/* Package nep11 contains RPC wrappers for NEP-11 contracts. The set of types provided is split between common NEP-11 methods (BaseReader and Base types) and divisible (DivisibleReader and Divisible) and non-divisible (NonDivisibleReader and NonDivisible). If you don't know the type of NEP-11 contract you're going to use you can use Base and BaseReader types for many purposes, otherwise more specific types are recommended. */ package nep11 import ( "fmt" "math/big" "unicode/utf8" "github.com/google/uuid" "github.com/nspcc-dev/neo-go/pkg/core/transaction" "github.com/nspcc-dev/neo-go/pkg/neorpc/result" "github.com/nspcc-dev/neo-go/pkg/rpcclient/neptoken" "github.com/nspcc-dev/neo-go/pkg/rpcclient/unwrap" "github.com/nspcc-dev/neo-go/pkg/smartcontract" "github.com/nspcc-dev/neo-go/pkg/util" "github.com/nspcc-dev/neo-go/pkg/vm/stackitem" ) // Invoker is used by reader types to call various methods. type Invoker interface { neptoken.Invoker CallAndExpandIterator(contract util.Uint160, method string, maxItems int, params ...interface{}) (*result.Invoke, error) TerminateSession(sessionID uuid.UUID) error TraverseIterator(sessionID uuid.UUID, iterator *result.Iterator, num int) ([]stackitem.Item, error) } // Actor is used by complete NEP-11 types to create and send transactions. type Actor interface { Invoker MakeRun(script []byte) (*transaction.Transaction, error) MakeUnsignedRun(script []byte, attrs []transaction.Attribute) (*transaction.Transaction, error) SendRun(script []byte) (util.Uint256, uint32, error) } // BaseReader is a reader interface for common divisible and non-divisible NEP-11 // methods. It allows to invoke safe methods. type BaseReader struct { neptoken.Base invoker Invoker hash util.Uint160 } // Base is a state-changing interface for common divisible and non-divisible NEP-11 // methods. type Base struct { BaseReader actor Actor } // TransferEvent represents a Transfer event as defined in the NEP-11 standard. type TransferEvent struct { From util.Uint160 To util.Uint160 Amount *big.Int ID []byte } // TokenIterator is used for iterating over TokensOf results. type TokenIterator struct { client Invoker session uuid.UUID iterator result.Iterator } // NewBaseReader creates an instance of BaseReader for a contract with the given // hash using the given invoker. func NewBaseReader(invoker Invoker, hash util.Uint160) *BaseReader { return &BaseReader{*neptoken.New(invoker, hash), invoker, hash} } // NewBase creates an instance of Base for contract with the given // hash using the given actor. func NewBase(actor Actor, hash util.Uint160) *Base { return &Base{*NewBaseReader(actor, hash), actor} } // BalanceOf returns the number of NFTs owned by the given account. For divisible // NFTs that's the sum of all parts of tokens. func (t *BaseReader) BalanceOf(account util.Uint160) (*big.Int, error) { return unwrap.BigInt(t.invoker.Call(t.hash, "balanceOf", account)) } // Properties returns a set of token's properties such as name or URL. The map // is returned as is from this method (stack item) for maximum flexibility, // contracts can return a lot of specific data there. Most of the time though // they return well-defined properties outlined in NEP-11 and // UnwrapKnownProperties can be used to get them in more convenient way. It's an // optional method per NEP-11 specification, so it can fail. func (t *BaseReader) Properties(token []byte) (*stackitem.Map, error) { return unwrap.Map(t.invoker.Call(t.hash, "properties", token)) } // Tokens returns an iterator that allows to retrieve all tokens minted by the // contract. It depends on the server to provide proper session-based // iterator, but can also work with expanded one. The method itself is optional // per NEP-11 specification, so it can fail. func (t *BaseReader) Tokens() (*TokenIterator, error) { sess, iter, err := unwrap.SessionIterator(t.invoker.Call(t.hash, "tokens")) if err != nil { return nil, err } return &TokenIterator{t.invoker, sess, iter}, nil } // TokensExpanded uses the same NEP-11 method as Tokens, but can be useful if // the server used doesn't support sessions and doesn't expand iterators. It // creates a script that will get num of result items from the iterator right in // the VM and return them to you. It's only limited by VM stack and GAS available // for RPC invocations. func (t *BaseReader) TokensExpanded(num int) ([][]byte, error) { return unwrap.ArrayOfBytes(t.invoker.CallAndExpandIterator(t.hash, "tokens", num)) } // TokensOf returns an iterator that allows to walk through all tokens owned by // the given account. It depends on the server to provide proper session-based // iterator, but can also work with expanded one. func (t *BaseReader) TokensOf(account util.Uint160) (*TokenIterator, error) { sess, iter, err := unwrap.SessionIterator(t.invoker.Call(t.hash, "tokensOf", account)) if err != nil { return nil, err } return &TokenIterator{t.invoker, sess, iter}, nil } // TokensOfExpanded uses the same NEP-11 method as TokensOf, but can be useful if // the server used doesn't support sessions and doesn't expand iterators. It // creates a script that will get num of result items from the iterator right in // the VM and return them to you. It's only limited by VM stack and GAS available // for RPC invocations. func (t *BaseReader) TokensOfExpanded(account util.Uint160, num int) ([][]byte, error) { return unwrap.ArrayOfBytes(t.invoker.CallAndExpandIterator(t.hash, "tokensOf", num, account)) } // Transfer creates and sends a transaction that performs a `transfer` method // call using the given parameters and checks for this call result, failing the // transaction if it's not true. It works for divisible NFTs only when there is // one owner for the particular token. The returned values are transaction hash, // its ValidUntilBlock value and an error if any. func (t *Base) Transfer(to util.Uint160, id []byte, data interface{}) (util.Uint256, uint32, error) { script, err := t.transferScript(to, id, data) if err != nil { return util.Uint256{}, 0, err } return t.actor.SendRun(script) } // TransferTransaction creates a transaction that performs a `transfer` method // call using the given parameters and checks for this call result, failing the // transaction if it's not true. It works for divisible NFTs only when there is // one owner for the particular token. This transaction is signed, but not sent // to the network, instead it's returned to the caller. func (t *Base) TransferTransaction(to util.Uint160, id []byte, data interface{}) (*transaction.Transaction, error) { script, err := t.transferScript(to, id, data) if err != nil { return nil, err } return t.actor.MakeRun(script) } // TransferUnsigned creates a transaction that performs a `transfer` method // call using the given parameters and checks for this call result, failing the // transaction if it's not true. It works for divisible NFTs only when there is // one owner for the particular token. This transaction is not signed and just // returned to the caller. func (t *Base) TransferUnsigned(to util.Uint160, id []byte, data interface{}) (*transaction.Transaction, error) { script, err := t.transferScript(to, id, data) if err != nil { return nil, err } return t.actor.MakeUnsignedRun(script, nil) } func (t *Base) transferScript(params ...interface{}) ([]byte, error) { return smartcontract.CreateCallWithAssertScript(t.hash, "transfer", params...) } // Next returns the next set of elements from the iterator (up to num of them). // It can return less than num elements in case iterator doesn't have that many // or zero elements if the iterator has no more elements or the session is // expired. func (v *TokenIterator) Next(num int) ([][]byte, error) { items, err := v.client.TraverseIterator(v.session, &v.iterator, num) if err != nil { return nil, err } res := make([][]byte, len(items)) for i := range items { b, err := items[i].TryBytes() if err != nil { return nil, fmt.Errorf("element %d is not a byte string: %w", i, err) } res[i] = b } return res, nil } // Terminate closes the iterator session used by TokenIterator (if it's // session-based). func (v *TokenIterator) Terminate() error { if v.iterator.ID == nil { return nil } return v.client.TerminateSession(v.session) } // UnwrapKnownProperties can be used as a proxy function to extract well-known // NEP-11 properties (name/description/image/tokenURI) defined in the standard. // These properties are checked to be valid UTF-8 strings, but can contain // control codes or special characters. func UnwrapKnownProperties(m *stackitem.Map, err error) (map[string]string, error) { if err != nil { return nil, err } elems := m.Value().([]stackitem.MapElement) res := make(map[string]string) for _, e := range elems { k, err := e.Key.TryBytes() if err != nil { // Shouldn't ever happen in the valid Map, but. continue } ks := string(k) if !result.KnownNEP11Properties[ks] { // Some additional elements are OK. continue } v, err := e.Value.TryBytes() if err != nil { // But known ones MUST be proper strings. return nil, fmt.Errorf("invalid %s property: %w", ks, err) } if !utf8.Valid(v) { return nil, fmt.Errorf("invalid %s property: not a UTF-8 string", ks) } res[ks] = string(v) } return res, nil }