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782 lines
34 KiB
Plaintext
[[blockchain]]
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== The Blockchain
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The blockchain is the history of every confirmed Bitcoin transaction.
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It's what allows every full node to independently determine what keys and
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scripts control which bitcoins. In this chapter, we'll look at the
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structure of the blockchain and see how it uses cryptographic
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commitments and other clever tricks to make every part of it easy for
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full nodes (and sometimes light clients) to validate.
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The blockchain data structure is
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an ordered, back-linked list of blocks of transactions. The blockchain
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can be stored as a flat file, or in a simple database.
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Blocks are linked "back," each referring to the previous block in the
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chain. The blockchain is often visualized
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as a vertical stack, with blocks layered on top of each other and the
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first block serving as the foundation of the stack. The visualization of
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blocks stacked on top of each other results in the use of terms such as
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"height" to refer to the distance from the first block, and "top" or
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"tip" to refer to the most recently added block.
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Each block
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within the blockchain is identified by a hash, generated using the
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SHA256 cryptographic hash algorithm on the header of the block. Each
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block also commits to the previous block, known as the _parent_ block,
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through the "previous block hash" field in the block header.
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The sequence of hashes linking each block to its parent creates a chain
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going back all the way to the first block ever created, known as the
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_genesis block_.
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Although a block has just one parent, it can have multiple
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children. Each of the children commits to the same parent block.
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Multiple children arise during a blockchain "fork," a temporary
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situation that can occur when different blocks are discovered almost
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simultaneously by different miners (see <<forks>>). Eventually, only one
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child block becomes part of the blockchain accepted by all full nodes and the "fork" is resolved.
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The "previous block hash" field is inside the block header and thereby
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affects the _current_ block's hash.
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Any change to a parent block
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requires a child block's hash to change, which requires a change in the
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pointer of the grandchild, which in turn changes the grandchild, and so
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on. This sequence ensures that, once a block has many generations
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following it, it cannot be changed without forcing a recalculation of
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all subsequent blocks. Because such a recalculation would require
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enormous computation (and therefore energy consumption), the existence
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of a long chain of blocks makes the blockchain's deep history impractical to change,
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which is a key feature of Bitcoin's security.
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One way to think about the blockchain is like layers in a geological
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formation, or glacier core sample. The surface layers might change with
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the seasons, or even be blown away before they have time to settle. But
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once you go a few inches deep, geological layers become more and more
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stable. By the time you look a few hundred feet down, you are looking at
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a snapshot of the past that has remained undisturbed for millions of
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years. In the blockchain, the most recent few blocks might be revised if
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there is a chain reorganization due to a fork. The top six blocks are
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like a few inches of topsoil. But once you go more deeply into the
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blockchain, beyond six blocks, blocks are less and less likely to
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change. After 100 blocks back there is so much stability that
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the coinbase transaction--the transaction containing the reward in
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bitcoin for creating a new block--can be spent.
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While the
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protocol always allows a chain to be undone by a longer chain and while
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the possibility of any block being reversed always exists, the
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probability of such an event decreases as time passes until it becomes
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infinitesimal.
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=== Structure of a Block
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A block is a container data structure that aggregates
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transactions for inclusion in the blockchain. The
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block is made of a header, containing metadata, followed by a long list
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of transactions that make up the bulk of its size. The block header is
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80 bytes, whereas the total size of all transactions in a block can be
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up to about 4,000,000 bytes. A complete block,
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with all transactions, can therefore be almost 50,000 times larger than the block
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header. <<block_structure1>> describes how Bitcoin Core stores the structure of a block.
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[[block_structure1]]
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.The structure of a block
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[options="header"]
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|=======
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|Size| Field | Description
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| 4 bytes | Block Size | The size of the block, in bytes, following this field
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| 80 bytes | Block Header | Several fields form the block header
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| 1-3 bytes (compactSize) | Transaction Counter | How many transactions follow
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| Variable | Transactions | The transactions recorded in this block
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|=======
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[[block_header]]
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=== Block Header
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The block header consists of
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block metadata as shown in <<block_header_structure_ch09>>.
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[[block_header_structure_ch09]]
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.The structure of the block header
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[options="header"]
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|=======
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|Size| Field | Description
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| 4 bytes | Version | Originally a version field; its use has evolved over time
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| 32 bytes | Previous Block Hash | A hash of the previous (parent) block in the chain
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| 32 bytes | Merkle Root | The root hash of the merkle tree of this block's transactions
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| 4 bytes | Timestamp | The approximate creation time of this block (Unix epoch time)
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| 4 bytes | Target | A compact encoding of the Proof-of-Work target for this block
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| 4 bytes | Nonce | Arbitrary data used for the Proof-of-Work algorithm
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|=======
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The nonce, target, and timestamp are used in the mining
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process and will be discussed in more detail in <<mining>>.
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[[block_hash]]
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=== Block Identifiers: Block Header Hash and Block Height
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The primary identifier of a block
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is its cryptographic hash, a commitment made by hashing the
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block header twice through the SHA256 algorithm. The resulting 32-byte
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hash is called the _block hash_ but is more accurately the _block header
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hash_, pass:[<span class="keep-together">because only the block header is
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used to compute it. For example,</span>]
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+000000000019d6689c085ae165831e934ff763ae46a2a6c172b3f1b60a8ce26f+ is
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the block hash of the first block on Bitcoin's blockchain. The block hash
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identifies a block uniquely and unambiguously and can be independently
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derived by any node by simply hashing the block header.
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Note that the block hash is not actually included inside the block's
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data structure.
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Instead, the block's hash is computed by each node as the
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block is received from the network. The block hash might be stored in a
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separate database table as part of the block's metadata, to facilitate
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indexing and faster retrieval of blocks from disk.
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A second way to identify a block is by its position in the blockchain,
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called the pass:[<span class="keep-together"><em>block height</em>. The
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genesis block is at block height 0 (zero) and is the</span>]
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pass:[<span class="keep-together">same block that was previously
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referenced by the following block hash</span>]
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+000000000019d6689c085ae165831e934ff763ae46a2a6c172b3f1b60a8ce26f+. A
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block can thus be identified in two ways: by referencing the block hash
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or by referencing the block height. Each subsequent block added "on top"
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of that first block is one position "higher" in the blockchain, like
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boxes stacked one on top of the other. The block height 800,000 was
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reached during the writing of this book in mid-2023, meaning there were
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800,000 blocks stacked on top of the first block created in January
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2009.
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Unlike the block hash, the block height is not a unique identifier.
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Although a single block will always have a specific and invariant block
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height, the reverse is not true—the block height does not always
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identify a single block. Two or more blocks might have the same block
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height, competing for the same position in the blockchain. This scenario
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is discussed in detail in the section <<forks>>. In early blocks, the block height was
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also not a part of the block's data structure; it was not stored within
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the block. Each node dynamically identified a block's position (height)
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in the blockchain when it was received from the Bitcoin network. A
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later protocol change (BIP34) began including the block height in the
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coinbase transaction, although its purpose was to ensure each block had
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a different coinbase transaction. Nodes still need to dynamically
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identify a block's height in order to validate the coinbase field. The
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block height might also be stored as metadata in an indexed database
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table for faster retrieval.
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[TIP]
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====
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A block's _block hash_ always identifies a single block uniquely. A
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block also always has a specific _block height_. However, it is not
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always the case that a specific block height identifies a single
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block. Rather, two or more blocks might compete for a single position in
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the blockchain.
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====
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=== The Genesis Block
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The first block in the blockchain is called the _genesis block_
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and was created in 2009. It is the common ancestor of all the blocks in
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the blockchain, meaning that if you start at any block and follow the
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chain backward in time, you will eventually arrive at the genesis block.
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Every node always starts with a blockchain of at least one block because
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the genesis block is statically encoded within Bitcoin Core,
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such that it cannot be altered. Every node always "knows" the
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genesis block's hash and structure, the fixed time it was created, and
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even the single transaction within. Thus, every node has the starting
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point for the blockchain, a secure "root" from which to build a trusted
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blockchain.
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See the statically encoded genesis block inside the Bitcoin Core client,
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in https://github.com/bitcoin/bitcoin/blob/3955c3940eff83518c186facfec6f50545b5aab5/src/chainparams.cpp#L123[_chainparams.cpp_].
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The following identifier hash belongs to the genesis block:
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----
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000000000019d6689c085ae165831e934ff763ae46a2a6c172b3f1b60a8ce26f
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----
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You can search for that block hash in almost any block explorer website, such
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as _blockstream.info_, and you will find a page describing the contents
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of this block, with a URL containing that hash:
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https://blockstream.info/block/000000000019d6689c085ae165831e934ff763ae46a2a6c172b3f1b60a8ce26f
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Using the Bitcoin Core reference client on the command line:
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----
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$ bitcoin-cli getblock 000000000019d6689c085ae165831e934ff763ae46a2a6c172b3f1b60a8ce26f
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----
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[source,json]
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----
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{
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"hash": "000000000019d6689c085ae165831e934ff763ae46a2a6c172b3f1b60a8ce26f",
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"confirmations": 790496,
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"height": 0,
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"version": 1,
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"versionHex": "00000001",
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"merkleroot": "4a5e1e4baab89f3a32518a88c31bc87f618f76673e2cc77ab2127b7afdeda33b",
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"time": 1231006505,
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"mediantime": 1231006505,
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"nonce": 2083236893,
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"bits": "1d00ffff",
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"difficulty": 1,
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"chainwork": "0000000000000000000000000000000000000000000000000000000100010001",
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"nTx": 1,
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"nextblockhash": "00000000839a8e6886ab5951d76f411475428afc90947ee320161bbf18eb6048",
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"strippedsize": 285,
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"size": 285,
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"weight": 1140,
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"tx": [
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"4a5e1e4baab89f3a32518a88c31bc87f618f76673e2cc77ab2127b7afdeda33b"
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]
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}
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----
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The genesis block contains a message within it. The coinbase
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transaction input contains the text "The Times 03/Jan/2009 Chancellor on
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brink of second bailout for banks." This message was intended to offer
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proof of the earliest date this block could have been created, by referencing the
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headline of the British newspaper _The Times_. It also serves as a
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tongue-in-cheek reminder of the importance of an independent monetary
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system, with Bitcoin's launch occurring at the same time as an
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unprecedented worldwide monetary crisis. The message was embedded in the
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first block by Satoshi Nakamoto, Bitcoin's creator.
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=== Linking Blocks in the Blockchain
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Bitcoin full nodes validate every
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block in the blockchain after the genesis block. Their local view of
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the blockchain is constantly updated as new blocks are found and used to
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extend the chain. As a node receives incoming blocks from the network,
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it will validate these blocks and then link them to its view of the existing
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blockchain. To establish a link, a node will examine the incoming block
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header and look for the "previous block hash."
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Let's assume, for example, that a node has 277,314 blocks in the local
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copy of the blockchain. The last block the node knows about is block
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277,314, with a block header hash of:
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----
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00000000000000027e7ba6fe7bad39faf3b5a83daed765f05f7d1b71a1632249
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----
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The Bitcoin node then receives a new block from the network, which it
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parses as follows:
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[source,json]
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----
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{
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"size" : 43560,
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"version" : 2,
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"previousblockhash" :
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"00000000000000027e7ba6fe7bad39faf3b5a83daed765f05f7d1b71a1632249",
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"merkleroot" :
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"5e049f4030e0ab2debb92378f53c0a6e09548aea083f3ab25e1d94ea1155e29d",
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"time" : 1388185038,
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"difficulty" : 1180923195.25802612,
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"nonce" : 4215469401,
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"tx" : [
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"257e7497fb8bc68421eb2c7b699dbab234831600e7352f0d9e6522c7cf3f6c77",
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"[... many more transactions omitted ...]",
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"05cfd38f6ae6aa83674cc99e4d75a1458c165b7ab84725eda41d018a09176634"
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]
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}
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----
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Looking at this new block, the node finds the +previousblockhash+ field,
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which contains the hash of its parent block. It is a hash known to the
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node, that of the last block on the chain at height 277,314. Therefore,
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this new block is a child of the last block on the chain and extends the
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existing blockchain. The node adds this new block to the end of the
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chain, making the blockchain longer with a new height of 277,315.
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<<chain_of_blocks>> shows the chain of three blocks, linked by
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references in the +previousblockhash+ field.
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[[chain_of_blocks]]
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[role="smallerfourtyfive"]
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.Blocks linked in a chain by each referencing the previous block header hash
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image::images/mbc3_1101.png[]
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[[merkle_trees]]
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=== Merkle Trees
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Each block in the Bitcoin blockchain contains
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a summary of all the transactions in the block using a _merkle tree_.
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A _merkle tree_, also known
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as a _binary hash tree_, is a data structure used for efficiently
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summarizing and verifying the integrity of large sets of data. Merkle
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trees are binary trees containing cryptographic hashes. The term "tree"
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is used in computer science to describe a branching data structure, but
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these trees are usually displayed upside down with the "root" at the top
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and the "leaves" at the bottom of a diagram, as you will see in the
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examples that follow.
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Merkle trees are used in bitcoin to summarize all the transactions in a
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block, producing an overall commitment to the entire set of
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transactions and permitting a very efficient process to verify whether a
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transaction is included in a block. A merkle tree is constructed by
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recursively hashing pairs of elements until there is only one hash, called
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the _root_, or _merkle root_. The cryptographic hash algorithm used in
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Bitcoin's merkle trees is SHA256 applied twice, also known as
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double-SHA256.
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When N data elements are hashed and summarized in a merkle tree, you can
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check to see if any one data element is included in the tree with at
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about +log~2~(N)+ calculations, making this a very efficient data
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structure.
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The merkle tree is constructed bottom-up. In the following example, we
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start with four transactions, A, B, C, and D, which form the _leaves_ of
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the merkle tree, as shown in <<simple_merkle>>. The transactions are not
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stored in the merkle tree; rather, their data is hashed and the
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resulting hash is stored in each leaf node as H~A~, H~B~, H~C~, and
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H~D~:
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++++
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<pre data-type="codelisting">
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H<sub>A</sub> = SHA256(SHA256(Transaction A))
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</pre>
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++++
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Consecutive pairs of leaf nodes are then summarized in a parent node, by
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concatenating the two hashes and hashing them together. For example, to
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construct the parent node H~AB~, the two 32-byte hashes of the children
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are concatenated to create a 64-byte string. That string is then
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double-hashed to produce the parent node's hash:
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++++
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<pre data-type="codelisting">
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H<sub>AB</sub> = SHA256(SHA256(H<sub>A</sub> || H<sub>B</sub>))
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</pre>
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++++
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The process continues until there is only one node at the top, the node
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known as the merkle root. That 32-byte hash is stored in the block
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header and summarizes all the data in all four transactions.
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<<simple_merkle>> shows how the root is calculated by pair-wise hashes
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of the nodes.
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[[simple_merkle]]
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.Calculating the nodes in a merkle tree
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image::images/mbc3_1102.png["merkle_tree"]
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Because the merkle tree is a binary tree, it needs
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an even number of leaf nodes. If there is an odd number of transactions
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to summarize, the last transaction hash will be duplicated to create an
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even number of leaf nodes, also known as a _balanced tree_. This is
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shown in <<merkle_tree_odd>>, where transaction C is duplicated.
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Similarly, if there are an odd number of hashes to process at any level,
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the last hash is duplicated.
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[[merkle_tree_odd]]
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.Duplicating one data element achieves an even number of data elements
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image::images/mbc3_1103.png["merkle_tree_odd"]
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.A design flaw in Bitcoin's merkle tree
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****
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An extended comment in Bitcoin Core's source code describes a
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significant problems in the design of Bitcoin's duplication of odd
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elements in its merkle tree:
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[quote,Bitcoin Core src/consensus/merkle.cpp]
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____
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WARNING! If you're reading this because you're learning about crypto
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and/or designing a new system that will use merkle trees, keep in mind
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that the following merkle tree algorithm has a serious flaw related to
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duplicate txids, resulting in a vulnerability (CVE-2012-2459).
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The reason is that if the number of hashes in the list at a given level
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is odd, the last one is duplicated before computing the next level (which
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is unusual in Merkle trees). This results in certain sequences of
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transactions leading to the same merkle root. For example, these two
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trees:
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[[cve_tree]]
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.Two Bitcoin-style merkle tree with the same root but a different number of leaves
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image::images/mbc3_1104.png["Two Bitcoin-style merkle tree with the same root but a different number of leaves"]
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For transaction lists [1,2,3,4,5,6] and [1,2,3,4,5,6,5,6] (where 5 and
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6 are repeated) result in the same root hash A (because the hash of both
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of (F) and (F,F) is C).
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The vulnerability results from being able to send a block with such a
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transaction list, with the same merkle root, and the same block hash as
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the original without duplication, resulting in failed validation. If the
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receiving node proceeds to mark that block as permanently invalid
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however, it will fail to accept further unmodified (and thus potentially
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valid) versions of the same block. We defend against this by detecting
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the case where we would hash two identical hashes at the end of the list
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together, and treating that identically to the block having an invalid
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merkle root. Assuming no double-SHA256 collisions, this will detect all
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known ways of changing the transactions without affecting the merkle
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root.
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____
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****
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The same method for constructing a tree from four transactions can be
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generalized to construct trees of any size. In Bitcoin it is common to
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have several thousand transactions in a single
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block, which are summarized in exactly the same way, producing just 32
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bytes of data as the single merkle root. In <<merkle_tree_large>>, you
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will see a tree built from 16 transactions. Note that although the root
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looks bigger than the leaf nodes in the diagram, it is the exact same
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size, just 32 bytes. Whether there is one transaction or ten
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thousand transactions in the block, the merkle root always summarizes
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them into 32 bytes.
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To prove that a specific transaction is
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included in a block, a node only needs to produce approximately +log~2~(N)+ 32-byte
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hashes, constituting an _authentication path_ or _merkle path_
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connecting the specific transaction to the root of the tree. This is
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especially important as the number of transactions increases, because
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the base-2 logarithm of the number of transactions increases much more
|
||
slowly. This allows Bitcoin nodes to efficiently produce paths of 10 or
|
||
12 hashes (320–384 bytes), which can provide proof of a single
|
||
transaction out of more than a thousand transactions in a multi-megabyte
|
||
block.
|
||
|
||
[[merkle_tree_large]]
|
||
.A merkle tree summarizing many data elements
|
||
image::images/mbc3_1105.png["merkle_tree_large"]
|
||
|
||
In <<merkle_tree_path>>, a node can prove that a transaction K is
|
||
included in the block by producing a merkle path that is only four
|
||
32-byte hashes long (128 bytes total). The path consists of the four
|
||
hashes (shown with a shaded background) H~L~,
|
||
H~IJ~, H~MNOP~, and H~ABCDEFGH~. With those four hashes provided as an
|
||
authentication path, any node can prove that H~K~ (with a black
|
||
background at the bottom of the diagram) is included in the merkle root
|
||
by computing four additional pair-wise hashes H~KL~, H~IJKL~,
|
||
H~IJKLMNOP~, and the merkle tree root (outlined in a dashed line in the
|
||
diagram).
|
||
|
||
[[merkle_tree_path]]
|
||
.A merkle path used to prove inclusion of a data element
|
||
image::images/mbc3_1106.png["merkle_tree_path"]
|
||
|
||
The efficiency of merkle trees becomes obvious as the scale increases.
|
||
The largest possible block can hold almost 16,000 transactions in 4,000,000
|
||
bytes, but proving any particular one of those sixteen thousand transactions
|
||
is a part of that block only requires a copy of the transaction, a copy
|
||
of the 80-byte block header, and 448 bytes for the merkle proof. That
|
||
makes the largest possible proof almost 10,000 times smaller than the
|
||
largest possible Bitcoin block.
|
||
|
||
=== Merkle Trees and Lightweight Clients
|
||
|
||
Merkle trees are used extensively by lightweight clients. Lightweight clients don't
|
||
have all transactions and do not download full blocks, just block
|
||
headers. In order to verify that a transaction is included in a block,
|
||
without having to download all the transactions in the block, they use
|
||
a merkle path.
|
||
|
||
Consider, for example, a lightweight client that is interested in incoming
|
||
payments to an address contained in its wallet. The lightweight client will
|
||
establish a bloom filter (see <<bloom_filters>>) on its connections to
|
||
peers to limit the transactions received to only those containing
|
||
addresses of interest. When a peer sees a transaction that matches the
|
||
bloom filter, it will send that block using a +merkleblock+ message. The
|
||
+merkleblock+ message contains the block header as well as a merkle path
|
||
that links the transaction of interest to the merkle root in the block.
|
||
The lightweight client can use this merkle path to connect the transaction to the
|
||
block header and verify that the transaction is included in the block. The lightweight
|
||
client also uses the block header to link the block to the rest of the
|
||
blockchain. The combination of these two links, between the transaction
|
||
and block, and between the block and blockchain, proves that the
|
||
transaction is recorded in the blockchain. All in all, the lightweight client will
|
||
have received less than a kilobyte of data for the block header and
|
||
merkle path, an amount of data that is more than a thousand times less
|
||
than a full block (about 2 megabytes currently).
|
||
|
||
=== Bitcoin's Test Blockchains
|
||
|
||
You might be
|
||
surprised to learn that there is more than one blockchain used with Bitcoin. The
|
||
"main" Bitcoin blockchain, the one created by Satoshi Nakamoto on
|
||
January 3rd, 2009, the one with the genesis block we studied in this
|
||
chapter, is called _mainnet_. There are other Bitcoin blockchains that
|
||
are used for testing purposes: at this time _testnet_, _signet_, and
|
||
_regtest_. Let's look at each in turn.
|
||
|
||
==== Testnet: Bitcoin's Testing Playground
|
||
|
||
Testnet is the name of the test blockchain, network, and currency that
|
||
is used for testing purposes. The testnet is a fully featured live P2P
|
||
network, with wallets, test bitcoins (testnet coins), mining, and all
|
||
the other features of mainnet. The most important difference is that
|
||
testnet coins are meant to be worthless.
|
||
|
||
Any software development that is intended for production use on
|
||
Bitcoin's mainnet can first be tested on testnet with test coins.
|
||
This protects both the developers from monetary losses due to bugs and
|
||
the network from unintended behavior due to bugs.
|
||
|
||
The current testnet is called _testnet3_, the third iteration of
|
||
testnet, restarted in February 2011 to reset the difficulty from the
|
||
previous testnet. Testnet3 is a large blockchain, in excess of 30 GB in
|
||
2023. It will take a while to sync fully and use up resources
|
||
on your computer. Not as much as mainnet, but not exactly "lightweight"
|
||
either.
|
||
|
||
[TIP]
|
||
====
|
||
Testnet and the other test blockchains described in this book don't use
|
||
the same address prefixes as mainnet addresses to prevent someone from
|
||
accidentally sending real bitcoins to a test address. Mainnet addresses
|
||
begin with +1+, +3+, or +bc1+. Addresses for the test networks
|
||
mentioned in this book begin with +m+, +n+, or +tb1+. Other test
|
||
networks, or new protocols being developed on test networks, may use
|
||
other address prefixes or alterations.
|
||
====
|
||
|
||
===== Using testnet
|
||
|
||
Bitcoin Core, like many other Bitcoin programs, has full support
|
||
for operation on testnet as an alternative mainnet. All of Bitcoin Core's
|
||
functions work on testnet, including the wallet, mining testnet coins,
|
||
and syncing a full testnet node.
|
||
|
||
To start Bitcoin Core on testnet instead of mainnet you use the
|
||
+testnet+ switch:
|
||
|
||
----
|
||
$ bitcoind -testnet
|
||
----
|
||
|
||
In the logs you should see that bitcoind is building a new blockchain in
|
||
the +testnet3+ subdirectory of the default bitcoind directory:
|
||
|
||
----
|
||
bitcoind: Using data directory /home/username/.bitcoin/testnet3
|
||
----
|
||
|
||
To connect to bitcoind, you use the +bitcoin-cli+ command-line tool, but
|
||
you must also switch it to testnet mode:
|
||
|
||
----
|
||
$ bitcoin-cli -testnet getblockchaininfo
|
||
{
|
||
"chain": "test",
|
||
"blocks": 1088,
|
||
"headers": 139999,
|
||
"bestblockhash": "0000000063d29909d475a1c4ba26da64b368e56cce5d925097bf3a2084370128",
|
||
"difficulty": 1,
|
||
"mediantime": 1337966158,
|
||
"verificationprogress": 0.001644065914099759,
|
||
"chainwork": "0000000000000000000000000000000000000000000000000000044104410441",
|
||
"pruned": false,
|
||
"softforks": [
|
||
|
||
[...]
|
||
----
|
||
|
||
You can also run on testnet3 with other full-node implementations, such
|
||
as +btcd+ (written in Go) and +bcoin+ (written in JavaScript), to
|
||
experiment and learn in other programming languages and frameworks.
|
||
|
||
Testnet3 supports all the features of mainnet, including
|
||
Segregated Witness v0 and v1 (see <<segwit>> and <<taproot>>). Therefore, testnet3 can also be
|
||
used to test Segregated Witness features.
|
||
|
||
===== Problems With Testnet
|
||
|
||
Testnet doesn't just use the same data structures as Bitcoin, it also
|
||
uses almost exactly the same Proof-of-Work (PoW) security mechanism as
|
||
Bitcoin. The notable differences for testnet are that it's minimum
|
||
difficulty is half that of Bitcoin and that it's allowed to include a
|
||
block at the minimum difficulty if that block's timestamp is more than
|
||
20 minutes after the previous block.
|
||
|
||
Unfortunately, Bitcoin's PoW security mechanism was designed to depend
|
||
on economic incentives--incentives which don't exist in a test
|
||
blockchain that is forbidden from having value. On mainnet, miners are
|
||
incentivized to include user transactions in their blocks because those
|
||
transactions pay fees. On testnet, transactions still contain something
|
||
called fees, but those fees don't have any economic value. That means
|
||
the only incentive for a testnet miner to include transactions is
|
||
because they want to help users and developers to test their software.
|
||
|
||
Alas, people who like to disrupt systems often feel a stronger
|
||
incentive, at least in the short term. Because PoW mining is designed
|
||
to be permissionless, anyone can mine, whether their intention is good
|
||
or not. That means disruptive miners can create many blocks in a row on
|
||
testnet without including any user transactions. When those attacks
|
||
happen, testnet becomes unusable for users and developers.
|
||
|
||
==== Signet: The Proof of Authority Testnet
|
||
|
||
There's no known way for a system dependent on permissionless PoW to
|
||
provide a highly usable blockchain without introducing economic
|
||
incentives, so Bitcoin protocol developers began considering
|
||
alternatives. The primary goal was to preserve as much of the structure of
|
||
Bitcoin as possible so that software could run on a testnet with minimal
|
||
changes--but to also provide an environment that would remain useful.
|
||
A secondary goal was to produce a reusable design that would allow
|
||
developers of new software to easily create their own test networks.
|
||
|
||
The solution implemented in Bitcoin Core and other software is called
|
||
_signet_, as defined by BIP325. A signet is a test network where each
|
||
block must contain proof (such as a signature) that the creation of that
|
||
block was sanctioned by a trusted authority.
|
||
|
||
Whereas mining in Bitcoin is permissionless--anyone can do it--mining on
|
||
signet is fully permissioned. Only those with permission can do it.
|
||
This would be a completely unacceptable change to Bitcoin's mainnet--no
|
||
one would use that software--but it's reasonable on a testnet where coins have
|
||
no value and the only purpose is testing software and systems.
|
||
|
||
BIP325 signets are designed to make it very easy to create your own. If
|
||
you disagree with how someone else is running their signet, you can
|
||
start your own signet and connect your software to it.
|
||
|
||
===== The Default Signet and Custom Signets
|
||
|
||
Bitcoin Core supports a default signet, which we believe to be the most
|
||
widely used signet at the time of writing. It is currently operated by
|
||
two contributors to that project. If you start Bitcoin Core with the
|
||
+-signet+ parameter and no other signet-related parameters, this is the
|
||
signet you will be using.
|
||
|
||
As of this writing, the default signet has about 150,000 blocks and is
|
||
about a gigabyte in size. It supports all of the same features as
|
||
Bitcoin's mainnet and is also used for testing proposed upgrades through
|
||
the Bitcoin Inquisition project, which is a software fork of Bitcoin
|
||
Core that's only designed to run on signet.
|
||
|
||
If you want to use a different signet, called a _custom signet_, you
|
||
will need to know the script used to determine when a block is
|
||
authorized, called the _challenge_ script. This is a standard Bitcoin
|
||
script, so it can use features such as multisig to allow multiple people
|
||
to authorize blocks. You may also need to connect to a seed node that
|
||
will provide you with the addresses of peers on the custom signet. For
|
||
example:
|
||
|
||
----
|
||
bitcoind -signet -signetchallenge=0123...cdef -signetseednode=example.com:1234
|
||
----
|
||
|
||
As of this writing, we generally recommend that the public testing of
|
||
mining software occur on testnet3 and that all other public testing of
|
||
Bitcoin software occur on the default signet.
|
||
|
||
To interact with your chosen signet, you can use the +-signet+ parameter
|
||
with +bitcoin-cli+, similar to how you used testnet. For example:
|
||
|
||
----
|
||
$ bitcoin-cli -signet getblockchaininfo
|
||
{
|
||
"chain": "signet",
|
||
"blocks": 143619,
|
||
"headers": 143619,
|
||
"bestblockhash": "000000c46cb3505ddd29653720686b6a3565ad1c5768e2908439382447572a93",
|
||
"difficulty": 0.003020638517858618,
|
||
"time": 1684530244,
|
||
"mediantime": 1684526116,
|
||
"verificationprogress": 0.999997961940662,
|
||
"initialblockdownload": false,
|
||
"chainwork": "0000000000000000000000000000000000000000000000000000019ab37d2194",
|
||
"size_on_disk": 769525915,
|
||
"pruned": false,
|
||
"warnings": ""
|
||
}
|
||
----
|
||
|
||
==== Regtest—The Local Blockchain
|
||
|
||
Regtest, which stands for
|
||
"Regression Testing," is a Bitcoin Core feature that allows you to
|
||
create a local blockchain for testing purposes. Unlike signet and testnet3, which
|
||
are a public and shared test blockchain, the regtest blockchains are
|
||
intended to be run as closed systems for local testing. You launch a
|
||
regtest blockchain from scratch. You may
|
||
add other nodes to the network, or run it with a single node only to
|
||
test the Bitcoin Core software.
|
||
|
||
To start Bitcoin Core in regtest mode, you use the +regtest+ flag:
|
||
|
||
----
|
||
$ bitcoind -regtest
|
||
----
|
||
|
||
Just like with testnet, Bitcoin Core will initialize a new blockchain
|
||
under the _regtest_ subdirectory of your bitcoind default directory:
|
||
|
||
----
|
||
bitcoind: Using data directory /home/username/.bitcoin/regtest
|
||
----
|
||
|
||
To use the command-line tool, you need to specify the +regtest+ flag
|
||
too. Let's try the +getblockchaininfo+ command to inspect the regtest
|
||
blockchain:
|
||
|
||
----
|
||
$ bitcoin-cli -regtest getblockchaininfo
|
||
{
|
||
"chain": "regtest",
|
||
"blocks": 0,
|
||
"headers": 0,
|
||
"bestblockhash": "0f9188f13cb7b2c71f2a335e3a4fc328bf5beb436012afca590b1a11466e2206",
|
||
"difficulty": 4.656542373906925e-10,
|
||
"mediantime": 1296688602,
|
||
"verificationprogress": 1,
|
||
"chainwork": "0000000000000000000000000000000000000000000000000000000000000002",
|
||
"pruned": false,
|
||
[...]
|
||
----
|
||
|
||
As you can see, there are no blocks yet. Let's create a default wallet,
|
||
get an address, and then mine some (500 blocks) to earn the reward:
|
||
|
||
----
|
||
$ bitcoin-cli -regtest createwallet ""
|
||
|
||
$ bitcoin-cli -regtest getnewaddress
|
||
bcrt1qwvfhw8pf79kw6tvpmtxyxwcfnd2t4e8v6qfv4a
|
||
|
||
$ bitcoin-cli -regtest generatetoaddress 500 bcrt1qwvfhw8pf79kw6tvpmtxyxwcfnd2t4e8v6qfv4a
|
||
[
|
||
"3153518205e4630d2800a4cb65b9d2691ac68eea99afa7fd36289cb266b9c2c0",
|
||
"621330dd5bdabcc03582b0e49993702a8d4c41df60f729cc81d94b6e3a5b1556",
|
||
"32d3d83538ba128be3ba7f9dbb8d1ef03e1b536f65e8701893f70dcc1fe2dbf2",
|
||
...,
|
||
"32d55180d010ffebabf1c3231e1666e9eeed02c905195f2568c987c2751623c7"
|
||
]
|
||
----
|
||
|
||
It will only take a few seconds to mine all these blocks, which
|
||
certainly makes it easy for testing. If you check your wallet balance,
|
||
you will see that you earned reward for the first 400 blocks (coinbase
|
||
rewards must be 100 blocks deep before you can spend them):
|
||
|
||
----
|
||
$ bitcoin-cli -regtest getbalance
|
||
12462.50000000
|
||
----
|
||
|
||
=== Using Test Blockchains for Development
|
||
|
||
Bitcoin's various
|
||
blockchains (+regtest+, +signet+, +testnet3+, +mainnet+) offer a range
|
||
of testing environments for bitcoin development. Use the test
|
||
blockchains whether you are developing for Bitcoin Core, or another
|
||
full-node consensus client; an application such as a wallet, exchange,
|
||
ecommerce site; or even developing novel smart contracts and complex
|
||
scripts.
|
||
|
||
You can use the test blockchains to establish a development pipeline.
|
||
Test your code locally on a +regtest+ as you develop it. Once you are
|
||
ready to try it on a public network, switch to +signet+ or +testnet+ to expose your
|
||
code to a more dynamic environment with more diversity of code and
|
||
applications. Finally, once you are confident your code works as
|
||
expected, switch to +mainnet+ to deploy it in production. As you make
|
||
changes, improvements, bug fixes, etc., start the pipeline again,
|
||
deploying each change first on +regtest+, then on +signet+ or +testnet+, and finally
|
||
into production.
|
||
|
||
Now that we know what data the blockchain contains and how cryptographic
|
||
commitments securely tie the various parts together, we will look at the
|
||
specical commitment that both provides computational security and
|
||
ensures no block can be changed without invalidating all other blocks
|
||
built on top of it: Bitcoin's mining function.
|