--- id: entrypoints-contracts title: Entrypoints, Contracts --- ## Entrypoints Each LIGO smart contract is essentially a single function, that has the following *(pseudo)* type signature: ``` (const parameter: my_type, const store: my_store_type): (list(operation), my_store_type) ``` ``` (parameter, store: my_type * my_store_type) : operation list * my_store_type ``` ``` (parameter_store: (my_type, my_store_type)) : (list(operation), my_store_type) ``` This means that every smart contract needs at least one entrypoint function, here's an example: > 💡 The contract below literally does *nothing* ```pascaligo group=a type parameter is unit; type store is unit; function main(const parameter: parameter; const store: store): (list(operation) * store) is block { skip } with ((nil : list(operation)), store) ``` ```cameligo group=a type parameter = unit type store = unit let main (parameter, store: parameter * store) : operation list * store = (([]: operation list), store) ``` ```reasonligo group=a type parameter = unit; type store = unit; let main = (parameter_store: (parameter, store)) : (list(operation), store) => { let parameter, store = parameter_store; (([]: list(operation)), store); }; ``` Each entrypoint function receives two arguments: - `parameter` - this is the parameter received in the invocation operation - `storage` - this is the current (real) on-chain storage value Storage can only be modified by running the smart contract entrypoint, which is responsible for returning a list of operations, and a new storage at the end of its execution. ## Built-in contract variables Each LIGO smart contract deployed on the Tezos blockchain, has access to certain built-in variables/constants that can be used to determine a range of useful things. In this section you'll find how those built-ins can be utilized. ### Accepting/declining money in a smart contract This example shows how `amount` and `failwith` can be used to decline a transaction that sends more tez than `0mutez`. ```pascaligo group=b function main (const p : unit ; const s : unit) : (list(operation) * unit) is block { if amount > 0mutez then failwith("This contract does not accept tez") else skip } with ((nil : list(operation)), unit); ``` ```cameligo group=b let main (p, s: unit * unit) : operation list * unit = if amount > 0mutez then (failwith "This contract does not accept tez": operation list * unit) else (([]: operation list), unit) ``` ```reasonligo group=b let main = (p_s: (unit, unit)) : (list(operation), unit) => { if (amount > 0mutez) { (failwith("This contract does not accept tez"): (list(operation), unit)); } else { (([]: list(operation)), ()); }; }; ``` ### Access Control This example shows how `sender` or `source` can be used to deny access to an entrypoint. ```pascaligo group=c const owner: address = ("tz1KqTpEZ7Yob7QbPE4Hy4Wo8fHG8LhKxZSx": address); function main (const p : unit ; const s : unit) : (list(operation) * unit) is block { if source =/= owner then failwith("This address can't call the contract") else skip } with ((nil : list(operation)), unit); ``` ```cameligo group=c let owner: address = ("tz1KqTpEZ7Yob7QbPE4Hy4Wo8fHG8LhKxZSx": address) let main (p,s: unit * unit) : operation list * unit = if source <> owner then (failwith "This address can't call the contract": operation list * unit) else (([]: operation list), ()) ``` ```reasonligo group=c let owner: address = ("tz1KqTpEZ7Yob7QbPE4Hy4Wo8fHG8LhKxZSx": address); let main = (p_s: (unit, unit)) : (list(operation), unit) => { if (source != owner) { (failwith("This address can't call the contract"): (list(operation), unit)); } else { (([]: list(operation)), ()); }; }; ``` ### Cross contract calls This example shows how a contract can invoke another contract by emiting a transaction operation at the end of an entrypoint. > The same technique can be used to transfer tez to an implicit account (tz1, ...), all you have to do is use `unit` instead of a parameter for a smart contract. In our case, we have a `counter.ligo` contract that accepts a parameter of type `action`, and we have a `proxy.ligo` contract that accepts the same parameter type, and forwards the call to the deployed counter contract. ```pascaligo // counter.ligo type action is | Increment of int | Decrement of int | Reset of unit ``` ```pascaligo skip // proxy.ligo type action is | Increment of int | Decrement of int | Reset of unit const dest: address = ("KT19wgxcuXG9VH4Af5Tpm1vqEKdaMFpznXT3": address); function proxy(const param: action; const store: unit): (list(operation) * unit) is block { const counter: contract(action) = get_contract(dest); // re-use the param passed to the proxy in the subsequent transaction // e.g.: // const mockParam: action = Increment(5); const op: operation = transaction(param, 0mutez, counter); const opList: list(operation) = list op; end; } with (opList, store) ``` ```cameligo // counter.mligo type action = | Increment of int | Decrement of int | Reset of unit // ... ``` ```cameligo // proxy.mligo type action = | Increment of int | Decrement of int | Reset of unit let dest: address = ("KT19wgxcuXG9VH4Af5Tpm1vqEKdaMFpznXT3": address) let proxy (param, storage: action * unit): operation list * unit = let counter: action contract = Operation.get_contract dest in let op: operation = Operation.transaction param 0mutez counter in [op], storage ``` ```reasonligo // counter.religo type action = | Increment(int) | Decrement(int) | Reset(unit); // ... ``` ```reasonligo // proxy.religo type action = | Increment(int) | Decrement(int) | Reset(unit); let dest: address = ("KT19wgxcuXG9VH4Af5Tpm1vqEKdaMFpznXT3": address); let proxy = (param_s: (action, unit)): (list(operation), unit) => let counter: contract(action) = Operation.get_contract(dest); let op: operation = Operation.transaction(param_s[0], 0mutez, counter); ([op], param_s[1]); ```