// Copyright (C) 2019 Nicola Murino // // This program is free software: you can redistribute it and/or modify // it under the terms of the GNU Affero General Public License as published // by the Free Software Foundation, version 3. // // This program is distributed in the hope that it will be useful, // but WITHOUT ANY WARRANTY; without even the implied warranty of // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the // GNU Affero General Public License for more details. // // You should have received a copy of the GNU Affero General Public License // along with this program. If not, see . // Package vfs provides local and remote filesystems support package vfs import ( "errors" "fmt" "io" "net/url" "os" "path" "path/filepath" "runtime" "slices" "strconv" "strings" "sync" "time" "github.com/eikenb/pipeat" "github.com/pkg/sftp" "github.com/sftpgo/sdk" "github.com/drakkan/sftpgo/v2/internal/kms" "github.com/drakkan/sftpgo/v2/internal/logger" "github.com/drakkan/sftpgo/v2/internal/util" ) const ( dirMimeType = "inode/directory" s3fsName = "S3Fs" gcsfsName = "GCSFs" azBlobFsName = "AzureBlobFs" lastModifiedField = "sftpgo_last_modified" preResumeTimeout = 90 * time.Second // ListerBatchSize defines the default limit for DirLister implementations ListerBatchSize = 1000 ) // Additional checks for files const ( CheckParentDir = 1 CheckResume = 2 CheckUpdateModTime = 4 ) var ( validAzAccessTier = []string{"", "Archive", "Hot", "Cool"} // ErrStorageSizeUnavailable is returned if the storage backend does not support getting the size ErrStorageSizeUnavailable = errors.New("unable to get available size for this storage backend") // ErrVfsUnsupported defines the error for an unsupported VFS operation ErrVfsUnsupported = errors.New("not supported") errInvalidDirListerLimit = errors.New("dir lister: invalid limit, must be > 0") tempPath string sftpFingerprints []string allowSelfConnections int renameMode int readMetadata int resumeMaxSize int64 uploadMode int ) var ( createPipeFn = func(dirPath string, _ int64) (pipeReaderAt, pipeWriterAt, error) { return pipeat.PipeInDir(dirPath) } ) // SetAllowSelfConnections sets the desired behaviour for self connections func SetAllowSelfConnections(value int) { allowSelfConnections = value } // SetTempPath sets the path for temporary files func SetTempPath(fsPath string) { tempPath = fsPath } // GetTempPath returns the path for temporary files func GetTempPath() string { return tempPath } // SetSFTPFingerprints sets the SFTP host key fingerprints func SetSFTPFingerprints(fp []string) { sftpFingerprints = fp } // SetRenameMode sets the rename mode func SetRenameMode(val int) { renameMode = val } // SetReadMetadataMode sets the read metadata mode func SetReadMetadataMode(val int) { readMetadata = val } // SetResumeMaxSize sets the max size allowed for resuming uploads for backends // with immutable objects func SetResumeMaxSize(val int64) { resumeMaxSize = val } // SetUploadMode sets the upload mode func SetUploadMode(val int) { uploadMode = val } // Fs defines the interface for filesystem backends type Fs interface { Name() string ConnectionID() string Stat(name string) (os.FileInfo, error) Lstat(name string) (os.FileInfo, error) Open(name string, offset int64) (File, PipeReader, func(), error) Create(name string, flag, checks int) (File, PipeWriter, func(), error) Rename(source, target string, checks int) (int, int64, error) Remove(name string, isDir bool) error Mkdir(name string) error Symlink(source, target string) error Chown(name string, uid int, gid int) error Chmod(name string, mode os.FileMode) error Chtimes(name string, atime, mtime time.Time, isUploading bool) error Truncate(name string, size int64) error ReadDir(dirname string) (DirLister, error) Readlink(name string) (string, error) IsUploadResumeSupported() bool IsConditionalUploadResumeSupported(size int64) bool IsAtomicUploadSupported() bool CheckRootPath(username string, uid int, gid int) bool ResolvePath(virtualPath string) (string, error) IsNotExist(err error) bool IsPermission(err error) bool IsNotSupported(err error) bool ScanRootDirContents() (int, int64, error) GetDirSize(dirname string) (int, int64, error) GetAtomicUploadPath(name string) string GetRelativePath(name string) string Walk(root string, walkFn filepath.WalkFunc) error Join(elem ...string) string HasVirtualFolders() bool GetMimeType(name string) (string, error) GetAvailableDiskSize(dirName string) (*sftp.StatVFS, error) Close() error } // FsRealPather is a Fs that implements the RealPath method. type FsRealPather interface { Fs RealPath(p string) (string, error) } // FsFileCopier is a Fs that implements the CopyFile method. type FsFileCopier interface { Fs CopyFile(source, target string, srcInfo os.FileInfo) (int, int64, error) } // File defines an interface representing a SFTPGo file type File interface { io.Reader io.Writer io.Closer io.ReaderAt io.WriterAt io.Seeker Stat() (os.FileInfo, error) Name() string Truncate(size int64) error } // PipeWriter defines an interface representing a SFTPGo pipe writer type PipeWriter interface { io.Writer io.WriterAt io.Closer Done(err error) GetWrittenBytes() int64 } // PipeReader defines an interface representing a SFTPGo pipe reader type PipeReader interface { io.Reader io.ReaderAt io.Closer setMetadata(value map[string]string) setMetadataFromPointerVal(value map[string]*string) Metadata() map[string]string } type pipeReaderAt interface { Read(p []byte) (int, error) ReadAt(p []byte, offset int64) (int, error) GetReadedBytes() int64 Close() error CloseWithError(err error) error } type pipeWriterAt interface { Write(p []byte) (int, error) WriteAt(p []byte, offset int64) (int, error) GetWrittenBytes() int64 Close() error CloseWithError(err error) error } // DirLister defines an interface for a directory lister type DirLister interface { Next(limit int) ([]os.FileInfo, error) Close() error } // Metadater defines an interface to implement to return metadata for a file type Metadater interface { Metadata() map[string]string } type baseDirLister struct { cache []os.FileInfo } func (l *baseDirLister) Next(limit int) ([]os.FileInfo, error) { if limit <= 0 { return nil, errInvalidDirListerLimit } if len(l.cache) >= limit { return l.returnFromCache(limit), nil } return l.returnFromCache(limit), io.EOF } func (l *baseDirLister) returnFromCache(limit int) []os.FileInfo { if len(l.cache) >= limit { result := l.cache[:limit] l.cache = l.cache[limit:] return result } result := l.cache l.cache = nil return result } func (l *baseDirLister) Close() error { l.cache = nil return nil } // QuotaCheckResult defines the result for a quota check type QuotaCheckResult struct { HasSpace bool AllowedSize int64 AllowedFiles int UsedSize int64 UsedFiles int QuotaSize int64 QuotaFiles int } // GetRemainingSize returns the remaining allowed size func (q *QuotaCheckResult) GetRemainingSize() int64 { if q.QuotaSize > 0 { return q.QuotaSize - q.UsedSize } return 0 } // GetRemainingFiles returns the remaining allowed files func (q *QuotaCheckResult) GetRemainingFiles() int { if q.QuotaFiles > 0 { return q.QuotaFiles - q.UsedFiles } return 0 } // S3FsConfig defines the configuration for S3 based filesystem type S3FsConfig struct { sdk.BaseS3FsConfig AccessSecret *kms.Secret `json:"access_secret,omitempty"` SSECustomerKey *kms.Secret `json:"sse_customer_key,omitempty"` } // HideConfidentialData hides confidential data func (c *S3FsConfig) HideConfidentialData() { if c.AccessSecret != nil { c.AccessSecret.Hide() } if c.SSECustomerKey != nil { c.SSECustomerKey.Hide() } } func (c *S3FsConfig) isEqual(other S3FsConfig) bool { if c.Bucket != other.Bucket { return false } if c.KeyPrefix != other.KeyPrefix { return false } if c.Region != other.Region { return false } if c.AccessKey != other.AccessKey { return false } if c.RoleARN != other.RoleARN { return false } if c.Endpoint != other.Endpoint { return false } if c.StorageClass != other.StorageClass { return false } if c.ACL != other.ACL { return false } if !c.areMultipartFieldsEqual(other) { return false } if c.ForcePathStyle != other.ForcePathStyle { return false } if c.SkipTLSVerify != other.SkipTLSVerify { return false } return c.isSecretEqual(other) } func (c *S3FsConfig) areMultipartFieldsEqual(other S3FsConfig) bool { if c.UploadPartSize != other.UploadPartSize { return false } if c.UploadConcurrency != other.UploadConcurrency { return false } if c.DownloadConcurrency != other.DownloadConcurrency { return false } if c.DownloadPartSize != other.DownloadPartSize { return false } if c.DownloadPartMaxTime != other.DownloadPartMaxTime { return false } if c.UploadPartMaxTime != other.UploadPartMaxTime { return false } return true } func (c *S3FsConfig) isSecretEqual(other S3FsConfig) bool { if c.SSECustomerKey == nil { c.SSECustomerKey = kms.NewEmptySecret() } if other.SSECustomerKey == nil { other.SSECustomerKey = kms.NewEmptySecret() } if !c.SSECustomerKey.IsEqual(other.SSECustomerKey) { return false } if c.AccessSecret == nil { c.AccessSecret = kms.NewEmptySecret() } if other.AccessSecret == nil { other.AccessSecret = kms.NewEmptySecret() } return c.AccessSecret.IsEqual(other.AccessSecret) } func (c *S3FsConfig) checkCredentials() error { if c.AccessKey == "" && !c.AccessSecret.IsEmpty() { return util.NewI18nError( errors.New("access_key cannot be empty with access_secret not empty"), util.I18nErrorAccessKeyRequired, ) } if c.AccessSecret.IsEmpty() && c.AccessKey != "" { return util.NewI18nError( errors.New("access_secret cannot be empty with access_key not empty"), util.I18nErrorAccessSecretRequired, ) } if c.AccessSecret.IsEncrypted() && !c.AccessSecret.IsValid() { return errors.New("invalid encrypted access_secret") } if !c.AccessSecret.IsEmpty() && !c.AccessSecret.IsValidInput() { return errors.New("invalid access_secret") } if c.SSECustomerKey.IsEncrypted() && !c.SSECustomerKey.IsValid() { return errors.New("invalid encrypted sse_customer_key") } if !c.SSECustomerKey.IsEmpty() && !c.SSECustomerKey.IsValidInput() { return errors.New("invalid sse_customer_key") } return nil } // ValidateAndEncryptCredentials validates the configuration and encrypts access secret if it is in plain text func (c *S3FsConfig) ValidateAndEncryptCredentials(additionalData string) error { if err := c.validate(); err != nil { var errI18n *util.I18nError errValidation := util.NewValidationError(fmt.Sprintf("could not validate s3config: %v", err)) if errors.As(err, &errI18n) { return util.NewI18nError(errValidation, errI18n.Message) } return util.NewI18nError(errValidation, util.I18nErrorFsValidation) } if c.AccessSecret.IsPlain() { c.AccessSecret.SetAdditionalData(additionalData) err := c.AccessSecret.Encrypt() if err != nil { return util.NewI18nError( util.NewValidationError(fmt.Sprintf("could not encrypt s3 access secret: %v", err)), util.I18nErrorFsValidation, ) } } if c.SSECustomerKey.IsPlain() { c.SSECustomerKey.SetAdditionalData(additionalData) err := c.SSECustomerKey.Encrypt() if err != nil { return util.NewI18nError( util.NewValidationError(fmt.Sprintf("could not encrypt s3 SSE customer key: %v", err)), util.I18nErrorFsValidation, ) } } return nil } func (c *S3FsConfig) checkPartSizeAndConcurrency() error { if c.UploadPartSize != 0 && (c.UploadPartSize < 5 || c.UploadPartSize > 5000) { return util.NewI18nError( errors.New("upload_part_size cannot be != 0, lower than 5 (MB) or greater than 5000 (MB)"), util.I18nErrorULPartSizeInvalid, ) } if c.UploadConcurrency < 0 || c.UploadConcurrency > 64 { return util.NewI18nError( fmt.Errorf("invalid upload concurrency: %v", c.UploadConcurrency), util.I18nErrorULConcurrencyInvalid, ) } if c.DownloadPartSize != 0 && (c.DownloadPartSize < 5 || c.DownloadPartSize > 5000) { return util.NewI18nError( errors.New("download_part_size cannot be != 0, lower than 5 (MB) or greater than 5000 (MB)"), util.I18nErrorDLPartSizeInvalid, ) } if c.DownloadConcurrency < 0 || c.DownloadConcurrency > 64 { return util.NewI18nError( fmt.Errorf("invalid download concurrency: %v", c.DownloadConcurrency), util.I18nErrorDLConcurrencyInvalid, ) } return nil } func (c *S3FsConfig) isSameResource(other S3FsConfig) bool { if c.Bucket != other.Bucket { return false } if c.Endpoint != other.Endpoint { return false } return c.Region == other.Region } // validate returns an error if the configuration is not valid func (c *S3FsConfig) validate() error { if c.AccessSecret == nil { c.AccessSecret = kms.NewEmptySecret() } if c.SSECustomerKey == nil { c.SSECustomerKey = kms.NewEmptySecret() } if c.Bucket == "" { return util.NewI18nError(errors.New("bucket cannot be empty"), util.I18nErrorBucketRequired) } // the region may be embedded within the endpoint for some S3 compatible // object storage, for example B2 if c.Endpoint == "" && c.Region == "" { return util.NewI18nError(errors.New("region cannot be empty"), util.I18nErrorRegionRequired) } if err := c.checkCredentials(); err != nil { return err } if c.KeyPrefix != "" { if strings.HasPrefix(c.KeyPrefix, "/") { return util.NewI18nError(errors.New("key_prefix cannot start with /"), util.I18nErrorKeyPrefixInvalid) } c.KeyPrefix = path.Clean(c.KeyPrefix) if !strings.HasSuffix(c.KeyPrefix, "/") { c.KeyPrefix += "/" } } c.StorageClass = strings.TrimSpace(c.StorageClass) c.ACL = strings.TrimSpace(c.ACL) return c.checkPartSizeAndConcurrency() } // GCSFsConfig defines the configuration for Google Cloud Storage based filesystem type GCSFsConfig struct { sdk.BaseGCSFsConfig Credentials *kms.Secret `json:"credentials,omitempty"` } // HideConfidentialData hides confidential data func (c *GCSFsConfig) HideConfidentialData() { if c.Credentials != nil { c.Credentials.Hide() } } // ValidateAndEncryptCredentials validates the configuration and encrypts credentials if they are in plain text func (c *GCSFsConfig) ValidateAndEncryptCredentials(additionalData string) error { if err := c.validate(); err != nil { var errI18n *util.I18nError errValidation := util.NewValidationError(fmt.Sprintf("could not validate GCS config: %v", err)) if errors.As(err, &errI18n) { return util.NewI18nError(errValidation, errI18n.Message) } return util.NewI18nError(errValidation, util.I18nErrorFsValidation) } if c.Credentials.IsPlain() { c.Credentials.SetAdditionalData(additionalData) err := c.Credentials.Encrypt() if err != nil { return util.NewI18nError( util.NewValidationError(fmt.Sprintf("could not encrypt GCS credentials: %v", err)), util.I18nErrorFsValidation, ) } } return nil } func (c *GCSFsConfig) isEqual(other GCSFsConfig) bool { if c.Bucket != other.Bucket { return false } if c.KeyPrefix != other.KeyPrefix { return false } if c.AutomaticCredentials != other.AutomaticCredentials { return false } if c.StorageClass != other.StorageClass { return false } if c.ACL != other.ACL { return false } if c.UploadPartSize != other.UploadPartSize { return false } if c.UploadPartMaxTime != other.UploadPartMaxTime { return false } if c.Credentials == nil { c.Credentials = kms.NewEmptySecret() } if other.Credentials == nil { other.Credentials = kms.NewEmptySecret() } return c.Credentials.IsEqual(other.Credentials) } func (c *GCSFsConfig) isSameResource(other GCSFsConfig) bool { return c.Bucket == other.Bucket } // validate returns an error if the configuration is not valid func (c *GCSFsConfig) validate() error { if c.Credentials == nil || c.AutomaticCredentials == 1 { c.Credentials = kms.NewEmptySecret() } if c.Bucket == "" { return util.NewI18nError(errors.New("bucket cannot be empty"), util.I18nErrorBucketRequired) } if c.KeyPrefix != "" { if strings.HasPrefix(c.KeyPrefix, "/") { return util.NewI18nError(errors.New("key_prefix cannot start with /"), util.I18nErrorKeyPrefixInvalid) } c.KeyPrefix = path.Clean(c.KeyPrefix) if !strings.HasSuffix(c.KeyPrefix, "/") { c.KeyPrefix += "/" } } if c.Credentials.IsEncrypted() && !c.Credentials.IsValid() { return errors.New("invalid encrypted credentials") } if c.AutomaticCredentials == 0 && !c.Credentials.IsValidInput() { return util.NewI18nError(errors.New("invalid credentials"), util.I18nErrorFsCredentialsRequired) } c.StorageClass = strings.TrimSpace(c.StorageClass) c.ACL = strings.TrimSpace(c.ACL) if c.UploadPartSize < 0 { c.UploadPartSize = 0 } if c.UploadPartMaxTime < 0 { c.UploadPartMaxTime = 0 } return nil } // AzBlobFsConfig defines the configuration for Azure Blob Storage based filesystem type AzBlobFsConfig struct { sdk.BaseAzBlobFsConfig // Storage Account Key leave blank to use SAS URL. // The access key is stored encrypted based on the kms configuration AccountKey *kms.Secret `json:"account_key,omitempty"` // Shared access signature URL, leave blank if using account/key SASURL *kms.Secret `json:"sas_url,omitempty"` } // HideConfidentialData hides confidential data func (c *AzBlobFsConfig) HideConfidentialData() { if c.AccountKey != nil { c.AccountKey.Hide() } if c.SASURL != nil { c.SASURL.Hide() } } func (c *AzBlobFsConfig) isEqual(other AzBlobFsConfig) bool { if c.Container != other.Container { return false } if c.AccountName != other.AccountName { return false } if c.Endpoint != other.Endpoint { return false } if c.SASURL.IsEmpty() { c.SASURL = kms.NewEmptySecret() } if other.SASURL.IsEmpty() { other.SASURL = kms.NewEmptySecret() } if !c.SASURL.IsEqual(other.SASURL) { return false } if c.KeyPrefix != other.KeyPrefix { return false } if c.UploadPartSize != other.UploadPartSize { return false } if c.UploadConcurrency != other.UploadConcurrency { return false } if c.DownloadPartSize != other.DownloadPartSize { return false } if c.DownloadConcurrency != other.DownloadConcurrency { return false } if c.UseEmulator != other.UseEmulator { return false } if c.AccessTier != other.AccessTier { return false } return c.isSecretEqual(other) } func (c *AzBlobFsConfig) isSecretEqual(other AzBlobFsConfig) bool { if c.AccountKey == nil { c.AccountKey = kms.NewEmptySecret() } if other.AccountKey == nil { other.AccountKey = kms.NewEmptySecret() } return c.AccountKey.IsEqual(other.AccountKey) } // ValidateAndEncryptCredentials validates the configuration and encrypts access secret if it is in plain text func (c *AzBlobFsConfig) ValidateAndEncryptCredentials(additionalData string) error { if err := c.validate(); err != nil { var errI18n *util.I18nError errValidation := util.NewValidationError(fmt.Sprintf("could not validate Azure Blob config: %v", err)) if errors.As(err, &errI18n) { return util.NewI18nError(errValidation, errI18n.Message) } return util.NewI18nError(errValidation, util.I18nErrorFsValidation) } if c.AccountKey.IsPlain() { c.AccountKey.SetAdditionalData(additionalData) if err := c.AccountKey.Encrypt(); err != nil { return util.NewI18nError( util.NewValidationError(fmt.Sprintf("could not encrypt Azure blob account key: %v", err)), util.I18nErrorFsValidation, ) } } if c.SASURL.IsPlain() { c.SASURL.SetAdditionalData(additionalData) if err := c.SASURL.Encrypt(); err != nil { return util.NewI18nError( util.NewValidationError(fmt.Sprintf("could not encrypt Azure blob SAS URL: %v", err)), util.I18nErrorFsValidation, ) } } return nil } func (c *AzBlobFsConfig) checkCredentials() error { if c.SASURL.IsPlain() { _, err := url.Parse(c.SASURL.GetPayload()) if err != nil { return util.NewI18nError(err, util.I18nErrorSASURLInvalid) } return nil } if c.SASURL.IsEncrypted() && !c.SASURL.IsValid() { return errors.New("invalid encrypted sas_url") } if !c.SASURL.IsEmpty() { return nil } if c.AccountName == "" || !c.AccountKey.IsValidInput() { return util.NewI18nError(errors.New("credentials cannot be empty or invalid"), util.I18nErrorAccountNameRequired) } if c.AccountKey.IsEncrypted() && !c.AccountKey.IsValid() { return errors.New("invalid encrypted account_key") } return nil } func (c *AzBlobFsConfig) checkPartSizeAndConcurrency() error { if c.UploadPartSize < 0 || c.UploadPartSize > 100 { return util.NewI18nError( fmt.Errorf("invalid upload part size: %v", c.UploadPartSize), util.I18nErrorULPartSizeInvalid, ) } if c.UploadConcurrency < 0 || c.UploadConcurrency > 64 { return util.NewI18nError( fmt.Errorf("invalid upload concurrency: %v", c.UploadConcurrency), util.I18nErrorULConcurrencyInvalid, ) } if c.DownloadPartSize < 0 || c.DownloadPartSize > 100 { return util.NewI18nError( fmt.Errorf("invalid download part size: %v", c.DownloadPartSize), util.I18nErrorDLPartSizeInvalid, ) } if c.DownloadConcurrency < 0 || c.DownloadConcurrency > 64 { return util.NewI18nError( fmt.Errorf("invalid upload concurrency: %v", c.DownloadConcurrency), util.I18nErrorDLConcurrencyInvalid, ) } return nil } func (c *AzBlobFsConfig) tryDecrypt() error { if err := c.AccountKey.TryDecrypt(); err != nil { return fmt.Errorf("unable to decrypt account key: %w", err) } if err := c.SASURL.TryDecrypt(); err != nil { return fmt.Errorf("unable to decrypt SAS URL: %w", err) } return nil } func (c *AzBlobFsConfig) isSameResource(other AzBlobFsConfig) bool { if c.AccountName != other.AccountName { return false } if c.Endpoint != other.Endpoint { return false } return c.SASURL.GetPayload() == other.SASURL.GetPayload() } // validate returns an error if the configuration is not valid func (c *AzBlobFsConfig) validate() error { if c.AccountKey == nil { c.AccountKey = kms.NewEmptySecret() } if c.SASURL == nil { c.SASURL = kms.NewEmptySecret() } // container could be embedded within SAS URL we check this at runtime if c.SASURL.IsEmpty() && c.Container == "" { return util.NewI18nError(errors.New("container cannot be empty"), util.I18nErrorContainerRequired) } if err := c.checkCredentials(); err != nil { return err } if c.KeyPrefix != "" { if strings.HasPrefix(c.KeyPrefix, "/") { return util.NewI18nError(errors.New("key_prefix cannot start with /"), util.I18nErrorKeyPrefixInvalid) } c.KeyPrefix = path.Clean(c.KeyPrefix) if !strings.HasSuffix(c.KeyPrefix, "/") { c.KeyPrefix += "/" } } if err := c.checkPartSizeAndConcurrency(); err != nil { return err } if !slices.Contains(validAzAccessTier, c.AccessTier) { return fmt.Errorf("invalid access tier %q, valid values: \"''%v\"", c.AccessTier, strings.Join(validAzAccessTier, ", ")) } return nil } // CryptFsConfig defines the configuration to store local files as encrypted type CryptFsConfig struct { sdk.OSFsConfig Passphrase *kms.Secret `json:"passphrase,omitempty"` } // HideConfidentialData hides confidential data func (c *CryptFsConfig) HideConfidentialData() { if c.Passphrase != nil { c.Passphrase.Hide() } } func (c *CryptFsConfig) isEqual(other CryptFsConfig) bool { if c.Passphrase == nil { c.Passphrase = kms.NewEmptySecret() } if other.Passphrase == nil { other.Passphrase = kms.NewEmptySecret() } return c.Passphrase.IsEqual(other.Passphrase) } // ValidateAndEncryptCredentials validates the configuration and encrypts the passphrase if it is in plain text func (c *CryptFsConfig) ValidateAndEncryptCredentials(additionalData string) error { if err := c.validate(); err != nil { var errI18n *util.I18nError errValidation := util.NewValidationError(fmt.Sprintf("could not validate crypt fs config: %v", err)) if errors.As(err, &errI18n) { return util.NewI18nError(errValidation, errI18n.Message) } return util.NewI18nError(errValidation, util.I18nErrorFsValidation) } if c.Passphrase.IsPlain() { c.Passphrase.SetAdditionalData(additionalData) if err := c.Passphrase.Encrypt(); err != nil { return util.NewI18nError( util.NewValidationError(fmt.Sprintf("could not encrypt Crypt fs passphrase: %v", err)), util.I18nErrorFsValidation, ) } } return nil } func (c *CryptFsConfig) isSameResource(other CryptFsConfig) bool { return c.Passphrase.GetPayload() == other.Passphrase.GetPayload() } // validate returns an error if the configuration is not valid func (c *CryptFsConfig) validate() error { if c.Passphrase == nil || c.Passphrase.IsEmpty() { return util.NewI18nError(errors.New("invalid passphrase"), util.I18nErrorPassphraseRequired) } if !c.Passphrase.IsValidInput() { return util.NewI18nError(errors.New("passphrase cannot be empty or invalid"), util.I18nErrorPassphraseRequired) } if c.Passphrase.IsEncrypted() && !c.Passphrase.IsValid() { return errors.New("invalid encrypted passphrase") } return nil } // pipeWriter defines a wrapper for a pipeWriterAt. type pipeWriter struct { pipeWriterAt err error done chan bool } // NewPipeWriter initializes a new PipeWriter func NewPipeWriter(w pipeWriterAt) PipeWriter { return &pipeWriter{ pipeWriterAt: w, err: nil, done: make(chan bool), } } // Close waits for the upload to end, closes the pipeWriterAt and returns an error if any. func (p *pipeWriter) Close() error { p.pipeWriterAt.Close() //nolint:errcheck // the returned error is always null <-p.done return p.err } // Done unlocks other goroutines waiting on Close(). // It must be called when the upload ends func (p *pipeWriter) Done(err error) { p.err = err p.done <- true } func newPipeWriterAtOffset(w pipeWriterAt, offset int64) PipeWriter { return &pipeWriterAtOffset{ pipeWriter: &pipeWriter{ pipeWriterAt: w, err: nil, done: make(chan bool), }, offset: offset, writeOffset: offset, } } type pipeWriterAtOffset struct { *pipeWriter offset int64 writeOffset int64 } func (p *pipeWriterAtOffset) WriteAt(buf []byte, off int64) (int, error) { if off < p.offset { return 0, fmt.Errorf("invalid offset %d, minimum accepted %d", off, p.offset) } return p.pipeWriter.WriteAt(buf, off-p.offset) } func (p *pipeWriterAtOffset) Write(buf []byte) (int, error) { n, err := p.WriteAt(buf, p.writeOffset) p.writeOffset += int64(n) return n, err } // NewPipeReader initializes a new PipeReader func NewPipeReader(r pipeReaderAt) PipeReader { return &pipeReader{ pipeReaderAt: r, } } // pipeReader defines a wrapper for pipeat.PipeReaderAt. type pipeReader struct { pipeReaderAt mu sync.RWMutex metadata map[string]string } func (p *pipeReader) setMetadata(value map[string]string) { p.mu.Lock() defer p.mu.Unlock() p.metadata = value } func (p *pipeReader) setMetadataFromPointerVal(value map[string]*string) { p.mu.Lock() defer p.mu.Unlock() if len(value) == 0 { p.metadata = nil return } p.metadata = map[string]string{} for k, v := range value { val := util.GetStringFromPointer(v) if val != "" { p.metadata[k] = val } } } // Metadata implements the Metadater interface func (p *pipeReader) Metadata() map[string]string { p.mu.RLock() defer p.mu.RUnlock() if len(p.metadata) == 0 { return nil } result := make(map[string]string) for k, v := range p.metadata { result[k] = v } return result } func isEqualityCheckModeValid(mode int) bool { return mode >= 0 || mode <= 1 } // isDirectory checks if a path exists and is a directory func isDirectory(fs Fs, path string) (bool, error) { fileInfo, err := fs.Stat(path) if err != nil { return false, err } return fileInfo.IsDir(), err } // IsLocalOsFs returns true if fs is a local filesystem implementation func IsLocalOsFs(fs Fs) bool { return fs.Name() == osFsName } // IsCryptOsFs returns true if fs is an encrypted local filesystem implementation func IsCryptOsFs(fs Fs) bool { return fs.Name() == cryptFsName } // IsSFTPFs returns true if fs is an SFTP filesystem func IsSFTPFs(fs Fs) bool { return strings.HasPrefix(fs.Name(), sftpFsName) } // IsHTTPFs returns true if fs is an HTTP filesystem func IsHTTPFs(fs Fs) bool { return strings.HasPrefix(fs.Name(), httpFsName) } // IsBufferedLocalOrSFTPFs returns true if this is a buffered SFTP or local filesystem func IsBufferedLocalOrSFTPFs(fs Fs) bool { if osFs, ok := fs.(*OsFs); ok { return osFs.writeBufferSize > 0 } if !IsSFTPFs(fs) { return false } return !fs.IsUploadResumeSupported() } // FsOpenReturnsFile returns true if fs.Open returns a *os.File handle func FsOpenReturnsFile(fs Fs) bool { if osFs, ok := fs.(*OsFs); ok { return osFs.readBufferSize == 0 } if sftpFs, ok := fs.(*SFTPFs); ok { return sftpFs.config.BufferSize == 0 } return false } // IsLocalOrSFTPFs returns true if fs is local or SFTP func IsLocalOrSFTPFs(fs Fs) bool { return IsLocalOsFs(fs) || IsSFTPFs(fs) } // HasTruncateSupport returns true if the fs supports truncate files func HasTruncateSupport(fs Fs) bool { return IsLocalOsFs(fs) || IsSFTPFs(fs) || IsHTTPFs(fs) } // IsRenameAtomic returns true if renaming a directory is supposed to be atomic func IsRenameAtomic(fs Fs) bool { if strings.HasPrefix(fs.Name(), s3fsName) { return false } if strings.HasPrefix(fs.Name(), gcsfsName) { return false } if strings.HasPrefix(fs.Name(), azBlobFsName) { return false } return true } // HasImplicitAtomicUploads returns true if the fs don't persists partial files on error func HasImplicitAtomicUploads(fs Fs) bool { if strings.HasPrefix(fs.Name(), s3fsName) { return uploadMode&4 == 0 } if strings.HasPrefix(fs.Name(), gcsfsName) { return uploadMode&8 == 0 } if strings.HasPrefix(fs.Name(), azBlobFsName) { return uploadMode&16 == 0 } return false } // HasOpenRWSupport returns true if the fs can open a file // for reading and writing at the same time func HasOpenRWSupport(fs Fs) bool { if IsLocalOsFs(fs) { return true } if IsSFTPFs(fs) && fs.IsUploadResumeSupported() { return true } return false } // IsLocalOrCryptoFs returns true if fs is local or local encrypted func IsLocalOrCryptoFs(fs Fs) bool { return IsLocalOsFs(fs) || IsCryptOsFs(fs) } // SetPathPermissions calls fs.Chown. // It does nothing for local filesystem on windows func SetPathPermissions(fs Fs, path string, uid int, gid int) { if uid == -1 && gid == -1 { return } if IsLocalOsFs(fs) { if runtime.GOOS == "windows" { return } } if err := fs.Chown(path, uid, gid); err != nil { fsLog(fs, logger.LevelWarn, "error chowning path %v: %v", path, err) } } // IsUploadResumeSupported returns true if resuming uploads is supported func IsUploadResumeSupported(fs Fs, size int64) bool { if fs.IsUploadResumeSupported() { return true } return fs.IsConditionalUploadResumeSupported(size) } func getLastModified(metadata map[string]string) int64 { if val, ok := metadata[lastModifiedField]; ok && val != "" { lastModified, err := strconv.ParseInt(val, 10, 64) if err == nil { return lastModified } } return 0 } func getAzureLastModified(metadata map[string]*string) int64 { for k, v := range metadata { if strings.ToLower(k) == lastModifiedField { if val := util.GetStringFromPointer(v); val != "" { lastModified, err := strconv.ParseInt(val, 10, 64) if err == nil { return lastModified } } return 0 } } return 0 } func validateOSFsConfig(config *sdk.OSFsConfig) error { if config.ReadBufferSize < 0 || config.ReadBufferSize > 10 { return fmt.Errorf("invalid read buffer size must be between 0 and 10 MB") } if config.WriteBufferSize < 0 || config.WriteBufferSize > 10 { return fmt.Errorf("invalid write buffer size must be between 0 and 10 MB") } return nil } func doCopy(dst io.Writer, src io.Reader, buf []byte) (written int64, err error) { if buf == nil { buf = make([]byte, 32768) } for { nr, er := src.Read(buf) if nr > 0 { nw, ew := dst.Write(buf[0:nr]) if nw < 0 || nr < nw { nw = 0 if ew == nil { ew = errors.New("invalid write") } } written += int64(nw) if ew != nil { err = ew break } if nr != nw { err = io.ErrShortWrite break } } if er != nil { if er != io.EOF { err = er } break } } return written, err } func getMountPath(mountPath string) string { if mountPath == "/" { return "" } return mountPath } func getLocalTempDir() string { if tempPath != "" { return tempPath } return filepath.Clean(os.TempDir()) } func doRecursiveRename(fs Fs, source, target string, renameFn func(string, string, os.FileInfo, int, bool) (int, int64, error), recursion int, updateModTime bool, ) (int, int64, error) { var numFiles int var filesSize int64 if recursion > util.MaxRecursion { return numFiles, filesSize, util.ErrRecursionTooDeep } recursion++ lister, err := fs.ReadDir(source) if err != nil { return numFiles, filesSize, err } defer lister.Close() for { entries, err := lister.Next(ListerBatchSize) finished := errors.Is(err, io.EOF) if err != nil && !finished { return numFiles, filesSize, err } for _, info := range entries { sourceEntry := fs.Join(source, info.Name()) targetEntry := fs.Join(target, info.Name()) files, size, err := renameFn(sourceEntry, targetEntry, info, recursion, updateModTime) if err != nil { if fs.IsNotExist(err) { fsLog(fs, logger.LevelInfo, "skipping rename for %q: %v", sourceEntry, err) continue } return numFiles, filesSize, err } numFiles += files filesSize += size } if finished { return numFiles, filesSize, nil } } } func fsLog(fs Fs, level logger.LogLevel, format string, v ...any) { logger.Log(level, fs.Name(), fs.ConnectionID(), format, v...) }