def update(self, params):
# If there is no value for the public key, the oracle is revoked. Ignore updates.
sp.verify(self.data.publicKey.is_some(), "revoked")
# Iterate over assets in the input map.
keyValueList = params.items()
sp.for assetData in keyValueList:
# Extract asset names, signatures, and the new data.
assetName = assetData.key
signature = sp.compute(sp.fst(assetData.value))
newData = sp.compute(sp.snd(assetData.value))
# Verify Oracle is tracking this asset.
sp.if self.data.oracleData.contains(assetName):
# Verify start timestamp is newer than the last update.
oldData = sp.compute(self.data.oracleData[assetName])
oldStartTime = sp.compute(sp.fst(oldData))
newStartTime = sp.compute(sp.fst(newData))
sp.if newStartTime > oldStartTime:
# Verify signature.
bytes = sp.pack((assetName, newData))
sp.verify(
sp.check_signature(
self.data.publicKey.open_some(), signature, bytes
),
"bad sig"
)
# Replace the data.
self.data.oracleData[assetName] = newData
def token_metadata(self, params):
sp.verify( ~self.is_paused() )
sp.set_type(params,
sp.TRecord(
token_ids = sp.TList(sp.TNat),
handler = sp.TLambda(
sp.TList(self.token_meta_data.get_type()),
sp.TUnit)
).layout(("token_ids", "handler")))
def f_on_request(req):
self.token_meta_data.set_type_and_layout(self.data.token_metadata[req])
sp.result(self.data.token_metadata[req])
sp.compute(params.handler(params.token_ids.map(f_on_request)))
def receiveNft(self, nft):
sp.set_type(nft, sp.TTicket(sp.TNat))
ticket_data, ticket_next = sp.read_ticket(nft)
qty = sp.compute(sp.snd(sp.snd(ticket_data)))
originator = sp.compute(sp.fst(ticket_data))
id = sp.compute(sp.fst(sp.snd(ticket_data)))
sp.verify(qty == 1, "Only send 1 Nft to this entrypoint")
sp.verify(sp.source == self.data.admin,
"Ticket needs to be sent by wallet admin")
current_id = self.data.current_id
new_map = sp.update_map(self.data.tickets, current_id,
sp.some(ticket_next))
self.data.tickets = new_map
self.data.current_id = current_id + 1
def update(self, updateMap):
sp.set_type(updateMap, sp.TBigMap(sp.TString, Harbinger.OracleDataType))
# Verify the sender is the whitelisted oracle contract.
sp.verify(
sp.sender == self.data.oracleContract,
message="bad sender"
)
# Iterate over assets this normalizer is tracking
sp.for assetCode in self.data.assetCodes:
# Only process updates if this normalizer is tracking the asset code.
sp.if updateMap.contains(assetCode):
assetData = updateMap.get(assetCode)
# Only process updates that are monotonically increasing in start times.
updateStartTime = sp.compute(sp.fst(assetData))
sp.if updateStartTime > self.data.assetMap[assetCode].lastUpdateTime:
# Extract required information
endPair = sp.compute(sp.snd(assetData))
openPair = sp.compute(sp.snd(endPair))
highPair = sp.compute(sp.snd(openPair))
lowPair = sp.compute(sp.snd(highPair))
closeAndVolumePair = sp.compute(sp.snd(lowPair))
high = sp.compute(sp.fst(highPair))
low = sp.compute(sp.fst(lowPair))
close = sp.compute(sp.fst(closeAndVolumePair))
volume = sp.compute(sp.snd(closeAndVolumePair))
# Ignore candles with zero volumes.
sp.if volume > 0:
# Calculate the the price for this data point.
# average price * volume
volumePrice = ((high + low + close) / 3) * volume
# Update the last updated time.
self.data.assetMap[assetCode].lastUpdateTime = updateStartTime
# Push the latest items to the FIFO queue
fifoDT.push(self.data.assetMap[assetCode].prices, volumePrice)
fifoDT.push(self.data.assetMap[assetCode].volumes, volume)
# Trim the queue if it exceeds the number of data points.
sp.if fifoDT.len(self.data.assetMap[assetCode].prices) > self.data.numDataPoints:
fifoDT.pop(self.data.assetMap[assetCode].prices)
fifoDT.pop(self.data.assetMap[assetCode].volumes)
def get(self, requestPair):
sp.set_type(requestPair, sp.TPair(sp.TString, sp.TContract(sp.TPair(sp.TString, sp.TPair(sp.TTimestamp, sp.TNat)))))
# Destructure the arguments.
requestedAsset = sp.compute(sp.fst(requestPair))
callback = sp.compute(sp.snd(requestPair))
# Verify this normalizer has data for the requested asset.
sp.verify(
self.data.assetMap.contains(requestedAsset),
message="bad request"
)
# Callback with the requested data.
assetData = self.data.assetMap[requestedAsset]
normalizedPrice = assetData.computedPrice
lastUpdateTime = assetData.lastUpdateTime
callbackParam = (requestedAsset, (lastUpdateTime, normalizedPrice))
sp.transfer(callbackParam, sp.mutez(0), callback)
def cancel_request(self, client_request_id):
# We do not want to check active here (it would be bad for the client).
# sp.sender needs to be validated; this process is done through the use of the reverse_request_key.
reverse_request_key = sp.compute(sp.record(client = sp.sender, client_request_id = client_request_id))
request_id = sp.local('request_id', self.data.reverse_requests[reverse_request_key]).value
request = sp.local('request', self.data.requests[request_id]).value
sp.verify(request.timeout <= sp.now, message = "TTL not met")
token = sp.contract(self.token_contract.batch_transfer.get_type(), self.data.token, entry_point = "transfer").open_some(message = "Incompatible token interface")
sp.transfer([sp.record(from_ = sp.to_address(sp.self), txs = [sp.record(to_ = request.client, token_id = 0, amount = request.amount)])],
sp.tez(0),
token)
del self.data.requests[request_id]
del self.data.reverse_requests[reverse_request_key]
def create_request(self, client, params):
sp.verify(sp.sender == self.data.token, message = "Invalid source")
sp.verify(self.data.active, message = "Inactive")
amount = params.amount
target = params.target
job_id = params.job_id
parameters = params.parameters
timeout = params.timeout
sp.verify(self.data.min_amount <= amount, message = "Invalid payment")
sp.verify(sp.now.add_minutes(self.data.min_timeout_minutes) <= timeout, message = "Invalid timeout")
client_request_id = params.client_request_id
new_request = sp.record(client = client,
target = target,
job_id = job_id,
parameters = parameters,
amount = amount,
timeout = timeout,
client_request_id = client_request_id)
reverse_request_key = sp.compute(sp.record(client = client, client_request_id = client_request_id))
sp.verify(~self.data.reverse_requests.contains(reverse_request_key), message = "Bad request key")
self.data.reverse_requests[reverse_request_key] = self.data.next_id
self.data.requests[self.data.next_id] = new_request
self.data.next_id += 1
def collect(self, amount):
sp.verify(sp.sender == self.data.owner, 'Only owner can collect.')
max_collect = sp.compute(sp.split_tokens(sp.balance,sp.nat(100),self.data.max_collect_percent))
sp.verify(amount <= max_collect, 'Withdrawal amount exceeds allowed limit.')
sp.if (self.data.next_collect.is_some()):
sp.verify(sp.some(sp.now) > self.data.next_collect, 'Withdrawal frequency exceeds limit.')
