Reliable Transaction Submission

Financial institutions and other services using the XRP Ledger should use the best practices described here to make sure that transactions are validated or rejected in a verifiable and prompt way. You should submit transactions to trusted (locally operated) rippled servers.

The best practices detailed in this document allow applications to submit transactions to the XRP Ledger while achieving:

  1. Idempotency - Transactions should be processed once and only once, or not at all.
  2. Verifiability - Applications can determine the final result of a transaction.

Applications which fail to implement best practices are at risk of the following errors:

  1. Submitting transactions which are inadvertently never executed.
  2. Mistaking provisional transaction results for their final, immutable results.
  3. Failing to find authoritative results of transactions previously applied to the ledger.

These types of errors can potentially lead to serious problems. For example, an application that fails to find a prior successful payment transaction might erroneously submit another transaction, duplicating the original payment. This underscores the importance that applications base their actions on authoritive transaction results, using the techniques described in this document.

Background

The XRP Ledger protocol provides a ledger shared across all servers in the network. Through a process of consensus and validation, the network agrees on order in which transactions are applied to (or omitted from) the ledger.

Well-formed transactions submitted to trusted XRP Ledger servers are usually validated or rejected in a matter of seconds. There are cases, however, in which a well-formed transaction is neither validated nor rejected this quickly. One specific case can occur if the global transaction cost increases after an application sends a transaction. If the transaction cost increases above what has been specified in the transaction, the transaction is not included in the next validated ledger. If at some later date the global transaction cost decreases, the transaction could be included in a later ledger. If the transaction does not specify an expiration, there is no limit to how much later this can occur.

If a power or network outage occurs, applications face more challenges finding the status of submitted transactions. Applications must take care both to properly submit a transaction and later to properly get authoritative results.

Transaction Timeline

The XRP Ledger provides several APIs for submitting transactions, including rippled, and RippleAPI. Regardless of the API used, the transaction is applied to the ledger as follows.

  1. An account owner creates and signs a transaction.
  2. The owner submits the transaction to the network as a candidate transaction.
    • Malformed or nonsensical transactions are rejected immediately.
    • Well-formed transactions may provisionally succeed, then later fail.
    • Well-formed transactions may provisionally fail, then later succeed.
    • Well-formed transactions may provisionally succeed, and then later succeed in a slightly different way. (For example, by consuming a different offer and achieving a better or worse exchange rate than the provisional execution.)
  3. Through consensus and validation, the transaction is applied to the ledger. Even some failed transactions are applied, to enforce a cost for being propagated through the network.
  4. The validated ledger includes the transaction, and its effects are reflected in the ledger state.
    • Transaction results are no longer provisional, success or failure is now final and immutable.

Note: When submitting a transaction via rippled, a successful status code returned from a submit command indicates the rippled server has received the candidate transaction. The transaction may or may not be applied to a validated ledger.

APIs may return provisional results based on the result of applying candidate transactions to the current, in-progress ledger. Applications must not confuse these with the final, immutable, results of a transaction. Immutable results are found only in validated ledgers. Applications may need to query the status of a transaction repeatedly, until the ledger containing the transaction results is validated.

While applying transactions, rippled servers use the last validated ledger, a snapshot of the ledger state based on transactions the entire network has validated. The process of consensus and validation apply a set of new transactions to the last validated ledger in canonical order, resulting in a new validated ledger. This new validated ledger instance and the ones that preceded it form the ledger history.

Each validated ledger instance has a sequence number, which is one greater than the sequence number of the preceding instance. Each ledger also has an identifying hash value, which is uniquely determined from its contents. There may be many different versions of in-progress ledgers, which have the same sequence number but different hash values. Only one version can ever be validated.

Each validated ledger has a canonical order in which transactions apply. This order is deterministic based on the final transaction set of the ledger. In contrast, each rippled server's in-progress ledger is calculated incrementally, as transactions are received. The order in which transactions execute provisionally is usually not the same as the order in which transactions execute to build a new validated ledger. This is one reason why the provisional outcome of a transaction may be different than the final result. For example, a payment may achieve a different final exchange rate depending on whether it executes before or after another payment that would consume the same offer.

LastLedgerSequence

LastLedgerSequence is an optional parameter of all transactions. This instructs the XRP Ledger that a transaction must be validated on or before a specific ledger instance. The XRP Ledger never includes a transaction in a ledger instance whose sequence number is higher than the transaction's LastLedgerSequence parameter.

Use the LastLedgerSequence parameter to prevent undesirable cases where a transaction is not confirmed promptly but could be included in a future ledger. You should specify the LastLedgerSequence parameter on every transaction. Automated processes should use a value of 4 greater than the last validated ledger index to make sure that a transaction is validated or rejected in a predictable and prompt way.

Applications using rippled APIs should explicitly specify a LastLedgerSequence when submitting transactions. RippleAPI uses the maxLedgerVersion field of Transaction Instructions to specify the LastLedgerSequence. RippleAPI automatically provides an appropriate value by default. You can specify maxLedgerVersion as null to intentionally omit LastLedgerSequence, in case you want a transaction that can be executed after an unlimited amount of time.

Best Practices

Reliable Transactions Submission

Applications submitting transactions should use the following practices to submit reliably even in the event that a process dies or other failure occurs. Application transaction results must be verified so that applications can act on the final, validated results.

Submission and verification are two separate procedures which may be implemented using the logic described in this document.

  1. Submission - The transaction is submitted to the network and a provisional result is returned.
  2. Verification - The authoritative result is determined by examining validated ledgers.

Submission

Persist details of the transaction before submission, in case of power failure or network failure before submission completes. On restart, the persisted values make it possible to verify the status of the transaction.

The submission process:

  1. Construct and sign the transaction
    • Include LastLedgerSequence parameter
  2. Persist the transaction details, saving:
    • Transaction hash
    • LastLedgerSequence
    • Sender address and sequence number
    • Application-specific data, as needed
  3. Submit the transaction

Verification

During normal operation, applications may check the status of submitted transactions by their hashes; or, depending on the API used, receive notifications when transactions have been validated (or failed). This normal operation may be interrupted, for example by network failures or power failures. In case of such interruption applications need to reliably verify the status of transactions which may or may not have been submitted to the network before the interruption.

On restart, or the determination of a new last validated ledger (pseudocode):

For each persisted transaction without validated result:
    Query transaction by hash
    If (result appears in validated ledger)
        Persist the final result
        If (result code is tesSUCCESS)
            Application may act based on successful transaction
        Else
            Application may act based on failure
            Maybe resubmit with new LastLedgerSequence and Fee
    Else if (LastLedgerSequence > newest validated ledger)
        Wait for more ledgers to be validated
    Else
        If (server has contiguous ledger history up to and
            including the ledger identified by LastLedgerSequence)
            The transaction failed
            Submit a new transaction, if appropriate for application
        Else
            Repeat submission of original transaction

Technical Application

To implement the transaction submission and verification best practices, applications need to do the following:

  1. Determine the signing account's next sequence number
    • Each transaction has an account-specific sequence number. This guarantees the order in which transactions signed by an account are executed and makes it safe to resubmit a transaction without danger of the transaction being applied to the ledger more than once.
  2. Decide on a LastLedgerSequence
    • A transaction's LastLedgerSequence is calculated from the last validated ledger sequence number.
  3. Construct and sign the transaction
    • Persist the details of a signed transaction before submission.
  4. Submit the transaction
    • Initial results are provisional and subject to change.
  5. Determine the final result of a transaction
    • Final results are an immutable part of the ledger history.

How the application does these actions depends on the API the application uses. An application may use any of the following interfaces:

  1. rippled's internal APIs
  2. RippleAPI
  3. Any number of other software APIs layered on top of rippled

rippled - Submitting and Verifying Transactions

Determine the Account Sequence

rippled provides the account_info method to learn an account's sequence number in the last validated ledger.

JSON-RPC Request:

{
  "method": "account_info",
  "params": [
    {
      "account": "rG5Ro9e3uGEZVCh3zu5gB9ydKUskCs221W",
      "ledger": "validated"
    }
  ]
}

Response body:

{
    "result": {
        "validated": true,
        "status": "success",
        "ledger_index": 10266396,
        "account_data": {
            "index": "96AB97A1BBC37F4F8A22CE28109E0D39D709689BDF412FE8EDAFB57A55E37F38",
            "Sequence": 4,
            "PreviousTxnLgrSeq": 9905632,
            "PreviousTxnID": "CAEE0E34B3DB50A7A0CA486E3A236513531DE9E52EAC47CE4C26332CC847DE26",
            "OwnerCount": 2,
            "LedgerEntryType": "AccountRoot",
            "Flags": 0,
            "Balance": "49975988",
            "Account": "rG5Ro9e3uGEZVCh3zu5gB9ydKUskCs221W"
        }
    }
}

In this example, the account's sequence is 4 (note "Sequence": 4, in "account_data") as of the last validated ledger (note "ledger": "validated" in the request, and "validated": "true" in the response).

If an application were to submit three transactions signed by this account, they would use sequence numbers 4, 5, and 6. To submit multiple transactions without waiting for validation of each, an application should keep a running account sequence number.

Determine the Last Validated Ledger

rippled provides the server_state command which returns the ledger sequence number of the last validated ledger.

Request:

{
  "id": "client id 1",
  "method": "server_state"
}

Response:

{
    "result": {
        "status": "success",
        "state": {
            "validation_quorum": 3,
            "validated_ledger": {
                "seq": 10268596,
                "reserve_inc": 5000000,
                "reserve_base": 20000000,
                "hash": "0E0901DA980251B8A4CCA17AB4CA6C3168FE83FA1D3F781AFC5B9B097FD209EF",
                "close_time": 470798600,
                "base_fee": 10
            },
            "server_state": "full",
            "published_ledger": 10268596,
            "pubkey_node": "n9LGg37Ya2SS9TdJ4XEuictrJmHaicdgTKiPJYi8QRSdvQd3xMnK",
            "peers": 58,
            "load_factor": 256000,
            "load_base": 256,
            "last_close": {
                "proposers": 5,
                "converge_time": 3004
            },
            "io_latency_ms": 2,
            "fetch_pack": 10121,
            "complete_ledgers": "10256331-10256382,10256412-10268596",
            "build_version": "0.26.4-sp3-private"
        }
    }
}

In this example the last validated ledger sequence number is 10268596 (found under result.state.validated_ledger in the response). Note also this example indicates a gap in ledger history. The server used here would not be able to provide information about the transactions applied during that gap (ledgers 10256383 through 10256411). If configured to do so, the server eventually retrieves that part of the ledger history.

Construct the Transaction

rippled provides the sign method to prepare a transaction for submission. This method requires an account secret, which should only be passed to trusted rippled instances. This example issues 10 FOO (a made-up currency) to another XRP Ledger address.

Request:

{
    "method": "sign",
    "params": [
        {
            "offline": true,
            "secret": "sssssssssssssssssssssssssssss",
            "tx_json": {
               "Account": "rG5Ro9e3uGEZVCh3zu5gB9ydKUskCs221W",
                "Sequence": 4,
                "LastLedgerSequence": 10268600,
                "Fee": 10000,
                "Amount": {
                    "currency": "FOO",
                    "issuer": "rG5Ro9e3uGEZVCh3zu5gB9ydKUskCs221W",
                    "value": "10"
                },
                "Destination": "rawz2WQ8i9FdTHp4KSNpBdyxgFqNpKe8fM",
                "TransactionType": "Payment"
            }
        }
    ]
}

Notice the application specifies the account sequence "Sequence": 4, learned from an earlier call to account_info, to avoid tefPAST_SEQ errors.

Notice also the LastLedgerSequence based on the last validated ledger our application learned from server_state. The recommendation for backend applications is to use (last validated ledger sequence + 4). Alternately, use a value of (current ledger + 3). If LastLedgerSequence is miscalculated and less than the last validated ledger, the transaction fails with tefMAX_LEDGER error.

Response:

{
    "result": {
        "tx_json": {
            "hash": "395C313F6F11F70FEBAF3785529A6D6DE3F44C7AF679515A7EAE22B30146DE57",
            "TxnSignature": "304402202646962A21EC0516FCE62DC9280F79E7265778C571E9410D795E67BB72A2D8E402202FF4AF7B2E2160F5BCA93011CB548014626CAC7FCBEBDB81FE8193CEFF69C753",
            "TransactionType": "Payment",
            "SigningPubKey": "0267268EE0DDDEE6A862C9FF9DDAF898CF17060A673AF771B565AA2F4AE24E3FC5",
            "Sequence": 4,
            "LastLedgerSequence": 10268600,
            "Flags": 2147483648,
            "Fee": "10000",
            "Destination": "rawz2WQ8i9FdTHp4KSNpBdyxgFqNpKe8fM",
            "Amount": {
                "value": "10",
                "issuer": "rG5Ro9e3uGEZVCh3zu5gB9ydKUskCs221W",
                "currency": "FOO"
            },
            "Account": "rG5Ro9e3uGEZVCh3zu5gB9ydKUskCs221W"
        },
        "tx_blob": "12000022800000002400000004201B009CAFB861D4C38D7EA4C68000000000000000000000000000464F4F0000000000AC5FA3BB28A09BD2EC1AE0EED2315060E83D796A68400000000000271073210267268EE0DDDEE6A862C9FF9DDAF898CF17060A673AF771B565AA2F4AE24E3FC57446304402202646962A21EC0516FCE62DC9280F79E7265778C571E9410D795E67BB72A2D8E402202FF4AF7B2E2160F5BCA93011CB548014626CAC7FCBEBDB81FE8193CEFF69C7538114AC5FA3BB28A09BD2EC1AE0EED2315060E83D796A831438BC6F9F5A6F6C4E474DB0D59892E90C2C7CED5C",
        "status": "success"
    }
}

Applications should persist the transaction's hash before submitting. The result of the sign method includes the hash under tx_json.

Submit the transaction

rippled provides the submit method, allowing us to submit the signed transaction. This uses the tx_blob parameter that was returned by the sign method.

Request:

{
    "method": "submit",
    "params": [
        {
        "tx_blob": "12000022800000002400000004201B009CAFB861D4C38D7EA4C68000000000000000000000000000464F4F0000000000AC5FA3BB28A09BD2EC1AE0EED2315060E83D796A68400000000000271073210267268EE0DDDEE6A862C9FF9DDAF898CF17060A673AF771B565AA2F4AE24E3FC57446304402202646962A21EC0516FCE62DC9280F79E7265778C571E9410D795E67BB72A2D8E402202FF4AF7B2E2160F5BCA93011CB548014626CAC7FCBEBDB81FE8193CEFF69C7538114AC5FA3BB28A09BD2EC1AE0EED2315060E83D796A831438BC6F9F5A6F6C4E474DB0D59892E90C2C7CED5C"
        }
    ]
}

Response:

{
    "result": {
        "tx_json": {
            "hash": "395C313F6F11F70FEBAF3785529A6D6DE3F44C7AF679515A7EAE22B30146DE57",
            "TxnSignature": "304402202646962A21EC0516FCE62DC9280F79E7265778C571E9410D795E67BB72A2D8E402202FF4AF7B2E2160F5BCA93011CB548014626CAC7FCBEBDB81FE8193CEFF69C753",
            "TransactionType": "Payment",
            "SigningPubKey": "0267268EE0DDDEE6A862C9FF9DDAF898CF17060A673AF771B565AA2F4AE24E3FC5",
            "Sequence": 4,
            "LastLedgerSequence": 10268600,
            "Flags": 2147483648,
            "Fee": "10000",
            "Destination": "rawz2WQ8i9FdTHp4KSNpBdyxgFqNpKe8fM",
            "Amount": {
                "value": "10",
                "issuer": "rG5Ro9e3uGEZVCh3zu5gB9ydKUskCs221W",
                "currency": "FOO"
            },
            "Account": "rG5Ro9e3uGEZVCh3zu5gB9ydKUskCs221W"
        },
        "tx_blob": "12000022800000002400000004201B009CAFB861D4C38D7EA4C68000000000000000000000000000464F4F0000000000AC5FA3BB28A09BD2EC1AE0EED2315060E83D796A68400000000000271073210267268EE0DDDEE6A862C9FF9DDAF898CF17060A673AF771B565AA2F4AE24E3FC57446304402202646962A21EC0516FCE62DC9280F79E7265778C571E9410D795E67BB72A2D8E402202FF4AF7B2E2160F5BCA93011CB548014626CAC7FCBEBDB81FE8193CEFF69C7538114AC5FA3BB28A09BD2EC1AE0EED2315060E83D796A831438BC6F9F5A6F6C4E474DB0D59892E90C2C7CED5C",
        "status": "success",
        "engine_result_message": "The transaction was applied.",
        "engine_result_code": 0,
        "engine_result": "tesSUCCESS"
    }
}

This a preliminary result. Final results are only available from validated ledgers. The lack of a "validated": true field indicates that this is not an immutable result.

Verify the Transaction

The transaction hash, generated when the transaction was signed, is passed to the tx method to retrieve the result of a transaction.

Request:

{
    "method": "tx",
    "params": [
        {
            "transaction": "395C313F6F11F70FEBAF3785529A6D6DE3F44C7AF679515A7EAE22B30146DE57",
            "binary": false
        }
    ]
}

Response:

{
    "result": {
        "validated": true,
        "status": "success",
        "meta": {
            "TransactionResult": "tesSUCCESS",
            "TransactionIndex": 2,
            "AffectedNodes": [...]
        },
        "ledger_index": 10268599[d],
        "inLedger": 10268599,
        "hash": "395C313F6F11F70FEBAF3785529A6D6DE3F44C7AF679515A7EAE22B30146DE57",
        "date": 470798270,
        "TxnSignature": "304402202646962A21EC0516FCE62DC9280F79E7265778C571E9410D795E67BB72A2D8E402202FF4AF7B2E2160F5BCA93011CB548014626CAC7FCBEBDB81FE8193CEFF69C753",
        "TransactionType": "Payment",
        "SigningPubKey": "0267268EE0DDDEE6A862C9FF9DDAF898CF17060A673AF771B565AA2F4AE24E3FC5",
        "Sequence": 4,
        "LastLedgerSequence": 10268600,
        "Flags": 2147483648,
        "Fee": "10000",
        "Destination": "rawz2WQ8i9FdTHp4KSNpBdyxgFqNpKe8fM",
        "Amount": {
            "value": "10",
            "issuer": "rG5Ro9e3uGEZVCh3zu5gB9ydKUskCs221W",
            "currency": "FOO"
        },
        "Account": "rG5Ro9e3uGEZVCh3zu5gB9ydKUskCs221W"
    }
}

This example response shows "validated": true, indicating the transaction has been included in a validated ledger, so the result of the transaction is immutable. Further, the metadata includes "TransactionResult": "tesSUCCESS", indicating the transaction was applied to the ledger.

If the response does not include "validated": true, the result is provisional and subject to change. To retrieve a final result, applications must invoke the tx method again, allowing enough time for the network to validate more ledger instances. It may be necessary to wait for the ledger specified in LastLedgerSequence to be validated, although if the transaction is included in an earlier validated ledger the result become immutable at that time.

Verify Missing Transaction

Applications must handle cases where a call to the tx method returns a txnNotFound error.

{
    "result": {
        "status": "error",
        "request": {
            "transaction": "395C313F6F11F70FEBAF3785529A6D6DE3F44C7AF679515A7EAE22B30146DE56",
            "command": "tx",
            "binary": false
        },
        "error_message": "Transaction not found.",
        "error_code": 24,
        "error": "txnNotFound"
    }
}

The txnNotFound result code occurs in cases where the transaction is not included in any ledger. However, it could also occur when a rippled instance does not have a complete ledger history, or if the transaction has not yet propagated to the rippled instance. Applications should make further queries to determine how to react.

The server_state method (used earlier to determine the last validated ledger) indicates how complete the ledger history is, under result.state.complete_ledgers.

{
    "result": {
        "status": "success",
        "state": {
            "validation_quorum": 3,
            "validated_ledger": {
                "seq": 10269447,
                "reserve_inc": 5000000,
                "reserve_base": 20000000,
                "hash": "D05C7ECC66DD6F4FEA3A6394F209EB5D6824A76C16438F562A1749CCCE7EAFC2",
                "close_time": 470802340,
                "base_fee": 10
            },
            "server_state": "full",
            "pubkey_node": "n9LJ5eCNjeUXQpNXHCcLv9PQ8LMFYy4W8R1BdVNcpjc1oDwe6XZF",
            "peers": 84,
            "load_factor": 256000,
            "load_base": 256,
            "last_close": {
                "proposers": 5,
                "converge_time": 2002
            },
            "io_latency_ms": 1,
            "complete_ledgers": "10256331-10256382,10256412-10269447",
            "build_version": "0.26.4-sp3-private"
        }
    }
}

Our example transaction specified LastLedgerSequence 10268600, based on the last validated ledger at the time, plus four. To determine whether our missing transaction has permanently failed, our rippled server must have ledgers 10268597 through 10268600. If the server has those validated ledgers in its history, and tx returns txnNotFound, then the transaction has failed and cannot be included in any future ledger. In this case, application logic may dictate building and submitting a replacement transaction with the same account sequence and updated LastLedgerSequence.

The server may report a last validated ledger sequence number less than the specified LastLedgerSequence. If so, the txnNotFound indicates either (a) the submitted transaction has not been distributed to the network, or (b) the transaction has been distributed to the network but has not yet been processed. To handle the former case, applications may submit again the same signed transaction. Because the transaction has a unique account sequence number, it can be processed at most once.

Finally the server may show one or more gaps in the transaction history. The completed_ledgers field shown in the response above indicates that ledgers 10256383 through 10256411 are missing from this rippled instance. Our example transaction can only appear in ledgers 10268597 - 10268600 (based on when it was submitted and LastLedgerSequence), so the gap shown here is not relevant. However, if the gap indicated a ledger in that range was missing, then an application would need to query another rippled server (or wait for this one to retrieve the missing ledgers) to determine that a txnNotFound result is immutable.

Additional Resources