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Changes for page Networks

Last modified by Zenna Elfen on 2026/01/05 21:51
From version 14.1
edited by Zenna Elfen
on 2025/11/24 11:48
Change comment: There is no comment for this version
To version 45.1
edited by Zenna Elfen
on 2026/01/05 20:02
Change comment: There is no comment for this version

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3 -This page contains an overview of all P4P Networks in this wiki and their building blocks.
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5 += Peer-for-Peer Networks =
4 4  
5 -You can also [[add a P4P Network>>doc:Projects.WebHome]] or have a look at the [[P4P Applications>>doc:P4P.Applications.WebHome]].
7 +P4P, short for Peer-4-Peer (which in turn is short for Peer-for-Peer) are a family of networks which build on principles of local-first, peer-2-peer, open-source, routing agnostic (offline-first) and mutual-aid principles. The above is a lot of terms which in and of themselves carry a lot of meaning, yet when combined they enable censorship-resistant, resilient and adaptive, sustainable and energy-efficient communication infrastructures.
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21 +{{box title=" **Contents**"}}
22 +{{toc depth="5"/}}
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14 14  
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15 15  
16 16  
17 -== Building Blocks of P4P Networks ==
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22 -Lost in translation? Take a look at the [[terminology>>doc:P4P.Definitions.WebHome]].
32 +== Building Blocks of P4P Networks ==
33 +
34 +To fully assemble a P4P network one needs a few different building blocks, below is an overview of 15 of those building blocks. Lost in translation? Take a look at the [[terminology>>doc:P4P.Definitions.WebHome]].
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25 -To fully assemble a P4P network one needs a few different building blocks. The following is an overview of the building blocks needed for P4P networks.
26 26  
27 27  
28 -==== **Data Synchronization** ====
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29 29  
43 +==== **1. Data Synchronization** ====
44 +
30 30  > Synchronization answers **how updates flow between peers** and how they determine what data to exchange. This layer is about **diffing, reconciliation, order, causality tracking, and efficient exchange**, not persistence or user-facing collaboration semantics.
31 31  
32 -- _How do peers detect differences and synchronize state?_
33 -- Examples: Range-Based Set Reconciliation, RIBLT, Gossip-based sync, State-based vs op-based sync, Lamport/Vector/HLC clocks, Braid Protocol
47 +* //How do peers detect differences and synchronize state?//
48 +* Examples: Range-Based Set Reconciliation, RIBLT, Gossip-based sync, State-based vs op-based sync, Lamport/Vector/HLC clocks, Braid Protocol
34 34  
35 -*Relevant links or documentation:*
36 36  
37 37  
38 -==== **Collaborative Data Structures & Conflict Resolution** ====
52 +==== **2. Collaborative Data Structures & Conflict Resolution** ====
39 39  
40 40  > This layer defines **how shared data evolves** when multiple peers edit concurrently. It focuses on **conflict-free merging, causality, and consistency of meaning**, not transport or storage. CRDTs ensure deterministic convergence, while event-sourced or stream-driven models maintain a history of all changes and derive consistent state from it.
41 41  
42 -- _How do peers collaboratively change shared data and merge conflicts?_
43 -- Examples: CRDTs (Yjs, Automerge), OT, Event Sourcing, Stream Processing, Version Vectors, Peritext
56 +* //How do peers collaboratively change shared data and merge conflicts?//
57 +* Examples: CRDTs (Yjs, Automerge), OT, Event Sourcing, Stream Processing, Version Vectors, Peritext
44 44  
45 -*Relevant links or documentation:*
46 46  
47 47  
48 -==== **Data Storage & Replication** ====
61 +==== **3. Data Storage & Replication** ====
49 49  
50 50  > This layer focuses on **durability, consistency, and redundancy**. It handles write-paths, crash-resilience, and replication semantics across nodes. It is the “database/storage engine” layer where **data lives and survives over time**, independent of sync or merging logic.
51 51  
52 -- _How is data persisted locally and replicated between peers?_
53 -- Examples: SQLite, IndexedDB, LMDB, Hypercore (append-only logs), WALs, Merkle-DAGs (IPFS/IPLD), Blob/media storage
65 +* //How is data persisted locally and replicated between peers?//
66 +* Examples: SQLite, IndexedDB, LMDB, Hypercore (append-only logs), WALs, Merkle-DAGs (IPFS/IPLD), Blob/media storage
54 54  
55 -*Relevant links or documentation:*
56 56  
57 -==== **Peer & Content Discovery** ====
58 58  
70 +==== **4. Peer & Content Discovery** ====
71 +
59 59  > Discovery occurs in two phases:
60 60  > 1. **Peer Discovery** → finding _any_ nodes
61 61  > 2. **Topic Discovery** → finding _relevant_ nodes or resources
62 62  > These mechanisms enable decentralized bootstrapping and interest-based overlays.
63 63  
77 +* //How do peers find each other, and how do they discover content in the network?//
78 +* Examples: DHTs (Kademlia, Pastry), mDNS, DNS-SD, Bluetooth scanning, QR bootstrapping, static peer lists, Interest-based routing, PubSub discovery (libp2p), Rendezvous protocols
64 64  
65 -- _How do peers find each other, and how do they discover content in the network?_
66 -- Examples: DHTs (Kademlia, Pastry), mDNS, DNS-SD, Bluetooth scanning, QR bootstrapping, static peer lists, Interest-based routing, PubSub discovery (libp2p), Rendezvous protocols
67 67  
68 -*Relevant links or documentation:*
69 69  
70 -# **Identity & Trust**
82 +==== **5. Identity & Trust** ====
71 71  
72 72  > Identity systems ensure reliable mapping between peers and cryptographic keys. They underpin authorization, federated trust, and secure overlays.
73 73  
74 -- _How peers identify themselves, authenticate, and establish trustworthy relationships?_
75 -- Examples: PKI, Distributed Identities (DIDs), Web-of-Trust, TOFU (SSH-style), Verifiable Credentials (VCs), Peer key fingerprints (libp2p PeerIDs), Key transparency logs
86 +* //How peers identify themselves, authenticate, and establish trustworthy relationships?//
87 +* Examples: PKI, Distributed Identities (DIDs), Web-of-Trust, TOFU (SSH-style), Verifiable Credentials (VCs), Peer key fingerprints (libp2p PeerIDs), Key transparency logs
76 76  
77 77  
78 78  
91 +==== **6. Transport Layer** ====
79 79  
93 +> This layer provides logical connections and flow control. QUIC and WebRTC bring modern congestion control and encryption defaults; Interpeer explores transport beyond IP assumptions.
80 80  
95 +* //How do peers establish end-to-end byte streams and reliable delivery?//
96 +* Examples: TCP, UDP, QUIC, SCTP, WebRTC DataChannels, Interpeer transport stack
81 81  
98 +
99 +
100 +==== **7. Underlying Transport (Physical/Link Layer)** ====
101 +
102 +> Highly relevant for **offline-first / edge networks**, device-to-device communication, and mesh networks and relates to the hardware which facilitates connections.
103 +
104 +* //How does data move across the medium?//
105 +* Examples: Ethernet, Wi-Fi Direct / Wi-Fi Aware (post-AWDL), Bluetooth Mesh, LoRa, NFC, Cellular, CSMA/CA, TDMA, FHSS
106 +
107 +
108 +
109 +==== **8. Session & Connection Management** ====
110 +
111 +> Manages **connection lifecycle**, including authentication handshakes, reconnection after drops, and session continuation—especially important in lossy or mobile networks.
112 +
113 +* //How are connections initiated, authenticated, resumed, and kept alive?//
114 +* Examples: TLS handshake semantics, Noise IK/XX patterns, session tokens, keep-alive heartbeats, reconnection strategies, session resumption tickets
115 +
116 +
117 +
118 +==== **9. Content Addressing** ====
119 +
120 +> Content addressing ensures **immutability, verifiability, and deduplication**. Identity of data = cryptographic hash, enabling offline-first and tamper-evident systems.
121 +
122 +* //How is data addressed and verified by content, not location?//
123 +* Examples: IPFS CIDs, BitTorrent infohashes, Git hashes, SHA-256 addressing, Named Data Networking (NDN)
124 +
125 +
126 +
127 +==== **10. P2P Connectivity** ====
128 +
129 +> Connectivity ensures peers bypass NATs/firewalls to reach each other. 
130 +
131 +* //How can two peers connect directly across networks, firewalls, and NATs?//
132 +* Examples: IPv6 direct, NAT Traversal, STUN, TURN, ICE (used in WebRTC), UDP hole punching, UPnP
133 +
134 +
135 +
136 +==== **11. Session & Connection Management** ====
137 +
138 +> Manages **connection lifecycle**, including authentication handshakes, reconnection after drops, and session continuation.
139 +
140 +* //How are connections initiated, authenticated, resumed, and kept alive?//
141 +* Examples: TLS handshake semantics, Noise IK/XX patterns, session tokens, keep-alive heartbeats, reconnection strategies, session resumption tickets
142 +
143 +
144 +
145 +==== **12. Message Format & Serialization** ====
146 +
147 +> Serialization ensures **portable data representation**, forward-compatible schemas, and efficient messaging. IPLD provides content-addressed structuring for P2P graph data.
148 +
149 +* //How is data encoded, structured, and made interoperable between peers?//
150 +* Examples: CBOR, Protocol Buffers, Cap’n Proto, JSON, ASN.1, IPLD schemas, Flatbuffers
151 +
152 +
153 +
154 +==== **13. File / Blob Synchronization** ====
155 +
156 +> Bulk data syncing has **different trade-offs** than small collaborative state (chunking, deduplication, partial transfer, resume logic). Critical for media and archival P2P use-cases.
157 +
158 +//How are large objects transferred and deduplicated efficiently across peers?//
159 +Examples: BitTorrent chunking, IPFS block-store, NDN segments, rsync-style delta sync, ZFS send-receive, streaming blob transfers
160 +
161 +
162 +==== **14. Local Storage & Processing Primitives** ====
163 +
164 +> Provides durable on-device state and local computation (event sourcing, materialization, compaction). Enables offline-first writes and deterministic replay.
165 +
166 +* //How do nodes persist, index, and process data locally—without external servers?//
167 +* Examples: RocksDB, LevelDB, SQLite, LMDB, local WALs/append-only logs, embedded stream processors (NATS Core JetStream mode, Actyx-like edge runtimes), Kafka-like libraries
168 +
169 +
170 +
171 +==== **15. Crash Resilience & Abortability** ====
172 +
173 +> Ensures P2P apps don’t corrupt state on crashes. Tied to **local storage & stream-processing**, and critical in offline-first and distributed update pipelines. Abortability is the updated term for Atomicity as part of the ACID abbreviation.
174 +
175 +* //How do nodes recover and maintain correctness under failure?//
176 +* Examples: WALs, idempotent ops, partial log replay, transactional journaling, write fences
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180 +
82 82  == Distributed Network Types ==
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89 89  == Overview of P4P Networks ==
90 90  
91 91  {{include reference="Projects.WebHome"/}}
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199 +~)~)~)
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