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Ethereum-Contract-ABI.md

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Ethereum Contract ABI

Functions

Basic design

We assume the ABI is strongly typed, known at compilation time and static. No introspection mechanism will be provided. We assert that all contracts will have the interface definitions of any contracts they call available at compile-time.

This specification does not address contracts whose interface is dynamic or otherwise known only at run-time. Should these cases become important they can be adequately handled as facilities built within the Ethereum ecosystem.

Function Selector

The first four bytes of the call data for a function call specifies the function to be called. It is the first (left, high-order in big-endian) four bytes of the Keccak (SHA-3) hash of the signature of the function. The signature is defined as the canonical expression of the basic prototype, i.e. the function name with the parenthesised list of parameter types. Parameter types are split by a single comma - no spaces are used.

Argument Encoding

Starting from the fifth byte, the encoded arguments follow. This encoding is also used in other places, e.g. the return values and also event arguments are encoded in the same way, without the four bytes specifying the function.

Types

The following elementary types exist:

  • uint<N>: unsigned integer type of N bits, 0 < N <= 256, N % 8 == 0. e.g. uint32, uint8, uint256.
  • int<N>: two's complement signed integer type of N bits, 0 < N <= 256, N % 8 == 0.
  • address: equivalent to bytes20, except for the assumed interpretation and language typing.
  • uint, int: synonyms for uint256, int256 respectively (not to be used for computing the function selector).
  • bool: equivalent to uint8 restricted to the values 0 and 1
  • real<N>x<M>: fixed-point signed number of N+M bits, 0 < N + M <= 256, N % 8 == M % 8 == 0. Corresponds to the int256 equivalent binary value divided by 2^M.
  • ureal<N>x<M>: unsigned variant of real<N>x<M>.
  • real, ureal: synonyms for real128x128, ureal128x128 respectively (not to be used for computing the function selector).
  • bytes<N>: binary type of N bytes, N >= 0.

The following (fixed-size) array type exists:

  • <type>[N]: a fixed-length array of the given fixed-length type.

The following non-fixed-size types exist:

  • bytes: dynamic sized byte sequence.
  • string: dynamic sized unicode string assumed to be UTF-8 encoded.
  • <type>[]: a variable-length array of the given fixed-length type.

Formal Specification of the Encoding

We will now formally specify the encoding, such that it will have the following properties, which are especially useful if some arguments are nested arrays:

Properties:

  1. The number of reads necessary to access a value is at most the depth of the value inside the argument array structure, i.e. four reads are needed to retrieve a_i[k][l][r]. In a previous version of the ABI, the number of reads scaled linearly with the total number of dynamic parameters in the worst case.

  2. The data of a variable or array element is not interleaved with other data and it is relocatable, i.e. it only uses relative "addresses"

We distinguish static and dynamic types. Static types are encoded in-place and dynamic types are encoded at a separately allocated location after the current block.

Definition: The following types are called "dynamic":

  • bytes
  • string
  • T[] for any T
  • T[k] for any dynamic T and any k > 0

All other types are called "static".

Definition: len(a) is the number of bytes in a binary string a. The type of len(a) is assumed to be uint256.

We define enc, the actual encoding, as a mapping of values of the ABI types to binary strings such that len(enc(X)) depends on the value of X if and only if the type of X is dynamic.

Definition: For any ABI value X, we recursively define enc(X), depending on the type of X being

  • T[k] for any T and k:

    enc(X) = head(X[0]) ... head(X[k-1]) tail(X[0]) ... tail(X[k-1])

    where head and tail are defined for X[i] being of a static type as head(X[i]) = enc(X[i]) and tail(X[i]) = "" (the empty string) and as head(X[i]) = enc(len(head(X[0]) ... head(X[k-1]) tail(X[0]) ... tail(X[i-1]))) tail(X[i]) = enc(X[i]) otherwise.

    Note that in the dynamic case, head(X[i]) is well-defined since the lengths of the head parts only depend on the types and not the values. Its value is the offset of the beginning of tail(X[i]) relative to the start of enc(X).

  • T[] where X has k elements (k is assumed to be of type uint256):

    enc(X) = enc(k) enc([X[1], ..., X[k]])

    i.e. it is encoded as if it were an array of static size k, prefixed with the number of elements.

  • bytes, of length k (which is assumed to be of type uint256):

    enc(X) = enc(k) pad_right(X), i.e. the number of bytes is encoded as a uint256 followed by the actual value of X as a byte sequence, followed by the minimum number of zero-bytes such that len(enc(X)) is a multiple of 32.

  • string:

    enc(X) = enc(enc_utf8(X)), i.e. X is utf-8 encoded and this value is interpreted as of bytes type and encoded further. Note that the length used in this subsequent encoding is the number of bytes of the utf-8 encoded string, not its number of characters.

  • uint<N>: enc(X) is the big-endian encoding of X, padded on the higher-order (left) side with zero-bytes such that the length is a multiple of 32 bytes.

  • address: as in the uint160 case

  • int<N>: enc(X) is the big-endian two's complement encoding of X, padded on the higher-oder (left) side with 0xff for negative X and with zero bytes for positive X such that the length is a multiple of 32 bytes.

  • bool: as in the uint8 case, where 1 is used for true and 0 for false

  • real<N>x<M>: enc(X) is enc(X * 2**M) where X * 2**M is interpreted as a int256.

  • real: as in the real128x128 case

  • ureal<N>x<M>: enc(X) is enc(X * 2**M) where X * 2**M is interpreted as a uint256.

  • ureal: as in the ureal128x128 case

  • bytes<N>: enc(X) is the sequence of bytes in X padded with zero-bytes to a length of 32.

Note that for any X, len(enc(X)) is a multiple of 32.

Function Selector and Argument Encoding

All in all, a call to the function f with parameters a_1, ..., a_n is encoded as

function_selector(f) enc([a_1, ..., a_n])

and the return values v_1, ..., v_k of f are encoded as

enc([v_1, ..., v_k])

where the types of [a_1, ..., a_n] and [v_1, ..., v_k] are assumed to be fixed-size arrays of length n and k, respectively. Note that strictly, [a_1, ..., a_n] can be an "array" with elements of different types, but the encoding is still well-defined as the assumed common type T (above) is not actually used.

Examples

Given the contract:

contract Foo {
  function bar(real[2] xy) {}
  function baz(uint32 x, bool y) returns (bool r) { r = x > 32 || y; }
  function sam(bytes name, bool z, uint[] data) {}
}

Thus for our Foo example if we wanted to call baz with the parameters 69 and true, we would pass 68 bytes total, which can be broken down into:

  • 0xcdcd77c0: the Method ID. This is derived as the first 4 bytes of the Keccak hash of the ASCII form of the signature baz(uint32,bool).
  • 0x0000000000000000000000000000000000000000000000000000000000000045: the first parameter, a uint32 value 69 padded to 32 bytes
  • 0x0000000000000000000000000000000000000000000000000000000000000001: the second parameter - boolean true, padded to 32 bytes

In total:

0xcdcd77c000000000000000000000000000000000000000000000000000000000000000450000000000000000000000000000000000000000000000000000000000000001

It returns a single bool. If, for example, it were to return false, its output would be the single byte array 0x0000000000000000000000000000000000000000000000000000000000000000, a single bool.

If we wanted to call bar with the argument [2.125, 8.5], we would pass 68 bytes total, broken down into:

  • 0x3e279860: the Method ID. This is derived from the signature bar(real128x128[2]). Note that real is substituted for its canonical representation real128x128.
  • 0x0000000000000000000000000000000240000000000000000000000000000000: the first part of the first parameter, a real128x128 value 2.125.
  • 0x0000000000000000000000000000000880000000000000000000000000000000: the first part of the first parameter, a real128x128 value 8.5.

In total:

0x3e27986000000000000000000000000000000002400000000000000000000000000000000000000000000000000000000000000880000000000000000000000000000000

If we wanted to call sam with the arguments "dave", true and [1,2,3], we would pass 292 bytes total, broken down into:

  • 0x8FF261B0: the Method ID. This is derived from the signature sam(bytes,bool,uint256[]). Note that uint is substituted for its canonical representation uint256.
  • 0x0000000000000000000000000000000000000000000000000000000000000060: the location of the data part of the first parameter (dynamic type), measured in bytes from the start of the arguments block. In this case, 0x60.
  • 0x0000000000000000000000000000000000000000000000000000000000000001: the second parameter: boolean true.
  • 0x00000000000000000000000000000000000000000000000000000000000000c0: the location of the data part of the third parameter (dynamic type), measured in bytes. In this case, 0xc0.
  • 0x0000000000000000000000000000000000000000000000000000000000000004: the data part of the first argument, it starts with the length of the byte array in elements, in this case, 4.
  • 0x6461766500000000000000000000000000000000000000000000000000000000: the contents of the first argument: the UTF-8 (equal to ASCII in this case) encoding of "dave", padded on the right to 32 bytes.
  • 0x0000000000000000000000000000000000000000000000000000000000000003: the data part of the third argument, it starts with the length of the array in elements, in this case, 3.
  • 0x0000000000000000000000000000000000000000000000000000000000000001: the first entry of the third parameter.
  • 0x0000000000000000000000000000000000000000000000000000000000000002: the second entry of the third parameter.
  • 0x0000000000000000000000000000000000000000000000000000000000000003: the third entry of the third parameter.

In total:

0x8FF261B00000000000000000000000000000000000000000000000000000000000000060000000000000000000000000000000000000000000000000000000000000000100000000000000000000000000000000000000000000000000000000000000c0000000000000000000000000000000000000000000000000000000000000000464617665000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000003000000000000000000000000000000000000000000000000000000000000000100000000000000000000000000000000000000000000000000000000000000020000000000000000000000000000000000000000000000000000000000000003

Use of Dynamic Types

A call to a function with the signature f(uint,uint32[],bytes10,bytes) with values (0x123, [0x456, 0x789], "1234567890", "Hello, world!") is encoded in the following way:

We take the first four bytes of sha3("f(uint256,uint32[],bytes10,bytes)"), i.e. 0x8be65246. Then we encode the head parts of all four arguments. For the static types uint256 and bytes10, these are directly the values we want to pass, whereas for the dynamic types uint32[] and bytes, we use the offset in bytes to the start of their data area, measured from the start of the value encoding (i.e. not counting the first four bytes containing the hash of the function signature). These are:

  • 0x0000000000000000000000000000000000000000000000000000000000000123 (0x123 padded to 32 bytes)
  • 0x0000000000000000000000000000000000000000000000000000000000000080 (offset to start of data part of second parameter, 4*32 bytes, exactly the size of the head part)
  • 0x3132333435363738393000000000000000000000000000000000000000000000 ("1234567890" padded to 32 bytes on the right)
  • 0x00000000000000000000000000000000000000000000000000000000000000e0 (offset to start of data part of fourth parameter = offset to start of data part of first dynamic parameter + size of data part of first dynamic parameter = 432 + 332 (see below))

After this, the data part of the first dynamic argument, [0x456, 0x789] follows:

  • 0x0000000000000000000000000000000000000000000000000000000000000002 (number of elements of the array, 2)
  • 0x0000000000000000000000000000000000000000000000000000000000000456 (first element)
  • 0x0000000000000000000000000000000000000000000000000000000000000789 (second element)

Finally, we encode the data part of the second dynamic argument, "Hello, world!":

  • 0x000000000000000000000000000000000000000000000000000000000000000d (number of elements (bytes in this case): 13)
  • 0x48656c6c6f2c20776f726c642100000000000000000000000000000000000000 ("Hello, world!" padded to 32 bytes on the right)

All together, the encoding is (spaces added for clarity):

0x8be65246 0000000000000000000000000000000000000000000000000000000000000123 0000000000000000000000000000000000000000000000000000000000000080 3132333435363738393000000000000000000000000000000000000000000000 00000000000000000000000000000000000000000000000000000000000000e0 0000000000000000000000000000000000000000000000000000000000000002 0000000000000000000000000000000000000000000000000000000000000456 0000000000000000000000000000000000000000000000000000000000000789 000000000000000000000000000000000000000000000000000000000000000d 48656c6c6f2c20776f726c642100000000000000000000000000000000000000

Events

Events are an abstraction of the Ethereum logging/event-watching protocol. Log entries provide the contract's address, a series of up to four topics and some arbitrary length binary data. Events leverage the existing function ABI in order to interpret this (together with an interface spec) as a properly typed structure.

Given an event name and series of event parameters, we split them into two sub-series: those which are indexed and those which are not. Those which are indexed, which may number up to 3, are used alongside the Keccak hash of the event signature to form the topics of the log entry. Those which as not indexed form the byte array of the event.

In effect, a log entry using this ABI is described as:

  • address: the address of the contract (intrinsically provided by Ethereum);
  • topics[0]: keccak(EVENT_NAME+"("+EVENT_ARGS.map(canonical_type_of).join(",")+")") (canonical_type_of is a function that simply returns the canonical type of a given argument, e.g. for uint indexed foo, it would return uint256). If the event is declared as anonymous the topics[0] is not generated;
  • topics[n]: EVENT_INDEXED_ARGS[n - 1] (EVENT_INDEXED_ARGS is the series of EVENT_ARGS that are indexed);
  • data: abi_serialise(EVENT_NON_INDEXED_ARGS) (EVENT_NON_INDEXED_ARGS is the series of EVENT_ARGS that are not indexed, abi_serialise is the ABI serialisation function used for returning a series of typed values from a function, as described above).

JSON

The JSON format for a contract's interface is given by an array of function and/or event descriptions. A function description is a JSON object with the fields:

  • type: "function" or "constructor" (can be omitted, defaulting to function);
  • name: the name of the function (only present for function types);
  • inputs: an array of objects, each of which contains:
  • name: the name of the parameter;
  • type: the canonical type of the parameter.
  • outputs: an array of objects similar to inputs, can be omitted.

An event description is a JSON object with fairly similar fields:

  • type: always "event"
  • name: the name of the event;
  • inputs: an array of objects, each of which contains:
  • name: the name of the parameter;
  • type: the canonical type of the parameter.
  • indexed: true if the field is part of the log's topics, false if it one of the log's data segment.
  • anonymous: true if the event was declared as anonymous.

For example,

contract Test {
function Test(){ b = 0x12345678901234567890123456789012; }
event Event(uint indexed a, bytes32 b)
event Event2(uint indexed a, bytes32 b)
function foo(uint a) { Event(a, b); }
bytes32 b;
}

would result in the JSON:

[{
"type":"event",
"inputs": [{"name":"a","type":"uint256","indexed":true},{"name":"b","type":"bytes32","indexed":false}],
"name":"Event"
}, {
"type":"event",
"inputs": [{"name":"a","type":"uint256","indexed":true},{"name":"b","type":"bytes32","indexed":false}],
"name":"Event2"
}, {
"type":"event",
"inputs": [{"name":"a","type":"uint256","indexed":true},{"name":"b","type":"bytes32","indexed":false}],
"name":"Event2"
}, {
"type":"function",
"inputs": [{"name":"a","type":"uint256"}],
"name":"foo",
"outputs": []
}]

Example Javascript Usage

var Test = eth.contract(
[{
"type":"event",
"inputs": [{"name":"a","type":"uint256","indexed":true},{"name":"b","type":"bytes32","indexed":false}],
"name":"Event"
}, {
"type":"event",
"inputs": [{"name":"a","type":"uint256","indexed":true},{"name":"b","type":"bytes32","indexed":false}],
"name":"Event2"
}, {
"type":"function",
"inputs": [{"name":"a","type":"uint256"}],
"name":"foo",
"outputs": []
}]);
var theTest = new Test(addrTest);

// examples of usage:
// every log entry ("event") coming from theTest (i.e. Event & Event2):
var f0 = eth.filter(theTest);
// just log entries ("events") of type "Event" coming from theTest:
var f1 = eth.filter(theTest.Event);
// also written as
var f1 = theTest.Event();
// just log entries ("events") of type "Event" and "Event2" coming from theTest:
var f2 = eth.filter([theTest.Event, theTest.Event2]);
// just log entries ("events") of type "Event" coming from theTest with indexed parameter 'a' equal to 69:
var f3 = eth.filter(theTest.Event, {'a': 69});
// also written as
var f3 = theTest.Event({'a': 69});
// just log entries ("events") of type "Event" coming from theTest with indexed parameter 'a' equal to 69 or 42:
var f4 = eth.filter(theTest.Event, {'a': [69, 42]});
// also written as
var f4 = theTest.Event({'a': [69, 42]});

// options may also be supplied as a second parameter with `earliest`, `latest`, `offset` and `max`, as defined for `eth.filter`.
var options = { 'max': 100 };
var f4 = theTest.Event({'a': [69, 42]}, options);

var trigger;
f4.watch(trigger);

// call foo to make an Event:
theTest.foo(69);

// would call trigger like:
//trigger(theTest.Event, {'a': 69, 'b': '0x12345678901234567890123456789012'}, n);
// where n is the block number that the event triggered in.

Implementation:

// e.g. f4 would be similar to:
web3.eth.filter({'max': 100, 'address': theTest.address, 'topics': [ [69, 42] ]});
// except that the resultant data would need to be converted from the basic log entry format like:
{
  'address': theTest.address,
  'topics': [web3.sha3("Event(uint256,bytes32)"), 0x00...0045 /* 69 in hex format */],
  'data': '0x12345678901234567890123456789012',
  'number': n
}
// into data good for the trigger, specifically the three fields:
  Test.Event // derivable from the first topic
  {'a': 69, 'b': '0x12345678901234567890123456789012'} // derivable from the 'indexed' bool in the interface, the later 'topics' and the 'data'
  n // from the 'number'

Event result:

[ {
  'event': Test.Event,
  'args': {'a': 69, 'b': '0x12345678901234567890123456789012'},
  'number': n
  },
  { ...
  } ...
]

JUST DONE! [develop branch]

NOTE: THIS IS OLD - IGNORE IT unless reading for historical purposes

  • Internal LogFilter, log-entry matching mechanism and eth_installFilter needs to support matching multiple values (OR semantics) per topic index (at present it will only match topics with AND semantics and set-inclusion, not per-index).

i.e. at present you can only ask for each of a number of given topic values to be matched throughout each topic:

  • topics: [69, 42, "Gav"] would match against logs with 3 topics [42, 69, "Gav"], ["Gav", 69, 42] but not against logs with topics [42, 70, "Gav"].

we need to be able to provide one of a number of topic values, and, each of these options for each topic index:

  • topics: [[69, 42], [] /* anything */, "Gav"] should match against logs with 3 topics [42, 69, "Gav"], [42, 70, "Gav"] but not against ["Gav", 69, 42].