4 Transforming data using choices¶
In the example in Contract keys the accountant party wanted to change some data on a contract. They did so by archiving the contract and re-creating it with the updated data. That works because the accountant is the sole signatory on the Account
contract defined there.
But what if the accountant wanted to allow the bank to change their own telephone number? Or what if the owner of a CashBalance
should be able to transfer ownership to someone else?
In this section you will learn about how to define simple data transformations using choices and how to delegate the right to exercise these choices to other parties.
Hint
Remember that you can load all the code for this section into a folder called 4_Transformations
by running daml new 4_Transformations daml-intro-4
Choices as methods¶
If you think of templates as classes and contracts as objects, where are the methods?
Take as an example a Contact
contract on which the contact owner wants to be able to change the telephone number, just like on the Account
in Contract keys. Rather than requiring them to manually look up the contract, archive the old one and create a new one, you can provide them a convenience method on Contact
:
template Contact
with
owner : Party
party : Party
address : Text
telephone : Text
where
signatory owner
controller owner can
UpdateTelephone
: ContractId Contact
with
newTelephone : Text
do
create this with
telephone = newTelephone
The above defines a choice called UpdateTelephone
. Choices are part of a contract template. They’re permissioned functions that result in an Update
. Using choices, authority can be passed around, allowing the construction of complex transactions.
Let’s unpack the code snippet above:
The first line,
controller owner can
says that the following choices are controlled byowner
, meaningowner
is the only party that is allowed to exercise them. The line starts a new block in which multiple choices can be defined.UpdateTelephone
is the name of a choice. It starts a new block in which that choice is defined.: ContractId Contact
is the return type of the choice.This particular choice archives the current
Contact
, and creates a new one. What it returns is a reference to the new contract, in the form of aContractId Contact
The following
with
block is that of a record. Just like with templates, in the background, a new record type is declared:data UpdateTelephone = UpdateTelephone with
The
do
starts a block defining the action the choice should perform when exercised. In this case a newContact
is created.The new
Contact
is created usingthis with
.this
is a special value available within thewhere
block of templates and takes the value of the current contract’s arguments.
There is nothing here explicitly saying that the current Contact
should be archived. That’s because choices are consuming by default. That means when the above choice is exercised on a contract, that contract is archived.
If you paid a lot of attention in 3 Data types, you may have noticed that the create
statement returns an Update (ContractId Contact)
, not a ContractId Contact
. As a do
block always returns the value of the last statement within it, the whole do
block returns an Update
, but the return type on the choice is just a ContractId Contact
. This is a convenience. Choices always return an Update
so for readability it’s omitted on the type declaration of a choice.
Now to exercise the new choice in a scenario:
choice_test = scenario do
owner <- getParty "Alice"
party <- getParty "Bob"
contactCid <- submit owner do
create Contact with
owner
party
address = "1 Bobstreet"
telephone = "012 345 6789"
-- The bank can't change its own telephone number as the accountant controls
-- that choice.
submitMustFail party do
exercise contactCid UpdateTelephone with
newTelephone = "098 7654 321"
newContactCid <- submit owner do
exercise contactCid UpdateTelephone with
newTelephone = "098 7654 321"
submit owner do
newContact <- fetch newContactCid
assert (newContact.telephone == "098 7654 321")
You exercise choices using the exercise
function, which takes a ContractId a
, and a value of type c
, where c
is a choice on template a
. Since c
is just a record, you can also just fill in the choice parameters using the with
syntax you are already familiar with.
exercise
returns an Update r
where r
is the return type specified on the choice, allowing the new ContractId Contact
to be stored in the variable new_contactCid
.
Choices as delegation¶
Up to this point all the contracts only involved one party. party
may have been stored as Party
field in the above, which suggests they are actors on the ledger, but they couldn’t see the contracts, nor change them in any way. It would be reasonable for the party for which a Contact
is stored to be able to update their own address and telephone number. In other words, the owner
of a Contact
should be able to delegate the right to perform a certain kind of data transformation to party
.
The below demonstrates this using an UpdateAddress
choice and corresponding extension of the scenario:
controller party can
UpdateAddress
: ContractId Contact
with
newAddress : Text
do
create this with
address = newAddress
newContactCid <- submit party do
exercise newContactCid UpdateAddress with
newAddress = "1-10 Bobstreet"
submit owner do
newContact <- fetch newContactCid
assert (newContact.address == "1-10 Bobstreet")
If you open the scenario view in the IDE, you will notice that Bob sees the Contact
. Controllers specified via controller c can
syntax become observers of the contract. More on observers later, but in short, they get to see any changes to the contract.
Choices in the Ledger Model¶
In 1 Basic contracts you learned about the high-level structure of a DAML ledger. With choices and the exercise function, you have the next important ingredient to understand the structure of the ledger and transactions.
A transaction is a list of actions, and there are just four kinds of action: create
, exercise
, fetch
and key assertion
.
- A
create
action creates a new contract with the given arguments and sets its status to active. - A
fetch
action checks the existence and activeness of a contract. - An
exercise
action exercises a choice on a contract resulting in a transaction (list of sub-actions) called the consequences. Exercises come in two kinds calledconsuming
andnonconsuming
.consuming
is the default kind and changes the contract’s status from active to archived. - A
key assertion
records the assertion that the given contract key (see Contract keys) is not assigned to any active contract on the ledger.
Each action can be visualized as a tree, where the action is the root node, and its children are its consequences. Every consequence may have further consequences. As fetch
, create
and key assertion
actions have no consequences, they are always leaf nodes. You can see the actions and their consequences in the transaction view of the above scenario:
Transactions:
TX #0 1970-01-01T00:00:00Z (Contact:43:17)
#0:0
│ consumed by: #2:0
│ referenced by #2:0
│ known to (since): 'Alice' (#0), 'Bob' (#0)
└─> create Contact:Contact
with
owner = 'Alice'; party = 'Bob'; address = "1 Bobstreet"; telephone = "012 345 6789"
TX #1 1970-01-01T00:00:00Z
mustFailAt 'Bob' (Contact:52:3)
TX #2 1970-01-01T00:00:00Z (Contact:56:22)
#2:0
│ known to (since): 'Alice' (#2), 'Bob' (#2)
└─> 'Alice' exercises UpdateTelephone on #0:0 (Contact:Contact)
with
newTelephone = "098 7654 321"
children:
#2:1
│ consumed by: #4:0
│ referenced by #3:0, #4:0
│ known to (since): 'Alice' (#2), 'Bob' (#2)
└─> create Contact:Contact
with
owner = 'Alice'; party = 'Bob'; address = "1 Bobstreet"; telephone = "098 7654 321"
TX #3 1970-01-01T00:00:00Z (Contact:60:3)
#3:0
└─> fetch #2:1 (Contact:Contact)
TX #4 1970-01-01T00:00:00Z (Contact:66:22)
#4:0
│ known to (since): 'Alice' (#4), 'Bob' (#4)
└─> 'Bob' exercises UpdateAddress on #2:1 (Contact:Contact)
with
newAddress = "1-10 Bobstreet"
children:
#4:1
│ referenced by #5:0
│ known to (since): 'Alice' (#4), 'Bob' (#4)
└─> create Contact:Contact
with
owner = 'Alice';
party = 'Bob';
address = "1-10 Bobstreet";
telephone = "098 7654 321"
TX #5 1970-01-01T00:00:00Z (Contact:70:3)
#5:0
└─> fetch #4:1 (Contact:Contact)
Active contracts: #4:1
Return value: {}
There are four commits corresponding to the four submit
statements in the scenario. Within each commit, we see that it’s actually actions that have IDs of the form #commit_number:action_number
. Contract IDs are just the ID of their create
action.
So commits #2
and #4
contain exercise
actions with IDs #2:0
and #4:0
. The create
actions of the updated, Contact
contracts, #2:1
and #4:1
, are indented and found below a line reading children:
, making the tree structure apparent.
The Archive choice¶
You may have noticed that there is no archive action. That’s because archive cid
is just shorthand for exercise cid Archive
, where Archive
is a choice implicitly added to every template, with the signatories as controllers.
A simple cash model¶
With the power of choices, you can build your first interesting model: issuance of cash IOUs (I owe you). The model presented here is simpler than the one in 3 Data types as it’s not concerned with the location of the physical cash, but merely with liabilities:
-- Copyright (c) 2020 Digital Asset (Switzerland) GmbH and/or its affiliates. All rights reserved.
-- SPDX-License-Identifier: Apache-2.0
module SimpleIou where
data Cash = Cash with
currency : Text
amount : Decimal
deriving (Eq, Show)
template SimpleIou
with
issuer : Party
owner : Party
cash : Cash
where
signatory issuer
controller owner can
Transfer
: ContractId SimpleIou
with
newOwner : Party
do
create this with owner = newOwner
test_iou = scenario do
alice <- getParty "Alice"
bob <- getParty "Bob"
charlie <- getParty "Charlie"
dora <- getParty "Dora"
-- The bank issues an Iou for $100 to Alice.
iou <- submit dora do
create SimpleIou with
issuer = dora
owner = alice
cash = Cash with
amount = 100.0
currency = "USD"
-- Alice transfers it to Bob.
iou2 <- submit alice do
exercise iou Transfer with
newOwner = bob
-- Bob transfers it to Charlie.
submit bob do
exercise iou2 Transfer with
newOwner = charlie
The above model is fine as long as everyone trusts Dora. Dora could revoke the SimpleIou at any point by archiving it. However, the provenance of all transactions would be on the ledger so the owner could prove that Dora was dishonest and cancelled her debt.
Next up¶
You can now store and transform data on the ledger, even giving other parties specific write access through choices.
In 5 Adding constraints to a contract, you will learn how to restrict data and transformations further. In that context, you will also learn about time on DAML ledgers, do
blocks and <-
notation within those.