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ExampleNFT.cdc
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ExampleNFT.cdc
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/*
*
* This is an example implementation of a Flow Non-Fungible Token
* using the V2 standard.
* It is not part of the official standard but it assumed to be
* similar to how many NFTs would implement the core functionality.
*
* This contract does not implement any sophisticated classification
* system for its NFTs. It defines a simple NFT with minimal metadata.
*
*/
import "NonFungibleToken"
import "ViewResolver"
import "MetadataViews"
access(all) contract ExampleNFT: NonFungibleToken {
/// Standard Paths
access(all) let CollectionStoragePath: StoragePath
access(all) let CollectionPublicPath: PublicPath
/// Path where the minter should be stored
/// The standard paths for the collection are stored in the collection resource type
access(all) let MinterStoragePath: StoragePath
/// We choose the name NFT here, but this type can have any name now
/// because the interface does not require it to have a specific name any more
access(all) resource NFT: NonFungibleToken.NFT {
access(all) let id: UInt64
/// From the Display metadata view
access(all) let name: String
access(all) let description: String
access(all) let thumbnail: String
/// For the Royalties metadata view
access(self) let royalties: [MetadataViews.Royalty]
/// Generic dictionary of traits the NFT has
access(self) let metadata: {String: AnyStruct}
init(
name: String,
description: String,
thumbnail: String,
royalties: [MetadataViews.Royalty],
metadata: {String: AnyStruct},
) {
self.id = self.uuid
self.name = name
self.description = description
self.thumbnail = thumbnail
self.royalties = royalties
self.metadata = metadata
}
/// createEmptyCollection creates an empty Collection
/// and returns it to the caller so that they can own NFTs
/// @{NonFungibleToken.Collection}
access(all) fun createEmptyCollection(): @{NonFungibleToken.Collection} {
return <-ExampleNFT.createEmptyCollection(nftType: Type<@ExampleNFT.NFT>())
}
access(all) view fun getViews(): [Type] {
return [
Type<MetadataViews.Display>(),
Type<MetadataViews.Royalties>(),
Type<MetadataViews.Editions>(),
Type<MetadataViews.ExternalURL>(),
Type<MetadataViews.NFTCollectionData>(),
Type<MetadataViews.NFTCollectionDisplay>(),
Type<MetadataViews.Serial>(),
Type<MetadataViews.Traits>(),
Type<MetadataViews.EVMBridgedMetadata>()
]
}
access(all) fun resolveView(_ view: Type): AnyStruct? {
switch view {
case Type<MetadataViews.Display>():
return MetadataViews.Display(
name: self.name,
description: self.description,
thumbnail: MetadataViews.HTTPFile(
url: self.thumbnail
)
)
case Type<MetadataViews.Editions>():
// There is no max number of NFTs that can be minted from this contract
// so the max edition field value is set to nil
let editionInfo = MetadataViews.Edition(name: "Example NFT Edition", number: self.id, max: nil)
let editionList: [MetadataViews.Edition] = [editionInfo]
return MetadataViews.Editions(
editionList
)
case Type<MetadataViews.Serial>():
return MetadataViews.Serial(
self.id
)
case Type<MetadataViews.Royalties>():
return MetadataViews.Royalties(
self.royalties
)
case Type<MetadataViews.ExternalURL>():
return MetadataViews.ExternalURL("https://example-nft.onflow.org/".concat(self.id.toString()))
case Type<MetadataViews.NFTCollectionData>():
return ExampleNFT.resolveContractView(resourceType: Type<@ExampleNFT.NFT>(), viewType: Type<MetadataViews.NFTCollectionData>())
case Type<MetadataViews.NFTCollectionDisplay>():
return ExampleNFT.resolveContractView(resourceType: Type<@ExampleNFT.NFT>(), viewType: Type<MetadataViews.NFTCollectionDisplay>())
case Type<MetadataViews.Traits>():
// exclude mintedTime and foo to show other uses of Traits
let excludedTraits = ["mintedTime", "foo"]
let traitsView = MetadataViews.dictToTraits(dict: self.metadata, excludedNames: excludedTraits)
// mintedTime is a unix timestamp, we should mark it with a displayType so platforms know how to show it.
let mintedTimeTrait = MetadataViews.Trait(name: "mintedTime", value: self.metadata["mintedTime"]!, displayType: "Date", rarity: nil)
traitsView.addTrait(mintedTimeTrait)
// foo is a trait with its own rarity
let fooTraitRarity = MetadataViews.Rarity(score: 10.0, max: 100.0, description: "Common")
let fooTrait = MetadataViews.Trait(name: "foo", value: self.metadata["foo"], displayType: nil, rarity: fooTraitRarity)
traitsView.addTrait(fooTrait)
return traitsView
case Type<MetadataViews.EVMBridgedMetadata>():
// Implementing this view gives the project control over how the bridged NFT is represented as an
// ERC721 when bridged to EVM on Flow via the public infrastructure bridge.
// Get the contract-level name and symbol values
let contractLevel = ExampleNFT.resolveContractView(
resourceType: nil,
viewType: Type<MetadataViews.EVMBridgedMetadata>()
) as! MetadataViews.EVMBridgedMetadata?
if let contractMetadata = contractLevel {
// Compose the token-level URI based on a base URI and the token ID, pointing to a JSON file. This
// would be a file you've uploaded and are hosting somewhere - in this case HTTP, but this could be
// IPFS, S3, a data URL containing the JSON directly, etc.
let baseURI = "https://example-nft.onflow.org/token-metadata/"
let uriValue = self.id.toString().concat(".json")
return MetadataViews.EVMBridgedMetadata(
name: contractMetadata.name,
symbol: contractMetadata.symbol,
uri: MetadataViews.URI(
baseURI: baseURI, // defining baseURI results in a concatenation of baseURI and value
value: self.id.toString().concat(".json")
)
)
} else {
return nil
}
}
return nil
}
}
// Deprecated: Only here for backward compatibility.
access(all) resource interface ExampleNFTCollectionPublic {}
access(all) resource Collection: NonFungibleToken.Collection, ExampleNFTCollectionPublic {
/// dictionary of NFT conforming tokens
/// NFT is a resource type with an `UInt64` ID field
access(all) var ownedNFTs: @{UInt64: {NonFungibleToken.NFT}}
init () {
self.ownedNFTs <- {}
}
/// getSupportedNFTTypes returns a list of NFT types that this receiver accepts
access(all) view fun getSupportedNFTTypes(): {Type: Bool} {
let supportedTypes: {Type: Bool} = {}
supportedTypes[Type<@ExampleNFT.NFT>()] = true
return supportedTypes
}
/// Returns whether or not the given type is accepted by the collection
/// A collection that can accept any type should just return true by default
access(all) view fun isSupportedNFTType(type: Type): Bool {
return type == Type<@ExampleNFT.NFT>()
}
/// withdraw removes an NFT from the collection and moves it to the caller
access(NonFungibleToken.Withdraw) fun withdraw(withdrawID: UInt64): @{NonFungibleToken.NFT} {
let token <- self.ownedNFTs.remove(key: withdrawID)
?? panic("ExampleNFT.Collection.withdraw: Could not withdraw an NFT with ID "
.concat(withdrawID.toString())
.concat(". Check the submitted ID to make sure it is one that this collection owns."))
return <-token
}
/// deposit takes a NFT and adds it to the collections dictionary
/// and adds the ID to the id array
access(all) fun deposit(token: @{NonFungibleToken.NFT}) {
let token <- token as! @ExampleNFT.NFT
let id = token.id
// add the new token to the dictionary which removes the old one
let oldToken <- self.ownedNFTs[token.id] <- token
destroy oldToken
// This code is for testing purposes only
// Do not add to your contract unless you have a specific
// reason to want to emit the NFTUpdated event somewhere
// in your contract
let authTokenRef = (&self.ownedNFTs[id] as auth(NonFungibleToken.Update) &{NonFungibleToken.NFT}?)!
//authTokenRef.updateTransferDate(date: getCurrentBlock().timestamp)
ExampleNFT.emitNFTUpdated(authTokenRef)
}
/// getIDs returns an array of the IDs that are in the collection
access(all) view fun getIDs(): [UInt64] {
return self.ownedNFTs.keys
}
/// Gets the amount of NFTs stored in the collection
access(all) view fun getLength(): Int {
return self.ownedNFTs.length
}
access(all) view fun borrowNFT(_ id: UInt64): &{NonFungibleToken.NFT}? {
return &self.ownedNFTs[id]
}
/// Borrow the view resolver for the specified NFT ID
access(all) view fun borrowViewResolver(id: UInt64): &{ViewResolver.Resolver}? {
if let nft = &self.ownedNFTs[id] as &{NonFungibleToken.NFT}? {
return nft as &{ViewResolver.Resolver}
}
return nil
}
/// createEmptyCollection creates an empty Collection of the same type
/// and returns it to the caller
/// @return A an empty collection of the same type
access(all) fun createEmptyCollection(): @{NonFungibleToken.Collection} {
return <-ExampleNFT.createEmptyCollection(nftType: Type<@ExampleNFT.NFT>())
}
}
/// createEmptyCollection creates an empty Collection for the specified NFT type
/// and returns it to the caller so that they can own NFTs
access(all) fun createEmptyCollection(nftType: Type): @{NonFungibleToken.Collection} {
return <- create Collection()
}
/// Function that returns all the Metadata Views implemented by a Non Fungible Token
///
/// @return An array of Types defining the implemented views. This value will be used by
/// developers to know which parameter to pass to the resolveView() method.
///
access(all) view fun getContractViews(resourceType: Type?): [Type] {
return [
Type<MetadataViews.NFTCollectionData>(),
Type<MetadataViews.NFTCollectionDisplay>(),
Type<MetadataViews.EVMBridgedMetadata>()
]
}
/// Function that resolves a metadata view for this contract.
///
/// @param view: The Type of the desired view.
/// @return A structure representing the requested view.
///
access(all) fun resolveContractView(resourceType: Type?, viewType: Type): AnyStruct? {
switch viewType {
case Type<MetadataViews.NFTCollectionData>():
let collectionData = MetadataViews.NFTCollectionData(
storagePath: self.CollectionStoragePath,
publicPath: self.CollectionPublicPath,
publicCollection: Type<&ExampleNFT.Collection>(),
publicLinkedType: Type<&ExampleNFT.Collection>(),
createEmptyCollectionFunction: (fun(): @{NonFungibleToken.Collection} {
return <-ExampleNFT.createEmptyCollection(nftType: Type<@ExampleNFT.NFT>())
})
)
return collectionData
case Type<MetadataViews.NFTCollectionDisplay>():
let media = MetadataViews.Media(
file: MetadataViews.HTTPFile(
url: "https://assets.website-files.com/5f6294c0c7a8cdd643b1c820/5f6294c0c7a8cda55cb1c936_Flow_Wordmark.svg"
),
mediaType: "image/svg+xml"
)
return MetadataViews.NFTCollectionDisplay(
name: "The Example Collection",
description: "This collection is used as an example to help you develop your next Flow NFT.",
externalURL: MetadataViews.ExternalURL("https://example-nft.onflow.org"),
squareImage: media,
bannerImage: media,
socials: {
"twitter": MetadataViews.ExternalURL("https://twitter.com/flow_blockchain")
}
)
case Type<MetadataViews.EVMBridgedMetadata>():
// Implementing this view gives the project control over how the bridged NFT is represented as an ERC721
// when bridged to EVM on Flow via the public infrastructure bridge.
// Compose the contract-level URI. In this case, the contract metadata is located on some HTTP host,
// but it could be IPFS, S3, a data URL containing the JSON directly, etc.
return MetadataViews.EVMBridgedMetadata(
name: "ExampleNFT",
symbol: "XMPL",
uri: MetadataViews.URI(
baseURI: nil, // setting baseURI as nil sets the given value as the uri field value
value: "https://example-nft.onflow.org/contract-metadata.json"
)
)
}
return nil
}
/// Resource that an admin or something similar would own to be
/// able to mint new NFTs
///
access(all) resource NFTMinter {
/// mintNFT mints a new NFT with a new ID
/// and returns it to the calling context
access(all) fun mintNFT(
name: String,
description: String,
thumbnail: String,
royalties: [MetadataViews.Royalty]
): @ExampleNFT.NFT {
let metadata: {String: AnyStruct} = {}
let currentBlock = getCurrentBlock()
metadata["mintedBlock"] = currentBlock.height
metadata["mintedTime"] = currentBlock.timestamp
// this piece of metadata will be used to show embedding rarity into a trait
metadata["foo"] = "bar"
// create a new NFT
var newNFT <- create NFT(
name: name,
description: description,
thumbnail: thumbnail,
royalties: royalties,
metadata: metadata,
)
return <-newNFT
}
}
init() {
// Set the named paths
self.CollectionStoragePath = /storage/exampleNFTCollection
self.CollectionPublicPath = /public/exampleNFTCollection
self.MinterStoragePath = /storage/exampleNFTMinter
// Create a Collection resource and save it to storage
let collection <- create Collection()
self.account.storage.save(<-collection, to: self.CollectionStoragePath)
// create a public capability for the collection
let collectionCap = self.account.capabilities.storage.issue<&ExampleNFT.Collection>(self.CollectionStoragePath)
self.account.capabilities.publish(collectionCap, at: self.CollectionPublicPath)
// Create a Minter resource and save it to storage
let minter <- create NFTMinter()
self.account.storage.save(<-minter, to: self.MinterStoragePath)
}
}