Go implementation of NeoFS SDK. It contains high-level version-independent wrappers for structures from neofs-api-go as well as helper functions for simplifying node/dApp implementations.
Contains fixed-point Decimal
type for performing balance calculations.
Contains Extended ACL types for fine-grained access control. There is also a reference implementation of checking algorithm which is used in NeoFS node.
Contains Checksum
type encapsulating checksum as well as it's kind.
Currently Sha256 and Tillich-Zemor hashsum are in use.
owner.ID
type represents single account interacting with NeoFS. In v2 version of protocol
it is just raw bytes behing base58-encoded address
in Neo blockchain. Note that for historical reasons it contains
version prefix and checksum in addition to script-hash.
Contains Bearer token type with several NeoFS-specific methods.
In NeoFS there are 2 types of name resolution: DNS and NNS. NNS stands for Neo Name Service is just a contract deployed on a Neo blockchain. Basically, NNS is just a DNS-on-chain which can be used for resolving container nice-names as well as any other name in dApps. See our CoreDNS plugin for the example of how NNS can be integrated in DNS.
To help lightweight clients interact with NeoFS without sacrificing trust, NeoFS has a concept of session token. It is signed by client and allows any node with which a session is established to perform certain actions on behalf of the user.
Contains client for working with NeoFS.
var prmInit client.PrmInit
prmInit.SetDefaultPrivateKey(key) // private key for request signing
c, err := client.New(prmInit)
if err != nil {
return
}
var prmDial client.PrmDial
prmDial.SetServerURI("grpcs://localhost:40005") // endpoint address
err := c.Dial(prmDial)
if err != nil {
return
}
ctx, cancel := context.WithTimeout(context.Background(), 5 * time.Second)
defer cancel()
var prm client.PrmBalanceGet
prm.SetAccount(acc)
res, err := c.BalanceGet(ctx, prm)
if err != nil {
return
}
fmt.Printf("Balance for %s: %v\n", acc, res.Amount())
In NeoFS every operation can fail on multiple levels, so a single error
doesn't suffice,
e.g. consider a case when object was put on 4 out of 5 replicas. Thus, all request execution
details are contained in Status
returned from every RPC call. dApp can inspect them
if needed and perform any desired action. In the case above we may want to report
these details to the user as well as retry an operation, possibly with different parameters.
Status wire-format is extendable and each node can report any set of details it wants.
The set of reserved status codes can be found in
NeoFS API.
Contains helpers allowing conversion of placing policy from/to JSON representation and SQL-like human-readable language.
p, _ := policy.Parse(`
REP 2
SELECT 6 FROM F
FILTER StorageType EQ SSD AS F`)
// Convert parsed policy back to human-readable text and print.
println(strings.Join(policy.Encode(p), "\n"))
Contains CRUSH-like implementation of container node selection algorithm. Relevant details are described in this paper http://ceur-ws.org/Vol-2344/short10.pdf . Note that it can be outdated in some details.
netmap/json_tests
subfolder contains language-agnostic tests for selection algorithm.
import (
"github.com/nspcc-dev/neofs-sdk-go/netmap"
"github.com/nspcc-dev/neofs-sdk-go/object"
)
func placementNodes(addr *object.Address, p *netmap.PlacementPolicy, neofsNodes []netmap.NodeInfo) {
// Convert list of nodes in NeoFS API format to the intermediate representation.
nodes := netmap.NodesFromInfo(nodes)
// Create new netmap (errors are skipped for the sake of clarity).
nm, _ := NewNetmap(nodes)
// Calculate nodes of container.
cn, _ := nm.GetContainerNodes(p, addr.ContainerID().ToV2().GetValue())
// Return list of nodes for each replica to place object on in the order of priority.
return nm.GetPlacementVectors(cn, addr.ObjectID().ToV2().GetValue())
}
Simple pool for managing connections to NeoFS nodes.
Contain simple API wrappers.
Wrapper over zap.Logger
which is used across NeoFS codebase.
Utilities for working with signature-related code.