neo-go/examples/nft-nd/nft.go
2021-04-08 12:36:02 +03:00

250 lines
7.4 KiB
Go

/*
Package nft contains non-divisible non-fungible NEP11-compatible token
implementation. This token can be minted with GAS transfer to contract address,
it will hash some data (including data provided in transfer) and produce
base58-encoded string that is your NFT. Since it's based on hashing and basically
you own a hash it's HASHY.
*/
package nft
import (
"github.com/nspcc-dev/neo-go/pkg/interop"
"github.com/nspcc-dev/neo-go/pkg/interop/contract"
"github.com/nspcc-dev/neo-go/pkg/interop/iterator"
"github.com/nspcc-dev/neo-go/pkg/interop/native/crypto"
"github.com/nspcc-dev/neo-go/pkg/interop/native/gas"
"github.com/nspcc-dev/neo-go/pkg/interop/native/management"
"github.com/nspcc-dev/neo-go/pkg/interop/native/std"
"github.com/nspcc-dev/neo-go/pkg/interop/runtime"
"github.com/nspcc-dev/neo-go/pkg/interop/storage"
"github.com/nspcc-dev/neo-go/pkg/interop/util"
)
// Prefixes used for contract data storage.
const (
totalSupplyPrefix = "s"
accountPrefix = "a"
tokenPrefix = "t"
)
var (
// contractOwner is a special address that can perform some management
// functions on this contract like updating/destroying it and can also
// be used for contract address verification.
contractOwner = util.FromAddress("NX1yL5wDx3inK2qUVLRVaqCLUxYnAbv85S")
)
// Symbol returns token symbol, it's HASHY.
func Symbol() string {
return "HASHY"
}
// Decimals returns token decimals, this NFT is non-divisible, so it's 0.
func Decimals() int {
return 0
}
// TotalSupply is a contract method that returns the number of tokens minted.
func TotalSupply() int {
return totalSupply(storage.GetReadOnlyContext())
}
// totalSupply is an internal implementation of TotalSupply operating with
// given context. The number itself is stored raw in the DB with totalSupplyPrefix
// key.
func totalSupply(ctx storage.Context) int {
var res int
val := storage.Get(ctx, []byte(totalSupplyPrefix))
if val != nil {
res = val.(int)
}
return res
}
// mkAccountKey creates DB key for account specified by concatenating accountPrefix
// and account address.
func mkAccountKey(holder interop.Hash160) []byte {
res := []byte(accountPrefix)
return append(res, holder...)
}
// mkStringKey creates DB key for token specified by concatenating tokenPrefix
// and token ID.
func mkTokenKey(token []byte) []byte {
res := []byte(tokenPrefix)
return append(res, token...)
}
// BalanceOf returns the number of tokens owned by specified address.
func BalanceOf(holder interop.Hash160) int {
if len(holder) != 20 {
panic("bad owner address")
}
ctx := storage.GetReadOnlyContext()
tokens := getTokensOf(ctx, holder)
return len(tokens)
}
// getTokensOf is an internal implementation of TokensOf, tokens are stored
// as a serialized slice of strings in the DB, so it gets and unwraps them
// (or returns an empty slice).
func getTokensOf(ctx storage.Context, holder interop.Hash160) []string {
var res = []string{}
key := mkAccountKey(holder)
val := storage.Get(ctx, key)
if val != nil {
res = std.Deserialize(val.([]byte)).([]string)
}
return res
}
// setTokensOf saves current tokens owned by account if there are any,
// otherwise it just drops the appropriate key from the DB.
func setTokensOf(ctx storage.Context, holder interop.Hash160, tokens []string) {
key := mkAccountKey(holder)
if len(tokens) != 0 {
val := std.Serialize(tokens)
storage.Put(ctx, key, val)
} else {
storage.Delete(ctx, key)
}
}
// TokensOf returns an iterator with all tokens held by specified address.
func TokensOf(holder interop.Hash160) iterator.Iterator {
if len(holder) != 20 {
panic("bad owner address")
}
ctx := storage.GetReadOnlyContext()
tokens := getTokensOf(ctx, holder)
return iterator.Create(tokens)
}
// getOwnerOf returns current owner of the specified token or panics if token
// ID is invalid. Owner is stored as value of the token key (prefix + token ID).
func getOwnerOf(ctx storage.Context, token []byte) interop.Hash160 {
key := mkTokenKey(token)
val := storage.Get(ctx, key)
if val == nil {
panic("no token found")
}
return val.(interop.Hash160)
}
// setOwnerOf writes current owner of the specified token into the DB.
func setOwnerOf(ctx storage.Context, token []byte, holder interop.Hash160) {
key := mkTokenKey(token)
storage.Put(ctx, key, holder)
}
// OwnerOf returns owner of specified token.
func OwnerOf(token []byte) interop.Hash160 {
ctx := storage.GetReadOnlyContext()
return getOwnerOf(ctx, token)
}
// Transfer token from its owner to another user, notice that it only has two
// parameters because token owner can be deduced from token ID itself and RC1
// implementation doesn't yet have 'data' parameter as in NEP-17 Transfer.
func Transfer(to interop.Hash160, token []byte) bool {
if len(to) != 20 {
panic("invalid 'to' address")
}
ctx := storage.GetContext()
owner := getOwnerOf(ctx, token)
// Note that although calling script hash is not checked explicitly in
// this contract it is in fact checked for in `CheckWitness` itself.
if !runtime.CheckWitness(owner) {
return false
}
if string(owner) != string(to) {
toksOwner := getTokensOf(ctx, owner)
toksTo := getTokensOf(ctx, to)
var newToksOwner = []string{}
for _, tok := range toksOwner {
if tok != string(token) {
newToksOwner = append(newToksOwner, tok)
}
}
toksTo = append(toksTo, string(token))
setTokensOf(ctx, owner, newToksOwner)
setTokensOf(ctx, to, toksTo)
setOwnerOf(ctx, token, to)
}
postTransfer(owner, to, token)
return true
}
// postTransfer emits Transfer event and calls onNEP11Payment if needed.
func postTransfer(from interop.Hash160, to interop.Hash160, token []byte) {
runtime.Notify("Transfer", from, to, 1, token)
if management.GetContract(to) != nil {
contract.Call(to, "onNEP11Payment", contract.All, from, 1, token)
}
}
// OnNEP17Payment mints tokens if at least 10 GAS is provided. You don't call
// this method directly, instead it's called by GAS contract when you transfer
// GAS from your address to the address of this NFT contract.
func OnNEP17Payment(from interop.Hash160, amount int, data interface{}) {
if string(runtime.GetCallingScriptHash()) != gas.Hash {
panic("only GAS is accepted")
}
if amount < 10_00000000 {
panic("minting HASHY costs at least 10 GAS")
}
var tokIn = []byte{}
var ctx = storage.GetContext()
total := totalSupply(ctx)
tokIn = append(tokIn, []byte(std.Itoa(total, 10))...)
tokIn = append(tokIn, []byte(std.Itoa(amount, 10))...)
tokIn = append(tokIn, from...)
tx := runtime.GetScriptContainer()
tokIn = append(tokIn, tx.Hash...)
if data != nil {
tokIn = append(tokIn, std.Serialize(data)...)
}
tokenHash := crypto.Sha256(tokIn)
token := std.Base58Encode(tokenHash)
toksOf := getTokensOf(ctx, from)
toksOf = append(toksOf, token)
setTokensOf(ctx, from, toksOf)
setOwnerOf(ctx, []byte(token), from)
total++
storage.Put(ctx, []byte(totalSupplyPrefix), total)
postTransfer(nil, from, []byte(token))
}
// Verify allows owner to manage contract's address, including earned GAS
// transfer from contract's address to somewhere else. It just checks for transaction
// to also be signed by contract owner, so contract's witness should be empty.
func Verify() bool {
return runtime.CheckWitness(contractOwner)
}
// Destroy destroys the contract, only owner can do that.
func Destroy() {
if !Verify() {
panic("only owner can destroy")
}
management.Destroy()
}
// Update updates the contract, only owner can do that.
func Update(nef, manifest []byte) {
if !Verify() {
panic("only owner can update")
}
management.Update(nef, manifest)
}