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@ -11,17 +11,17 @@ Bitcoin's P2P network architecture is much more than a topology choice. Bitcoin
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=== Nodes Types and Roles
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((("bitcoin network","nodes")))((("nodes","roles of")))((("nodes","types of")))Although nodes in the bitcoin P2P network are equal, they may take on different roles depending on the functionality they are supporting. A bitcoin node is a collection of functions: routing, the block chain database, mining, and wallet services. A full node with all four of these functions is shown in <<full_node_reference>>.
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((("bitcoin network","nodes")))((("nodes","roles of")))((("nodes","types of")))Although nodes in the bitcoin P2P network are equal, they may take on different roles depending on the functionality they are supporting. A bitcoin node is a collection of functions: routing, the blockchain database, mining, and wallet services. A full node with all four of these functions is shown in <<full_node_reference>>.
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[[full_node_reference]]
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.A bitcoin network node with all four functions: wallet, miner, full block chain database, and network routing
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.A bitcoin network node with all four functions: wallet, miner, full blockchain database, and network routing
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image::images/msbt_0601.png["FullNodeReferenceClient_Small"]
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All nodes include the routing function to participate in the network and might include other functionality. All nodes validate and propagate transactions and blocks, and discover and maintain connections to peers. In the full-node example in <<full_node_reference>>, the routing function is indicated by an orange circle named "Network Routing Node."
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Some nodes, called full nodes, also maintain a complete and up-to-date copy of the block chain. Full nodes can autonomously and authoritatively verify any transaction without external reference. Some nodes maintain only a subset of the block chain and verify transactions using a method called((("simplified payment verification (SPV) nodes","defined"))) _simplified payment verification_, or SPV. These nodes are known as SPV or lightweight nodes. In the full-node example in the figure, the full-node block chain database function is indicated by a blue circle named "Full Blockchain." SPV nodes are drawn without the blue circle, showing that they do not have a full copy of the block chain.
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Some nodes, called full nodes, also maintain a complete and up-to-date copy of the blockchain. Full nodes can autonomously and authoritatively verify any transaction without external reference. Some nodes maintain only a subset of the blockchain and verify transactions using a method called((("simplified payment verification (SPV) nodes","defined"))) _simplified payment verification_, or SPV. These nodes are known as SPV or lightweight nodes. In the full-node example in the figure, the full-node blockchain database function is indicated by a blue circle named "Full Blockchain." SPV nodes are drawn without the blue circle, showing that they do not have a full copy of the blockchain.
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Mining nodes compete to create new blocks by running specialized hardware to solve the proof-of-work algorithm. Some mining nodes are also full nodes, maintaining a full copy of the block chain, while others are lightweight nodes participating in pool mining and depending on a pool server to maintain a full node. The mining function is shown in the full node as a black circle named "Miner."
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Mining nodes compete to create new blocks by running specialized hardware to solve the proof-of-work algorithm. Some mining nodes are also full nodes, maintaining a full copy of the blockchain, while others are lightweight nodes participating in pool mining and depending on a pool server to maintain a full node. The mining function is shown in the full node as a black circle named "Miner."
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User wallets might be part of a full node, as is usually the case with desktop bitcoin clients. Increasingly, many user wallets, especially those running on resource-constrained devices such as smartphones, are SPV nodes. The wallet function is shown in <<node_type_ledgend>> as a green circle named "Wallet".
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@ -35,9 +35,9 @@ image::images/msbt_0602.png["BitcoinNodeTypes"]
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=== The Extended Bitcoin Network
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((("bitcoin network","extended")))((("extended bitcoin network")))The main bitcoin network, running the bitcoin P2P protocol, consists of between 7,000 and 10,000 listening nodes running various versions of the bitcoin reference client (Bitcoin Core) and a few hundred nodes running various other implementations of the bitcoin P2P protocol, such as((("BitcoinJ library")))((("btcd")))((("libbitcoin library"))) BitcoinJ, Libbitcoin, and btcd. A small percentage of the nodes on the bitcoin P2P network are also mining nodes, competing in the mining process, validating transactions, and creating new blocks. Various large companies interface with the bitcoin network by running full-node clients based on the Bitcoin Core client, with full copies of the block chain and a network node, but without mining or wallet functions. These nodes act as network edge routers, allowing various other services (exchanges, wallets, block explorers, merchant payment processing) to be built on top.
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((("bitcoin network","extended")))((("extended bitcoin network")))The main bitcoin network, running the bitcoin P2P protocol, consists of between 7,000 and 10,000 listening nodes running various versions of the bitcoin reference client (Bitcoin Core) and a few hundred nodes running various other implementations of the bitcoin P2P protocol, such as((("BitcoinJ library")))((("btcd")))((("libbitcoin library"))) BitcoinJ, Libbitcoin, and btcd. A small percentage of the nodes on the bitcoin P2P network are also mining nodes, competing in the mining process, validating transactions, and creating new blocks. Various large companies interface with the bitcoin network by running full-node clients based on the Bitcoin Core client, with full copies of the blockchain and a network node, but without mining or wallet functions. These nodes act as network edge routers, allowing various other services (exchanges, wallets, block explorers, merchant payment processing) to be built on top.
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The extended bitcoin network includes the network running the bitcoin P2P protocol, described earlier, as well as nodes running specialized protocols. Attached to the main bitcoin P2P network are a number of((("mining pools","on the bitcoin network"))) pool servers and protocol gateways that connect nodes running other protocols. These other protocol nodes are mostly pool mining nodes (see <<ch8>>) and lightweight wallet clients, which do not carry a full copy of the block chain.
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The extended bitcoin network includes the network running the bitcoin P2P protocol, described earlier, as well as nodes running specialized protocols. Attached to the main bitcoin P2P network are a number of((("mining pools","on the bitcoin network"))) pool servers and protocol gateways that connect nodes running other protocols. These other protocol nodes are mostly pool mining nodes (see <<ch8>>) and lightweight wallet clients, which do not carry a full copy of the blockchain.
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<<bitcoin_network>> shows the extended bitcoin network with the various types of nodes, gateway servers, edge routers, and wallet clients and the various protocols they use to connect to each other.
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@ -128,34 +128,34 @@ If there is no traffic on a connection, nodes will periodically send a message t
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=== Full Nodes
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((("block chains","full nodes and")))((("full nodes")))((("nodes","full")))Full nodes are nodes that maintain a full block chain with all transactions. More accurately, they probably should be called "full block chain nodes." In the early years of bitcoin, all nodes were full nodes and currently the Bitcoin Core client is a full block chain node. In the past two years, however, new forms of bitcoin clients have been introduced that do not maintain a full block chain but run as lightweight clients. We'll examine these in more detail in the next section.
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((("blockchains","full nodes and")))((("full nodes")))((("nodes","full")))Full nodes are nodes that maintain a full blockchain with all transactions. More accurately, they probably should be called "full blockchain nodes." In the early years of bitcoin, all nodes were full nodes and currently the Bitcoin Core client is a full blockchain node. In the past two years, however, new forms of bitcoin clients have been introduced that do not maintain a full blockchain but run as lightweight clients. We'll examine these in more detail in the next section.
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((("block chains","on full nodes")))Full block chain nodes maintain a complete and up-to-date copy of the bitcoin block chain with all the transactions, which they independently build and verify, starting with the very first block (genesis block) and building up to the latest known block in the network. A full block chain node can independently and authoritatively verify any transaction without recourse or reliance on any other node or source of information. The full block chain node relies on the network to receive updates about new blocks of transactions, which it then verifies and incorporates into its local copy of the block chain.
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((("blockchains","on full nodes")))Full blockchain nodes maintain a complete and up-to-date copy of the bitcoin block chain with all the transactions, which they independently build and verify, starting with the very first block (genesis block) and building up to the latest known block in the network. A full block chain node can independently and authoritatively verify any transaction without recourse or reliance on any other node or source of information. The full block chain node relies on the network to receive updates about new blocks of transactions, which it then verifies and incorporates into its local copy of the block chain.
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Running a full block chain node gives you the pure bitcoin experience: independent verification of all transactions without the need to rely on, or trust, any other systems. It's easy to tell if you're running a full node because it requires 20+ gigabytes of persistent storage (disk space) to store the full block chain. If you need a lot of disk and it takes two to three days to sync to the network, you are running a full node. That is the price of complete independence and freedom from central authority.
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Running a full blockchain node gives you the pure bitcoin experience: independent verification of all transactions without the need to rely on, or trust, any other systems. It's easy to tell if you're running a full node because it requires 20+ gigabytes of persistent storage (disk space) to store the full blockchain. If you need a lot of disk and it takes two to three days to sync to the network, you are running a full node. That is the price of complete independence and freedom from central authority.
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There are a few alternative implementations of full block chain bitcoin clients, built using different programming languages and software architectures. However, the most common implementation is the reference client((("Bitcoin Core client","and full nodes"))) Bitcoin Core, also known as the Satoshi client. More than 90% of the nodes on the bitcoin network run various versions of Bitcoin Core. It is identified as "Satoshi" in the sub-version string sent in the +version+ message and shown by the command +getpeerinfo+ as we saw earlier; for example, +/Satoshi:0.8.6/+.
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There are a few alternative implementations of full blockchain bitcoin clients, built using different programming languages and software architectures. However, the most common implementation is the reference client((("Bitcoin Core client","and full nodes"))) Bitcoin Core, also known as the Satoshi client. More than 90% of the nodes on the bitcoin network run various versions of Bitcoin Core. It is identified as "Satoshi" in the sub-version string sent in the +version+ message and shown by the command +getpeerinfo+ as we saw earlier; for example, +/Satoshi:0.8.6/+.
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=== Exchanging "Inventory"
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((("block chains","creating on nodes")))((("block chains","on new nodes")))((("blocks","on new nodes")))((("full nodes","creating full block chains on")))The first thing a full node will do once it connects to peers is try to construct a complete block chain. If it is a brand-new node and has no block chain at all, it only knows one block, the genesis block, which is statically embedded in the client software. Starting with block #0 (the genesis block), the new node will have to download hundreds of thousands of blocks to synchronize with the network and re-establish the full block chain.
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((("blockchains","creating on nodes")))((("blockchains","on new nodes")))((("blocks","on new nodes")))((("full nodes","creating full blockchains on")))The first thing a full node will do once it connects to peers is try to construct a complete blockchain. If it is a brand-new node and has no blockchain at all, it only knows one block, the genesis block, which is statically embedded in the client software. Starting with block #0 (the genesis block), the new node will have to download hundreds of thousands of blocks to synchronize with the network and re-establish the full blockchain.
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((("syncing the block chain")))The process of syncing the block chain starts with the +version+ message, because that contains +BestHeight+, a node's current block chain height (number of blocks). A node will see the +version+ messages from its peers, know how many blocks they each have, and be able to compare to how many blocks it has in its own block chain. Peered nodes will exchange a%605.420%%% +getblocks+ message that contains the hash (fingerprint) of the top block on their local block chain. One of the peers will be able to identify the received hash as belonging to a block that is not at the top, but rather belongs to an older block, thus deducing that its own local block chain is longer than its peer's.
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((("syncing the blockchain")))The process of syncing the blockchain starts with the +version+ message, because that contains +BestHeight+, a node's current blockchain height (number of blocks). A node will see the +version+ messages from its peers, know how many blocks they each have, and be able to compare to how many blocks it has in its own blockchain. Peered nodes will exchange a%605.420%%% +getblocks+ message that contains the hash (fingerprint) of the top block on their local blockchain. One of the peers will be able to identify the received hash as belonging to a block that is not at the top, but rather belongs to an older block, thus deducing that its own local blockchain is longer than its peer's.
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The peer that has the longer block chain has more blocks than the other node and can identify which blocks the other node needs in order to "catch up." It will identify the first 500 blocks to share and transmit their hashes using an((("inv messages"))) +inv+ (inventory) message. The node missing these blocks will then retrieve them, by issuing a series of +getdata+ messages requesting the full block data and identifying the requested blocks using the hashes from the +inv+ message.
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The peer that has the longer blockchain has more blocks than the other node and can identify which blocks the other node needs in order to "catch up." It will identify the first 500 blocks to share and transmit their hashes using an((("inv messages"))) +inv+ (inventory) message. The node missing these blocks will then retrieve them, by issuing a series of +getdata+ messages requesting the full block data and identifying the requested blocks using the hashes from the +inv+ message.
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Let's assume, for example, that a node only has the genesis block. It will then receive an +inv+ message from its peers containing the hashes of the next 500 blocks in the chain. It will start requesting blocks from all of its connected peers, spreading the load and ensuring that it doesn't overwhelm any peer with requests. The node keeps track of how many blocks are "in transit" per peer connection, meaning blocks that it has requested but not received, checking that it does not exceed a limit((("MAX_BLOCKS_IN_TRANSIT_PER_PEER constant"))) (+MAX_BLOCKS_IN_TRANSIT_PER_PEER+). This way, if it needs a lot of blocks, it will only request new ones as previous requests are fulfilled, allowing the peers to control the pace of updates and not overwhelming the network. As each block is received, it is added to the block chain, as we will see in <<blockchain>>. As the local block chain is gradually built up, more blocks are requested and received, and the process continues until the node catches up to the rest of the network.
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Let's assume, for example, that a node only has the genesis block. It will then receive an +inv+ message from its peers containing the hashes of the next 500 blocks in the chain. It will start requesting blocks from all of its connected peers, spreading the load and ensuring that it doesn't overwhelm any peer with requests. The node keeps track of how many blocks are "in transit" per peer connection, meaning blocks that it has requested but not received, checking that it does not exceed a limit((("MAX_BLOCKS_IN_TRANSIT_PER_PEER constant"))) (+MAX_BLOCKS_IN_TRANSIT_PER_PEER+). This way, if it needs a lot of blocks, it will only request new ones as previous requests are fulfilled, allowing the peers to control the pace of updates and not overwhelming the network. As each block is received, it is added to the blockchain, as we will see in <<blockchain>>. As the local blockchain is gradually built up, more blocks are requested and received, and the process continues until the node catches up to the rest of the network.
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This process of comparing the local block chain with the peers and retrieving any missing blocks happens any time a node goes offline for any period of time. Whether a node has been offline for a few minutes and is missing a few blocks, or a month and is missing a few thousand blocks, it starts by sending +getblocks+, gets an +inv+ response, and starts downloading the missing blocks. <<inventory_synchronization>> shows the inventory and block propagation protocol.
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This process of comparing the local blockchain with the peers and retrieving any missing blocks happens any time a node goes offline for any period of time. Whether a node has been offline for a few minutes and is missing a few blocks, or a month and is missing a few thousand blocks, it starts by sending +getblocks+, gets an +inv+ response, and starts downloading the missing blocks. <<inventory_synchronization>> shows the inventory and block propagation protocol.
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[[inventory_synchronization]]
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.Node synchronizing the block chain by retrieving blocks from a peer
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.Node synchronizing the blockchain by retrieving blocks from a peer
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image::images/msbt_0606.png["InventorySynchronization"]
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[[spv_nodes]]
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=== Simplified Payment Verification (SPV) Nodes
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((("nodes","SPV", id="ix_ch06-asciidoc5", range="startofrange")))((("nodes","lightweight", id="ix_ch06-asciidoc5a", range="startofrange")))((("simplified payment verification (SPV) nodes", id="ix_ch06-asciidoc6", range="startofrange")))Not all nodes have the ability to store the full block chain. Many bitcoin clients are designed to run on space- and power-constrained devices, such as smartphones, tablets, or embedded systems. For such devices, a _simplified payment verification_ (SPV) method is used to allow them to operate without storing the full block chain. These types of clients are called SPV clients or lightweight clients. As bitcoin adoption surges, the SPV node is becoming the most common form of bitcoin node, especially for bitcoin wallets.
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((("nodes","SPV", id="ix_ch06-asciidoc5", range="startofrange")))((("nodes","lightweight", id="ix_ch06-asciidoc5a", range="startofrange")))((("simplified payment verification (SPV) nodes", id="ix_ch06-asciidoc6", range="startofrange")))Not all nodes have the ability to store the full blockchain. Many bitcoin clients are designed to run on space- and power-constrained devices, such as smartphones, tablets, or embedded systems. For such devices, a _simplified payment verification_ (SPV) method is used to allow them to operate without storing the full blockchain. These types of clients are called SPV clients or lightweight clients. As bitcoin adoption surges, the SPV node is becoming the most common form of bitcoin node, especially for bitcoin wallets.
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((("block chains","on SPV nodes")))SPV nodes download only the block headers and do not download the transactions included in each block. The resulting chain of blocks, without transactions, is 1,000 times smaller than the full block chain. SPV nodes cannot construct a full picture of all the UTXOs that are available for spending because they do not know about all the transactions on the network. SPV nodes verify transactions using a slightly different methodology that relies on peers to provide partial views of relevant parts of the block chain on demand.
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