The main unit of code in Sophia is the contract.
- A contract implementation, or simply a contract, is the code for a smart contract and consists of a list of types, entrypoints and local functions. Only the entrypoints can be called from outside the contract.
- A contract instance is an entity living on the block chain (or in a state channel). Each instance has an address that can be used to call its entrypoints, either from another contract or in a call transaction.
- A contract may define a type
state
encapsulating its local state. When creating a new contract theinit
entrypoint is executed and the state is initialized to its return value.
The language offers some primitive functions to interact with the blockchain and contracts. Please refer to the Chain, Contract and the Call namespaces in the documentation.
To call a function in another contract you need the address to an instance of the contract. The type of the address must be a contract type, which consists of a number of type definitions and entrypoint declarations. For instance,
// A contract type
contract interface VotingType =
entrypoint vote : string => unit
Now given contract address of type VotingType
you can call the vote
entrypoint of that contract:
contract VoteTwice =
entrypoint voteTwice(v : VotingType, alt : string) =
v.vote(alt)
v.vote(alt)
Contract calls take two optional named arguments gas : int
and value : int
that lets you set a gas limit and provide tokens to a contract call. If omitted
the defaults are no gas limit and no tokens. Suppose there is a fee for voting:
entrypoint voteTwice(v : VotingType, fee : int, alt : string) =
v.vote(value = fee, alt)
v.vote(value = fee, alt)
Named arguments can be given in any order.
Note that reentrant calls are not permitted. In other words, when calling another contract it cannot call you back (directly or indirectly).
To construct a value of a contract type you can give a contract address literal
(for instance ct_2gPXZnZdKU716QBUFKaT4VdBZituK93KLvHJB3n4EnbrHHw4Ay
), or
convert an account address to a contract address using Address.to_contract
.
Note that if the contract does not exist, or it doesn't have the entrypoint, or
the type of the entrypoint does not match the stated contract type, the call
fails.
To recover the underlying address
of a contract instance there is a field
address : address
. For instance, to send tokens to the voting contract (given that it is payable)
without calling it you can write
entrypoint pay(v : VotingType, amount : int) =
Chain.spend(v.address, amount)
If a contract call fails for any reason (for instance, the remote contract
crashes or runs out of gas, or the entrypoint doesn't exist or has the wrong
type) the parent call also fails. To make it possible to recover from failures,
contract calls takes a named argument protected : bool
(default false
).
The protected argument must be a literal boolean, and when set to true
changes the type of the contract call, wrapping the result in an option
type.
If the call fails the result is None
, otherwise it's Some(r)
where r
is
the return value of the call.
contract interface VotingType =
entrypoint vote : string => unit
contract Voter =
entrypoint tryVote(v : VotingType, alt : string) =
switch(v.vote(alt, protected = true) : option(unit))
None => "Voting failed"
Some(_) => "Voting successful"
Any gas that was consumed by the contract call before the failure stays
consumed, which means that in order to protect against the remote contract
running out of gas it is necessary to set a gas limit using the gas
argument.
However, note that errors that would normally consume all the gas in the
transaction still only uses up the gas spent running the contract.
Any side effects (state change, token transfers, etc.) made by a failing protected call is rolled back, just like they would be in the unprotected case.
Since the version 6.0.0 Sophia supports deploying contracts by other contracts. This can be done in two ways:
- Contract cloning via
Chain.clone
- Direct deploy via
Chain.create
These functions take variable number of arguments that must match the created
contract's init
function. Beside that they take some additional named
arguments – please refer to their documentation for the details.
While Chain.clone
requires only a contract interface
and a living instance
of a given contract on the chain, Chain.create
needs a full definition of a
to-create contract defined by the standard contract
syntax, for example
contract IntHolder =
type state = int
entrypoint init(x) = x
entrypoint get() = state
main contract IntHolderFactory =
stateful entrypoint new(x : int) : IntHolder =
let ih = Chain.create(x) : IntHolder
ih
In case of a presence of child contracts (IntHolder
in this case), the main
contract must be pointed out with the main
keyword as shown in the example.
Contracts can implement one or multiple interfaces, the contract has to define every entrypoint from the implemented interface and the entrypoints in both the contract and implemented interface should have compatible types.
contract interface Animal =
entrypoint sound : () => string
contract Cat : Animal =
entrypoint sound() = "Cat sound"
Contract interfaces can extend other interfaces. An extended interface has to declare all entrypoints from every parent interface. All the declarations in the extended interface must have types compatible with the declarations from the parent interface.
contract interface II =
entrypoint f : () => unit
contract interface I : II =
entrypoint f : () => unit
entrypoint g : () => unit
contract C : I =
entrypoint f() = ()
entrypoint g() = ()
It is only possible to implement (or extend) an interface that has been already defined earlier in the file (or in an included file). Therefore recursive interface implementation is not allowed in Sophia.
// The following code would show an error
contract interface X : Z =
entrypoint x : () => int
contract interface Y : X =
entrypoint x : () => int
entrypoint y : () => int
contract interface Z : Y =
entrypoint x : () => int
entrypoint y : () => int
entrypoint z : () => int
contract C : Z =
entrypoint x() = 1
entrypoint y() = 1
entrypoint z() = 1
When a contract
or a contract interface
implements another contract interface
, the payable
and stateful
modifiers can be kept or changed, both in the contract and in the entrypoints, according to the following rules:
- A
payable
contract or interface can implement apayable
interface or a non-payable
interface. - A non-
payable
contract or interface can only implement a non-payable
interface, and cannot implement apayable
interface. - A
payable
entrypoint can implement apayable
entrypoint or a non-payable
entrypoint. - A non-
payable
entrypoint can only implement a non-payable
entrypoint, and cannot implement apayable
entrypoint. - A non-
stateful
entrypoint can implement astateful
entrypoint or a non-stateful
entrypoint. - A
stateful
entrypoint can only implement astateful
entrypoint, and cannot implement a non-stateful
entrypoint.
Subtyping in Sophia follows common rules that take type variance into account. As described by Wikipedia,
Variance refers to how subtyping between more complex types relates to subtyping between their components.
This concept plays an important role in complex types such as tuples, datatype
s and functions. Depending on the context, it can apply to positions in the structure of a type, or type parameters of generic types. There are four kinds of variances:
- covariant
- contravariant
- invariant
- bivariant
A type is said to be on a "covariant" position when it describes output or a result of some computation. Analogously, position is "contravariant" when it is an input, or a parameter. Intuitively, when a part of the type is produced by values of it, it is covariant. When it is consumed, it is contravariant. When a type appears to be simultaneously input and output, it is described as invariant. If a type is neither of those (that is, it's unused) it's bivariant. Furthermore, whenever a complex type appears on a contravariant position, all its covariant components become contravariant and vice versa.
Variance influences how subtyping is applied. Types on covariant positions are subtyped normally, while contravariant the opposite way. Invariant types have to be exactly the same in order for subtyping to work. Bivariant types are always compatible.
A good example of where it matters can be pictured by subtyping of function types. Let us assume there is a contract interface Animal
and two contracts that implement it: Dog
and Cat
.
contract interface Animal =
entrypoint age : () => int
contract Dog : Animal =
entrypoint age() = // ...
entrypoint woof() = "woof"
contract Cat : Animal =
entrypoint age() = // ...
entrypoint meow() = "meow"
The assumption of this exercise is that cats do not bark (because Cat
does not define the woof
entrypoint). If subtyping rules were applied naively, that is if we let Dog => Dog
be a subtype of Animal => Animal
, the following code would break:
let f : (Dog) => string = d => d.woof()
let g : (Animal) => string = f
let c : Cat = Chain.create()
g(c) // Cat barking!
That is because arguments of functions are contravariant, as opposed to return the type which is covariant. Because of that, the assignment of f
to g
is invalid - while Dog
is a subtype of Animal
, Dog => string
is not a subtype of Animal => string
. However, Animal => string
is a subtype of Dog => string
. More than that, (Dog => Animal) => Dog
is a subtype of (Animal => Dog) => Animal
.
This has consequences on how user-defined generic types work. A type variable gains its variance from its role in the type definition as shown in the example:
datatype co('a) = Co('a) // co is covariant on 'a
datatype ct('a) = Ct('a => unit) // ct is contravariant on 'a
datatype in('a) = In('a => 'a) // in is invariant on 'a
datatype bi('a) = Bi // bi is bivariant on 'a
The following facts apply here:
co('a)
is a subtype ofco('b)
when'a
is a subtype of'b
ct('a)
is a subtype ofct('b)
when'b
is a subtype of'a
in('a)
is a subtype ofin('b)
when'a
is equal to'b
bi('a)
is a subtype ofbi('b)
always
That altogether induce the following rules of subtyping in Sophia:
-
A function type
(Args1) => Ret1
is a subtype of(Args2) => Ret2
whenRet1
is a subtype ofRet2
and each argument type fromArgs2
is a subtype of its counterpart inArgs1
. -
A list type
list(A)
is a subtype oflist(B)
ifA
is a subtype ofB
. -
An option type
option(A)
is a subtype ofoption(B)
ifA
is a subtype ofB
. -
A map type
map(A1, A2)
is a subtype ofmap(B1, B2)
ifA1
is a subtype ofB1
, andA2
is a subtype ofB2
. -
An oracle type
oracle(A1, A2)
is a subtype oforacle(B1, B2)
ifB1
is a subtype ofA1
, andA2
is a subtype ofB2
. -
An oracle_query type
oracle_query(A1, A2)
is a subtype oforacle_query(B1, B2)
ifA1
is a subtype ofB1
, andA2
is a subtype ofB2
. -
A user-defined datatype
t(Args1)
is a subtype oft(Args2)
-
When a user-defined type
t('a)
is covariant in'a
, thent(A)
is a subtype oft(B)
whenA
is a subtype ofB
. -
When a user-defined type
t('a)
is contravariant in'a
, thent(A)
is a subtype oft(B)
whenB
is a subtype ofA
. -
When a user-defined type
t('a)
is binvariant in'a
, thent(A)
is a subtype oft(B)
when eitherA
is a subtype ofB
or whenB
is a subtype ofA
. -
When a user-defined type
t('a)
is invariant in'a
, thent(A)
can never be a subtype oft(B)
.
Because of how FATE represents types as values there is a fixed upper limit (256) of type variables that can be used in a single type signature.
Sophia does not have arbitrary mutable state, but only a limited form of state associated with each contract instance.
- Each contract defines a type
state
encapsulating its mutable state. The typestate
defaults to theunit
. - The initial state of a contract is computed by the contract's
init
function. Theinit
function is pure and returns the initial state as its return value. If the typestate
isunit
, theinit
function defaults to returning the value()
. At contract creation time, theinit
function is executed and its result is stored as the contract state. - The value of the state is accessible from inside the contract
through an implicitly bound variable
state
. - State updates are performed by calling a function
put : state => unit
. - Aside from the
put
function (and similar functions for transactions and events), the language is purely functional. - Functions modifying the state need to be annotated with the
stateful
keyword (see below).
To make it convenient to update parts of a deeply nested state Sophia provides special syntax for map/record updates.
Top-level functions and entrypoints must be annotated with the
stateful
keyword to be allowed to affect the state of the running contract.
For instance,
stateful entrypoint set_state(s : state) =
put(s)
Without the stateful
annotation the compiler does not allow the call to
put
. A stateful
annotation is required to
- Use a stateful primitive function. These are
put
Chain.spend
Oracle.register
Oracle.query
Oracle.respond
Oracle.extend
AENS.preclaim
AENS.claim
AENS.transfer
AENS.revoke
AENS.update
- Call a
stateful
function in the current contract - Call another contract with a non-zero
value
argument.
A stateful
annotation is not required to
- Read the contract state.
- Issue an event using the
event
function. - Call another contract with
value = 0
, even if the called function is stateful.
A concrete contract is by default not payable. Any attempt at spending to such
a contract (either a Chain.spend
or a normal spend transaction) will fail. If a
contract shall be able to receive funds in this way it has to be declared payable
:
// A payable contract
payable contract ExampleContract =
stateful entrypoint do_stuff() = ...
If in doubt, it is possible to check if an address is payable using
Address.is_payable(addr)
.
A contract entrypoint is by default not payable. Any call to such a function
(either a Remote call or a contract call transaction)
that has a non-zero value
will fail. Contract entrypoints that should be called
with a non-zero value should be declared payable
.
payable stateful entrypoint buy(to : address) =
if(Call.value > 42)
transfer_item(to)
else
abort("Value too low")
Code can be split into libraries using the namespace
construct. Namespaces
can appear at the top-level and can contain type and function definitions, but
not entrypoints. Outside the namespace you can refer to the (non-private) names
by qualifying them with the namespace (Namespace.name
).
For example,
namespace Library =
type number = int
function inc(x : number) : number = x + 1
contract MyContract =
entrypoint plus2(x) : Library.number =
Library.inc(Library.inc(x))
Functions in namespaces have access to the same environment (including the
Chain
, Call
, and Contract
, builtin namespaces) as function in a contract,
with the exception of state
, put
and Chain.event
since these are
dependent on the specific state and event types of the contract.
To avoid mentioning the namespace every time it is used, Sophia allows
including the namespace in the current scope with the using
keyword:
include "Pair.aes"
using Pair
contract C =
type state = int
entrypoint init() =
let p = (1, 2)
fst(p) // this is the same as Pair.fst(p)
It is also possible to make an alias for the namespace with the as
keyword:
include "Pair.aes"
contract C =
using Pair as P
type state = int
entrypoint init() =
let p = (1, 2)
P.fst(p) // this is the same as Pair.fst(p)
Having the same alias for multiple namespaces is possible and it allows referening functions that are defined in different namespaces and have different names with the same alias:
namespace Xa = function f() = 1
namespace Xb = function g() = 2
contract Cntr =
using Xa as A
using Xb as A
type state = int
entrypoint init() = A.f() + A.g()
Note that using functions with the same name would result in an ambiguous name error:
namespace Xa = function f() = 1
namespace Xb = function f() = 2
contract Cntr =
using Xa as A
using Xb as A
type state = int
// the next line has an error because f is defined in both Xa and Xb
entrypoint init() = A.f()
Importing specific parts of a namespace or hiding these parts can also be done like this:
using Pair for [fst, snd] // this will only import fst and snd
using Triple hiding [fst, snd] // this will import everything except for fst and snd
Note that it is possible to use a namespace in the top level of the file, in the contract level, namespace level, or in the function level.
Code from another file can be included in a contract using an include
statement. These must appear at the top-level (outside the main contract). The
included file can contain one or more namespaces and abstract contracts. For
example, if the file library.aes
contains
namespace Library =
function inc(x) = x + 1
you can use it from another file using an include
:
include "library.aes"
contract MyContract =
entrypoint plus2(x) = Library.inc(Library.inc(x))
This behaves as if the contents of library.aes
was textually inserted into
the file, except that error messages will refer to the original source
locations. The language will try to include each file at most one time automatically,
so even cyclic includes should be working without any special tinkering.
When including code from another file using the include
statement, the path
is relative to the file that includes it. Consider the following file tree:
c1.aes
c3.aes
dir1/c2.aes
dir1/c3.aes
If c1.aes
contains include "c3.aes"
it will include the top level c3.aes
,
while if c2.aes
contained the same line it would as expected include
dir1/c3.aes
.
Note: Prior to v7.5.0, it would consider the include path relative to the main contract file (or any explicitly set include path).
Sophia offers standard library which exposes some
primitive operations and some higher level utilities. The builtin
namespaces like Chain
, Contract
, Map
are included by default and are supported internally by the compiler.
Others like List
, Frac
, Option
need to be manually included using the
include
directive. For example
include "List.aes"
include "Pair.aes"
-- Map is already there!
namespace C =
entrypoint keys(m : map('a, 'b)) : list('a) =
List.map(Pair.fst, (Map.to_list(m)))
Sophia has the following types:
Type | Description | Example |
---|---|---|
int | A 2-complement integer | -1 |
address | æternity address, 32 bytes | Call.origin |
bool | A Boolean | true |
bits | A bit field | Bits.none |
bytes(n) | A byte array with n bytes |
#fedcba9876543210 |
string | An array of bytes | "Foo" |
list | A homogeneous immutable singly linked list. | [1, 2, 3] |
('a, 'b) => 'c | A function. Parentheses can be skipped if there is only one argument | (x : int, y : int) => x + y |
tuple | An ordered heterogeneous array | (42, "Foo", true) |
record | An immutable key value store with fixed key names and typed values | record balance = { owner: address, value: int } |
map | An immutable key value store with dynamic mapping of keys of one type to values of one type | type accounts = map(string, address) |
option('a) | An optional value either None or Some('a) | Some(42) |
state | A user defined type holding the contract state | record state = { owner: address, magic_key: bytes(4) } |
event | An append only list of blockchain events (or log entries) | datatype event = EventX(indexed int, string) |
hash | A 32-byte hash - equivalent to bytes(32) |
|
signature | A signature - equivalent to bytes(64) |
|
Chain.ttl | Time-to-live (fixed height or relative to current block) | FixedTTL(1050) RelativeTTL(50) |
oracle('a, 'b) | And oracle answering questions of type 'a with answers of type 'b | Oracle.register(acct, qfee, ttl) |
oracle_query('a, 'b) | A specific oracle query | Oracle.query(o, q, qfee, qttl, rttl) |
contract | A user defined, typed, contract address | function call_remote(r : RemoteContract) = r.fun() |
Type | Constant/Literal example(s) |
---|---|
unit | () |
int | -1 , 2425 , 4598275923475723498573485768 |
address | ak_2gx9MEFxKvY9vMG5YnqnXWv1hCsX7rgnfvBLJS4aQurustR1rt |
bool | true , false |
bits | Bits.none , Bits.all |
bytes(8) | #fedcba9876543210 |
string | "This is a string" |
list | [1, 2, 3] , [(true, 24), (false, 19), (false, -42)] |
tuple | (42, "Foo", true) |
record | { owner = Call.origin, value = 100000000 } |
map | {["foo"] = 19, ["bar"] = 42} , {} |
option(int) | Some(42) , None |
state | state{ owner = Call.origin, magic_key = #a298105f } |
event | EventX(0, "Hello") |
hash | #000102030405060708090a0b0c0d0e0f000102030405060708090a0b0c0d0e0f |
signature | sg_MhibzTP1wWzGCTjtPFr1TiPqRJrrJqw7auvEuF5i3FdoALWqXLBDY6xxRRNUSPHK3EQTnTzF12EyspkxrSMxVHKsZeSMj , #000102030405060708090a0b0c0d0e0f000102030405060708090a0b0c0d0e0f000102030405060708090a0b0c0d0e0f000102030405060708090a0b0c0d0e0f |
Chain.ttl | FixedTTL(1050) , RelativeTTL(50) |
oracle('a, 'b) | ok_2YNyxd6TRJPNrTcEDCe9ra59SVUdp9FR9qWC5msKZWYD9bP9z5 |
oracle_query('a, 'b) | oq_2oRvyowJuJnEkxy58Ckkw77XfWJrmRgmGaLzhdqb67SKEL1gPY |
contract | ct_Ez6MyeTMm17YnTnDdHTSrzMEBKmy7Uz2sXu347bTDPgVH2ifJ |
Hole expressions, written as ???
, are expressions that are used as a placeholder. During compilation, the compiler will generate a type error indication the type of the hole expression.
include "List.aes"
contract C =
entrypoint f() =
List.sum(List.map(???, [1,2,3]))
A hole expression found in the example above will generate the error Found a hole of type `(int) => int`
. This says that the compiler expects a function from int
to int
in place of the ???
placeholder.
Constants in Sophia are contract-level bindings that can be used in either contracts or namespaces. The value of a constant can be a literal, another constant, or arithmetic operations applied to other constants. Lists, tuples, maps, and records can also be used to define a constant as long as their elements are also constants.
The following visibility rules apply to constants:
- Constants defined inside a contract are private in that contract. Thus, cannot be accessed through instances of their defining contract.
- Constants defined inside a namespace are public. Thus, can be used in other contracts or namespaces.
- Constants cannot be defined inside a contract interface.
When a constant is shadowed, it can be accessed using its qualified name:
contract C =
let c = 1
entrypoint f() =
let c = 2
c + C.c // the result is 3
The name of the constant must be an id; therefore, no pattern matching is allowed when defining a constant:
contract C
let x::y::_ = [1,2,3] // this will result in an error
Sophia integers (int
) are represented by arbitrary-sized signed words and support the following
arithmetic operations:
- addition (
x + y
) - subtraction (
x - y
) - multiplication (
x * y
) - division (
x / y
), truncated towards zero - remainder (
x mod y
), satisfyingy * (x / y) + x mod y == x
for non-zeroy
- exponentiation (
x ^ y
)
All operations are safe with respect to overflow and underflow. The division and modulo operations throw an arithmetic error if the right-hand operand is zero.
Sophia arbitrary-sized integers (FATE) also supports the following bitwise operations:
- bitwise and (
x band y
) - bitwise or (
x bor y
) - bitwise xor (
x bxor y
) - bitwise not (
bnot x
) - arithmetic bitshift left (
x << n
) - arithmetic bitshift right (
x >> n
)
Note: Arithmetic bitshift treats the number as a signed integer (in 2s complement), and "retains" the topmost bit. I.e. shifting in zeros if the topmost bit was 0, and ones if it was one.
Originally Sophia integers did not support bit arithmetic. Instead we used a
separate type bits
(see the standard library
documentation) - it is still provided as an
alternative to bit arithmetic.
A bit field can be of arbitrary size (but it is still represented by the corresponding integer, so setting very high bits can be expensive).
Type aliases can be introduced with the type
keyword and can be
parameterized. For instance
type number = int
type string_map('a) = map(string, 'a)
A type alias and its definition can be used interchangeably. Sophia does not support
higher-kinded types, meaning that following type alias is invalid: type wrap('f, 'a) = 'f('a)
Sophia supports algebraic data types (variant types) and pattern matching. Data types are declared by giving a list of constructors with their respective arguments. For instance,
datatype one_or_both('a, 'b) = Left('a) | Right('b) | Both('a, 'b)
Elements of data types can be pattern matched against, using the switch
construct:
function get_left(x : one_or_both('a, 'b)) : option('a) =
switch(x)
Left(x) => Some(x)
Right(_) => None
Both(x, _) => Some(x)
or directly in the left-hand side:
function
get_left : one_or_both('a, 'b) => option('a)
get_left(Left(x)) = Some(x)
get_left(Right(_)) = None
get_left(Both(x, _)) = Some(x)
NOTE: Data types cannot currently be recursive.
Sophia also supports the assignment of patterns to variables:
function f(x) = switch(x)
h1::(t = h2::_) => (h1 + h2)::t // same as `h1::h2::k => (h1 + h2)::h2::k`
_ => x
function g(p : int * option(int)) : int =
let (a, (o = Some(b))) = p // o is equal to Pair.snd(p)
b
Guards are boolean expressions that can be used on patterns in both switch
statements and functions definitions. If a guard expression evaluates to
true
, then the corresponding body will be used. Otherwise, the next pattern
will be checked:
function get_left_if_positive(x : one_or_both(int, 'b)) : option(int) =
switch(x)
Left(x) | x > 0 => Some(x)
Both(x, _) | x > 0 => Some(x)
_ => None
function
get_left_if_positive : one_or_both(int, 'b) => option(int)
get_left_if_positive(Left(x)) | x > 0 = Some(x)
get_left_if_positive(Both(x, _)) | x > 0 = Some(x)
get_left_if_positive(_) = None
Guards cannot be stateful even when used inside a stateful function.
A Sophia list is a dynamically sized, homogenous, immutable, singly
linked list. A list is constructed with the syntax [1, 2, 3]
. The
elements of a list can be any of datatype but they must have the same
type. The type of lists with elements of type 'e
is written
list('e)
. For example we can have the following lists:
[1, 33, 2, 666] : list(int)
[(1, "aaa"), (10, "jjj"), (666, "the beast")] : list(int * string)
[{[1] = "aaa", [10] = "jjj"}, {[5] = "eee", [666] = "the beast"}] : list(map(int, string))
New elements can be prepended to the front of a list with the ::
operator. So 42 :: [1, 2, 3]
returns the list [42, 1, 2, 3]
. The
concatenation operator ++
appends its second argument to its first
and returns the resulting list. So concatenating two lists
[1, 22, 33] ++ [10, 18, 55]
returns the list [1, 22, 33, 10, 18, 55]
.
Sophia supports list comprehensions known from languages like Python, Haskell or Erlang. Example syntax:
[x + y | x <- [1,2,3,4,5], let k = x*x, if (k > 5), y <- [k, k+1, k+2]]
// yields [12,13,14,20,21,22,30,31,32]
Lists can be constructed using the range syntax using special ..
operator:
[1..4] == [1,2,3,4]
The ranges are always ascending and have step equal to 1.
Please refer to the standard library for the predefined functionalities.
A Sophia record type is given by a fixed set of fields with associated, possibly different, types. For instance
record account = { name : string,
balance : int,
history : list(transaction) }
Maps, on the other hand, can contain an arbitrary number of key-value bindings,
but of a fixed type. The type of maps with keys of type 'k
and values of type
'v
is written map('k, 'v)
. The key type can be any type that does not
contain a map or a function type.
Please refer to the standard library for the predefined functionalities.
A value of record type is constructed by giving a value for each of the fields. For the example above,
function new_account(name) =
{name = name, balance = 0, history = []}
Maps are constructed similarly, with keys enclosed in square brackets
function example_map() : map(string, int) =
{["key1"] = 1, ["key2"] = 2}
The empty map is written {}
.
Record fields access is written r.f
and map lookup m[k]
. For instance,
function get_balance(a : address, accounts : map(address, account)) =
accounts[a].balance
Looking up a non-existing key in a map results in contract execution failing. A
default value to return for non-existing keys can be provided using the syntax
m[k = default]
. See also Map.member
and Map.lookup
below.
Record field updates are written r{f = v}
. This creates a new record value
which is the same as r
, but with the value of the field f
replaced by v
.
Similarly, m{[k] = v}
constructs a map with the same values as m
except
that k
maps to v
. It makes no difference if m
has a mapping for k
or
not.
It is possible to give a name to the old value of a field or mapping in an
update: instead of acc{ balance = acc.balance + 100 }
it is possible to write
acc{ balance @ b = b + 100 }
, binding b
to acc.balance
. When giving a
name to a map value (m{ [k] @ x = v }
), the corresponding key must be present
in the map or execution fails, but a default value can be provided:
m{ [k = default] @ x = v }
. In this case x
is bound to default
if
k
is not in the map.
Updates can be nested:
function clear_history(a : address, accounts : map(address, account)) : map(address, account) =
accounts{ [a].history = [] }
This is equivalent to accounts{ [a] @ acc = acc{ history = [] } }
and thus
requires a
to be present in the accounts map. To have clear_history
create
an account if a
is not in the map you can write (given a function empty_account
):
accounts{ [a = empty_account()].history = [] }
Internally in the VM maps are implemented as hash maps and support fast lookup and update. Large maps can be stored in the contract state and the size of the map does not contribute to the gas costs of a contract call reading or updating it.
There is a builtin type string
, which can be seen as an array of bytes.
Strings can be compared for equality (==
, !=
), used as keys in maps and
records, and used in builtin functions String.length
, String.concat
and
the hash functions described below.
Please refer to the String
library documentation.
There is a builtin type char
(the underlying representation being an integer),
mainly used to manipulate strings via String.to_list
/String.from_list
.
Characters can also be introduced as character literals (`'x', '+', ...).
Please refer to the Char
library documentation.
Byte arrays are fixed size arrays of 8-bit integers. They are described in hexadecimal system,
for example the literal #cafe
creates a two-element array of bytes ca
(202) and fe
(254)
and thus is a value of type bytes(2)
.
Please refer to the Bytes
library documentation.
Libraries Crypto and String provide functions to
hash objects, verify signatures etc. The hash
is a type alias for bytes(32)
.
When a Generalized account is authorized, the authorization function needs
access to the transaction and the transaction hash for the wrapped transaction. (A GAMetaTx
wrapping a transaction.) The transaction and the transaction hash is available in the primitive
Auth.tx
and Auth.tx_hash
respectively, they are only available during authentication if invoked by a
normal contract call they return None
.
You can attach an oracle to the current contract and you can interact with oracles through the Oracle interface.
For a full description of how Oracle works see Oracles. For a functionality documentation refer to the standard library.
Example for an oracle answering questions of type string
with answers of type int
:
contract Oracles =
stateful entrypoint registerOracle(acct : address,
sign : signature, // Signed network id + oracle address + contract address
qfee : int,
ttl : Chain.ttl) : oracle(string, int) =
Oracle.register(acct, signature = sign, qfee, ttl)
entrypoint queryFee(o : oracle(string, int)) : int =
Oracle.query_fee(o)
payable stateful entrypoint createQuery(o : oracle_query(string, int),
q : string,
qfee : int,
qttl : Chain.ttl,
rttl : int) : oracle_query(string, int) =
require(qfee =< Call.value, "insufficient value for qfee")
Oracle.query(o, q, qfee, qttl, RelativeTTL(rttl))
stateful entrypoint extendOracle(o : oracle(string, int),
ttl : Chain.ttl) : unit =
Oracle.extend(o, ttl)
stateful entrypoint signExtendOracle(o : oracle(string, int),
sign : signature, // Signed network id + oracle address + contract address
ttl : Chain.ttl) : unit =
Oracle.extend(o, signature = sign, ttl)
stateful entrypoint respond(o : oracle(string, int),
q : oracle_query(string, int),
sign : signature, // Signed network id + oracle query id + contract address
r : int) =
Oracle.respond(o, q, signature = sign, r)
entrypoint getQuestion(o : oracle(string, int),
q : oracle_query(string, int)) : string =
Oracle.get_question(o, q)
entrypoint hasAnswer(o : oracle(string, int),
q : oracle_query(string, int)) =
switch(Oracle.get_answer(o, q))
None => false
Some(_) => true
entrypoint getAnswer(o : oracle(string, int),
q : oracle_query(string, int)) : option(int) =
Oracle.get_answer(o, q)
When an Oracle literal is passed to a contract, no deep checks are performed. For extra safety Oracle.check and Oracle.check_query functions are provided.
Contracts can interact with the æternity naming system. For this purpose the AENS and later the AENSv2 library was exposed.
In this example we assume that the name name
already exists, and is owned by
an account with address addr
. In order to allow a contract ct
to handle
name
the account holder needs to create a delegation
signature sig
from the name owner address addr
, the
name hash and the contract address.
Armed with this information we can for example write a function that extends the name if it expires within 1000 blocks:
stateful entrypoint extend_if_necessary(addr : address, name : string, sig : signature) =
switch(AENS.lookup(name))
None => ()
Some(AENS.Name(_, FixedTTL(expiry), _)) =>
if(Chain.block_height + 1000 > expiry)
AENS.update(addr, name, Some(RelativeTTL(50000)), None, None, signature = sig)
And we can write functions that adds and removes keys from the pointers of the name:
stateful entrypoint add_key(addr : address, name : string, key : string,
pt : AENS.pointee, sig : signature) =
switch(AENS.lookup(name))
None => ()
Some(AENS.Name(_, _, ptrs)) =>
AENS.update(addr, name, None, None, Some(ptrs{[key] = pt}), signature = sig)
stateful entrypoint delete_key(addr : address, name : string,
key : string, sig : signature) =
switch(AENS.lookup(name))
None => ()
Some(AENS.Name(_, _, ptrs)) =>
let ptrs = Map.delete(key, ptrs)
AENS.update(addr, name, None, None, Some(ptrs), signature = sig)
Note: From the Iris hardfork more strict rules apply for AENS pointers, when a Sophia contract lookup or update (bad) legacy pointers, the bad keys are automatically removed so they will not appear in the pointers map.
Sophia contracts log structured messages to an event log in the resulting blockchain transaction. The event log is quite similar to Events in Solidity. Events are further discussed in the protocol.
To use events a contract must declare a datatype event
, and events are then
logged using the Chain.event
function:
datatype event
= Event1(int, int, string)
| Event2(string, address)
Chain.event(e : event) : unit
The event can have 0-3 indexed fields, and an optional payload field. A field is indexed if it fits in a 32-byte word, i.e.
bool
int
bits
address
oracle(_, _)
oracle_query(_, _)
- contract types
bytes(n)
forn
≤ 32, in particularhash
The payload field must be either a string or a byte array of more than 32 bytes. The fields can appear in any order.
NOTE: Indexing is not part of the core æternity node.
Events are emitted by using the Chain.event
function. The following function
will emit one Event of each kind in the example.
entrypoint emit_events() : () =
Chain.event(Event1(42, 34, "foo"))
Chain.event(Event2("This is not indexed", Contract.address))
It is only possible to have one (1) string
parameter in the event, but it can
be placed in any position (and its value will end up in the data
field), i.e.
AnotherEvent(string, indexed address)
...
Chain.event(AnotherEvent("This is not indexed", Contract.address))
would yield exactly the same result in the example above!
To enforce that a contract is only compiled with specific versions of the
Sophia compiler, you can give one or more @compiler
pragmas at the
top-level (typically at the beginning) of a file. For instance, to enforce that
a contract is compiled with version 4.3 of the compiler you write
@compiler >= 4.3
@compiler < 4.4
Valid operators in compiler pragmas are <
, =<
, ==
, >=
, and >
. Version
numbers are given as a sequence of non-negative integers separated by dots.
Trailing zeros are ignored, so 4.0.0 == 4
. If a constraint is violated an
error is reported and compilation fails.
Contracts can fail with an (uncatchable) exception using the built-in function
abort(reason : string) : 'a
Calling abort causes the top-level call transaction to return an error result
containing the reason
string. Only the gas used up to and including the abort
call is charged. This is different from termination due to a crash which
consumes all available gas.
For convenience the following function is also built-in:
function require(b : bool, err : string) =
if(!b) abort(err)
Aside from that, there is an almost equivalent function exit
exit(reason : string) : 'a
Just like abort
, it breaks the execution with the given reason. The difference
however is in the gas consumption — while abort
returns unused gas, a call to
exit
burns it all.
Some chain operations (Oracle.<operation>
and AENSv2.<operation>
) have an
optional delegation signature. This is typically used when a user/accounts
would like to allow a contract to act on it's behalf.
From the Ceres protocol version the delegation signatures have more structure,
including a unique tag, network_id
and identifiers; there are five different
delegation signatures:
- AENS wildcard - the user signs:
owner account + contract
AENS_PRECLAIM
- the user signs:owner account + contract
AENS_CLAIM, AENS_UPDATE, AENS_TRANSFER, AENS_REVOKE
- the user signs:owner account + name hash + contract
ORACLE_REGISTER, ORACLE_EXTEND
- the user signs:owner account + contract
ORACLE_RESPOND
- the user signs:query id + contract
See Serialized signature data for the exact structure used.
The exact data to be signed varies for the different operations, but in all
cases you should prepend the signature data with the network_id
(ae_mainnet
for the æternity mainnet, etc.).
There are four different delegation signatures:
AENS_PRECLAIM
- the user signs: ownernetwork_id + account + contract
AENS_CLAIM, AENS_UPDATE, AENS_TRANSFER, AENS_REVOKE
- the user signs:network_id + owner account + name hash + contract
ORACLE_REGISTER, ORACLE_EXTEND
- the user signs:network_id + owner account + contract
ORACLE_RESPOND
- the user signs:network_id + query id + contract