--- id: entrypoints-contracts title: Main function and Entrypoints --- ## Access Functions A LIGO contract is made of a series of constant and function declarations. Only functions having a special type can be called when the contract is activated: we called them *main functions*. A main function takes two parameters, the *contract parameter* and the *on-chain storage*, and returns a pair made of a *list of operations* and a (new) storage. When the contract is originated, the initial value of the storage is provided. When a main function is later called, only the parameter is provided, but the type of a main function contains both. The type of the contract parameter and the storage are up to the contract designer, but the type for list operations is not. The return type of a main function is as follows, assuming that the type `storage` has been defined elsewhere. (Note that you can use any type with any name for the storage.) ```pascaligo skip type storage is ... // Any name, any type type return is list (operation) * storage ``` ```cameligo skip type storage = ... // Any name, any type type return = operation list * storage ``` ```reasonligo skip type storage = ...; // Any name, any type type return = (list (operation), storage); ``` The contract storage can only be modified by activating a main function. It is important to understand what that means. What it does *not* mean is that some global variable holding the storage is modified by the main function. Instead, what it *does* mean is that, given the state of the storage *on-chain*, a main function specifies how to create another state for it, depending on a parameter. Here is an example where the storage is a single natural number that is updated by the parameter. ```pascaligo group=a type parameter is nat type storage is nat type return is list (operation) * storage function save (const action : parameter; const store : storage) : return is ((nil : list (operation)), store) ``` ```cameligo group=a type parameter = nat type storage = nat type return = operation list * storage let save (action, store: parameter * storage) : return = (([] : operation list), store) ``` ```reasonligo group=a type parameter = nat; type storage = nat; type return = (list (operation), storage); let main = ((action, store): (parameter, storage)) : return => (([] : list (operation)), store); ``` ## Entrypoints In LIGO, the design pattern is to have *one* main function called `main`, that dispatches the control flow according to its parameter. Those functions called for those actions are called *entrypoints*. As an analogy, in the C programming language, the `main` function is the unique main function and any function called from it would be an entrypoint. The parameter of the contract is then a variant type, and, depending on the constructors of that type, different functions in the contract are called. In other terms, the unique main function dispatches the control flow depending on a *pattern matching* on the contract parameter. In the following example, the storage contains a counter of type `nat` and a name of type `string`. Depending on the parameter of the contract, either the counter or the name is updated. ```pascaligo group=b type parameter is Action_A of nat | Action_B of string type storage is record [ counter : nat; name : string ] type return is list (operation) * storage function entry_A (const n : nat; const store : storage) : return is ((nil : list (operation)), store with record [counter = n]) function entry_B (const s : string; const store : storage) : return is ((nil : list (operation)), store with record [name = s]) function main (const action : parameter; const store : storage): return is case action of Action_A (n) -> entry_A (n, store) | Action_B (s) -> entry_B (s, store) end ``` ```cameligo group=b type parameter = Action_A of nat | Action_B of string type storage = { counter : nat; name : string } type return = operation list * storage let entry_A (n, store : nat * storage) : return = ([] : operation list), {store with counter = n} let entry_B (s, store : string * storage) : return = ([] : operation list), {store with name = s} let main (action, store: parameter * storage) : return = match action with Action_A n -> entry_A (n, store) | Action_B s -> entry_B (s, store) ``` ```reasonligo group=b type parameter = | Action_A (nat) | Action_B (string); type storage = { counter : nat, name : string }; type return = (list (operation), storage); let entry_A = ((n, store): (nat, storage)) : return => (([] : list (operation)), {...store, counter : n}); let entry_B = ((s, store): (string, storage)) : return => (([] : list (operation)), {...store, name : s}); let main = ((action, store): (parameter, storage)) : return => switch (action) { | Action_A (n) => entry_A ((n, store)) | Action_B (s) => entry_B ((s, store)) }; ``` ## Tezos-specific Built-ins A LIGO smart contract can query part of the state of the Tezos blockchain by means of built-in values. In this section you will find how those built-ins can be utilized. ### Accepting or Declining Tokens in a Smart Contract This example shows how `amount` and `failwith` can be used to decline any transaction that sends more tez than `0mutez`, that is, no incoming tokens are accepted. ```pascaligo group=c type parameter is unit type storage is unit type return is list (operation) * storage function deny (const action : parameter; const store : storage) : return is if amount > 0mutez then (failwith ("This contract does not accept tokens.") : return) else ((nil : list (operation)), store) ``` ```cameligo group=c type parameter = unit type storage = unit type return = operation list * storage let deny (action, store : parameter * storage) : return = if amount > 0mutez then (failwith "This contract does not accept tokens.": return) else (([] : operation list), store) ``` ```reasonligo group=c type parameter = unit; type storage = unit; type return = (list (operation), storage); let deny = ((action, store): (parameter, storage)) : return => { if (amount > 0mutez) { (failwith("This contract does not accept tokens."): return); } else { (([] : list (operation)), store); }; }; ``` ### 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 action : parameter; const store : storage) : return is if source =/= owner then (failwith ("Access denied.") : return) else ((nil : list(operation)), store) ``` ```cameligo group=c let owner : address = ("tz1KqTpEZ7Yob7QbPE4Hy4Wo8fHG8LhKxZSx": address) let main (action, store: parameter * storage) : return = if source <> owner then (failwith "Access denied." : return) else (([] : operation list), store) ``` ```reasonligo group=c let owner : address = ("tz1KqTpEZ7Yob7QbPE4Hy4Wo8fHG8LhKxZSx": address); let main = ((action, store): (parameter, storage)) : storage => { if (source != owner) { (failwith ("Access denied.") : return); } else { (([] : list (operation)), store); }; }; ``` ### Inter-Contract Invocations It would be somewhat misleading to speak of "contract calls", as this wording may wrongly suggest an analogy between contract "calls" and function "calls". Indeed, the control flow returns to the site of a function call, and composed function calls therefore are *stacked*, that is, they follow a last in, first out ordering. This is not what happens when a contract invokes another: the invocation is *queued*, that is, follows a first in, first our ordering, and the dequeuing only starts at the normal end of a contract (no failure). That is why we speak of "contract invocations" instead of "calls". The following example shows how a contract can invoke another by emiting a transaction operation at the end of an entrypoint. > The same technique can be used to transfer tokens to an implicit > account (tz1, ...): all you have to do is use a unit value as the > parameter of the smart contract. In our case, we have a `counter.ligo` contract that accepts an action of type `parameter`, and we have a `proxy.ligo` contract that accepts the same parameter type, and forwards the call to the deployed counter contract. ```pascaligo skip // counter.ligo type parameter is Increment of nat | Decrement of nat | Reset type storage is unit type return is list (operation) * storage ``` ```pascaligo group=d // proxy.ligo type parameter is Increment of nat | Decrement of nat | Reset type storage is unit type return is list (operation) * storage const dest : address = ("KT19wgxcuXG9VH4Af5Tpm1vqEKdaMFpznXT3" : address) function proxy (const action : parameter; const store : storage): return is block { const counter : contract (parameter) = get_contract (dest); (* Reuse the parameter in the subsequent transaction or use another one, `mock_param`. *) const mock_param : parameter = Increment (5n); const op : operation = transaction (action, 0mutez, counter); const ops : list (operation) = list [op] } with (ops, store) ``` ```cameligo skip // counter.mligo type parameter = Increment of nat | Decrement of nat | Reset // ... ``` ```cameligo group=d // proxy.mligo type parameter = Increment of nat | Decrement of nat | Reset type storage = unit type return = operation list * storage let dest : address = ("KT19wgxcuXG9VH4Af5Tpm1vqEKdaMFpznXT3" : address) let proxy (action, store : parameter * storage) : return = let counter : parameter contract = Operation.get_contract dest in (* Reuse the parameter in the subsequent transaction or use another one, `mock_param`. *) let mock_param : parameter = Increment (5n) in let op : operation = Operation.transaction action 0mutez counter in [op], store ``` ```reasonligo skip // counter.religo type parameter = | Increment (nat) | Decrement (nat) | Reset // ... ``` ```reasonligo group=d // proxy.religo type parameter = | Increment (nat) | Decrement (nat) | Reset; type storage = unit; type return = (list (operation), storage); let dest : address = ("KT19wgxcuXG9VH4Af5Tpm1vqEKdaMFpznXT3" : address); let proxy = ((action, store): (parameter, storage)) : return => { let counter : contract (parameter) = Operation.get_contract (dest); (* Reuse the parameter in the subsequent transaction or use another one, `mock_param`. *) let mock_param : parameter = Increment (5n); let op : operation = Operation.transaction (action, 0mutez, counter); ([op], store) }; ```