--- id: tezos-specific title: Tezos Domain-Specific Operations --- LIGO is a programming language for writing Tezos smart contracts. It would be a little odd if it did not have any Tezos specific functions. This page will tell you about them. ## Pack and unpack Michelson provides the `PACK` and `UNPACK` instructions for data serialization. The instruction `PACK` converts Michelson data structures into a binary format, and `UNPACK` reverses that transformation. This functionality can be accessed from within LIGO. > ⚠️ `PACK` and `UNPACK` are Michelson instructions that are intended > to be used by people that really know what they are doing. There are > several risks and failure cases, such as unpacking a lambda from an > untrusted source, and most of which are beyond the scope of this > document. Do not use these functions without doing your homework > first. ```pascaligo group=a function id_string (const p : string) : option (string) is block { const packed : bytes = bytes_pack (p) } with (bytes_unpack (packed): option (string)) ``` ```cameligo group=a let id_string (p : string) : string option = let packed: bytes = Bytes.pack p in (Bytes.unpack packed : string option) ``` ```reasonligo group=a let id_string = (p : string) : option (string) => { let packed : bytes = Bytes.pack (p); (Bytes.unpack(packed) : option (string)); }; ``` ## Hashing Keys It is often desirable to hash a public key. In Michelson, certain data structures such as maps will not allow the use of the `key` type. Even if this were not the case, hashes are much smaller than keys, and storage on blockchains comes at a cost premium. You can hash keys an predefined function returning a value of type `key_hash`. ```pascaligo group=b function check_hash_key (const kh1 : key_hash; const k2 : key) : bool * key_hash is block { var ret : bool := False; var kh2 : key_hash := crypto_hash_key (k2); if kh1 = kh2 then ret := True else skip } with (ret, kh2) ``` ```cameligo group=b let check_hash_key (kh1, k2 : key_hash * key) : bool * key_hash = let kh2 : key_hash = Crypto.hash_key k2 in if kh1 = kh2 then true, kh2 else false, kh2 ``` ```reasonligo group=b let check_hash_key = ((kh1, k2) : (key_hash, key)) : (bool, key_hash) => { let kh2 : key_hash = Crypto.hash_key(k2); if (kh1 == kh2) { (true, kh2); } else { (false, kh2); } }; ``` ## Checking Signatures Sometimes a contract will want to check that a message has been signed by a particular key. For example, a point-of-sale system might want a customer to sign a transaction so it can be processed asynchronously. You can do this in LIGO using the `key` and `signature` types. > ⚠️ There is no way to *generate* a signed message in LIGO. This is > because that would require storing a private key on chain, at which > point it is not... private anymore. ```pascaligo group=c function check_signature (const pk : key; const signed : signature; const msg : bytes) : bool is crypto_check (pk, signed, msg) ``` ```cameligo group=c let check_signature (pk, signed, msg : key * signature * bytes) : bool = Crypto.check pk signed msg ``` ```reasonligo group=c let check_signature = ((pk, signed, msg) : (key, signature, bytes)) : bool => { Crypto.check (pk, signed, msg); }; ``` ## Getting the contract's own address Often you want to get the address of the contract being executed. You can do it with `self_address`. > ⚠️ Due to limitations in Michelson, `self_address` in a contract is > only allowed at the entry-point level (a.k.a top-level). Using it in > an auxiliaru function will cause an error. ```pascaligo group=d const current_addr : address = self_address ``` ```cameligo group=d let current_addr : address = Current.self_address ``` ```reasonligo group=d let current_addr : address = Current.self_address; ```