github.com/haliliceylan/bsc@v1.1.10-0.20220501224556-eb78d644ebcb/node/doc.go (about) 1 // Copyright 2016 The go-ethereum Authors 2 // This file is part of the go-ethereum library. 3 // 4 // The go-ethereum library is free software: you can redistribute it and/or modify 5 // it under the terms of the GNU Lesser General Public License as published by 6 // the Free Software Foundation, either version 3 of the License, or 7 // (at your option) any later version. 8 // 9 // The go-ethereum library is distributed in the hope that it will be useful, 10 // but WITHOUT ANY WARRANTY; without even the implied warranty of 11 // MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the 12 // GNU Lesser General Public License for more details. 13 // 14 // You should have received a copy of the GNU Lesser General Public License 15 // along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>. 16 17 /* 18 Package node sets up multi-protocol Ethereum nodes. 19 20 In the model exposed by this package, a node is a collection of services which use shared 21 resources to provide RPC APIs. Services can also offer devp2p protocols, which are wired 22 up to the devp2p network when the node instance is started. 23 24 25 Node Lifecycle 26 27 The Node object has a lifecycle consisting of three basic states, INITIALIZING, RUNNING 28 and CLOSED. 29 30 31 ●───────┐ 32 New() 33 │ 34 ▼ 35 INITIALIZING ────Start()─┐ 36 │ │ 37 │ ▼ 38 Close() RUNNING 39 │ │ 40 ▼ │ 41 CLOSED ◀──────Close()─┘ 42 43 44 Creating a Node allocates basic resources such as the data directory and returns the node 45 in its INITIALIZING state. Lifecycle objects, RPC APIs and peer-to-peer networking 46 protocols can be registered in this state. Basic operations such as opening a key-value 47 database are permitted while initializing. 48 49 Once everything is registered, the node can be started, which moves it into the RUNNING 50 state. Starting the node starts all registered Lifecycle objects and enables RPC and 51 peer-to-peer networking. Note that no additional Lifecycles, APIs or p2p protocols can be 52 registered while the node is running. 53 54 Closing the node releases all held resources. The actions performed by Close depend on the 55 state it was in. When closing a node in INITIALIZING state, resources related to the data 56 directory are released. If the node was RUNNING, closing it also stops all Lifecycle 57 objects and shuts down RPC and peer-to-peer networking. 58 59 You must always call Close on Node, even if the node was not started. 60 61 62 Resources Managed By Node 63 64 All file-system resources used by a node instance are located in a directory called the 65 data directory. The location of each resource can be overridden through additional node 66 configuration. The data directory is optional. If it is not set and the location of a 67 resource is otherwise unspecified, package node will create the resource in memory. 68 69 To access to the devp2p network, Node configures and starts p2p.Server. Each host on the 70 devp2p network has a unique identifier, the node key. The Node instance persists this key 71 across restarts. Node also loads static and trusted node lists and ensures that knowledge 72 about other hosts is persisted. 73 74 JSON-RPC servers which run HTTP, WebSocket or IPC can be started on a Node. RPC modules 75 offered by registered services will be offered on those endpoints. Users can restrict any 76 endpoint to a subset of RPC modules. Node itself offers the "debug", "admin" and "web3" 77 modules. 78 79 Service implementations can open LevelDB databases through the service context. Package 80 node chooses the file system location of each database. If the node is configured to run 81 without a data directory, databases are opened in memory instead. 82 83 Node also creates the shared store of encrypted Ethereum account keys. Services can access 84 the account manager through the service context. 85 86 87 Sharing Data Directory Among Instances 88 89 Multiple node instances can share a single data directory if they have distinct instance 90 names (set through the Name config option). Sharing behaviour depends on the type of 91 resource. 92 93 devp2p-related resources (node key, static/trusted node lists, known hosts database) are 94 stored in a directory with the same name as the instance. Thus, multiple node instances 95 using the same data directory will store this information in different subdirectories of 96 the data directory. 97 98 LevelDB databases are also stored within the instance subdirectory. If multiple node 99 instances use the same data directory, opening the databases with identical names will 100 create one database for each instance. 101 102 The account key store is shared among all node instances using the same data directory 103 unless its location is changed through the KeyStoreDir configuration option. 104 105 106 Data Directory Sharing Example 107 108 In this example, two node instances named A and B are started with the same data 109 directory. Node instance A opens the database "db", node instance B opens the databases 110 "db" and "db-2". The following files will be created in the data directory: 111 112 data-directory/ 113 A/ 114 nodekey -- devp2p node key of instance A 115 nodes/ -- devp2p discovery knowledge database of instance A 116 db/ -- LevelDB content for "db" 117 A.ipc -- JSON-RPC UNIX domain socket endpoint of instance A 118 B/ 119 nodekey -- devp2p node key of node B 120 nodes/ -- devp2p discovery knowledge database of instance B 121 static-nodes.json -- devp2p static node list of instance B 122 db/ -- LevelDB content for "db" 123 db-2/ -- LevelDB content for "db-2" 124 B.ipc -- JSON-RPC UNIX domain socket endpoint of instance B 125 keystore/ -- account key store, used by both instances 126 */ 127 package node