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1180 lines
55 KiB
Plaintext
[[c_transactions]]
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== Transactions
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The way we typically transfer physical cash has little resemblance to
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the way we transfer bitcoins. Physical cash is a bearer token. Alice
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pays Bob by handing him some number of tokens, such as dollar bills.
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By comparison, bitcoins don't exist either physically or as digital
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data--Alice can't hand Bob some bitcoins or send them by email.
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Instead, consider how Alice might transfer control over a parcel of land
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to Bob. She can't physically pick up the land and hand it to Bob.
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Rather there exists some sort of record (usually maintained by a local
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government) which describes the land Alice owns. Alice transfers that
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land to Bob by convincing the government to update the record to say
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that Bob now owns the land.
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Bitcoin works in a similar way. There exists a database on every
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Bitcoin full node which says that Alice controls some number of
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bitcoins. Alice pays Bob by convincing full nodes to update their
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database to say that some of Alice's bitcoins are now controlled by Bob.
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The data that Alice uses to convince full nodes to update their
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databases is called a _transaction_. This is done without directly
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using either Alice's or Bob's identities, as we'll see in
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<<c_authorization_authentication>>.
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In this chapter we'll deconstruct a Bitcoin transaction and examine each
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of its parts to see how they facilitate the transfer of value in a way
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that's highly expressive and amazingly reliable.
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[[tx_structure]]
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=== A Serialized Bitcoin Transaction
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In <<exploring_and_decoding_transactions>>, we used Bitcoin Core with
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the txindex option enabled to retrieve a copy of Alice's payment to Bob.
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Let's retrieve the transaction containing that payment again.
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[[alice_tx_serialized_reprint]]
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.Alice's serialized transaction
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====
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----
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$ bitcoin-cli getrawtransaction 466200308696215bbc949d5141a49a41\
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38ecdfdfaa2a8029c1f9bcecd1f96177
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01000000000101eb3ae38f27191aa5f3850dc9cad00492b88b72404f9da13569
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8679268041c54a0100000000ffffffff02204e0000000000002251203b41daba
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4c9ace578369740f15e5ec880c28279ee7f51b07dca69c7061e07068f8240100
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000000001600147752c165ea7be772b2c0acb7f4d6047ae6f4768e0141cf5efe
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2d8ef13ed0af21d4f4cb82422d6252d70324f6f4576b727b7d918e521c00b51b
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e739df2f899c49dc267c0ad280aca6dab0d2fa2b42a45182fc83e81713010000
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0000
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----
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====
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Bitcoin Core's serialization format is special because it's the format
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used to make commitments to transaction and to relay them across
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Bitcoin's Peer-to-Peer (P2P) network, but otherwise programs can use
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a different format as long as they transmit all of the
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same data. However, Bitcoin Core's format is reasonably compact for the
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data it transmits and simple to parse, so many other Bitcoin programs
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use this format.
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[TIP]
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====
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The only other widely-used transaction serialization format of which
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we're aware is the Partially Signed Bitcoin Transaction (PSBT) format
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documented in BIPs 174 and 370 (with extensions documented in other
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BIPs). PSBT allows an untrusted program to produce a transaction
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template which can be verified and updated by trusted programs (such as
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hardware signing devices) that possesses the necessary private keys or
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other sensitive data to fill in the template. To accomplish this, PSBT
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allows storing a significant amount of metadata about a transaction,
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making it much less compact than the standard serialization format.
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This book does not go into detail about PSBT, but we strongly recommend
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it to developers of wallets that plan to support signing
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with multiple keys.
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====
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The transaction displayed in hexadecimal in <<alice_tx_serialized_reprint>> is
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replicated as a byte map in <<alice_tx_byte_map>>. Note that it takes
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64 hexadecimal characters to display 32 bytes. This map shows only the
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top-level fields. We'll examine each of them in the order they appear
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in the transaction and describe any additional fields that they contain.
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[[alice_tx_byte_map]]
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.A byte map of Alice's transaction
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image::../images/tx-map-1.png["A byte map of Alice's transaction"]
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[[version]]
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=== Version
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The first four bytes of a serialized Bitcoin transaction are its
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version. The original version of Bitcoin transactions was version 1
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(0x01000000). All transactions in Bitcoin must follow
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the rules of version 1 transactions, with many of those rules being
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described throughout this book.
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Version 2 Bitcoin transactions were introduced in the BIP68 soft fork
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change to Bitcoin's consensus rules. BIP68 places additional
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constraints on the sequence field, but those constraints only apply to
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transactions with version 2 or higher. Version 1 transactions are
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unaffected. BIP112, which was part of the same soft fork as BIP68,
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upgraded an opcode (OP_CHECKSEQUENCEVERIFY) which will now fail if it is
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evaluated as part of a transaction with a version less than 2. Beyond
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those two changes, version 2 transactions are identical to version 1
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transactions.
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.Protecting Pre-Signed Transactions
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****
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The last step before broadcasting a transaction to the network for
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inclusion in the blockchain is to sign it. However, it's possible to
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sign a transaction without broadcasting it immediately. You can save
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that pre-signed transaction for months or years in the belief that it
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can be added to the blockchain later when you do broadcast it. In the
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interim, you may even lose access to the private key (or keys) necessary
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to sign an alternative transaction spending the funds. This isn't
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hypothetical: several protocols built on Bitcoin, including Lightning
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Network, depend on pre-signed transactions.
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This creates a challenge for protocol developers when they assist users
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in upgrading the Bitcoin consensus protocol. Adding new
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constraints--such as BIP68 did to the sequence field--may invalidate
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some pre-signed transactions. If there's no way to create a new
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signature for an equivalent transaction, then the money being spent in
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the pre-signed transaction is permanently lost.
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This problem is solved by reserving some transaction features for
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upgrades, such as version numbers. Anyone creating pre-signed
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transactions prior to BIP68 should have been using version 1
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transactions, so only applying BIP68's additional constraints on
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sequence to transactions v2 or higher should not invalidate any
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pre-signed transactions.
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If you implement a protocol that uses pre-signed transactions, ensure
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that it doesn't use any features that are reserved for future upgrades.
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Bitcoin Core's default transaction relay policy does not allow the use
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of reserved features. You can test whether a transaction complies with
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that policy by using the Bitcoin Core RPC +testmempoolaccept+ on Bitcoin
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mainnet.
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****
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As of this writing, a proposal to begin using version 3 transactions is
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being widely considered. That proposal does not seek to change the
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consensus rules but only the policy that Bitcoin full nodes use to relay
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transactions. Under the proposal, version 3 transactions would be
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subject to additional constraints in order to prevent certain Denial of
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Service (DoS) attacks that we'll discuss further in <<transaction_pinning>>
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=== Extended Marker and Flag
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The next two fields of the example serialized transaction were added as
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part of the Segregated Witness (segwit) soft fork change to Bitcoin's
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consensus rules. The rules were changed according to BIPs 141 and 143,
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but the _extended serialization format_ is defined in BIP144.
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If the transaction includes a witness structure (which we'll describe in
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<<witness_structure>>), the marker must be zero (0x00) and the flag must be
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non-zero. In the current P2P protocol, the flag should always be one
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(0x01); alternative flags are reserved for later protocol upgrades.
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If the transaction doesn't need a witness stack, the marker and flag must not
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be present. This is compatible with the original version of Bitcoin's
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transaction serialization format, now called _legacy serialization_.
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For details, see <<legacy_serialization>>.
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In legacy serialization, the marker byte would have been interpreted as
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the number of inputs (zero). A transaction can't have zero inputs, so
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the marker signals to modern programs that extended serialization is
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being used. The flag field provides a similar signal and also
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simplifies the process of updating the serialization format in the
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future.
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[[inputs]]
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=== Inputs
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The inputs field contains several other fields, so let's start by showing a
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map of those bytes in <<alice_tx_input_map>>.
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[[alice_tx_input_map]]
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.Map of bytes in the input field of Alice's transaction
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image::../images/input-byte-map.png["map of bytes in the input field of Alice's transaction"]
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==== Length of transaction input list
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The transaction input list starts with an integer indicating the number of inputs
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in the transaction. The minimum value is one. There's no explicit
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maximum value, but restrictions on the maximum size of a transaction
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effectively limit transactions to a few thousand inputs. The number is
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encoded as a compactSize unsigned integer.
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.CompactSize Unsigned Integers
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****
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Unsigned integers in Bitcoin that often have low values, but which may
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sometimes have high values, are usually encoded using the compactSize
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data type. CompactSize is a version of a variable-length integer, so
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it's sometimes called var_int or varint (see, for example, documentation
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for BIPs 37 and 144).
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[WARNING]
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====
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There are several different varieties of variable length integers used
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in different programs, including in different Bitcoin programs. For
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example, Bitcoin Core serializes its UTXO database using a data type it
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calls +VarInts+ which is different from compactSize. Additionally, the
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nBits field in a Bitcoin block header is encoded using a custom data
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type known as +Compact+, which is unrelated to compactSize. When
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talking about the variable length integers used in Bitcoin transaction
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serialization and other parts of the Bitcoin P2P protocol, we will
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always use the full name compactSize.
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====
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For numbers from 0 to 252, compactSize unsigned integers are identical
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to the C-language data type +uint8_t+, which is probably the native
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encoding familiar to any programmer. For other numbers up to
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0xffffffffffffffff, a byte is prefixed to the number to indicate its
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length—but otherwise the numbers look like regular C-language encoded
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unsigned integers.
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[cols="1,1,1"]
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|===
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| Value | Bytes Used | Format
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| >= 0 && \<= 252 (0xfc) | 1 | uint8_t
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| >= 253 && \<= 0xffff | 3 | 0xfd followed by the number as uint16_t
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| >= 0x10000 && \<= 0xffffffff | 5 | 0xfe followed by the number as uint32_t
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| >= 0x100000000 && \<= 0xffffffffffffffff | 9 | 0xff followed by the number as uint64_t
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|===
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****
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Each input in a transaction must contain three fields:
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- An _outpoint_ field
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- A length-prefixed _input script_ field
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- A _sequence_
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We'll look at each of those fields in the following sections. Some
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inputs also include a witness stack, but this is serialized at the end of a
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transaction and so we'll examine it later.
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[[outpoints]]
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==== Outpoint
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A Bitcoin transaction is a request for full nodes to update their
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database of coin ownership information. For Alice to transfer control
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of some of her bitcoins to Bob, she first needs to tell full nodes how
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to find the previous transfer where she received those bitcoins. Since
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control over bitcoins is assigned in transaction outputs, Alice _points_
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to the previous _output_ using an _outpoint_ field. Each input must
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contain a single outpoint.
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The outpoint contains a 32-byte transaction identifier (_txid_) for the
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transaction where Alice received the bitcoins she now wants to spend.
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This txid is in Bitcoin's internal byte order for hashes, see
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<<internal_and_display_order>>.
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Because transactions may contain multiple outputs, Alice also needs to
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identify which particular output from that transaction to use, called
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its _output index_. Output indexes are four-byte unsigned
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integers starting from zero.
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When a full node encounters an outpoint, it uses that information to try
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to find the referenced output. Full nodes are only required to look at earlier
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transactions in the blockchain. For example, Alice's transaction is
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included in block 774,958. A full node verifying her transaction
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only looks for the previous output referenced by her outpoint in that
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block and previous blocks, not any later blocks. Within block 774,958,
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they will only look at transactions placed in the block prior to Alice's
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transaction, as determined by the order of leaves in the block's merkle
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tree (see <<merkle_trees>>).
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Upon finding the previous output, the full node obtains several critical
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pieces of information from it:
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- The amount of bitcoins assigned to that previous output. All of those
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bitcoins will be transferred in this transaction. In the example
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transaction, the value of the previous output was 100,000 satoshis.
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- The authorization conditions for that previous output. These are the
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conditions that must be fulfilled in order to spend the bitcoins
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assigned to that previous output.
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- For confirmed transactions, the height of the block which confirmed it
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and the Median Time Past (MTP) for that block. This is required for
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relative timelocks (described in <<relative_timelocks>>) and outputs
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of coinbase transactions (described in <<coinbase_transactions>>).
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- Proof that the previous output exists in the blockchain (or as a known
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unconfirmed transaction) and that no other transaction has spent it.
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One of Bitcoin's consensus rules forbids any output from being spent
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more than once within a valid blockchain. This is the rule against
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_double spending_: Alice can't use the same previous output to pay
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both Bob and Carol is separate transactions. Two transactions which each try to spend the
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same previous output are called _conflicting transactions_ because
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only one of them can be included in a valid blockchain.
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Different approaches to tracking previous outputs have been tried by
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different full node implementations at various times. Bitcoin Core
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currently uses the solution believed to be most effective at retaining
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all necessary information while minimizing disk space: it keeps a
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database that stores every Unspent Transaction Output (UTXO) and
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essential metadata about it (like its confirmation block height). Each
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time a new block of transactions arrives, all of the outputs they spend
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are removed from the UTXO database and all of the outputs they create
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are added to the database.
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[[internal_and_display_order]]
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.Internal and Display Byte Orders
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****
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Bitcoin uses the output of hash functions, called _digests_, in various
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ways. Digests provide unique identifiers for blocks and transactions;
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they're used in commitments for addresses, blocks, transactions,
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signatures, and more; and digests are iterated upon in Bitcoin's
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proof-of-work function. In some cases, hash digests are displayed to
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users in one byte order but are used internally in a different byte
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order, creating confusion. For example, consider the previous output
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txid from the outpoint in our example transaction:
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----
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eb3ae38f27191aa5f3850dc9cad00492b88b72404f9da135698679268041c54a
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----
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If we try using that that txid to retrieve that transaction using
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Bitcoin Core, we get an error and must reverse its byte order:
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----
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$ bitcoin-cli getrawtransaction \
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eb3ae38f27191aa5f3850dc9cad00492b88b72404f9da135698679268041c54a
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error code: -5
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error message:
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No such mempool or blockchain transaction. Use gettransaction for wallet transactions.
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$ echo eb3ae38f27191aa5f3850dc9cad00492b88b72404f9da135698679268041c54a \
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| fold -w2 | tac | tr -d "\n"
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4ac541802679866935a19d4f40728bb89204d0cac90d85f3a51a19278fe33aeb
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$ bitcoin-cli getrawtransaction \
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4ac541802679866935a19d4f40728bb89204d0cac90d85f3a51a19278fe33aeb
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02000000000101c25ae90c9f3d40cc1fc509ecfd54b06e35450702...
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----
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This odd behavior is probably an unintentional consequence of a
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https://bitcoin.stackexchange.com/questions/116730/why-does-bitcoin-core-print-sha256-hashes-uint256-bytes-in-reverse-order[design
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decision in early Bitcoin software]. As a practical matter, it means
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developers of Bitcoin software need to remember to reverse the order of
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bytes in transaction and block identifiers that they show to users.
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In this book, we use the term _internal byte order_ for the data that
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appears within transactions and blocks. We use _display byte order_ for
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the form displayed to users. Another set of common terms is
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_little-endian byte order_ for the internal version and _big-endian byte
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order_ for the display version.
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****
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==== Input script
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The input script field is a remnant of the legacy transaction format. Our
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example transaction input spends a native segwit output which doesn't
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require any data in the input script, so the length prefix for the
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input script is set to zero (0x00).
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For an example of a length-prefixed input script that spends a legacy
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output, we use one from an arbitrary transaction in the most recent
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block as of this writing:
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----
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6b483045022100a6cc4e8cd0847951a71fad3bc9b14f24d44ba59d19094e0a8c
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fa2580bb664b020220366060ea8203d766722ed0a02d1599b99d3c95b97dab8e
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41d3e4d3fe33a5706201210369e03e2c91f0badec46c9c903d9e9edae67c167b
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9ef9b550356ee791c9a40896
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----
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The length prefix is a compactSize unsigned integer indicating the
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length of the serialized input script field. In this case, it's a single
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byte (0x6b) indicating the input script is 107 bytes. We'll cover parsing
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and using scripts in detail in the next chapter,
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<<c_authorization_authentication>>.
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[[sequence]]
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==== Sequence
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The final four bytes of an input are its _sequence_ number.
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The use and meaning of this field has changed over time.
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[[original_tx_replacement]]
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===== Original Sequence-Based Transaction Replacement
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The sequence field was originally intended to allow creation of
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multiple versions of the same transaction, with later versions replacing
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earlier versions as candidates for confirmation. The sequence number
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tracked the version of the transaction.
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For example, imagine Alice and Bob want to bet on a game of cards. They
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start by each signing a transaction that deposits some money into an
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output with a script which requires signatures from both of them to spend, a
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_multi-signature_ script (_multisig_ for short). This is called the
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_setup transaction_. They then create a transaction which spends that
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output:
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- The first version of the transaction, with nSequenece 0 (0x00000000)
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pays Alice and Bob back the money they initially deposited. This is
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called a _refund transaction_. Neither of them broadcasts the refund
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transaction at this time. They only need it if there's a problem.
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- Alice wins the first round of the card game, so the second version of
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the transaction, with sequence 1, increases the amount of money paid
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to Alice and decreases Bob's share. They both sign the updated
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transaction. Again, they don't need to broadcast this version of the
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transaction unless there's a problem.
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- Bob wins the second round, so the sequence is incremented to 2,
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Alice's share is decreased, and Bob's share is increased. They again
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sign but don't broadcast.
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- After many more rounds where the sequence is incremented, the
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funds redistributed, and the resulting transaction is signed but not
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broadcast, they decide to finalize the transaction. Creating a
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transaction with the final balance of funds, they set sequence to its
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maximum value (0xffffffff), finalizing the transaction. They broadcast
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this version of the transaction, it's relayed across the network, and
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eventually confirmed by miners.
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We can see the replacement rules for sequence at work if we consider
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alternative scenarios:
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- Imagine that Alice broadcasts the final transaction, with a sequence of
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0xffffffff, and then Bob broadcasts one of the earlier transactions
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where his balance was higher. Because Bob's version of the
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transaction has a lower sequence number, full nodes using the original
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Bitcoin code won't relay it to miners, and miners who also used the
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original code won't mine it.
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- In another scenario, imagine that Bob broadcasts an earlier version of
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the transaction a few seconds before Alice broadcasts the final
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version. Nodes will relay Bob's version and miners will attempt to
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mine it, but when Alice's version with its higher sequence number
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arrives, nodes will also relay it and miners using the original
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Bitcoin code will try to mine it instead of Bob's version. Unless Bob
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got lucky and a block was discovered before Alice's version arrived,
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it's Alice's version of the transaction that will get confirmed.
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This type of protocol is what we now call a _payment channel_.
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Bitcoin's creator, in an email attributed to him, called these
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high-frequency transactions and described a number of features added to
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the protocol to support them. We'll learn about several of those other
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features later and also discover how modern versions of payment channels
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are increasingly being used in Bitcoin today.
|
|
|
|
There were a few problems with purely sequence-based payment channels.
|
|
The first was that the rules for replacing a lower-sequence transaction
|
|
with a higher-sequence transaction were only a matter of software
|
|
policy. There was no direct incentive for miners to prefer one version
|
|
of the transaction over any other. The second problem was that the
|
|
first person to send their transaction might get lucky and have it
|
|
confirmed even if it wasn't the highest-sequence transaction. A
|
|
security protocol that fails a few percent of the time due to bad luck
|
|
isn't a very effective protocol.
|
|
|
|
The third problem was that it was possible to replace one version of a
|
|
transaction with a different version an unlimited number of
|
|
times. Each replacement would consume the bandwidth of all the relaying full nodes
|
|
on the network. For example, as of this writing there are about 50,000
|
|
relaying full nodes; an attacker creating 1,000 replacement transactions
|
|
per minute at 200 bytes each would use about 20 kilobytes of their
|
|
personal bandwidth but about 10 gigabytes of full node network bandwidth
|
|
every minute. Except for the cost of their 20 KB/minute bandwidth and
|
|
the occasional fee when a transaction got confirmed, the attacker wouldn't
|
|
need to pay any costs for the enormous burden they placed on full node
|
|
operators.
|
|
|
|
To eliminate the risk of this attack, the original type of
|
|
sequence-based transaction replacement was disabled in an early version
|
|
of the Bitcoin software. For several years, Bitcoin full nodes would
|
|
not allow an unconfirmed transaction containing a particular input (as
|
|
indicated by its outpoint) to be replaced by a different transaction
|
|
containing the same input. However, that situation didn't last forever.
|
|
|
|
[[sequence-bip125]]
|
|
===== Opt-in Transaction Replacement Signaling
|
|
|
|
After the original sequence-based transaction replacement was disabled
|
|
due to the potential for abuse, a solution was proposed: programming
|
|
Bitcoin Core and other relaying full node software to allow a
|
|
transaction that paid a higher transaction fee rate to replace a
|
|
conflicting transaction that paid a lower fee rate. This is called
|
|
_Replace-By-Fee_, or _RBF_ for short. Some users and businesses
|
|
objected to adding support for transaction replacement back into Bitcoin
|
|
Core, so a compromise was reached that once again used the sequence
|
|
field in support of replacement.
|
|
|
|
As documented in BIP125, an unconfirmed transaction with any input that
|
|
has an sequence set to a value below 0xfffffffe (i.e., at least 2 below
|
|
the maximum value) signals to the network that its signer wants it to be
|
|
replaceable by a conflicting transaction paying a higher fee rate.
|
|
Bitcoin Core allowed those unconfirmed transactions to be replaced and
|
|
continued to disallow other transactions from being replaced. This
|
|
allowed users and businesses that objected to replacement to simply
|
|
ignore unconfirmed transactions containing the BIP125 signal until they
|
|
became confirmed.
|
|
|
|
There's more to modern transaction replacement policies than fee rates
|
|
and sequence signals, which we'll see in <<rbf>>.
|
|
|
|
[[relative_timelocks]]
|
|
===== Sequence as a consensus-enforced relative timelock
|
|
|
|
In the <<version>> section, we learned that the BIP68 soft fork added
|
|
a new constraint to transactions with version numbers 2 or higher. That
|
|
constraint applies to the sequence field.
|
|
|
|
Transaction inputs with sequence values less than 2^31^ are
|
|
interpreted as having a relative timelock. Such a transaction may only
|
|
be included in the blockchain once the previous output (referenced by the
|
|
outpoint) has aged by the relative timelock amount. For example, a
|
|
transaction with one input with a relative timelock of 30 blocks can
|
|
only be confirmed in a block with at least 29 blocks between it and the
|
|
block containing the output being spent on the same blockchain.
|
|
Since sequence is a per-input field, a transaction may contain any
|
|
number of timelocked inputs, all of which must have sufficiently aged
|
|
for the transaction to be valid. A disable flag allows a transaction to
|
|
include both inputs with a relative timelock (sequence < 2^31^) and
|
|
inputs without a relative timelock (sequence >= 2^31^).
|
|
|
|
The sequence value is specified in either blocks or seconds.
|
|
A type-flag
|
|
is used to differentiate between values counting blocks and values
|
|
counting time in seconds. The type-flag is set in the 23rd
|
|
least-significant bit (i.e., value 1<<22). If the type-flag is set, then
|
|
the sequence value is interpreted as a multiple of 512 seconds. If
|
|
the type-flag is not set, the sequence value is interpreted as a
|
|
number of blocks.
|
|
|
|
|
|
When interpreting sequence as a relative timelock, only the 16 least
|
|
significant bits are considered. Once the flags (bits 32 and 23) are
|
|
evaluated, the sequence value is usually "masked" with a 16-bit mask
|
|
(e.g., +sequence+ & 0x0000FFFF). The multiple of 512 seconds is
|
|
roughly equal to the average amount of time between blocks, so the
|
|
maximum relative timelock in both blocks and seconds from 16 bits
|
|
(2^16^) is a bit more than one year.
|
|
|
|
<<bip_68_def_of_nseq>> shows the binary layout of the sequence value,
|
|
as defined by BIP68.
|
|
|
|
[[bip_68_def_of_nseq]]
|
|
.BIP68 definition of sequence encoding (Source: BIP68)
|
|
image::../images/mbc2_0701.png["BIP68 definition of sequence encoding"]
|
|
|
|
Note that any transaction which sets a relative timelock using sequence
|
|
also sends the signal for opt-in replace-by-fee as described in
|
|
<<sequence-bip125>>.
|
|
|
|
=== Outputs
|
|
|
|
The outputs field of a transaction contains several fields related to
|
|
specific outputs. Just as we did with the inputs field, we'll start by
|
|
looking at the specific bytes of the output field from the example
|
|
transaction where Alice pays Bob, displayed as
|
|
a map of those bytes in <<output-byte-map>>.
|
|
|
|
[[output-byte-map]]
|
|
.A byte map of the outputs field from Alice's transaction
|
|
image::../images/output-byte-map.png["A byte map of the outputs field from Alice's transaction"]
|
|
|
|
==== Outputs Count
|
|
|
|
Identical to the start of the input section of a transaction, the output
|
|
field begins with a count indicating the number of outputs in this
|
|
transaction. It's a compactSize integer and must be greater than zero.
|
|
|
|
The example transaction has two outputs.
|
|
|
|
==== Amount
|
|
|
|
The first field of a specific output is its _amount_, also called
|
|
"value" in Bitcoin Core. This is an eight-byte signed integer indicating
|
|
the number of _satoshis_ to transfer. A satoshi is the smallest unit of
|
|
bitcoin that can be represented in an onchain Bitcoin transaction.
|
|
There are 100 million satoshis in a bitcoin.
|
|
|
|
Bitcoin's consensus rules allow an output to have a value as small as
|
|
zero and as large as 21 million bitcoins (2.1 quadrillion satoshis).
|
|
|
|
//TODO:describe early integer overflow problem
|
|
|
|
[[uneconomical_outputs]]
|
|
===== Uneconomical Outputs and Disallowed Dust
|
|
|
|
Despite not having any value, a zero-value output can be spent under
|
|
the same rules as any other output. However, spending an output (using
|
|
it as the input in a transaction) increases the size of a transaction,
|
|
which increases the amount of fee that needs to be paid. If the value
|
|
of the output is less than the cost of the additional fee, then it doesn't
|
|
make economic sense to spend the output. Such outputs are known as
|
|
_uneconomical outputs_.
|
|
|
|
A zero-value output is always an uneconomical output; it wouldn't
|
|
contribute any value to a transaction spending it even if the
|
|
transaction's fee rate was zero. However, many other outputs with low
|
|
values can be uneconomical as well, even unintentionally. For example,
|
|
at a typical fee rate on the network today, an output might add more
|
|
value to a transaction than it costs to spend--but, tomorrow, fee rates
|
|
might rise and make the output uneconomical.
|
|
|
|
The need for full nodes to keep track of all unspent transaction outputs
|
|
(UTXOs), as described in <<outpoints>>, means that every UTXO makes it
|
|
slightly harder to run a full node. For UTXOs containing significant
|
|
value, there's an incentive to eventually spend them, so they aren't a
|
|
problem. But there's no incentive for the person controlling an
|
|
uneconomical UTXO to ever spend it, potentially making it a perpetual
|
|
burden on operators of full nodes. Because Bitcoin's decentralization
|
|
depends on many people being willing to run full nodes, several full
|
|
node implementations such as Bitcoin Core discourage the creation of
|
|
uneconomical outputs using policies that affect the relay and mining of
|
|
unconfirmed transactions.
|
|
|
|
The policies against relaying or mining transactions creating new
|
|
uneconomical outputs are called _dust_ policies, based on a metaphorical
|
|
comparison between outputs with very small values and particles with
|
|
very small size. Bitcoin Core's dust policy is complicated and contains
|
|
several arbitrary numbers, so many programs we're aware of simply
|
|
assume outputs with less than 546 satoshis are dust and will not be
|
|
relayed or mined by default. There are occasionally proposals to lower
|
|
dust limits, and counterproposals to raise them, so we encourage
|
|
developers using presigned transactions or multi-party protocols to
|
|
check whether the policy has changed since publication of this book.
|
|
|
|
[TIP]
|
|
====
|
|
Since Bitcoin's inception, every full node has needed to keep a copy of
|
|
every unspent transaction output (UTXO), but that might not always be
|
|
the case. Several developers have been working on Utreexo, a project
|
|
that allows full nodes to store a commitment to the set of UTXOs rather
|
|
than the data itself. A minimal commitment might be only a kilobyte or
|
|
two in size--compare that to the over five gigabytes Bitcoin Core stores
|
|
as of this writing.
|
|
|
|
However, Utreexo will still require some nodes to store all UTXO data,
|
|
especially nodes serving miners and other operations that need to
|
|
quickly validate new blocks. That means uneconomical outputs can still
|
|
be a problem for full nodes even in a possible future where most nodes
|
|
use Utreexo.
|
|
====
|
|
|
|
Bitcoin Core's policy rules about dust do have one exception: output
|
|
scripts starting with +OP_RETURN+, called _data carrier outputs_,
|
|
can have a value of zero. The OP_RETURN opcode causes the script to
|
|
immediately fail no matter what comes after it, so these outputs can
|
|
never be spent. That means full nodes don't need to keep track of them,
|
|
a feature Bitcoin Core takes advantage of to allow users to store small
|
|
amounts of arbitrary data in the blockchain without increasing the size
|
|
of its UTXO database. Since the outputs are unspendable, they aren't
|
|
uneconomical--any satoshis assigned to them become
|
|
permanently unspendable--so allowing the amount to be zero ensures
|
|
satoshis aren't being destroyed.
|
|
|
|
==== Output scripts
|
|
|
|
The output amount is followed by a compactSize integer indicating the
|
|
length of the _output script_, the script that contains the
|
|
conditions which will need to be fulfilled in order to spend the
|
|
bitcoins. According to Bitcoin's
|
|
consensus rules, the minimum size of an output script is zero.
|
|
|
|
The consensus maximum allowed size of an outputs script varies depending on
|
|
when it's being checked. There's no explicit limit on the size of an
|
|
output script in the output of a transaction, but a later transaction can
|
|
only spend a previous output with a script of 10,000 bytes or
|
|
smaller. Implicitly, an output script can be almost as large as the
|
|
transaction containing it, and a transaction can be almost as large as
|
|
the block containing it.
|
|
|
|
[[anyone-can-spend]]
|
|
[TIP]
|
|
====
|
|
An output script with zero length can be spent by a input script containing
|
|
OP_TRUE. Anyone can create that input script, which means anyone
|
|
can spend an empty output script. There are an essentially unlimited
|
|
number of scripts which anyone can spend and they are known to Bitcoin
|
|
protocol developers as _anyone can spends_. Upgrades to Bitcoin's
|
|
script language often take an existing anyone-can-spend script and add
|
|
new constraints to it, making it only spendable under the new
|
|
conditions. Application developers should never need to use an
|
|
anyone-can-spend script, but if you do, we highly recommend that you
|
|
loudly announce your plans to Bitcoin users and developers so that
|
|
future upgrades don't accidentally interfere with your system.
|
|
====
|
|
|
|
Bitcoin Core's policy for relaying and mining transactions effectively
|
|
limits output scripts to just a few templates, called _standard
|
|
transaction outputs_. This was originally implemented after the
|
|
discovery of several early bugs in Bitcoin related to the Script
|
|
language and is retained in modern Bitcoin Core to support
|
|
anyone-can-spend upgrades and to encourage the best practice of placing
|
|
script conditions in P2SH redeemScripts, segwit v0 witness scripts, and
|
|
segwit v1 (taproot) leaf scripts.
|
|
|
|
We'll look at each of the current standard transaction templates and
|
|
learn how to parse scripts in <<c_authorization_authentication>>.
|
|
|
|
[[witness_structure]]
|
|
=== Witness structure
|
|
|
|
In court, a witness is someone who testifies that they saw something
|
|
important happen. Human witnesses aren't always reliable, so courts
|
|
have various processes for interrogating witnesses to (ideally) only
|
|
accept evidence from those who are reliable.
|
|
|
|
Imagine what a witness would look like for a math problem. For example,
|
|
if the important problem was _x + 2 = 4_ and someone claimed they
|
|
witnessed the solution, what would we ask them? We'd want a
|
|
mathematical proof that showed a value which could be summed with two to
|
|
equal four. We could even omit the need for a person and just use the
|
|
proposed value for _x_ as our witness. If we were told that the witness
|
|
was _two_, then we could fill in the equation, check that it was correct, and
|
|
decide that the important problem had been solved.
|
|
|
|
When spending bitcoins, the important problem we want to solve is
|
|
determining whether the spend was authorized by the person or people who
|
|
control those bitcoins. The thousands of full nodes which enforce
|
|
Bitcoin's consensus rules can't interrogate human witnesses, but they can
|
|
accept _witnesses_ that consist entirely of data for solving math
|
|
problems. For example, a witness of _2_ will allow spending bitcoins
|
|
protected by the following script:
|
|
|
|
----
|
|
2 OP_ADD 4 OP_EQUAL
|
|
----
|
|
|
|
Obviously, allowing your bitcoins to be spent by anyone who can solve a
|
|
simple equation wouldn't be secure. As we'll see in <<c_signatures>>, an
|
|
unforgeable digital signature scheme uses an equation that can only be
|
|
solved by someone in possession of certain data which they're able to
|
|
keep secret. They're able to reference that secret data using a public
|
|
identifier. That public identifier is called a _public key_ and a
|
|
solution to the equation is called a _signature_.
|
|
|
|
The following script contains a public key and an opcode that requires
|
|
a corresponding signature commit to the data in the spending transaction. Like
|
|
the number _2_ in our simple example, the signature is our witness.
|
|
|
|
----
|
|
<public key> OP_CHECKSIG
|
|
----
|
|
|
|
Witnesses, the values used to solve the math problems that protect
|
|
bitcoins, need to be included in the transactions where they're used in
|
|
order for full nodes to verify them. In the legacy transaction format
|
|
used for all early Bitcoin transactions, signatures and other data are
|
|
placed in the input script field. However, when developers started to
|
|
implement contract protocols on Bitcoin, such as we saw in
|
|
<<original_tx_replacement>>, they discovered several significant
|
|
problems with placing witnesses in the input script field.
|
|
|
|
==== Circular Dependencies
|
|
|
|
Many contract protocols for Bitcoin involve a series of transactions
|
|
that are signed out of order. For example, Alice and Bob want to
|
|
deposit funds into a script that can only be spent with signatures from
|
|
both of them, but they each also want to get their money back if the
|
|
other person becomes unresponsive. A simple solution is to sign
|
|
transactions out of order.
|
|
|
|
- Tx~0~ pays money from Alice and money from Bob into an output with a
|
|
script that requries signatures from both Alice and Bob to spend
|
|
|
|
- Tx~1~ spends the previous output to two outputs, one refunding Alice
|
|
her money and one refunding Bob his money (minus a small amount for
|
|
transaction fees)
|
|
|
|
- If Alice and Bob sign Tx~1~ before they sign Tx~0~, then they're both
|
|
guaranteed to be able to get a refund at any time. The protocol
|
|
doesn't require either of them trust the other, making it a _trustless
|
|
protocol_.
|
|
|
|
A problem with this construction in the legacy transaction format is
|
|
that every field, including the input script field which contains
|
|
signatures, is used to derive a transaction's identifier (txid). The
|
|
txid for Tx~0~ is part of the input's outpoint in Tx~1~. That means
|
|
there's no way for Alice and Bob to construct Tx~1~ until both
|
|
signatures for Tx~0~ are known--but if they know the signatures for
|
|
Tx~0~, one of them can broadcast that transaction before signing the
|
|
refund transaction, eliminating the guarantee of a refund. This is a
|
|
_circular dependency_.
|
|
|
|
==== Third-Party Transaction Malleability
|
|
|
|
A more complex series of transactions can sometimes eliminate a circular
|
|
dependency, but many protocols will then encounter a new concern: it's
|
|
often possible to solve the same script in different ways. For example,
|
|
consider our simple script from <<witness_structure>>:
|
|
|
|
----
|
|
2 OP_ADD 4 OP_EQUAL
|
|
----
|
|
|
|
We can make this script pass by providing the value _2_ in a input script,
|
|
but there are several ways to put that value on the stack in Bitcoin.
|
|
Here are just a few:
|
|
|
|
----
|
|
OP_2
|
|
OP_PUSH1 0x02
|
|
OP_PUSH2 0x0002
|
|
OP_PUSH3 0x000002
|
|
...
|
|
OP_PUSHDATA1 0x0102
|
|
OP_PUSHDATA1 0x020002
|
|
...
|
|
OP_PUSHDATA2 0x000102
|
|
OP_PUSHDATA2 0x00020002
|
|
...
|
|
OP_PUSHDATA4 0x0000000102
|
|
OP_PUSHDATA4 0x000000020002
|
|
...
|
|
----
|
|
|
|
Each alternative encoding of the number _2_ in an input script will produce
|
|
a slightly different transaction with a completely different txid. Each
|
|
different version of the transaction spends the same inputs (outpoints)
|
|
as every other version of the transaction, making them all _conflict_
|
|
with each other. Only one version of a set of conflicting transactions
|
|
can be contained within a valid blockchain.
|
|
|
|
Imagine Alice creates one version of the transaction with +OP_2+ in the
|
|
input script and an output that pays Bob. Bob then immediately spends that
|
|
output to Carol. Anyone on the network can replace +OP_2+ with
|
|
+OP_PUSH1 0x02+, creating a conflict with Alice's original version. If
|
|
that conflicting transaction is confirmed, then there's no way to
|
|
include Alice's original version in the same blockchain, which means
|
|
there's no way for Bob's transaction to spend its output.
|
|
Bob's payment to Carol has been made invalid even though neither Alice,
|
|
Bob, nor Carol did anything wrong. Someone not involved in the
|
|
transaction (a third-party) was able to change (mutate) Alice's
|
|
transaction, a problem called _unwanted third-party transaction
|
|
malleability_.
|
|
|
|
[TIP]
|
|
====
|
|
There are cases when people want their transactions to be malleable and
|
|
Bitcoin provides several features to support that, most notably the
|
|
signature hashes (sighash) we'll learn about in <<sighash_types>>. For
|
|
example, Alice can use a sighash to allow Bob to help her pay some
|
|
transaction fees. This mutates Alice's transaction but only in a way
|
|
that Alice wants. For that reason, we will occasionally prefix the
|
|
word _unwanted_ to the term _transaction malleability_. Even when we
|
|
and other Bitcoin technical writers use the base term, we're almost
|
|
certainly talking about the unwanted variant of malleability.
|
|
====
|
|
|
|
==== Second-Party Transaction Malleability
|
|
|
|
When the legacy transaction format was the only transaction format,
|
|
developers worked on proposals to minimize third-party malleability,
|
|
such as BIP62. However, even if they were able to entirely eliminate
|
|
third-party malleability, users of contract protocols faced another problem:
|
|
if they required a signature from someone else involved in the protocol,
|
|
that person could generate alternative signatures and so change the txid.
|
|
|
|
For example, Alice and Bob have deposited their money into a script
|
|
requiring a signature from both of them to spend. They've also created
|
|
a refund transaction that allows each of them to get their money back at
|
|
any time. Alice decides she wants to spend just some of the
|
|
money, so she cooperates with Bob to create a chain of transactions.
|
|
|
|
- Tx~0~ includes signatures from both Alice and Bob, spending its
|
|
bitcoins to two outputs. The first output spends some of Alice's
|
|
money; the second output returns the remainder of the bitcoins back to
|
|
the script requiring Alice and Bob's signatures. Before signing this
|
|
transaction, they create a new refund transaction, Tx~1~.
|
|
|
|
- Tx~1~ spends the second output of Tx~0~ to two new outputs, one to
|
|
Alice for her share of the joint funds, and one to Bob for his share.
|
|
Alice and Bob both sign this transaction before they sign Tx~0~.
|
|
|
|
There's no circular dependency here and, if we ignore third-party
|
|
transaction malleability, this looks like it should provide us with a
|
|
trustless protocol. However, it's a property of Bitcoin signatures that
|
|
the signer has to choose a large random number when creating their
|
|
signature. Choosing a different random number will produce a different
|
|
signature even if everything being signed stays the same. It's sort of
|
|
like how, if you provide a handwritten signature for two copies of the
|
|
same contract, each of those physical signatures will look slightly
|
|
different.
|
|
|
|
This mutability of signatures means that, if Alice tries to broadcast
|
|
Tx~0~ (which contains Bob's signature), Bob can generate an alternative
|
|
signature to create a conflicting transaction with a different txid. If
|
|
Bob's alternative version of Tx~0~ gets confirmed, then Alice can't use
|
|
the presigned version of Tx~1~ to claim her refund. This type of
|
|
mutation is called _unwanted second-party transaction malleability_.
|
|
|
|
[[segwit]]
|
|
==== Segregated Witness
|
|
|
|
As early as https://bitcointalk.org/index.php?topic=40627.msg494697[2011],
|
|
protocol developers knew how to solve the problems of circular
|
|
dependence, third-party malleability, and second-party malleability. The
|
|
idea was to avoid including the input script in the calculation that
|
|
produces a transaction's txid. Recall that an abstract name for the data
|
|
held by a input script is a _witness_. The idea of separating the rest of
|
|
the data in a transaction from its witness for the purpose of generating
|
|
a txid is called _segregated witness_ (segwit).
|
|
|
|
The obvious method for implementing segwit requires a
|
|
change to Bitcoin's consensus rules that would not be compatible with
|
|
older full nodes, also called
|
|
a _hard fork_. Hard forks come with a lot of challenges, as we'll
|
|
discuss further in <<hard_forks>>.
|
|
|
|
An alternative approach to segwit was described in late 2015. This
|
|
would use a backwards-compatible change to the consensus rules, called a
|
|
_soft fork_. Backwards compatible means that full nodes implementing
|
|
the change must not accept any blocks that full nodes without the change
|
|
would consider invalid. As long as they obey that rule, newer full
|
|
nodes can reject blocks that older full nodes would accept, giving them
|
|
the ability to enforce new consensus rules (but only if the newer full
|
|
nodes represent the economic consensus among Bitcoin users--we'll
|
|
explore the details of upgrading Bitcoin's consensus rules in
|
|
<<mining>>).
|
|
|
|
The soft fork segwit approach is based on anyone-can-spend
|
|
output scripts. A script which starts with any of the numbers 0 to 16
|
|
and followed by 2 to 40 bytes of data is defined as a segwit
|
|
output script template. The number indicates its version (e.g. 0 is
|
|
segwit version 0, or _segwit v0_). The data is called a _witness
|
|
program_. It's also possible to wrap the segwit template in a P2SH
|
|
commitment, but we won't deal with that in this chapter.
|
|
|
|
From the perspective of old nodes, these output script templates can be
|
|
spent with an empty input script. From the perspective of a new node which
|
|
is aware of the new segwit rules, any payment to a segwit output script
|
|
template must only be spent with an empty input script. Notice the
|
|
difference here: old nodes _allow_ an empty input script; new nodes
|
|
_require_ an empty input script.
|
|
|
|
An empty input script keeps witnesses from affecting the txid, eliminating
|
|
circular dependencies, third-party transaction malleability, and
|
|
second-party transaction malleability. But, with no ability to put
|
|
data in an input script, users of segwit output script templates need a
|
|
new field. That field is called the _witness structure_.
|
|
|
|
The introduction of witness programs and the witness structure complicates Bitcoin,
|
|
but it follows an existing trend of increasing abstraction. Recall from
|
|
<<ch04_keys_addresses>> that the original Bitcoin whitepaper describes a system
|
|
where bitcoins were received to public keys (pubkeys) and spent with
|
|
signatures (sigs). The public key defined who was _authorized_ to spend
|
|
the bitcoins (whoever controlled the corresponding private key) and the
|
|
signature provided _authentication_ that the spending transaction came
|
|
from someone who controlled the private key. To make that system more
|
|
flexible, the initial release of Bitcoin introduced scripts that allow
|
|
bitcoins to be received to output scripts and spent with input scripts.
|
|
Later experience with contract protocols inspired allowing bitcoins to
|
|
be received to witness programs and spent with the witness structure.
|
|
|
|
.Terms used for authorization and authentication data in different parts of Bitcoin
|
|
[cols="1,1,1"]
|
|
|===
|
|
| | **Authorization** | **Authentication**
|
|
| **Whitepaper** | Public key | Signature
|
|
| **Original (Legacy)** | Output script | Input script
|
|
| **Segwit** | Witness program | Witness structure
|
|
|===
|
|
|
|
==== Witness Structure Serialization
|
|
|
|
Similar to the inputs and outputs fields, the witness structure contains
|
|
other fields, so we'll start with a map of those bytes from
|
|
Alice's transaction in <<alice_tx_witness_map>>:
|
|
|
|
[[alice_tx_witness_map]]
|
|
.A byte map of the witness structure from Alice's transaction
|
|
image::../images/witness-byte-map.png["A byte map of the witness from Alice's transaction"]
|
|
|
|
Unlike the inputs and outputs fields, the overall witness structure doesn't
|
|
start with any indication of the total number of witness stacks it contains.
|
|
Instead, this is implied by the inputs field--there's one witness
|
|
stack for every input in a transaction.
|
|
|
|
The witness structure for a particular input does start with a count of the
|
|
number of elements they contain. Those elements are called _witness
|
|
items_. We'll explore them in detail in
|
|
<<c_authorization_authentication>>, but for now we need to know that
|
|
each witness item is prefixed by a compactSize integer indicating its
|
|
size.
|
|
|
|
Legacy inputs don't contain any witness items so their witness stack
|
|
consists entirely of a count of zero (0x00).
|
|
|
|
Alice's transaction contains one input and one witness item.
|
|
|
|
[[lock_time]]
|
|
=== Lock Time
|
|
|
|
The final field in a serialized transaction is its lock time. This
|
|
field was part of Bitcoin's original serialization format but it was
|
|
initially only enforced by Bitcoin's policy for choosing which
|
|
transactions to mine. Bitcoin's earliest known soft fork added a rule
|
|
that, starting at block height 31,000, forbid the inclusion of a
|
|
transaction in a block unless it satisfies one of the following rules:
|
|
|
|
- The transaction indicates that it should be eligible for inclusion in
|
|
any block by setting its lock time to 0.
|
|
|
|
- The transaction indicates that it wants to restrict which blocks it
|
|
can be included in by setting its lock time to a value less than
|
|
500,000,000. In this case, the transaction can only be included in a
|
|
block that has a height equal to the lock time or higher. For
|
|
example, a transaction with a lock time of 123,456 can be included in
|
|
block 123,456 or any later block.
|
|
|
|
- The transaction indicates that it wants to restrict when it can be
|
|
included in the blockchain by setting its lock time to a value of
|
|
500,000,000 or greater. In this case, the field is parsed as epoch
|
|
time (the number of seconds since 1970-01-01T00:00 UTC) and the
|
|
transaction can only be included in a block with a _Median Time Past_
|
|
(MTP) greater than the lock time. MTP is normally about an hour or
|
|
two behind the current time. The rules for MTP are described in
|
|
<<mtp>>.
|
|
|
|
[[coinbase_transactions]]
|
|
=== Coinbase Transactions
|
|
|
|
The first transaction in each block is a special case. Most older
|
|
documentation calls this a _generation transaction_, but most newer
|
|
documentation calls it a _coinbase transaction_ (not to be confused with
|
|
transactions created by the company named "Coinbase").
|
|
|
|
Coinbase transactions are created by the miner of the block that
|
|
includes them and gives the miner the option to claim any fees paid by
|
|
transactions in that block. Additionally, up until block 6,720,000,
|
|
miners are allowed to claim a subsidy consisting of bitcoins that have
|
|
never previously been circulated, called the _block subsidy_. The total
|
|
amount a miner can claim for a block--the combination of fees and
|
|
subsidy--is called the _block reward_.
|
|
|
|
Some of the special rules for coinbase transactions include:
|
|
|
|
- They may only have one input.
|
|
|
|
- The single input must have outpoint with a null txid (consisting entirely
|
|
of zeroes) and a maximal output index (0xffffffff). This prevents the
|
|
coinbase transaction from referencing a previous transaction output,
|
|
which would (at the very least) be confusing given that the coinbase
|
|
transaction pays out fees and subsidy.
|
|
|
|
- The field which would contain a input script in a normal transaction is
|
|
called a _coinbase_. It's this field that gives the coinbase
|
|
transaction its name. The coinbase field must be at least two bytes
|
|
and not longer than 100 bytes. This script is not executed but legacy
|
|
transaction limits on the number of signature-checking operations
|
|
(sigops) do apply to it, so any arbitrary data placed in it should be
|
|
prefixed by a data-pushing opcode. Since a 2013 soft fork defined in
|
|
BIP34, the first few bytes of this field must follow additional rules
|
|
we'll describe in <<duplicate_transactions>>.
|
|
|
|
- The sum of the outputs must not exceed the value of the fees collected
|
|
from all the transactions in that block plus the subsidy. The subsidy
|
|
started at 50 BTC per block and halves every 210,000 blocks
|
|
(approximately every four years). Subsidy values are rounded down to the
|
|
nearest satoshi.
|
|
|
|
- Since the 2017 segwit soft fork documented in BIP141, any block that contains
|
|
a transaction spending a segwit output must contain an output to the
|
|
coinbase transaction that commits to all of the transactions in the
|
|
block (including their witnesses). We'll explore this commitment in
|
|
<<mining>>.
|
|
|
|
A coinbase transaction can have any other outputs that would be valid in
|
|
a normal transaction. However, a transaction spending one of those
|
|
outputs cannot be included in any block until after the coinbase
|
|
transaction has received 100 confirmations. This is called the
|
|
_maturity rule_ and coinbase transaction outputs which don't yet have
|
|
100 confirmations are called _immature_.
|
|
|
|
//TODO:stretch goal to describe the reason for the maturity rule and,
|
|
//by extension the reason for no expiring timelocks
|
|
|
|
Most Bitcoin software doesn't need to deal with coinbase transactions
|
|
but their special nature does mean they can occasionally be the cause of
|
|
unusual problems in software that's not designed to expect them.
|
|
|
|
// Useful content deleted
|
|
// - no input amount in transactions
|
|
// - no balances in transactions
|
|
// - UTXO model theory?
|
|
// Coin selection
|
|
// Change
|
|
// Inability for lightweight clients to get old UTXOs
|
|
|
|
=== Weight and Vbytes
|
|
|
|
Each Bitcoin block is limited in the amount of transaction data it can
|
|
contain, so most Bitcoin software needs to be able to measure the
|
|
transactions it creates or processes. The modern unit of measurement
|
|
for Bitcoin is called _weight_. An alternative version of weight is
|
|
_vbytes_, where four units of weight equal one vbyte, providing an easy
|
|
comparison to the original _byte_ measurement unit used in legacy
|
|
Bitcoin blocks.
|
|
|
|
Blocks are limited to 4 million weight. The block header takes up 240
|
|
weight. An additional field, the transaction count, uses either 4 or
|
|
12 weight. All of the remaining weight may be used for transaction
|
|
data.
|
|
|
|
To calculate the weight of a particular field in a transaction, the size
|
|
of that serialized field in bytes is multiplied by a factor. To
|
|
calculate the weight of a transaction, sum together the weights of all
|
|
of its fields. The factors for each of the fields in a transaction are
|
|
shown in <<weight_factors>>. To provide an example, we also calculate
|
|
the weight of each field in this chapter's example transaction from
|
|
Alice to Bob.
|
|
|
|
The factors, and the fields to which they are applied, were chosen to
|
|
reduce the weight used when spending a UTXO. This helps discourage the
|
|
creation of uneconomical outputs as described in
|
|
<<uneconomical_outputs>>.
|
|
|
|
[[weight_factors]]
|
|
.Weight factors for all fields in a Bitcoin transaction
|
|
[cols="1,1,1"]
|
|
|===
|
|
| **Field** | **Factor** | **Weight in Alice's Tx**
|
|
| Version | 4 | 16
|
|
| Marker & Flag | 1 | 2
|
|
| Inputs Count | 4 | 4
|
|
| Outpoint | 4 | 144
|
|
| Input script | 4 | 4
|
|
| Sequence | 4 | 16
|
|
| Outputs Count | 4 | 4
|
|
| Amout | 4 | 64 (2 outputs)
|
|
| Output script | 4 | 232 (2 outputs with different scripts)
|
|
| Witness Count | 1 | 1
|
|
| Witness items | 1 | 66
|
|
| Lock time | 4 | 16
|
|
| **Total** | _N/A_ | **569**
|
|
|===
|
|
|
|
We can verify our weight calculation by getting the total for Alice's
|
|
transaction from Bitcoin Core:
|
|
|
|
----
|
|
$ bitcoin-cli getrawtransaction 466200308696215bbc949d5141a49a41\
|
|
38ecdfdfaa2a8029c1f9bcecd1f96177 2 | jq .weight
|
|
569
|
|
----
|
|
|
|
Alice's transaction from <<alice_tx_serialized_reprint>> at the beginning of
|
|
this chapter is shown represented in weight units in
|
|
<<alice_tx_weight_map>>. You can see the factor at work by comparing
|
|
the difference in size between the various fields in the two images.
|
|
|
|
[[alice_tx_weight_map]]
|
|
.A byte map of Alice's transaction
|
|
image::../images/tx-weight-map.png["A weight map of Alice's transaction"]
|
|
|
|
[[legacy_serialization]]
|
|
=== Legacy Serialization
|
|
|
|
The serialization format described in this chapter is used for the
|
|
majority of new Bitcoin transactions as of the writing of this book, but
|
|
an older serialization format is still used for many transactions. That
|
|
older format, called _legacy serialization_, must be used on the Bitcoin
|
|
P2P network for any transaction with an empty witness structure (which is only
|
|
valid if the transaction doesn't spend any witness programs).
|
|
|
|
Legacy serialization does not include the marker, flag, and witness structure
|
|
fields.
|
|
|
|
In this chapter, we looked at each of the fields in a transaction and
|
|
discovered how they communicate to full nodes the details about the
|
|
bitcoins to be transferred between users. We only briefly looked at the
|
|
output script, input script, and witness structure that allow specifying and
|
|
satisfying conditions which restrict who can spend what bitcoins.
|
|
Understanding how to construct and use these conditions is essential to
|
|
ensuring that only Alice can spend her bitcoins, so they will be the
|
|
subject of the next chapter.
|
|
|
|
//TODO:text long section or full chapter about psbts
|