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- Stellar Attachment Convention
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- Hardware Requirements
- Issuing Assets
- Known Validators
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- Contribution Guide
Transactions are commands that modify the ledger state. Among other things, Transactions are used to send payments, enter orders into the distributed exchange, change settings on accounts, and authorize another account to hold your currency. If you think of the ledger as a database, then transactions are SQL commands.
Each transaction has the following attributes:
This is the account that originates the transaction. The transaction must be signed by valid signers for this account, and they must collectively meet a low threshold for the account. In addition, the transaction fee must be paid by this account. The sequence number of this transaction is based off this account.
Each transaction sets a fee that is paid by the source account.
Each transaction has a sequence number associated with the source account. Transactions follow a strict ordering rule when it comes to processing transactions per account in order to prevent double-spending. When submitting a single transaction, you should submit a sequence number 1 greater than the current sequence number. For example, if the sequence number on the account is 4, then the incoming transaction should have a sequence number of 5.
However, if several transactions with the same source account make it into the same transaction set, they are ordered and applied according to sequence number. For example, if you submitted 3 transactions that shared the same source account and the account is currently at sequence number 5, the transactions must have sequence numbers 6, 7, and 8.
List of Operations
Transactions contain an arbitrary list of operations inside them. Typically there is just one operation, but it’s possible to have multiple (up to 100). Operations are executed in order as one ACID transaction, meaning that either all operations are applied or none are. If any operation fails, the whole transaction fails. If operations are on accounts other than the source account, then they require signatures of the accounts in question.
List of Signatures
Up to 20 signatures can be attached to a transaction. See Multi-sig for more information. A transaction is considered invalid if it includes signatures that aren’t needed to authorize the transaction—superfluous signatures aren’t allowed.
Signatures are required to authorize operations and to authorize changes to the source account (fee and sequence number).
The memo contains optional extra information. It is the responsibility of the client to interpret this value. Memos can be one of the following types:
MEMO_TEXT: A string encoded using either ASCII or UTF-8, up to 28-bytes long.
MEMO_ID: A 64 bit unsigned integer.
MEMO_HASH: A 32 byte hash.
MEMO_RETURN: A 32 byte hash intended to be interpreted as the hash of the transaction the sender is refunding.
The optional UNIX timestamp (in seconds), determined by ledger time, of a lower and upper bound of when this transaction will be valid. If a transaction is submitted too early or too late, it will fail to make it into the transaction set.
0means that it’s not set. We highly advise for all transactions to use time bounds, and many SDKs enforce their usage. If a transaction doesn’t make it into the transaction set, it is kept around in memory in order to be added to the next transaction set on a best effort basis. Because of this behavior, we highly advise that all transactions are created with time bounds in order to invalidate transactions after a certain amount of time, especially if you plan to resubmit your transaction at a later time.
Once a transaction is ready to be signed, the transaction object is wrapped in an object called a
Transaction Envelope, which contains the transaction as well as a set of signatures. Most
transaction envelopes only contain a single signature along with the transaction, but in
multi-signature setups it can contain many signatures.
Ultimately, transaction envelopes are passed around the network and are included in transaction sets, as opposed to raw Transaction objects.
It’s of note that each signer signs the hash of the transaction object in addition to the network passphrase. This is done to ensure that a given transaction can only be submitted to the intended network by its signers. For more information, see Networks.
To determine if a transaction is valid, many checks take place over the course of the transaction’s lifecycle. The following conditions determine whether a transaction is valid:
Creation (Transaction Creator): A user creates a transaction by setting the source account, sequence number, list of operations and their respective parameters, fee, and optionally a memo and timebounds. You can try this out using the Stellar Laboratory.
Signing (Transaction Signers): Once the transaction is completely filled out, the transaction is formed into a transaction envelope, which contains the transaction itself and a list of signers. All the required signatures must be collected and added to the transaction envelope’s list of signers. Commonly it’s just the signature of the account doing the transaction, but more complicated setups can require collecting signatures from multiple parties.
Submitting (Transaction Submitter): After signing, the transaction must be valid and can now be submitted to the Stellar network. If the transaction is invalid, it will be immediately rejected by stellar-core based on the validity rules of a transaction, the account’s sequence number will not be incremented, and no fee will be consumed from the source account. Multiple transactions for the same account can be submitted, provided each of their sequence numbers are off by one. If they are all valid, stellar-core will craft a transaction set with each of those transactions applied in sequence number order. Transactions are typically submitted using horizon, but you can also submit the transaction directly to an instance of stellar-core.
Propagating (Validator): Once stellar-core has determined that a transaction is valid, it will then propagate the transaction to all of the other servers to which it’s connected. In this way, a valid transaction is flooded to the entire Stellar network.
Crafting a candidate transaction set (Validator): When it’s time to close the ledger, each stellar-core validator (a stellar-core node participating in consensus) takes all valid transactions it is aware since the last ledger close and collects them into a candidate transaction set. If it hears about any incoming transactions now, it puts them aside for the next ledger close. If the number of operations in the candidate transaction set is greater than the maximum number of operations per ledger, transactions will be prioritized by their fee for inclusion in the set.
Nominating a transaction set (Validator): Once each validator has crafted a candidate transaction set, the set is nominated to the network.
Stellar Consensus Protocol (SCP) determines the final transaction set (Validator Network): SCP resolves any differences between candidate transaction sets, and ultimately determining a single transaction set to apply, the close time of the ledger, and any upgrades to the protocol that need to be applied network wide at apply time.
Transaction apply order is determined (Validator Network): Once SCP agrees on a particular transaction set, the apply order in computed for the transaction set. This both shuffles the order of the set in order to create uncertainty for competing transactions, and maintains the order of sequence numbers for multiple transactions per account.
Fees are collected (Validator): Fees are collected for all transactions simultaneously.
Application (Validator): Each transaction is applied in the order previously determined. For each transaction, the account’s sequence number is consumed (increased by 1), the transaction’s validity is checked again, and each operation is applied in the order they occur in the transaction. Operations may fail at this stage due to errors that can occur outside of the transaction and operation validity checks. For example, an insufficient balance for a payment is not checked at submission, and would fail at this time. If any operation fails, the entire transaction will fail, and all previous operations will be rolled back.
Protocol Upgrades (Validator): Finally, upgrades are run if an upgrade took place. This can include arbitrary logic to upgrade the ledger state for protocol upgrades, along with ledger header modifications including the protocol version, base fee, maximum number of operations per ledger, etc. Once this has completed, the life cycle begins anew.
Transaction can fail with one of the errors in a table below. Error reference for operations can be found in List of operations doc.
|FAILED||-1||One of the operations failed (check List of operations for errors).|
|MISSING_OPERATION||-4||No operation was specified.|
|BAD_SEQ||-5||Sequence number does not match source account.|
|BAD_AUTH||-6||Too few valid signatures / wrong network.|
|INSUFFICIENT_BALANCE||-7||Fee would bring account below minimum reserve.|
|NO_ACCOUNT||-8||Source account not found.|
|INSUFFICIENT_FEE||-9||Fee is too small.|
|BAD_AUTH_EXTRA||-10||Unused signatures attached to transaction.|
|INTERNAL_ERROR||-11||An unknown error occured.|