public async Task QueueAllEventsForMakerDAOContract() { // Load config // - this will contain the secrets and connection strings we don't want to hard code var config = TestConfiguration.LoadConfig(); string azureStorageConnectionString = config["AzureStorageConnectionString"]; // Create a proxy for the blockchain var web3 = new Web3.Web3(TestConfiguration.BlockchainUrls.Infura.Mainnet); // Create Queue Factory // - In this sample we're targetting Azure // - The factory communicates with Azure to create and get different queues var queueFactory = new AzureSubscriberQueueFactory(azureStorageConnectionString); // Create a Queue // - This is where we're going to put the matching event logs var queue = await queueFactory.GetOrCreateQueueAsync("makerdaoevents"); // Get the maker DAO contract abi // - from this we're able to match and decode the events in the contract var contractAbi = new ABIDeserialiser().DeserialiseContract(MAKER_DAO_ABI); // Create an event subscription for these events // - Passing in the maker dao address to ensure only logs with a matching address are processed // - There is an option to pass an implementation of IEventHandlerHistoryRepository in to the constructor // - This would record history for each event handler and is used to prevent duplication var eventSubscription = new EventSubscription(contractAbi.Events, new[] { MAKER_CONTRACT_ADDRESS }); // Assign the queue to the event subscription // - Matching events will be written to this queue // - By default a generic message is written to the queue // - The message contains the raw log (aka FilterLog), decoded event parameter values and event metadata // - Therefore the message schema is consistent across all messages sent to any queues // - However - should you require your own queue message schema the method below accepts a custom message mapper // - Ultimately the message is converted to json eventSubscription.AddQueueHandler(queue); // Azure storage setup // - this example reads and writes block progress to an Azure storage table // - to avoid collision with other samples we provide a prefix var storageCloudSetup = new CloudTableSetup(azureStorageConnectionString, prefix: $"makerdao"); // Create a progress repository // - It stores and retrieves the most recent block processed var blockProgressRepo = storageCloudSetup.CreateBlockProgressRepository(); // Create a progress service // - This uses the progress repo to dictate what blocks to process next // - The MIN_BLOCK_NUMBER dictates the starting point if the progress repo is empty or has fallen too far behind var progressService = new BlockProgressService(web3, MIN_BLOCK_NUMBER, blockProgressRepo); // Create a filter // - This is essentially the query that is sent to the chain when retrieving logs // - It is OPTIONAL - without it, all logs in the block range are requested // - The filter is invoked before any event subscriptions evaluate the logs // - The subscriptions are free to implement their own matching logic // - In this sample we're only interested in MakerDAO logs // - Therefore it makes sense to restrict the number of logs to retrieve from the chain var makerAddressFilter = new NewFilterInput() { Address = new[] { MAKER_CONTRACT_ADDRESS } }; // Create a log processor // - This uses the blockchainProxy to get the logs // - It sends each log to the event subscriptions to indicate if the logs matches the subscription criteria // - It then allocates matching logs to separate batches per event subscription var logProcessor = new BlockRangeLogsProcessor(web3, new[] { eventSubscription }, makerAddressFilter); // Create a batch log processor service // - It uses the progress service to calculates the block range to progress // - It then invokes the log processor - passing in the range to process // - It updates progress via the progress service var batchProcessorService = new LogsProcessor(logProcessor, progressService, MAX_BLOCKS_PER_BATCH); // execute try { // Optional cancellation token // - Useful for cancelling long running processing operations var ctx = new System.Threading.CancellationTokenSource(); // instruct the service to get and process the next range of blocks // when the rangeProcessed is null - it means there was nothing to process var rangeProcessed = await batchProcessorService.ProcessOnceAsync(ctx.Token); // ensure we have processed the expected number of events // the event subscription has state which can record running totals across many processing batches Assert.Equal(16, eventSubscription.State.GetInt("EventsHandled")); // get the message count from the queue Assert.Equal(16, await queue.GetApproxMessageCountAsync()); } finally { // delete any data from Azure await ClearDown(queue, storageCloudSetup, queueFactory); } }
public async Task WritingCustomMessagesToTheQueue() { // Load config // - this will contain the secrets and connection strings we don't want to hard code var config = TestConfiguration.LoadConfig(); string azureStorageConnectionString = config["AzureStorageConnectionString"]; // Create a proxy for the blockchain var web3 = new Web3.Web3(TestConfiguration.BlockchainUrls.Infura.Mainnet); // Create Queue Factory // - In this sample we're targetting Azure // - The factory communicates with Azure to create and get different queues var queueFactory = new AzureSubscriberQueueFactory(azureStorageConnectionString); // Create a Queue // - This is where we're going to put the matching event logs var queue = await queueFactory.GetOrCreateQueueAsync("makerdaotransferscustom"); // Create an event subscription specifically for ERC20 Transfers // - Passing in the maker dao address to ensure only logs with a matching address are processed // - There is an option to pass an implementation of IEventHandlerHistoryRepository in to the constructor // - This would record history for each event handler and is used to prevent duplication var eventSubscription = new EventSubscription <TransferEventDto>( contractAddressesToMatch: new[] { MAKER_CONTRACT_ADDRESS }); // Create a mapper that will convert the DecodedEvent into a custom message we want on the queue // In this sample we're using a subscription that is specific to an EventDTO (EventSubscription<TransferEventDto>) // This ensures that the decodedEvent.DecodedEventDto property is populated during processing // ( If the subscription is not tied to an EventDTO the decodedEvent.DecodedEventDto property would be null // BUT we can still read the event arguments (aka parameters or topics) from the decodedEvent.Event property) var queueMessageMapper = new QueueMessageMapper((decodedEvent) => { return(new CustomQueueMessageForTransfers { BlockNumber = decodedEvent.Log.BlockNumber.Value.ToString(), TransactionHash = decodedEvent.Log.TransactionHash, LogIndex = decodedEvent.Log.LogIndex.Value.ToString(), Transfer = decodedEvent.DecodedEventDto as TransferEventDto }); }); // Assign the queue to the event subscription // - Matching events will be written to this queue // - Pass a custom mapper to create a suitable queue message // - Ultimately the message is converted to json eventSubscription.AddQueueHandler(queue, queueMessageMapper); // Azure storage setup // - this example reads and writes block progress to an Azure storage table // - to avoid collision with other samples we provide a prefix var storageCloudSetup = new CloudTableSetup(azureStorageConnectionString, prefix: $"makerdaotransferscustom"); // Create a progress repository // - It stores and retrieves the most recent block processed var blockProgressRepo = storageCloudSetup.CreateBlockProgressRepository(); // Create a progress service // - This uses the progress repo to dictate what blocks to process next // - The MIN_BLOCK_NUMBER dictates the starting point if the progress repo is empty or has fallen too far behind var progressService = new BlockProgressService(web3, MIN_BLOCK_NUMBER, blockProgressRepo); // Create a filter // - This is essentially the query that is sent to the chain when retrieving logs // - It is OPTIONAL - without it, all logs in the block range are requested // - The filter is invoked before any event subscriptions evaluate the logs // - The subscriptions are free to implement their own matching logic // - In this sample we're only interested in MakerDAO logs // - Therefore it makes sense to restrict the number of logs to retrieve from the chain var makerAddressFilter = new NewFilterInput() { Address = new[] { MAKER_CONTRACT_ADDRESS } }; // Create a log processor // - This uses the blockchainProxy to get the logs // - It sends each log to the event subscriptions to indicate if the logs matches the subscription criteria // - It then allocates matching logs to separate batches per event subscription var logProcessor = new BlockRangeLogsProcessor(web3, new[] { eventSubscription }, makerAddressFilter); // Create a batch log processor service // - It uses the progress service to calculates the block range to progress // - It then invokes the log processor - passing in the range to process // - It updates progress via the progress service var batchProcessorService = new LogsProcessor(logProcessor, progressService, MAX_BLOCKS_PER_BATCH); // execute try { // Optional cancellation token // - Useful for cancelling long running processing operations var ctx = new System.Threading.CancellationTokenSource(); // instruct the service to get and process the next range of blocks // when the rangeProcessed is null - it means there was nothing to process var rangeProcessed = await batchProcessorService.ProcessOnceAsync(ctx.Token); // ensure we have processed the expected number of events // the event subscription has state which can record running totals across many processing batches Assert.Equal(11, eventSubscription.State.GetInt("EventsHandled")); // get the message count from the queue Assert.Equal(11, await queue.GetApproxMessageCountAsync()); //A sample message body from the queue /* * {"BlockNumber":"7540010","TransactionHash":"0x8d58abc578f5e321f2e6b7c0637ccc60fbf62b39b120691cbf19ff201f5069b0","LogIndex":"132","Transfer":{"From":"0x296c61eaf5bea208bbabc65ae01c3bc5270fe386","To":"0x2a8f1a6af55b705b7daee0776d6f97302de2a839","Value":119928660890733235}} */ } finally { // delete any data from Azure await ClearDown(queue, storageCloudSetup, queueFactory); } }