/** \file ddm_userland_interface.cpp * * \brief Interface for userspace calls. */ #include #include #include #include #include #include #include #include #include #include "UserDataWriter.h" using namespace BPrivate::DiskDevice; // debugging #define ERROR(x) // TODO: Add user address checks and check return values of user_memcpy()! // ddm_strlcpy /*! \brief Wrapper around user_strlcpy() that returns a status_t indicating appropriate success or failure. \param allowTruncation If \c true, does not return an error if \a from is longer than \to. If \c false, returns \c B_NAME_TOO_LONG if \a from is longer than \to. */ static status_t ddm_strlcpy(char *to, const char *from, size_t size, bool allowTruncation = false) { ssize_t fromLen = user_strlcpy(to, from, size); if (fromLen < 0) return fromLen; if ((size_t)fromLen >= size && !allowTruncation) return B_NAME_TOO_LONG; return B_OK; } #if 0 // move_descendants static void move_descendants(KPartition *partition, off_t moveBy) { if (!partition) return; partition->SetOffset(partition->Offset() + moveBy); // move children for (int32 i = 0; KPartition *child = partition->ChildAt(i); i++) move_descendants(child, moveBy); } // move_descendants_contents static status_t move_descendants_contents(KPartition *partition) { if (!partition) return B_BAD_VALUE; // implicit content disk system changes KDiskSystem *diskSystem = partition->DiskSystem(); if (diskSystem || partition->AlgorithmData()) { status_t error = diskSystem->ShadowPartitionChanged(partition, NULL, B_PARTITION_MOVE); if (error != B_OK) return error; } // move children's contents for (int32 i = 0; KPartition *child = partition->ChildAt(i); i++) { status_t error = move_descendants_contents(child); if (error != B_OK) return error; } return B_OK; } #endif // 0 // _user_get_next_disk_device_id partition_id _user_get_next_disk_device_id(int32 *_cookie, size_t *neededSize) { if (!_cookie) return B_BAD_VALUE; int32 cookie; user_memcpy(&cookie, _cookie, sizeof(cookie)); partition_id id = B_ENTRY_NOT_FOUND; KDiskDeviceManager *manager = KDiskDeviceManager::Default(); // get the next device if (KDiskDevice *device = manager->RegisterNextDevice(&cookie)) { PartitionRegistrar _(device, true); id = device->ID(); if (neededSize) { if (DeviceReadLocker locker = device) { // get the needed size UserDataWriter writer; device->WriteUserData(writer); *neededSize = writer.AllocatedSize(); } else { id = B_ERROR; } } } user_memcpy(_cookie, &cookie, sizeof(cookie)); return id; } // _user_find_disk_device partition_id _user_find_disk_device(const char *_filename, size_t *neededSize) { if (!_filename) return B_BAD_VALUE; char filename[B_PATH_NAME_LENGTH]; status_t error = ddm_strlcpy(filename, _filename, B_PATH_NAME_LENGTH); if (error) return error; partition_id id = B_ENTRY_NOT_FOUND; KDiskDeviceManager *manager = KDiskDeviceManager::Default(); // find the device if (KDiskDevice *device = manager->RegisterDevice(filename)) { PartitionRegistrar _(device, true); id = device->ID(); if (neededSize) { if (DeviceReadLocker locker = device) { // get the needed size UserDataWriter writer; device->WriteUserData(writer); *neededSize = writer.AllocatedSize(); } else return B_ERROR; } } return id; } // _user_find_partition partition_id _user_find_partition(const char *_filename, size_t *neededSize) { if (!_filename) return B_BAD_VALUE; char filename[B_PATH_NAME_LENGTH]; status_t error = ddm_strlcpy(filename, _filename, B_PATH_NAME_LENGTH); if (error) return error; partition_id id = B_ENTRY_NOT_FOUND; KDiskDeviceManager *manager = KDiskDeviceManager::Default(); // find the partition if (KPartition *partition = manager->RegisterPartition(filename)) { PartitionRegistrar _(partition, true); id = partition->ID(); if (neededSize) { // get and lock the partition's device KDiskDevice *device = manager->RegisterDevice(partition->ID()); if (!device) return B_ENTRY_NOT_FOUND; PartitionRegistrar _2(device, true); if (DeviceReadLocker locker = device) { // get the needed size UserDataWriter writer; device->WriteUserData(writer); *neededSize = writer.AllocatedSize(); } else return B_ERROR; } } return id; } // _user_get_disk_device_data /*! \brief Writes data describing the disk device identified by ID and all its partitions into the supplied buffer. The function passes the buffer size required to hold the data back through the \a _neededSize parameter, if the device could be found at least and no serious error occured. If fails with \c B_BUFFER_OVERFLOW, if the supplied buffer is too small or a \c NULL buffer is supplied (and \c bufferSize is 0). The device is identified by \a id. If \a deviceOnly is \c true, then it must be the ID of a disk device, otherwise the disk device is chosen, on which the partition \a id refers to resides. \param id The ID of an arbitrary partition on the disk device (including the disk device itself), whose data shall be returned (if \a deviceOnly is \c false), or the ID of the disk device itself (if \a deviceOnly is true). \param deviceOnly Specifies whether only IDs of disk devices (\c true), or also IDs of partitions (\c false) are accepted for \a id. \param buffer The buffer into which the disk device data shall be written. May be \c NULL. \param bufferSize The size of \a buffer. \param _neededSize Pointer to a variable into which the actually needed buffer size is written. May be \c NULL. \return - \c B_OK: Everything went fine. The device was found and, if not \c NULL, in \a _neededSize the actually needed buffer size is returned. And \a buffer will contain the disk device data. - \c B_BAD_VALUE: \c NULL \a buffer, but not 0 \a bufferSize. - \c B_BUFFER_OVERFLOW: The supplied buffer was too small. \a _neededSize, if not \c NULL, will contain the required buffer size. - \c B_NO_MEMORY: Insufficient memory to complete the operation. - \c B_ENTRY_NOT_FOUND: \a id is no valid disk device ID (if \a deviceOnly is \c true) or not even a valid partition ID (if \a deviceOnly is \c false). - \c B_ERROR: An unexpected error occured. - another error code... */ status_t _user_get_disk_device_data(partition_id id, bool deviceOnly, user_disk_device_data *buffer, size_t bufferSize, size_t *_neededSize) { if (!buffer && bufferSize > 0) return B_BAD_VALUE; KDiskDeviceManager *manager = KDiskDeviceManager::Default(); // get the device if (KDiskDevice *device = manager->RegisterDevice(id, deviceOnly)) { PartitionRegistrar _(device, true); if (DeviceReadLocker locker = device) { // do a dry run first to get the needed size UserDataWriter writer; device->WriteUserData(writer); size_t neededSize = writer.AllocatedSize(); if (_neededSize) { status_t error = copy_ref_var_to_user(neededSize, _neededSize); if (error != B_OK) return error; } // if no buffer has been supplied or the buffer is too small, // then we're done if (!buffer || bufferSize < neededSize) return B_BUFFER_OVERFLOW; // otherwise allocate a kernel buffer user_disk_device_data *kernelBuffer = static_cast(malloc(neededSize)); if (!kernelBuffer) return B_NO_MEMORY; MemoryDeleter deleter(kernelBuffer); // write the device data into the buffer writer.SetTo(kernelBuffer, bufferSize); device->WriteUserData(writer); // sanity check if (writer.AllocatedSize() != neededSize) { ERROR(("Size of written disk device user data changed from " "%lu to %lu while device was locked!\n")); return B_ERROR; } // relocate status_t error = writer.Relocate(buffer); if (error != B_OK) return error; // copy out if (buffer) return user_memcpy(buffer, kernelBuffer, neededSize); } else return B_ERROR; } return B_ENTRY_NOT_FOUND; } // _user_register_file_device partition_id _user_register_file_device(const char *_filename) { if (!_filename) return B_BAD_VALUE; char filename[B_PATH_NAME_LENGTH]; status_t error = ddm_strlcpy(filename, _filename, B_PATH_NAME_LENGTH); if (error) return error; KDiskDeviceManager *manager = KDiskDeviceManager::Default(); if (ManagerLocker locker = manager) { if (KFileDiskDevice *device = manager->FindFileDevice(filename)) return device->ID(); return manager->CreateFileDevice(filename); } return B_ERROR; } // _user_unregister_file_device status_t _user_unregister_file_device(partition_id deviceID, const char *_filename) { if (deviceID < 0 && !_filename) return B_BAD_VALUE; KDiskDeviceManager *manager = KDiskDeviceManager::Default(); if (deviceID >= 0) { return manager->DeleteFileDevice(deviceID); } else { char filename[B_PATH_NAME_LENGTH]; status_t error = ddm_strlcpy(filename, _filename, B_PATH_NAME_LENGTH); if (error) return error; return manager->DeleteFileDevice(filename); } } // _user_get_disk_system_info status_t _user_get_disk_system_info(disk_system_id id, user_disk_system_info *_info) { if (!_info) return B_BAD_VALUE; KDiskDeviceManager *manager = KDiskDeviceManager::Default(); if (ManagerLocker locker = manager) { if (KDiskSystem *diskSystem = manager->FindDiskSystem(id)) { user_disk_system_info info; diskSystem->GetInfo(&info); user_memcpy(_info, &info, sizeof(info)); return B_OK; } } return B_ENTRY_NOT_FOUND; } // _user_get_next_disk_system_info status_t _user_get_next_disk_system_info(int32 *_cookie, user_disk_system_info *_info) { if (!_cookie || !_info) return B_BAD_VALUE; int32 cookie; user_memcpy(&cookie, _cookie, sizeof(cookie)); status_t result = B_ENTRY_NOT_FOUND; KDiskDeviceManager *manager = KDiskDeviceManager::Default(); if (ManagerLocker locker = manager) { if (KDiskSystem *diskSystem = manager->NextDiskSystem(&cookie)) { user_disk_system_info info; diskSystem->GetInfo(&info); user_memcpy(_info, &info, sizeof(info)); result = B_OK; } } user_memcpy(_cookie, &cookie, sizeof(cookie)); return result; } // _user_find_disk_system status_t _user_find_disk_system(const char *_name, user_disk_system_info *_info) { if (!_name || !_info) return B_BAD_VALUE; char name[B_DISK_SYSTEM_NAME_LENGTH]; status_t error = ddm_strlcpy(name, _name, B_DISK_SYSTEM_NAME_LENGTH); if (error) return error; KDiskDeviceManager *manager = KDiskDeviceManager::Default(); if (ManagerLocker locker = manager) { if (KDiskSystem *diskSystem = manager->FindDiskSystem(name)) { user_disk_system_info info; diskSystem->GetInfo(&info); user_memcpy(_info, &info, sizeof(info)); return B_OK; } } return B_ENTRY_NOT_FOUND; } // _user_defragment_partition status_t _user_defragment_partition(partition_id partitionID, int32* changeCounter) { #if 0 KDiskDeviceManager *manager = KDiskDeviceManager::Default(); // get the partition KPartition *partition = manager->WriteLockPartition(partitionID); if (!partition) return B_ENTRY_NOT_FOUND; PartitionRegistrar registrar1(partition, true); PartitionRegistrar registrar2(partition->Device(), true); DeviceWriteLocker locker(partition->Device(), true); // check whether the disk system supports defragmenting status_t error = validate_defragment_partition(partition, changeCounter); if (error != B_OK) return error; // set the defragmenting flag partition->Changed(B_PARTITION_CHANGED_DEFRAGMENTATION); return B_OK; #endif return B_BAD_VALUE; } // _user_repair_partition status_t _user_repair_partition(partition_id partitionID, int32* changeCounter, bool checkOnly) { #if 0 KDiskDeviceManager *manager = KDiskDeviceManager::Default(); // get the partition KPartition *partition = manager->WriteLockPartition(partitionID); if (!partition) return B_ENTRY_NOT_FOUND; PartitionRegistrar registrar1(partition, true); PartitionRegistrar registrar2(partition->Device(), true); DeviceWriteLocker locker(partition->Device(), true); // check whether the disk system supports defragmenting status_t error = validate_repair_partition(partition, changeCounter, checkOnly); if (error != B_OK) return error; // set the respective flag if (checkOnly) partition->Changed(B_PARTITION_CHANGED_CHECK); else partition->Changed(B_PARTITION_CHANGED_REPAIR); return B_OK; #endif return B_BAD_VALUE; } // _user_resize_partition status_t _user_resize_partition(partition_id partitionID, int32* changeCounter, partition_id childID, int32* childChangeCounter, off_t size, off_t contentSize) { #if 0 KDiskDeviceManager *manager = KDiskDeviceManager::Default(); // get the partition KPartition *partition = manager->WriteLockPartition(partitionID); if (!partition) return B_ENTRY_NOT_FOUND; PartitionRegistrar registrar1(partition, true); PartitionRegistrar registrar2(partition->Device(), true); DeviceWriteLocker locker(partition->Device(), true); // check the size if (size == partition->Size()) return B_OK; off_t proposedSize = size; off_t contentSize = 0; status_t error = validate_resize_partition(partition, changeCounter, &proposedSize, &contentSize); if (error != B_OK) return error; if (proposedSize != size) return B_BAD_VALUE; // new size is fine -- resize the thing partition->SetSize(size); partition->Changed(B_PARTITION_CHANGED_SIZE); // implicit partitioning system changes error = partition->Parent()->DiskSystem()->ShadowPartitionChanged( partition->Parent(), partition, B_PARTITION_RESIZE_CHILD); if (error != B_OK) return error; // implicit content disk system changes if (partition->DiskSystem()) { error = partition->DiskSystem()->ShadowPartitionChanged( partition, NULL, B_PARTITION_RESIZE); } return error; #endif return B_BAD_VALUE; } // _user_move_partition status_t _user_move_partition(partition_id partitionID, int32* changeCounter, partition_id childID, int32* childChangeCounter, off_t newOffset, partition_id* descendantIDs, int32* descendantChangeCounters, int32 descendantCount) { #if 0 KDiskDeviceManager *manager = KDiskDeviceManager::Default(); // get the partition KPartition *partition = manager->WriteLockPartition(partitionID); if (!partition) return B_ENTRY_NOT_FOUND; PartitionRegistrar registrar1(partition, true); PartitionRegistrar registrar2(partition->Device(), true); DeviceWriteLocker locker(partition->Device(), true); // check the new offset if (newOffset == partition->Offset()) return B_OK; off_t proposedOffset = newOffset; status_t error = validate_move_partition(partition, changeCounter, &proposedOffset, true); if (error != B_OK) return error; if (proposedOffset != newOffset) return B_BAD_VALUE; // new offset is fine -- move the thing off_t moveBy = newOffset - partition->Offset(); move_descendants(partition, moveBy); partition->Changed(B_PARTITION_CHANGED_OFFSET); // implicit partitioning system changes error = partition->Parent()->DiskSystem()->ShadowPartitionChanged( partition->Parent(), partition, B_PARTITION_MOVE_CHILD); if (error != B_OK) return error; // implicit descendants' content disk system changes return move_descendants_contents(partition); #endif return B_BAD_VALUE; } // _user_set_partition_name status_t _user_set_partition_name(partition_id partitionID, int32* changeCounter, partition_id childID, int32* childChangeCounter, const char* name) { #if 0 if (!_name) return B_BAD_VALUE; char name[B_DISK_DEVICE_NAME_LENGTH]; status_t error = ddm_strlcpy(name, _name, B_DISK_DEVICE_NAME_LENGTH); if (error) return error; KDiskDeviceManager *manager = KDiskDeviceManager::Default(); // get the partition KPartition *partition = manager->WriteLockPartition(partitionID); if (!partition) return B_ENTRY_NOT_FOUND; PartitionRegistrar registrar1(partition, true); PartitionRegistrar registrar2(partition->Device(), true); DeviceWriteLocker locker(partition->Device(), true); // check name char proposedName[B_DISK_DEVICE_NAME_LENGTH]; strcpy(proposedName, name); error = validate_set_partition_name(partition, changeCounter, proposedName); if (error != B_OK) return error; if (strcmp(name, proposedName)) return B_BAD_VALUE; // set name error = partition->SetName(name); if (error != B_OK) return error; partition->Changed(B_PARTITION_CHANGED_NAME); // implicit partitioning system changes return partition->Parent()->DiskSystem()->ShadowPartitionChanged( partition->Parent(), partition, B_PARTITION_SET_NAME); #endif return B_BAD_VALUE; } // _user_set_partition_content_name status_t _user_set_partition_content_name(partition_id partitionID, int32* changeCounter, const char* name) { #if 0 if (!_name) return B_BAD_VALUE; char name[B_DISK_DEVICE_NAME_LENGTH]; status_t error = ddm_strlcpy(name, _name, B_DISK_DEVICE_NAME_LENGTH); if (error) return error; KDiskDeviceManager *manager = KDiskDeviceManager::Default(); // get the partition KPartition *partition = manager->WriteLockPartition(partitionID); if (!partition) return B_ENTRY_NOT_FOUND; PartitionRegistrar registrar1(partition, true); PartitionRegistrar registrar2(partition->Device(), true); DeviceWriteLocker locker(partition->Device(), true); // check name char proposedName[B_DISK_DEVICE_NAME_LENGTH]; strcpy(proposedName, name); error = validate_set_partition_content_name(partition, changeCounter, proposedName); if (error != B_OK) return error; if (strcmp(name, proposedName)) return B_BAD_VALUE; // set name error = partition->SetContentName(name); if (error != B_OK) return error; partition->Changed(B_PARTITION_CHANGED_CONTENT_NAME); // implicit content disk system changes return partition->DiskSystem()->ShadowPartitionChanged( partition, NULL, B_PARTITION_SET_CONTENT_NAME); #endif return B_BAD_VALUE; } // _user_set_partition_type status_t _user_set_partition_type(partition_id partitionID, int32* changeCounter, partition_id childID, int32* childChangeCounter, const char* type) { #if 0 if (!_type) return B_BAD_VALUE; char type[B_DISK_DEVICE_TYPE_LENGTH]; status_t error = ddm_strlcpy(type, _type, B_DISK_DEVICE_TYPE_LENGTH); if (error) return error; KDiskDeviceManager *manager = KDiskDeviceManager::Default(); // get the partition KPartition *partition = manager->WriteLockPartition(partitionID); if (!partition) return B_ENTRY_NOT_FOUND; PartitionRegistrar registrar1(partition, true); PartitionRegistrar registrar2(partition->Device(), true); DeviceWriteLocker locker(partition->Device(), true); // check type error = validate_set_partition_type(partition, changeCounter, type); if (error != B_OK) return error; // set type error = partition->SetType(type); if (error != B_OK) return error; partition->Changed(B_PARTITION_CHANGED_TYPE); // implicit partitioning system changes return partition->Parent()->DiskSystem()->ShadowPartitionChanged( partition->Parent(), partition, B_PARTITION_SET_TYPE); #endif return B_BAD_VALUE; } // _user_set_partition_parameters status_t _user_set_partition_parameters(partition_id partitionID, int32* changeCounter, partition_id childID, int32* childChangeCounter, const char* parameters, size_t parametersSize) { #if 0 if (!_parameters || parametersSize > B_DISK_DEVICE_MAX_PARAMETER_SIZE) return B_BAD_VALUE; char *parameters = NULL; if (_parameters) { parameters = static_cast(malloc(parametersSize)); if (parameters) user_memcpy(parameters, _parameters, parametersSize); else return B_NO_MEMORY; } KDiskDeviceManager *manager = KDiskDeviceManager::Default(); // get the partition KPartition *partition = manager->WriteLockPartition(partitionID); status_t error = partition ? (status_t)B_OK : (status_t)B_ENTRY_NOT_FOUND; if (!error) { PartitionRegistrar registrar1(partition, true); PartitionRegistrar registrar2(partition->Device(), true); DeviceWriteLocker locker(partition->Device(), true); // check parameters error = validate_set_partition_parameters(partition, changeCounter, parameters); if (!error) { // set type error = partition->SetParameters(parameters); if (!error) { partition->Changed(B_PARTITION_CHANGED_PARAMETERS); // implicit partitioning system changes error = partition->Parent()->DiskSystem() ->ShadowPartitionChanged(partition->Parent(), partition, B_PARTITION_SET_PARAMETERS); } } } free(parameters); return error; #endif return B_BAD_VALUE; } // _user_set_partition_content_parameters status_t _user_set_partition_content_parameters(partition_id partitionID, int32* changeCounter, const char* parameters, size_t parametersSize) { #if 0 if (!_parameters || parametersSize > B_DISK_DEVICE_MAX_PARAMETER_SIZE) return B_BAD_VALUE; char *parameters = NULL; if (_parameters) { parameters = static_cast(malloc(parametersSize)); if (parameters) user_memcpy(parameters, _parameters, parametersSize); else return B_NO_MEMORY; } KDiskDeviceManager *manager = KDiskDeviceManager::Default(); // get the partition KPartition *partition = manager->WriteLockPartition(partitionID); status_t error = partition ? (status_t)B_OK : (status_t)B_ENTRY_NOT_FOUND; if (!error) { PartitionRegistrar registrar1(partition, true); PartitionRegistrar registrar2(partition->Device(), true); DeviceWriteLocker locker(partition->Device(), true); // check parameters error = validate_set_partition_content_parameters(partition, changeCounter, parameters); if (!error) { // set name error = partition->SetContentParameters(parameters); if (!error) { partition->Changed(B_PARTITION_CHANGED_CONTENT_PARAMETERS); // implicit content disk system changes error = partition->DiskSystem()->ShadowPartitionChanged( partition, NULL, B_PARTITION_SET_CONTENT_PARAMETERS); } } } free(partition); return error; #endif return B_BAD_VALUE; } // _user_initialize_partition status_t _user_initialize_partition(partition_id partitionID, int32* changeCounter, const char* diskSystemName, const char* name, const char* parameters, size_t parametersSize) { #if 0 if (!_diskSystemName || parametersSize > B_DISK_DEVICE_MAX_PARAMETER_SIZE) return B_BAD_VALUE; // copy disk system name char diskSystemName[B_DISK_SYSTEM_NAME_LENGTH]; status_t error = ddm_strlcpy(diskSystemName, _diskSystemName, B_DISK_SYSTEM_NAME_LENGTH); // copy name char name[B_DISK_DEVICE_NAME_LENGTH]; if (!error && _name) error = ddm_strlcpy(name, _name, B_DISK_DEVICE_NAME_LENGTH); if (error) return error; // copy parameters MemoryDeleter parameterDeleter; char *parameters = NULL; if (_parameters) { parameters = static_cast(malloc(parametersSize)); if (!parameters) return B_NO_MEMORY; parameterDeleter.SetTo(parameters); if (user_memcpy(parameters, _parameters, parametersSize) != B_OK) return B_BAD_ADDRESS; } // get the partition KDiskDeviceManager *manager = KDiskDeviceManager::Default(); KPartition *partition = manager->WriteLockPartition(partitionID); if (!partition) return B_ENTRY_NOT_FOUND; PartitionRegistrar registrar1(partition, true); PartitionRegistrar registrar2(partition->Device(), true); DeviceWriteLocker locker(partition->Device(), true); // get the disk system KDiskSystem *diskSystem = manager->LoadDiskSystem(diskSystemName); if (!diskSystem) return B_ENTRY_NOT_FOUND; DiskSystemLoader loader(diskSystem, true); // check parameters char proposedName[B_DISK_DEVICE_NAME_LENGTH]; if (_name) strcpy(proposedName, name); error = validate_initialize_partition(partition, changeCounter, diskSystemName, _name ? proposedName : NULL, parameters); if (error != B_OK) return error; if (_name && strcmp(name, proposedName) != 0) return B_BAD_VALUE; // unitialize the partition's contents and set the new // parameters if ((error = partition->UninitializeContents(true)) != B_OK) return error; partition->SetDiskSystem(diskSystem); if ((error = partition->SetContentName(_name ? name : NULL)) != B_OK) return error; partition->Changed(B_PARTITION_CHANGED_CONTENT_NAME); if ((error = partition->SetContentParameters(parameters)) != B_OK) return error; partition->Changed(B_PARTITION_CHANGED_CONTENT_PARAMETERS); partition->Changed(B_PARTITION_CHANGED_INITIALIZATION); // implicit content disk system changes return partition->DiskSystem()->ShadowPartitionChanged( partition, NULL, B_PARTITION_INITIALIZE); #endif return B_BAD_VALUE; } // _user_uninitialize_partition status_t _user_uninitialize_partition(partition_id partitionID, int32* changeCounter) { #if 0 KDiskDeviceManager *manager = KDiskDeviceManager::Default(); // get the partition KPartition *partition = manager->WriteLockPartition(partitionID); if (!partition) return B_ENTRY_NOT_FOUND; PartitionRegistrar registrar1(partition, true); PartitionRegistrar registrar2(partition->Device(), true); DeviceWriteLocker locker(partition->Device(), true); // unitialize the partition's contents and set the new parameters return partition->UninitializeContents(true); #endif return B_BAD_VALUE; } // _user_create_child_partition status_t _user_create_child_partition(partition_id partitionID, int32* changeCounter, off_t offset, off_t size, const char* type, const char* name, const char* parameters, size_t parametersSize, partition_id* childID, int32* childChangeCounter) { #if 0 if (!_type || parametersSize > B_DISK_DEVICE_MAX_PARAMETER_SIZE) return B_BAD_VALUE; char type[B_DISK_DEVICE_TYPE_LENGTH]; char *parameters = NULL; status_t error = ddm_strlcpy(type, _type, B_DISK_DEVICE_TYPE_LENGTH); if (error) return error; if (_parameters) { parameters = static_cast(malloc(parametersSize)); if (parameters) user_memcpy(parameters, _parameters, parametersSize); else return B_NO_MEMORY; } KDiskDeviceManager *manager = KDiskDeviceManager::Default(); // get the partition KPartition *partition = manager->WriteLockPartition(partitionID); error = partition ? (status_t)B_OK : (status_t)B_ENTRY_NOT_FOUND; if (!error) { PartitionRegistrar registrar1(partition, true); PartitionRegistrar registrar2(partition->Device(), true); DeviceWriteLocker locker(partition->Device(), true); // check the parameters off_t proposedOffset = offset; off_t proposedSize = size; int32 index = 0; error = validate_create_child_partition(partition, changeCounter, &proposedOffset, &proposedSize, type, parameters, &index); if (!error) { error = (proposedOffset == offset && proposedSize == size) ? B_OK : B_BAD_VALUE; if (!error) { // create the child KPartition *child = NULL; error = partition->CreateChild(-1, index, &child); if (!error) { partition->Changed(B_PARTITION_CHANGED_CHILDREN); if (_childID) { partition_id childID = child->ID(); user_memcpy(_childID, &childID, sizeof(childID)); } // set the parameters child->SetOffset(offset); child->SetSize(size); error = child->SetType(type); } if (!error) { error = child->SetParameters(parameters); } if (!error) { // implicit partitioning system changes error = partition->DiskSystem()->ShadowPartitionChanged( partition, child, B_PARTITION_CREATE_CHILD); } } } } free(parameters); return error; #endif return B_BAD_VALUE; } // _user_delete_child_partition status_t _user_delete_child_partition(partition_id partitionID, int32* changeCounter, partition_id childID, int32 childChangeCounter) { #if 0 KDiskDeviceManager *manager = KDiskDeviceManager::Default(); // get the partition KPartition *partition = manager->WriteLockPartition(partitionID); if (!partition) return B_ENTRY_NOT_FOUND; PartitionRegistrar registrar1(partition, true); PartitionRegistrar registrar2(partition->Device(), true); DeviceWriteLocker locker(partition->Device(), true); // check whether delete the child is OK status_t error = validate_delete_child_partition(partition, changeCounter); if (error != B_OK) return error; // delete the child KPartition *parent = partition->Parent(); if (!parent->RemoveChild(partition)) return B_ERROR; parent->Changed(B_PARTITION_CHANGED_CHILDREN); return B_OK; #endif return B_BAD_VALUE; }