Documentation ¶
Overview ¶
Package walletdb provides a namespaced database interface for dcrwallet.
A wallet essentially consists of a multitude of stored data such as private and public keys, key derivation bits, pay-to-script-hash scripts, and various metadata. One of the issues with many wallets is they are tightly integrated. Designing a wallet with loosely coupled components that provide specific functionality is ideal, however it presents a challenge in regards to data storage since each component needs to store its own data without knowing the internals of other components or breaking atomicity.
This package solves this issue by providing a pluggable driver, namespaced database interface that is intended to be used by the main wallet daemon. This allows the potential for any backend database type with a suitable driver. Each component, which will typically be a package, can then implement various functionality such as address management, voting pools, and colored coin metadata in their own namespace without having to worry about conflicts with other packages even though they are sharing the same database that is managed by the wallet.
A quick overview of the features walletdb provides are as follows:
- Key/value store
- Namespace support
- Allows multiple packages to have their own area in the database without worrying about conflicts
- Read-only and read-write transactions with both manual and managed modes
- Nested buckets
- Supports registration of backend databases
- Comprehensive test coverage
Database ¶
The main entry point is the DB interface. It exposes functionality for creating, retrieving, and removing namespaces. It is obtained via the Create and Open functions which take a database type string that identifies the specific database driver (backend) to use as well as arguments specific to the specified driver.
Namespaces ¶
The Namespace interface is an abstraction that provides facilities for obtaining transactions (the Tx interface) that are the basis of all database reads and writes. Unlike some database interfaces that support reading and writing without transactions, this interface requires transactions even when only reading or writing a single key.
The Begin function provides an unmanaged transaction while the View and Update functions provide a managed transaction. These are described in more detail below.
Transactions ¶
The Tx interface provides facilities for rolling back or committing changes that took place while the transaction was active. It also provides the root bucket under which all keys, values, and nested buckets are stored. A transaction can either be read-only or read-write and managed or unmanaged.
Managed versus Unmanaged Transactions ¶
A managed transaction is one where the caller provides a function to execute within the context of the transaction and the commit or rollback is handled automatically depending on whether or not the provided function returns an error. Attempting to manually call Rollback or Commit on the managed transaction will result in a panic.
An unmanaged transaction, on the other hand, requires the caller to manually call Commit or Rollback when they are finished with it. Leaving transactions open for long periods of time can have several adverse effects, so it is recommended that managed transactions are used instead.
Buckets ¶
The Bucket interface provides the ability to manipulate key/value pairs and nested buckets as well as iterate through them.
The Get, Put, and Delete functions work with key/value pairs, while the Bucket, CreateBucket, CreateBucketIfNotExists, and DeleteBucket functions work with buckets. The ForEach function allows the caller to provide a function to be called with each key/value pair and nested bucket in the current bucket.
Root Bucket ¶
As discussed above, all of the functions which are used to manipulate key/value pairs and nested buckets exist on the Bucket interface. The root bucket is the upper-most bucket in a namespace under which data is stored and is created at the same time as the namespace. Use the RootBucket function on the Tx interface to retrieve it.
Nested Buckets ¶
The CreateBucket and CreateBucketIfNotExists functions on the Bucket interface provide the ability to create an arbitrary number of nested buckets. It is a good idea to avoid a lot of buckets with little data in them as it could lead to poor page utilization depending on the specific driver in use.
Index ¶
- func BucketIsEmpty(bucket ReadBucket) bool
- func RegisterDriver(driver Driver) error
- func SupportedDrivers() []string
- func Update(ctx context.Context, db DB, f func(tx ReadWriteTx) error) (err error)
- func View(ctx context.Context, db DB, f func(tx ReadTx) error) error
- type DB
- type Driver
- type ReadBucket
- type ReadCursor
- type ReadTx
- type ReadWriteBucket
- type ReadWriteCursor
- type ReadWriteTx
Constants ¶
This section is empty.
Variables ¶
This section is empty.
Functions ¶
func BucketIsEmpty ¶
func BucketIsEmpty(bucket ReadBucket) bool
BucketIsEmpty returns whether the bucket is empty, that is, whether there are no key/value pairs or nested buckets.
func RegisterDriver ¶
RegisterDriver adds a backend database driver to available interfaces. Errors if the will be returned if the database type for the driver has already been registered.
func SupportedDrivers ¶
func SupportedDrivers() []string
SupportedDrivers returns a slice of strings that represent the database drivers that have been registered and are therefore supported.
func Update ¶
Update opens a database read/write transaction and executes the function f with the transaction passed as a parameter. After f exits, if f did not error, the transaction is committed. Otherwise, if f did error or panic, the transaction is rolled back. If a rollback fails, the original error returned by f is still returned. If the commit fails, the commit error is returned.
Types ¶
type DB ¶
type DB interface { // BeginReadTx opens a database read transaction. BeginReadTx() (ReadTx, error) // BeginReadWriteTx opens a database read+write transaction. BeginReadWriteTx() (ReadWriteTx, error) // Copy writes a copy of the database to the provided writer. This // call will start a read-only transaction to perform all operations. Copy(w io.Writer) error // Close cleanly shuts down the database and syncs all data. Close() error }
DB represents an ACID database. All database access is performed through read or read+write transactions.
type Driver ¶
type Driver struct { // DbType is the identifier used to uniquely identify a specific // database driver. There can be only one driver with the same name. DbType string // Create is the function that will be invoked with all user-specified // arguments to create the database. Create func(args ...any) (DB, error) // Open is the function that will be invoked with all user-specified // arguments to open the database. Open func(args ...any) (DB, error) }
Driver defines a structure for backend drivers to use when they registered themselves as a backend which implements the Db interface.
type ReadBucket ¶
type ReadBucket interface { // NestedReadBucket retrieves a nested bucket with the given key. // Returns nil if the bucket does not exist. NestedReadBucket(key []byte) ReadBucket // ForEach invokes the passed function with every key/value pair in // the bucket. This includes nested buckets, in which case the value // is nil, but it does not include the key/value pairs within those // nested buckets. // // NOTE: The values returned by this function are only valid during a // transaction. Attempting to access them after a transaction has ended // results in undefined behavior. This constraint prevents additional // data copies and allows support for memory-mapped database // implementations. ForEach(func(k, v []byte) error) error // Get returns the value for the given key. Returns nil if the key does // not exist in this bucket (or nested buckets). // // NOTE: The value returned by this function is only valid during a // transaction. Attempting to access it after a transaction has ended // results in undefined behavior. This constraint prevents additional // data copies and allows support for memory-mapped database // implementations. Get(key []byte) []byte // KeyN returns the number of keys and value pairs inside a bucket. KeyN() int ReadCursor() ReadCursor }
ReadBucket represents a bucket (a hierarchical structure within the database) that is only allowed to perform read operations.
type ReadCursor ¶
type ReadCursor interface { // First positions the cursor at the first key/value pair and returns // the pair. First() (key, value []byte) // Last positions the cursor at the last key/value pair and returns the // pair. Last() (key, value []byte) // Next moves the cursor one key/value pair forward and returns the new // pair. Next() (key, value []byte) // Prev moves the cursor one key/value pair backward and returns the new // pair. Prev() (key, value []byte) // Seek positions the cursor at the passed seek key. If the key does // not exist, the cursor is moved to the next key after seek. Returns // the new pair. Seek(seek []byte) (key, value []byte) // Close closes the cursor. Cursors must be closed before opening a new // cursor and before finishing a transaction. Close() }
ReadCursor represents a bucket cursor that can be positioned at the start or end of the bucket's key/value pairs and iterate over pairs in the bucket. This type is only allowed to perform database read operations.
type ReadTx ¶
type ReadTx interface { // ReadBucket opens the root bucket for read only access. If the bucket // described by the key does not exist, nil is returned. ReadBucket(key []byte) ReadBucket // Rollback closes the transaction, discarding changes (if any) if the // database was modified by a write transaction. Rollback() error }
ReadTx represents a database transaction that can only be used for reads. If a database update must occur, use a ReadWriteTx.
type ReadWriteBucket ¶
type ReadWriteBucket interface { ReadBucket // NestedReadWriteBucket retrieves a nested bucket with the given key. // Returns nil if the bucket does not exist. NestedReadWriteBucket(key []byte) ReadWriteBucket // CreateBucket creates and returns a new nested bucket with the given key. // Errors with code Exist if the bucket already exists and Invalid if the // key is empty or otherwise invalid for the driver. CreateBucket(key []byte) (ReadWriteBucket, error) // CreateBucketIfNotExists creates and returns a new nested bucket with the // given key if it does not already exist. Errors with code Invalid if the // key is empty or the key/value is not valid for the driver. CreateBucketIfNotExists(key []byte) (ReadWriteBucket, error) // DeleteNestedBucket removes a nested bucket with the given key. Errors // with code Invalid if attempted against a read-only transaction and // NotExist if the specified bucket does not exist. DeleteNestedBucket(key []byte) error // Put saves the specified key/value pair to the bucket. Keys that do not // already exist are added and keys that already exist are overwritten. // Errors with code Invalid if attempted against a read-only transaction. Put(key, value []byte) error // Delete removes the specified key from the bucket. Deleting a key that // does not exist does not return an error. Errors with code Invalid if // attempted against a read-only transaction. Delete(key []byte) error // Cursor returns a new cursor, allowing for iteration over the bucket's // key/value pairs and nested buckets in forward or backward order. // Only one cursor can be opened at a time and should be closed before // committing or rolling back the transaction. ReadWriteCursor() ReadWriteCursor }
ReadWriteBucket represents a bucket (a hierarchical structure within the database) that is allowed to perform both read and write operations.
type ReadWriteCursor ¶
type ReadWriteCursor interface { ReadCursor // Delete removes the current key/value pair the cursor is at without // invalidating the cursor. Errors with code Invalid if attempted when the // cursor points to a nested bucket. Delete() error }
ReadWriteCursor represents a bucket cursor that can be positioned at the start or end of the bucket's key/value pairs and iterate over pairs in the bucket. This abstraction is allowed to perform both database read and write operations.
type ReadWriteTx ¶
type ReadWriteTx interface { ReadTx // ReadWriteBucket opens the root bucket for read/write access. If the // bucket described by the key does not exist, nil is returned. ReadWriteBucket(key []byte) ReadWriteBucket // CreateTopLevelBucket creates the top level bucket for a key if it // does not exist. The newly-created bucket is returned. CreateTopLevelBucket(key []byte) (ReadWriteBucket, error) // DeleteTopLevelBucket deletes the top level bucket for a key. This // errors if the bucket can not be found or the key keys a single value // instead of a bucket. DeleteTopLevelBucket(key []byte) error // Commit commits all changes that have been on the transaction's root // buckets and all of their sub-buckets to persistent storage. Commit() error }
ReadWriteTx represents a database transaction that can be used for both reads and writes. When only reads are necessary, consider using a ReadTx instead.