CIP | Title | Authors | Discussions-To | Comments-URI | Category | Status | Type | Created | License | Requires |
---|---|---|---|---|---|---|---|---|---|---|
42 |
New Plutus built-in serialiseData |
Matthias Benkort <matthias.benkort@iohk.io>, Sebastian Nagel <sebastian.nagel@iohk.io> |
Plutus |
Active |
Standards Track |
2022-02-09 |
Apache-2.0 |
CIP-35 |
This document describes the addition of a new Plutus builtin for serialising BuiltinData
to BuiltinByteString
.
As part of developing on-chain script validators for the Hydra Head protocol, we stumble across a peculiar need for on-chain scripts: we need to verify and compare digests obtained from hashing elements of the script's surrounding transaction.
In this particular context, those elements are transaction outputs (a.k.a. TxOut
). While Plutus already provides built-in for hashing data-structure (e.g. sha2_256 :: BuiltinByteString -> BuiltinByteString
), it does not provide generic ways of serialising some data type to BuiltinByteString
.
In an attempt to pursue our work, we have implemented an on-chain library (plutus-cbor) for encoding data-types as structured CBOR / RFC 8949 in a relatively efficient way (although still quadratic, it is as efficient as it can be with Plutus' available built-ins) and measured the memory and CPU cost of encoding TxOut
in a script validator on-chain.
The above graph shows the memory and CPU costs relative against a baseline, of encoding a TxOut
using plutus-cbor
in function of the number of assets present in that TxOut
. The costs on the y-axis are relative to the maximum execution budgets (as per mainnet's parameters, December 2021) allowed for a single script execution. As can be seen, this is of linear complexity, i.e. O(n) in terms of the number of assets. These results can be reproduced using the encoding-cost executable in our repository.
Note that we have also calculated similar costs for ada-only
TxOut
, in function of the number ofTxOut
which is about twice as worse but of similar linear shape.
We we can see on the graph, the cost is manageable for a small number of assets (or equivalently, a small number of outputs) but rapidly becomes limiting. Ideally, we would prefer the transaction size to be the limiting factor when it comes to the number of outputs we can handle in a single validation.
Besides, in our discussions with the Marlowe team, we also discovered that they shared a similar problem when it came to serialising merkleized ASTs.
Underneath it all, it seems that it would be beneficial to have a new built-in at our disposal to serialise any Plutus BuiltinData
to BuiltinByteString
such that validators could leverage more optimized implementations and bytestring builders via built-ins than what's available on-chain, hopefully reducing the overall memory and CPU costs.
We define a new Plutus built-in function with the following type signature:
serialiseData :: BuiltinData -> BuiltinByteString
Behind the scene, we expect this function to use a well-known encoding format to ease construction of such serialisation off-chain (in particular, for non-Haskell off-chain contract codes). A natural choice of binary data format in this case is CBOR which is:
- Efficient;
- Relatively simple;
- Use pervasively across the Cardano ecosystem
Furthermore, the Plutus' ecosystem already provides a quite opinionated implementation of a CBOR encoder for built-in Data
. For the sake of documenting it as part of this proposal, we provide here-below the CDDL specification of that existing implementation:
plutus_data =
constr<plutus_data>
/ { * plutus_data => plutus_data }
/ [ * plutus_data ]
/ big_int
/ bounded_bytes
constr<a> =
#6.121([])
/ #6.122([a])
/ #6.123([a, a])
/ #6.124([a, a, a])
/ #6.125([a, a, a, a])
/ #6.126([a, a, a, a, a])
/ #6.127([a, a, a, a, a, a])
; similarly for tag range: #6.1280 .. #6.1400 inclusive
/ #6.102([uint, [* a]])
big_int = int / big_uint / big_nint
big_uint = #6.2(bounded_bytes)
big_nint = #6.3(bounded_bytes)
bounded_bytes = bytes .size (0..64)
NOTE: The CDDL specification is extracted from the wider alonzo_cddl specification of the Cardano ledger.
The Data
type is a recursive data-type, so costing it properly is a little tricky. The Plutus source code defines an instance of ExMemoryUsage
for Data
with the following interesting note:
This accounts for the number of nodes in a
Data
object, and also the sizes of the contents of the nodes. This is not ideal, but it seems to be the best we can do. At present this only comes into play for 'equalsData', which is implemented using the derived implementation of '==' [...].
We propose to re-use this instance to define a cost model linear in the size of data defined by this instance. What remains is to find a proper coefficient and offset for that linear model. To do so, we can benchmark the execution costs of encoding arbitrarily generated Data
of various sizes, and retro-fit the cost into a linear model (provided that the results are still attesting for that type of model).
Benchmarking and costing serialiseData
was done in this PR according to this strategy. As the benchmark is not very uniform, because some cases of Data
"structures" differ in CPU time taken to process, the linear model is used as an upper bound and thus conservatively overestimating actual costs.
-
Easy to implement as it reuses existing code of the Plutus codebase;
-
Such built-in is generic enough to also cover a wider set of use-cases, while nicely fitting ours;
-
Favoring manipulation of structured
Data
is an appealing alternative to manyByteString
manipulation use-cases; -
CBOR as encoding is a well-known and widely used standard in Cardano, existing tools can be used;
-
The hypothesis on the cost model here is that serialisation cost would be proportional to the
ExMemoryUsage
forData
; which means, given the current implementation, proportional to the number and total memory usage of nodes in theData
tree-like structure. -
Benchmarking the costs of serialising
TxOut
values between plutus-cbor and cborg confirms cborg and the existing encodeData's implementation in Plutus as a great candidate for implementing the built-in:Results can be reproduced with the plutus-cbor benchmark.
- Using the existing sizing metric for
Data
, we need to determine a costing function (using existing tooling / benchmarks? TBD) - The Plutus team updates plutus to add the built-in to PlutusV1 and PlutusV2 and uses a suitable cost function
- The binary format of
Data
is documented and embraced as an interface withinplutus
. - Release it as a backward-compatible change within the next hard-fork
-
We have identified that the cost mainly stems from concatenating bytestrings; so possibly, an alternative to this proposal could be a better way to concatenate (or to cost) bytestrings (Builders in Plutus?)
-
If costing for
BuiltinData
is unsatisfactory, maybe we want have only well-known input types, e.g.TxIn
,TxOut
,Value
and so on..WellKnown t => t -> BuiltinByteString
- Additional built-in: so can be added to PlutusV1 and PlutusV2 without breaking any existing script validators. A hard-fork is however required as it would makes more blocks validate.
This CIP is licensed under Apache-2.0