A store is a data structure that holds the state of the application. {synopsis}
- Anatomy of a Cosmos SDK application {prereq}
The Cosmos SDK comes with a large set of stores to persist the state of applications. By default, the main store of Cosmos SDK applications is a multistore
, i.e. a store of stores. Developers can add any number of key-value stores to the multistore, depending on their application needs. The multistore exists to support the modularity of the Cosmos SDK, as it lets each module declare and manage their own subset of the state. Key-value stores in the multistore can only be accessed with a specific capability key
, which is typically held in the keeper
of the module that declared the store.
+-----------------------------------------------------+
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| +--------------------------------------------+ |
| | | |
| | KVStore 1 - Manage by keeper of Module 1 |
| | | |
| +--------------------------------------------+ |
| |
| +--------------------------------------------+ |
| | | |
| | KVStore 2 - Manage by keeper of Module 2 | |
| | | |
| +--------------------------------------------+ |
| |
| +--------------------------------------------+ |
| | | |
| | KVStore 3 - Manage by keeper of Module 2 | |
| | | |
| +--------------------------------------------+ |
| |
| +--------------------------------------------+ |
| | | |
| | KVStore 4 - Manage by keeper of Module 3 | |
| | | |
| +--------------------------------------------+ |
| |
| +--------------------------------------------+ |
| | | |
| | KVStore 5 - Manage by keeper of Module 4 | |
| | | |
| +--------------------------------------------+ |
| |
| Main Multistore |
| |
+-----------------------------------------------------+
Application's State
At its very core, a Cosmos SDK store
is an object that holds a CacheWrapper
and has a GetStoreType()
method:
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/types/store.go#L15-L18
The GetStoreType
is a simple method that returns the type of store, whereas a CacheWrapper
is a simple interface that implements store read caching and write branching through Write
method:
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/types/store.go#L240-L264
Branching and cache is used ubiquitously in the Cosmos SDK and required to be implemented on every store type. A storage branch creates an isolated, ephemeral branch of a store that can be passed around and updated without affecting the main underlying store. This is used to trigger temporary state-transitions that may be reverted later should an error occur. Read more about it in context
A commit store is a store that has the ability to commit changes made to the underlying tree or db. The Cosmos SDK differentiates simple stores from commit stores by extending the basic store interfaces with a Committer
:
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/types/store.go#L29-L33
The Committer
is an interface that defines methods to persist changes to disk:
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/types/store.go#L20-L27
The CommitID
is a deterministic commit of the state tree. Its hash is returned to the underlying consensus engine and stored in the block header. Note that commit store interfaces exist for various purposes, one of which is to make sure not every object can commit the store. As part of the object-capabilities model of the Cosmos SDK, only baseapp
should have the ability to commit stores. For example, this is the reason why the ctx.KVStore()
method by which modules typically access stores returns a KVStore
and not a CommitKVStore
.
The Cosmos SDK comes with many types of stores, the most used being CommitMultiStore
, KVStore
and GasKv
store. Other types of stores include Transient
and TraceKV
stores.
Each Cosmos SDK application holds a multistore at its root to persist its state. The multistore is a store of KVStores
that follows the Multistore
interface:
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/types/store.go#L104-L133
If tracing is enabled, then branching the multistore will firstly wrap all the underlying KVStore
in TraceKv.Store
.
The main type of Multistore
used in the Cosmos SDK is CommitMultiStore
, which is an extension of the Multistore
interface:
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/types/store.go#L141-L184
As for concrete implementation, the [rootMulti.Store
] is the go-to implementation of the CommitMultiStore
interface.
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/rootmulti/store.go#L43-L61
The rootMulti.Store
is a base-layer multistore built around a db
on top of which multiple KVStores
can be mounted, and is the default multistore store used in baseapp
.
Whenever the rootMulti.Store
needs to be branched, a cachemulti.Store
is used.
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/cachemulti/store.go#L17-L28
cachemulti.Store
branches all substores (creates a virtual store for each substore) in its constructor and hold them in Store.stores
. Moreover caches all read queries. Store.GetKVStore()
returns the store from Store.stores
, and Store.Write()
recursively calls CacheWrap.Write()
on all the substores.
A KVStore
is a simple key-value store used to store and retrieve data. A CommitKVStore
is a KVStore
that also implements a Committer
. By default, stores mounted in baseapp
's main CommitMultiStore
are CommitKVStore
s. The KVStore
interface is primarily used to restrict modules from accessing the committer.
Individual KVStore
s are used by modules to manage a subset of the global state. KVStores
can be accessed by objects that hold a specific key. This key
should only be exposed to the keeper
of the module that defines the store.
CommitKVStore
s are declared by proxy of their respective key
and mounted on the application's multistore in the main application file. In the same file, the key
is also passed to the module's keeper
that is responsible for managing the store.
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/types/store.go#L189-L219
Apart from the traditional Get
and Set
methods, a KVStore
must provide an Iterator(start, end)
method which returns an Iterator
object. It is used to iterate over a range of keys, typically keys that share a common prefix. Below is an example from the bank's module keeper, used to iterate over all account balances:
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/x/bank/keeper/view.go#L115-L134
The default implementation of KVStore
and CommitKVStore
used in baseapp
is the iavl.Store
.
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/iavl/store.go#L37-L40
iavl
stores are based around an IAVL Tree, a self-balancing binary tree which guarantees that:
Get
andSet
operations are O(log n), where n is the number of elements in the tree.- Iteration efficiently returns the sorted elements within the range.
- Each tree version is immutable and can be retrieved even after a commit (depending on the pruning settings).
The documentation on the IAVL Tree is located here.
dbadapter.Store
is a adapter for dbm.DB
making it fulfilling the KVStore
interface.
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/dbadapter/store.go#L13-L16
dbadapter.Store
embeds dbm.DB
, meaning most of the KVStore
interface functions are implemented. The other functions (mostly miscellaneous) are manually implemented. This store is primarily used within Transient Stores
Transient.Store
is a base-layer KVStore
which is automatically discarded at the end of the block.
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/transient/store.go#L13-L16
Transient.Store
is a dbadapter.Store
with a dbm.NewMemDB()
. All KVStore
methods are reused. When Store.Commit()
is called, a new dbadapter.Store
is assigned, discarding previous reference and making it garbage collected.
This type of store is useful to persist information that is only relevant per-block. One example would be to store parameter changes (i.e. a bool set to true
if a parameter changed in a block).
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/x/params/types/subspace.go#L20-L30
Transient stores are typically accessed via the context
via the TransientStore()
method:
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/types/context.go#L232-L235
cachekv.Store
is a wrapper KVStore
which provides buffered writing / cached reading functionalities over the underlying KVStore
.
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/cachekv/store.go#L27-L34
This is the type used whenever an IAVL Store needs to be branched to create an isolated store (typically when we need to mutate a state that might be reverted later).
Store.Get()
firstly checks if Store.cache
has an associated value with the key. If the value exists, the function returns it. If not, the function calls Store.parent.Get()
, caches the result in Store.cache
, and returns it.
Store.Set()
sets the key-value pair to the Store.cache
. cValue
has the field dirty bool which indicates whether the cached value is different from the underlying value. When Store.Set()
caches a new pair, the cValue.dirty
is set true
so when Store.Write()
is called it can be written to the underlying store.
Store.Iterator()
have to traverse on both cached items and the original items. In Store.iterator()
, two iterators are generated for each of them, and merged. memIterator
is essentially a slice of the KVPairs
, used for cached items. mergeIterator
is a combination of two iterators, where traverse happens ordered on both iterators.
Cosmos SDK applications use gas
to track resources usage and prevent spam. GasKv.Store
is a KVStore
wrapper that enables automatic gas consumption each time a read or write to the store is made. It is the solution of choice to track storage usage in Cosmos SDK applications.
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/gaskv/store.go#L13-L19
When methods of the parent KVStore
are called, GasKv.Store
automatically consumes appropriate amount of gas depending on the Store.gasConfig
:
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/types/gas.go#L153-L162
By default, all KVStores
are wrapped in GasKv.Stores
when retrieved. This is done in the KVStore()
method of the context
:
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/types/context.go#L227-L230
In this case, the default gas configuration is used:
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/types/gas.go#L164-L175
tracekv.Store
is a wrapper KVStore
which provides operation tracing functionalities over the underlying KVStore
. It is applied automatically by the Cosmos SDK on all KVStore
if tracing is enabled on the parent MultiStore
.
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/tracekv/store.go#L20-L43
When each KVStore
methods are called, tracekv.Store
automatically logs traceOperation
to the Store.writer
. traceOperation.Metadata
is filled with Store.context
when it is not nil. TraceContext
is a map[string]interface{}
.
prefix.Store
is a wrapper KVStore
which provides automatic key-prefixing functionalities over the underlying KVStore
.
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.40.0-rc6/store/prefix/store.go#L15-L21
When Store.{Get, Set}()
is called, the store forwards the call to its parent, with the key prefixed with the Store.prefix
.
When Store.Iterator()
is called, it does not simply prefix the Store.prefix
, since it does not work as intended. In that case, some of the elements are traversed even they are not starting with the prefix.
listenkv.Store
is a wrapper KVStore
which provides state listening capabilities over the underlying KVStore
.
It is applied automatically by the Cosmos SDK on any KVStore
whose StoreKey
is specified during state streaming configuration.
Additional information about state streaming configuration can be found in the store/streaming/README.md.
+++ https://github.com/cosmos/cosmos-sdk/blob/v0.44.1/store/listenkv/store.go#L11-L18
When KVStore.Set
or KVStore.Delete
methods are called, listenkv.Store
automatically writes the operations to the set of Store.listeners
.
The SDK is in the process of transitioning to use the types listed here as the default interface for state storage. At the time of writing, these cannot be used within an application and are not directly compatible with the CommitMultiStore
and related types.
These types use the new db
sub-module of Cosmos-SDK (github.com/cosmos/cosmos-sdk/db
), rather than tmdb
(github.com/tendermint/tm-db
).
See ADR-040 for the motivations and design specifications of the change.
An interface providing only the basic CRUD functionality (Get
, Set
, Has
, and Delete
methods), without iteration or caching. This is used to partially expose components of a larger store, such as a root.Store
.
This is the new interface (or, set of interfaces) for the main client store, replacing the role of store/types.MultiStore
(v1). There are a few significant differences in behavior compared with v1:
- Commits are atomic and are performed on the entire store state; individual substores cannot be committed separately and cannot have different version numbers.
- The store's current version and version history track that of the backing
db.DBConnection
. Past versions are accessible read-only. - The set of valid substores is defined at initialization and cannot be updated dynamically in an existing store instance.
This is the main interface for persisent application state, analogous to the original CommitMultiStore
.
- Past version views are accessed with
GetVersion
, which returns aBasicMultiStore
. - Substores are accessed with
GetKVStore
. Trying to get a substore that was not defined at initialization will cause a panic. Close
must be called to release the DB resources being used by the store.
A minimal interface that only allows accessing substores. Note: substores returned by BasicMultiStore.GetKVStore
are read-only and will panic on Set
or Delete
calls.
The canonical implementation of MultiStore
is in store/v2alpha1/root
. It internally decouples the concerns of state storage and state commitment: values are stored in, and read directly from, the backing key-value database (state storage, or SS), but are also mapped in a logically separate database which generates cryptographic proofs (for state-commitment or SC).
The state-commitment component of each substore is implemented as an independent smt.Store
(see below). Internally, each substore is allocated in a logically separate partition within the same backing DB, such that commits apply to the state of all substores. Therefore, views of past versions also include the state of all substores (including SS and SC data).
This store can optionally be configured to use a different backend database instance for SC (e.g., badgerdb
for the state storage DB and memdb
for the state-commitment DB; see StoreConfig.StateCommitmentDB
).
store/v2alpha1/smt.Store
maps values into a Sparse Merkle Tree (SMT), and supports a BasicKVStore
interface as well as methods for cryptographic proof generation.
Learn about encoding {hide}