package hash import ( "crypto/sha256" "encoding/binary" "github.com/nspcc-dev/neo-go/pkg/util" "golang.org/x/crypto/ripemd160" //nolint:staticcheck // SA1019: package golang.org/x/crypto/ripemd160 is deprecated ) // Hashable represents an object which can be hashed. Usually, these objects // are io.Serializable and signable. They tend to cache the hash inside for // effectiveness, providing this accessor method. Anything that can be // identified with a hash can then be signed and verified. type Hashable interface { Hash() util.Uint256 } func getSignedData(net uint32, hh Hashable) []byte { var b = make([]byte, 4+32) binary.LittleEndian.PutUint32(b, net) h := hh.Hash() copy(b[4:], h[:]) return b } // NetSha256 calculates a network-specific hash of the Hashable item that can then // be signed/verified. func NetSha256(net uint32, hh Hashable) util.Uint256 { return Sha256(getSignedData(net, hh)) } // Sha256 hashes the incoming byte slice // using the sha256 algorithm. func Sha256(data []byte) util.Uint256 { hash := sha256.Sum256(data) return hash } // DoubleSha256 performs sha256 twice on the given data. func DoubleSha256(data []byte) util.Uint256 { var hash util.Uint256 h1 := Sha256(data) hash = Sha256(h1.BytesBE()) return hash } // RipeMD160 performs the RIPEMD160 hash algorithm // on the given data. func RipeMD160(data []byte) util.Uint160 { var hash util.Uint160 hasher := ripemd160.New() _, _ = hasher.Write(data) hasher.Sum(hash[:0]) return hash } // Hash160 performs sha256 and then ripemd160 // on the given data. func Hash160(data []byte) util.Uint160 { h1 := Sha256(data) h2 := RipeMD160(h1.BytesBE()) return h2 } // Checksum returns the checksum for a given piece of data // using sha256 twice as the hash algorithm. func Checksum(data []byte) []byte { hash := DoubleSha256(data) return hash[:4] }