package actor_test import ( "context" "encoding/json" "os" "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" "github.com/nspcc-dev/neo-go/pkg/rpcclient/actor" "github.com/nspcc-dev/neo-go/pkg/rpcclient/neo" "github.com/nspcc-dev/neo-go/pkg/rpcclient/policy" sccontext "github.com/nspcc-dev/neo-go/pkg/smartcontract/context" "github.com/nspcc-dev/neo-go/pkg/util" "github.com/nspcc-dev/neo-go/pkg/vm/vmstate" "github.com/nspcc-dev/neo-go/pkg/wallet" ) func ExampleActor() { // No error checking done at all, intentionally. w, _ := wallet.NewWalletFromFile("somewhere") defer w.Close() c, _ := rpcclient.New(context.Background(), "url", rpcclient.Options{}) // Create a simple CalledByEntry-scoped actor (assuming there are accounts // inside the wallet). a, _ := actor.NewSimple(c, w.Accounts[0]) customContract := util.Uint160{9, 8, 7} // Actor has an Invoker inside, so we can perform test invocations, it will // have a signer with the first wallet account and CalledByEntry scope. res, _ := a.Call(customContract, "method", 1, 2, 3) if res.State != vmstate.Halt.String() { // The call failed. } // All of the side-effects in res can be analyzed. // Now we want to send the same invocation in a transaction, but we already // have the script and a proper system fee for it, therefore SendUncheckedRun // can be used. txid, vub, _ := a.SendUncheckedRun(res.Script, res.GasConsumed, nil, nil) _ = txid _ = vub // You need to wait for it to persist and then check the on-chain result of it. // Now we want to send some transaction, but give it a priority by increasing // its network fee, this can be done with Tuned APIs. txid, vub, _ = a.SendTunedCall(customContract, "method", nil, func(r *result.Invoke, t *transaction.Transaction) error { // This code is run after the test-invocation done by *Call methods. // Reuse the default function to check for HALT execution state. err := actor.DefaultCheckerModifier(r, t) if err != nil { return err } // Some additional checks can be performed right here, but we only // want to raise the network fee by ~20%. t.NetworkFee += (t.NetworkFee / 5) return nil }, 1, 2, 3) _ = txid _ = vub // Actor can be used for higher-level wrappers as well, if we want to interact with // NEO then [neo] package can accept our Actor and allow to easily use NEO methods. neoContract := neo.New(a) balance, _ := neoContract.BalanceOf(a.Sender()) _ = balance // Now suppose the second wallet account is a committee account. We want to // create and sign transactions for committee, but use the first account as // a sender (because committee account has no GAS). We at the same time want // to make all transactions using this actor high-priority ones, because // committee can use this attribute. // Get the default options to have CheckerModifier/Modifier set up correctly. opts := actor.NewDefaultOptions() // And override attributes. opts.Attributes = []transaction.Attribute{{Type: transaction.HighPriority}} // Create an Actor. a, _ = actor.NewTuned(c, []actor.SignerAccount{{ // Sender, regular account with None scope. Signer: transaction.Signer{ Account: w.Accounts[0].ScriptHash(), Scopes: transaction.None, }, Account: w.Accounts[0], }, { // Commmitee. Signer: transaction.Signer{ Account: w.Accounts[1].ScriptHash(), Scopes: transaction.CalledByEntry, }, Account: w.Accounts[1], }}, opts) // Use policy contract wrapper to simplify things. All changes in the // Policy contract are made by the committee. policyContract := policy.New(a) // Create a transaction to set storage price, it'll be high-priority and have two // signers from above. Committee is a multisignature account, so we can't sign/send // it right away, w.Accounts[1] has only one public key. Therefore, we need to // create a partially signed transaction and save it, then collect other signatures // and send. tx, _ := policyContract.SetStoragePriceUnsigned(10) net := a.GetNetwork() scCtx := sccontext.NewParameterContext(sccontext.TransactionType, net, tx) sign := w.Accounts[0].SignHashable(net, tx) _ = scCtx.AddSignature(w.Accounts[0].ScriptHash(), w.Accounts[0].Contract, w.Accounts[0].PublicKey(), sign) sign = w.Accounts[1].SignHashable(net, tx) _ = scCtx.AddSignature(w.Accounts[1].ScriptHash(), w.Accounts[1].Contract, w.Accounts[1].PublicKey(), sign) data, _ := json.Marshal(scCtx) _ = os.WriteFile("tx.json", data, 0644) // Signature collection is out of scope, usually it's manual for cases like this. }