent->num_sectors();
729         new_extents.emplace_back(std::move(extent));
730     }
731 
732     for (auto& region : free_regions) {
733         // Note: this comes first, since we may enter the loop not needing any
734         // more sectors.
735         if (!sectors_needed) {
736             break;
737         }
738 
739         if (region.length() % sectors_per_block != 0) {
740             // This should never happen, because it would imply that we
741             // once allocated an extent that was not a multiple of the
742             // block size. That extent would be rejected by DM_TABLE_LOAD.
743             LERROR << "Region " << region.start << ".." << region.end
744                    << " is not a multiple of the block size, " << sectors_per_block;
745 
746             // If for some reason the final region is mis-sized we still want
747             // to be able to grow partitions. So just to be safe, round the
748             // region down to the nearest block.
749             region.end = region.start + (region.length() / sectors_per_block) * sectors_per_block;
750             if (!region.length()) {
751                 continue;
752             }
753         }
754 
755         uint64_t sectors = std::min(sectors_needed, region.length());
756         CHECK(sectors % sectors_per_block == 0);
757 
758         auto extent = std::make_unique<LinearExtent>(sectors, region.device_index, region.start);
759         new_extents.push_back(std::move(extent));
760         sectors_needed -= sectors;
761     }
762     if (sectors_needed) {
763         LERROR << "Not enough free space to expand partition: " << partition->name();
764         return false;
765     }
766 
767     // Everything succeeded, so commit the new extents.
768     for (auto& extent : new_extents) {
769         partition->AddExtent(std::move(extent));
770     }
771     return true;
772 }
773 
PrioritizeSecondHalfOfSuper(const std::vector<Interval> & free_list)774 std::vector<Interval> MetadataBuilder::PrioritizeSecondHalfOfSuper(
775         const std::vector<Interval>& free_list) {
776     const auto& super = block_devices_[0];
777     uint64_t first_sector = super.first_logical_sector;
778     uint64_t last_sector = super.size / LP_SECTOR_SIZE;
779     uint64_t midpoint = first_sector + (last_sector - first_sector) / 2;
780 
781     // Choose an aligned sector for the midpoint. This could lead to one half
782     // being slightly larger than the other, but this will not restrict the
783     // size of partitions (it might lead to one extra extent if "B" overflows).
784     if (!AlignSector(super, midpoint, &midpoint)) {
785         LERROR << "Unexpected integer overflow aligning midpoint " << midpoint;
786         return free_list;
787     }
788 
789     std::vector<Interval> first_half;
790     std::vector<Interval> second_half;
791     for (const auto& region : free_list) {
792         // Note: deprioritze if not the main super partition. Even though we
793         // don't call this for retrofit devices, we will allow adding additional
794         // block devices on non-retrofit devices.
795         if (region.device_index != 0 || region.end <= midpoint) {
796             first_half.emplace_back(region);
797             continue;
798         }
799         if (region.start < midpoint && region.end > midpoint) {
800             // Split this into two regions.
801             first_half.emplace_back(region.device_index, region.start, midpoint);
802             second_half.emplace_back(region.device_index, midpoint, region.end);
803         } else {
804             second_half.emplace_back(region);
805         }
806     }
807     second_half.insert(second_half.end(), first_half.begin(), first_half.end());
808     return second_half;
809 }
810 
ExtendFinalExtent(Partition * partition,const std::vector<Interval> & free_list,uint64_t sectors_needed) const811 std::unique_ptr<LinearExtent> MetadataBuilder::ExtendFinalExtent(
812         Partition* partition, const std::vector<Interval>& free_list,
813         uint64_t sectors_needed) const {
814     if (partition->extents().empty()) {
815         return nullptr;
816     }
817     LinearExtent* extent = partition->extents().back()->AsLinearExtent();
818     if (!extent) {
819         return nullptr;
820     }
821 
822     // If the sector ends where the next aligned chunk begins, then there's
823     // no missing gap to try and allocate.
824     const auto& block_device = block_devices_[extent->device_index()];
825     uint64_t next_aligned_sector;
826     if (!AlignSector(block_device, extent->end_sector(), &next_aligned_sector)) {
827         LERROR << "Integer overflow aligning sector " << extent->end_sector();
828         return nullptr;
829     }
830     if (extent->end_sector() == next_aligned_sector) {
831         return nullptr;
832     }
833 
834     uint64_t num_sectors = std::min(next_aligned_sector - extent->end_sector(), sectors_needed);
835     auto new_extent = std::make_unique<LinearExtent>(num_sectors, extent->device_index(),
836                                                      extent->end_sector());
837     if (IsAnyRegionAllocated(*new_extent.get()) ||
838         IsAnyRegionCovered(free_list, *new_extent.get())) {
839         LERROR << "Misaligned region " << new_extent->physical_sector() << ".."
840                << new_extent->end_sector() << " was allocated or marked allocatable.";
841         return nullptr;
842     }
843     return new_extent;
844 }
845 
IsAnyRegionCovered(const std::vector<Interval> & regions,const LinearExtent & candidate) const846 bool MetadataBuilder::IsAnyRegionCovered(const std::vector<Interval>& regions,
847                                          const LinearExtent& candidate) const {
848     for (const auto& region : regions) {
849         if (candidate.OverlapsWith(region)) {
850             return true;
851         }
852     }
853     return false;
854 }
855 
IsAnyRegionAllocated(const LinearExtent & candidate) const856 bool MetadataBuilder::IsAnyRegionAllocated(const LinearExtent& candidate) const {
857     for (const auto& partition : partitions_) {
858         for (const auto& extent : partition->extents()) {
859             LinearExtent* linear = extent->AsLinearExtent();
860             if (!linear) {
861                 continue;
862             }
863             if (linear->OverlapsWith(candidate)) {
864                 return true;
865             }
866         }
867     }
868     return false;
869 }
870 
ShrinkPartition(Partition * partition,uint64_t aligned_size)871 void MetadataBuilder::ShrinkPartition(Partition* partition, uint64_t aligned_size) {
872     partition->ShrinkTo(aligned_size);
873 }
874 
Export()875 std::unique_ptr<LpMetadata> MetadataBuilder::Export() {
876     if (!ValidatePartitionGroups()) {
877         return nullptr;
878     }
879 
880     std::unique_ptr<LpMetadata> metadata = std::make_unique<LpMetadata>();
881     metadata->header = header_;
882     metadata->geometry = geometry_;
883 
884     // Assign this early so the extent table can read it.
885     for (const auto& block_device : block_devices_) {
886         metadata->block_devices.emplace_back(block_device);
887         if (auto_slot_suffixing_) {
888             metadata->block_devices.back().flags |= LP_BLOCK_DEVICE_SLOT_SUFFIXED;
889         }
890     }
891 
892     std::map<std::string, size_t> group_indices;
893     for (const auto& group : groups_) {
894         LpMetadataPartitionGroup out = {};
895 
896         if (group->name().size() > sizeof(out.name)) {
897             LERROR << "Partition group name is too long: " << group->name();
898             return nullptr;
899         }
900         if (auto_slot_suffixing_ && group->name() != kDefaultGroup) {
901             out.flags |= LP_GROUP_SLOT_SUFFIXED;
902         }
903         strncpy(out.name, group->name().c_str(), sizeof(out.name));
904         out.maximum_size = group->maximum_size();
905 
906         group_indices[group->name()] = metadata->groups.size();
907         metadata->groups.push_back(out);
908     }
909 
910     // Flatten the partition and extent structures into an LpMetadata, which
911     // makes it very easy to validate, serialize, or pass on to device-mapper.
912     for (const auto& partition : partitions_) {
913         LpMetadataPartition part;
914         memset(&part, 0, sizeof(part));
915 
916         if (partition->name().size() > sizeof(part.name)) {
917             LERROR << "Partition name is too long: " << partition->name();
918             return nullptr;
919         }
920         if (partition->attributes() & ~(LP_PARTITION_ATTRIBUTE_MASK)) {
921             LERROR << "Partition " << partition->name() << " has unsupported attribute.";
922             return nullptr;
923         }
924 
925         if (partition->attributes() & LP_PARTITION_ATTRIBUTE_MASK_V1) {
926             static const uint16_t kMinVersion = LP_METADATA_VERSION_FOR_UPDATED_ATTR;
927             metadata->header.minor_version = std::max(metadata->header.minor_version, kMinVersion);
928         }
929 
930         strncpy(part.name, partition->name().c_str(), sizeof(part.name));
931         part.first_extent_index = static_cast<uint32_t>(metadata->extents.size());
932         part.num_extents = static_cast<uint32_t>(partition->extents().size());
933         part.attributes = partition->attributes();
934         if (auto_slot_suffixing_) {
935             part.attributes |= LP_PARTITION_ATTR_SLOT_SUFFIXED;
936         }
937 
938         auto iter = group_indices.find(partition->group_name());
939         if (iter == group_indices.end()) {
940             LERROR << "Partition " << partition->name() << " is a member of unknown group "
941                    << partition->group_name();
942             return nullptr;
943         }
944         part.group_index = iter->second;
945 
946         for (const auto& extent : partition->extents()) {
947             if (!extent->AddTo(metadata.get())) {
948                 return nullptr;
949             }
950         }
951         metadata->partitions.push_back(part);
952     }
953 
954     metadata->header.partitions.num_entries = static_cast<uint32_t>(metadata->partitions.size());
955     metadata->header.extents.num_entries = static_cast<uint32_t>(metadata->extents.size());
956     metadata->header.groups.num_entries = static_cast<uint32_t>(metadata->groups.size());
957     metadata->header.block_devices.num_entries =
958             static_cast<uint32_t>(metadata->block_devices.size());
959     return metadata;
960 }
961 
RequireExpandedMetadataHeader()962 void MetadataBuilder::RequireExpandedMetadataHeader() {
963     if (header_.minor_version >= LP_METADATA_VERSION_FOR_EXPANDED_HEADER) {
964         return;
965     }
966     header_.minor_version = LP_METADATA_VERSION_FOR_EXPANDED_HEADER;
967     header_.header_size = sizeof(LpMetadataHeaderV1_2);
968 }
969 
AllocatableSpace() const970 uint64_t MetadataBuilder::AllocatableSpace() const {
971     uint64_t total_size = 0;
972     for (const auto& block_device : block_devices_) {
973         total_size += block_device.size - (block_device.first_logical_sector * LP_SECTOR_SIZE);
974     }
975     return total_size;
976 }
977 
UsedSpace() const978 uint64_t MetadataBuilder::UsedSpace() const {
979     uint64_t size = 0;
980     for (const auto& partition : partitions_) {
981         size += partition->size();
982     }
983     return size;
984 }
985 
AlignSector(const LpMetadataBlockDevice & block_device,uint64_t sector,uint64_t * out) const986 bool MetadataBuilder::AlignSector(const LpMetadataBlockDevice& block_device, uint64_t sector,
987                                   uint64_t* out) const {
988     // Note: when reading alignment info from the Kernel, we don't assume it
989     // is aligned to the sector size, so we round up to the nearest sector.
990     uint64_t lba = sector * LP_SECTOR_SIZE;
991     if (!AlignTo(lba, block_device.alignment, out)) {
992         return false;
993     }
994     if (!AlignTo(*out, LP_SECTOR_SIZE, out)) {
995         return false;
996     }
997     *out /= LP_SECTOR_SIZE;
998     return true;
999 }
1000 
FindBlockDeviceByName(const std::string & partition_name,uint32_t * index) const1001 bool MetadataBuilder::FindBlockDeviceByName(const std::string& partition_name,
1002                                             uint32_t* index) const {
1003     for (size_t i = 0; i < block_devices_.size(); i++) {
1004         if (GetBlockDevicePartitionName(i) == partition_name) {
1005             *index = i;
1006             return true;
1007         }
1008     }
1009     return false;
1010 }
1011 
HasBlockDevice(const std::string & partition_name) const1012 bool MetadataBuilder::HasBlockDevice(const std::string& partition_name) const {
1013     uint32_t index;
1014     return FindBlockDeviceByName(partition_name, &index);
1015 }
1016 
GetBlockDeviceInfo(const std::string & partition_name,BlockDeviceInfo * info) const1017 bool MetadataBuilder::GetBlockDeviceInfo(const std::string& partition_name,
1018                                          BlockDeviceInfo* info) const {
1019     uint32_t index;
1020     if (!FindBlockDeviceByName(partition_name, &index)) {
1021         LERROR << "No device named " << partition_name;
1022         return false;
1023     }
1024     info->size = block_devices_[index].size;
1025     info->alignment = block_devices_[index].alignment;
1026     info->alignment_offset = block_devices_[index].alignment_offset;
1027     info->logical_block_size = geometry_.logical_block_size;
1028     info->partition_name = partition_name;
1029     return true;
1030 }
1031 
UpdateBlockDeviceInfo(const std::string & partition_name,const BlockDeviceInfo & device_info)1032 bool MetadataBuilder::UpdateBlockDeviceInfo(const std::string& partition_name,
1033                                             const BlockDeviceInfo& device_info) {
1034     uint32_t index;
1035     if (!FindBlockDeviceByName(partition_name, &index)) {
1036         LERROR << "No device named " << partition_name;
1037         return false;
1038     }
1039     return UpdateBlockDeviceInfo(index, device_info);
1040 }
1041 
UpdateBlockDeviceInfo(size_t index,const BlockDeviceInfo & device_info)1042 bool MetadataBuilder::UpdateBlockDeviceInfo(size_t index, const BlockDeviceInfo& device_info) {
1043     CHECK(index < block_devices_.size());
1044 
1045     LpMetadataBlockDevice& block_device = block_devices_[index];
1046     if (device_info.size != block_device.size) {
1047         LERROR << "Device size does not match (got " << device_info.size << ", expected "
1048                << block_device.size << ")";
1049         return false;
1050     }
1051     if (geometry_.logical_block_size % device_info.logical_block_size) {
1052         LERROR << "Device logical block size is misaligned (block size="
1053                << device_info.logical_block_size << ", alignment=" << geometry_.logical_block_size
1054                << ")";
1055         return false;
1056     }
1057 
1058     // The kernel does not guarantee these values are present, so we only
1059     // replace existing values if the new values are non-zero.
1060     if (device_info.alignment) {
1061         block_device.alignment = device_info.alignment;
1062     }
1063     if (device_info.alignment_offset) {
1064         block_device.alignment_offset = device_info.alignment_offset;
1065     }
1066     return true;
1067 }
1068 
ResizePartition(Partition * partition,uint64_t requested_size,const std::vector<Interval> & free_region_hint)1069 bool MetadataBuilder::ResizePartition(Partition* partition, uint64_t requested_size,
1070                                       const std::vector<Interval>& free_region_hint) {
1071     // Align the space needed up to the nearest sector.
1072     uint64_t aligned_size;
1073     if (!AlignTo(requested_size, geometry_.logical_block_size, &aligned_size)) {
1074         LERROR << "Cannot resize partition " << partition->name() << " to " << requested_size
1075                << " bytes; integer overflow.";
1076         return false;
1077     }
1078     uint64_t old_size = partition->size();
1079 
1080     if (!ValidatePartitionSizeChange(partition, old_size, aligned_size, false)) {
1081         return false;
1082     }
1083 
1084     if (aligned_size > old_size) {
1085         if (!GrowPartition(partition, aligned_size, free_region_hint)) {
1086             return false;
1087         }
1088     } else if (aligned_size < partition->size()) {
1089         ShrinkPartition(partition, aligned_size);
1090     }
1091 
1092     if (partition->size() != old_size) {
1093         LINFO << "Partition " << partition->name() << " will resize from " << old_size
1094               << " bytes to " << aligned_size << " bytes";
1095     }
1096     return true;
1097 }
1098 
ListGroups() const1099 std::vector<std::string> MetadataBuilder::ListGroups() const {
1100     std::vector<std::string> names;
1101     for (const auto& group : groups_) {
1102         names.emplace_back(group->name());
1103     }
1104     return names;
1105 }
1106 
RemoveGroupAndPartitions(std::string_view group_name)1107 void MetadataBuilder::RemoveGroupAndPartitions(std::string_view group_name) {
1108     if (group_name == kDefaultGroup) {
1109         // Cannot remove the default group.
1110         return;
1111     }
1112     std::vector<std::string> partition_names;
1113     for (const auto& partition : partitions_) {
1114         if (partition->group_name() == group_name) {
1115             partition_names.emplace_back(partition->name());
1116         }
1117     }
1118 
1119     for (const auto& partition_name : partition_names) {
1120         RemovePartition(partition_name);
1121     }
1122     for (auto iter = groups_.begin(); iter != groups_.end(); iter++) {
1123         if ((*iter)->name() == group_name) {
1124             groups_.erase(iter);
1125             break;
1126         }
1127     }
1128 }
1129 
CompareBlockDevices(const LpMetadataBlockDevice & first,const LpMetadataBlockDevice & second)1130 static bool CompareBlockDevices(const LpMetadataBlockDevice& first,
1131                                 const LpMetadataBlockDevice& second) {
1132     // Note: we don't compare alignment, since it's a performance thing and
1133     // won't affect whether old extents continue to work.
1134     return first.first_logical_sector == second.first_logical_sector && first.size == second.size &&
1135            android::fs_mgr::GetBlockDevicePartitionName(first) ==
1136                    android::fs_mgr::GetBlockDevicePartitionName(second);
1137 }
1138 
ImportPartitions(const LpMetadata & metadata,const std::set<std::string> & partition_names)1139 bool MetadataBuilder::ImportPartitions(const LpMetadata& metadata,
1140                                        const std::set<std::string>& partition_names) {
1141     // The block device list must be identical. We do not try to be clever and
1142     // allow ordering changes or changes that don't affect partitions. This
1143     // process is designed to allow the most common flashing scenarios and more
1144     // complex ones should require a wipe.
1145     if (metadata.block_devices.size() != block_devices_.size()) {
1146         LINFO << "Block device tables does not match.";
1147         return false;
1148     }
1149     for (size_t i = 0; i < metadata.block_devices.size(); i++) {
1150         const LpMetadataBlockDevice& old_device = metadata.block_devices[i];
1151         const LpMetadataBlockDevice& new_device = block_devices_[i];
1152         if (!CompareBlockDevices(old_device, new_device)) {
1153             LINFO << "Block device tables do not match";
1154             return false;
1155         }
1156     }
1157 
1158     // Import named partitions. Note that we do not attempt to merge group
1159     // information here. If the device changed its group names, the old
1160     // partitions will fail to merge. The same could happen if the group
1161     // allocation sizes change.
1162     for (const auto& partition : metadata.partitions) {
1163         std::string partition_name = GetPartitionName(partition);
1164         if (partition_names.find(partition_name) == partition_names.end()) {
1165             continue;
1166         }
1167         if (!ImportPartition(metadata, partition)) {
1168             return false;
1169         }
1170     }
1171     return true;
1172 }
1173 
ImportPartition(const LpMetadata & metadata,const LpMetadataPartition & source)1174 bool MetadataBuilder::ImportPartition(const LpMetadata& metadata,
1175                                       const LpMetadataPartition& source) {
1176     std::string partition_name = GetPartitionName(source);
1177     Partition* partition = FindPartition(partition_name);
1178     if (!partition) {
1179         std::string group_name = GetPartitionGroupName(metadata.groups[source.group_index]);
1180         partition = AddPartition(partition_name, group_name, source.attributes);
1181         if (!partition) {
1182             return false;
1183         }
1184     }
1185     if (partition->size() > 0) {
1186         LINFO << "Importing partition table would overwrite non-empty partition: "
1187               << partition_name;
1188         return false;
1189     }
1190 
1191     ImportExtents(partition, metadata, source);
1192 
1193     // Note: we've already increased the partition size by calling
1194     // ImportExtents(). In order to figure out the size before that,
1195     // we would have to iterate the extents and add up the linear
1196     // segments. Instead, we just force ValidatePartitionSizeChange
1197     // to check if the current configuration is acceptable.
1198     if (!ValidatePartitionSizeChange(partition, partition->size(), partition->size(), true)) {
1199         partition->RemoveExtents();
1200         return false;
1201     }
1202     return true;
1203 }
1204 
SetAutoSlotSuffixing()1205 void MetadataBuilder::SetAutoSlotSuffixing() {
1206     auto_slot_suffixing_ = true;
1207 }
1208 
SetVirtualABDeviceFlag()1209 void MetadataBuilder::SetVirtualABDeviceFlag() {
1210     RequireExpandedMetadataHeader();
1211     header_.flags |= LP_HEADER_FLAG_VIRTUAL_AB_DEVICE;
1212 }
1213 
IsABDevice()1214 bool MetadataBuilder::IsABDevice() {
1215     return !IPropertyFetcher::GetInstance()->GetProperty("ro.boot.slot_suffix", "").empty();
1216 }
1217 
IsRetrofitDynamicPartitionsDevice()1218 bool MetadataBuilder::IsRetrofitDynamicPartitionsDevice() {
1219     return IPropertyFetcher::GetInstance()->GetBoolProperty("ro.boot.dynamic_partitions_retrofit",
1220                                                             false);
1221 }
1222 
ShouldHalveSuper() const1223 bool MetadataBuilder::ShouldHalveSuper() const {
1224     return GetBlockDevicePartitionName(0) == LP_METADATA_DEFAULT_PARTITION_NAME &&
1225            !IPropertyFetcher::GetInstance()->GetBoolProperty("ro.virtual_ab.enabled", false);
1226 }
1227 
AddLinearExtent(Partition * partition,const std::string & block_device,uint64_t num_sectors,uint64_t physical_sector)1228 bool MetadataBuilder::AddLinearExtent(Partition* partition, const std::string& block_device,
1229                                       uint64_t num_sectors, uint64_t physical_sector) {
1230     uint32_t device_index;
1231     if (!FindBlockDeviceByName(block_device, &device_index)) {
1232         LERROR << "Could not find backing block device for extent: " << block_device;
1233         return false;
1234     }
1235 
1236     auto extent = std::make_unique<LinearExtent>(num_sectors, device_index, physical_sector);
1237     partition->AddExtent(std::move(extent));
1238     return true;
1239 }
1240 
ListPartitionsInGroup(std::string_view group_name)1241 std::vector<Partition*> MetadataBuilder::ListPartitionsInGroup(std::string_view group_name) {
1242     std::vector<Partition*> partitions;
1243     for (const auto& partition : partitions_) {
1244         if (partition->group_name() == group_name) {
1245             partitions.emplace_back(partition.get());
1246         }
1247     }
1248     return partitions;
1249 }
1250 
ChangePartitionGroup(Partition * partition,std::string_view group_name)1251 bool MetadataBuilder::ChangePartitionGroup(Partition* partition, std::string_view group_name) {
1252     if (!FindGroup(group_name)) {
1253         LERROR << "Partition cannot change to unknown group: " << group_name;
1254         return false;
1255     }
1256     partition->set_group_name(group_name);
1257     return true;
1258 }
1259 
ValidatePartitionGroups() const1260 bool MetadataBuilder::ValidatePartitionGroups() const {
1261     for (const auto& group : groups_) {
1262         if (!group->maximum_size()) {
1263             continue;
1264         }
1265         uint64_t used = TotalSizeOfGroup(group.get());
1266         if (used > group->maximum_size()) {
1267             LERROR << "Partition group " << group->name() << " exceeds maximum size (" << used
1268                    << " bytes used, maximum " << group->maximum_size() << ")";
1269             return false;
1270         }
1271     }
1272     return true;
1273 }
1274 
ChangeGroupSize(const std::string & group_name,uint64_t maximum_size)1275 bool MetadataBuilder::ChangeGroupSize(const std::string& group_name, uint64_t maximum_size) {
1276     if (group_name == kDefaultGroup) {
1277         LERROR << "Cannot change the size of the default group";
1278         return false;
1279     }
1280     PartitionGroup* group = FindGroup(group_name);
1281     if (!group) {
1282         LERROR << "Cannot change size of unknown partition group: " << group_name;
1283         return false;
1284     }
1285     group->set_maximum_size(maximum_size);
1286     return true;
1287 }
1288 
GetBlockDevicePartitionName(uint64_t index) const1289 std::string MetadataBuilder::GetBlockDevicePartitionName(uint64_t index) const {
1290     return index < block_devices_.size()
1291                    ? android::fs_mgr::GetBlockDevicePartitionName(block_devices_[index])
1292                    : "";
1293 }
1294 
logical_block_size() const1295 uint64_t MetadataBuilder::logical_block_size() const {
1296     return geometry_.logical_block_size;
1297 }
1298 
VerifyExtentsAgainstSourceMetadata(const MetadataBuilder & source_metadata,uint32_t source_slot_number,const MetadataBuilder & target_metadata,uint32_t target_slot_number,const std::vector<std::string> & partitions)1299 bool MetadataBuilder::VerifyExtentsAgainstSourceMetadata(
1300         const MetadataBuilder& source_metadata, uint32_t source_slot_number,
1301         const MetadataBuilder& target_metadata, uint32_t target_slot_number,
1302         const std::vector<std::string>& partitions) {
1303     for (const auto& base_name : partitions) {
1304         // Find the partition in metadata with the slot suffix.
1305         auto target_partition_name = base_name + SlotSuffixForSlotNumber(target_slot_number);
1306         const auto target_partition = target_metadata.FindPartition(target_partition_name);
1307         if (!target_partition) {
1308             LERROR << "Failed to find partition " << target_partition_name << " in metadata slot "
1309                    << target_slot_number;
1310             return false;
1311         }
1312 
1313         auto source_partition_name = base_name + SlotSuffixForSlotNumber(source_slot_number);
1314         const auto source_partition = source_metadata.FindPartition(source_partition_name);
1315         if (!source_partition) {
1316             LERROR << "Failed to find partition " << source_partition << " in metadata slot "
1317                    << source_slot_number;
1318             return false;
1319         }
1320 
1321         // We expect the partitions in the target metadata to have the identical extents as the
1322         // one in the source metadata. Because they are copied in NewForUpdate.
1323         if (target_partition->extents().size() != source_partition->extents().size()) {
1324             LERROR << "Extents count mismatch for partition " << base_name << " target slot has "
1325                    << target_partition->extents().size() << ", source slot has "
1326                    << source_partition->extents().size();
1327             return false;
1328         }
1329 
1330         for (size_t i = 0; i < target_partition->extents().size(); i++) {
1331             const auto& src_extent = *source_partition->extents()[i];
1332             const auto& tgt_extent = *target_partition->extents()[i];
1333             if (tgt_extent != src_extent) {
1334                 LERROR << "Extents " << i << " is different for partition " << base_name;
1335                 LERROR << "tgt extent " << tgt_extent << "; src extent " << src_extent;
1336                 return false;
1337             }
1338         }
1339     }
1340 
1341     return true;
1342 }
1343 
1344 }  // namespace fs_mgr
1345 }  // namespace android
1346