CESS Introduction

CESS (Cumulus Encrypted Storage System) is a blockchain powered decentralized storage and content delivery network (CDN) infrastructure for Web3. Users and creators alike use the platform for on-chain data sharing, whilst builders can develop and deploy DApps.

Offering the most optimal Web3 solution for storing and retrieving high-frequency dynamic data, CESS reshapes the value distribution and circulation of data assets whilst ensuring data sovereignty and user privacy. By utilizing a decentralized physical infrastructure network (DePIN) model, CESS drives mass deployment of network nodes globally through incentives.

CESS network consists of four layers: blockchain, data storage, content distribution, and application layer. CESS’s R²S consensus mechanism coordinates the network resources and network load, guarantees data security and integrity through proprietary technologies with data ownership protection, technologies such as Proof of Data Reduplication and Recovery (PoDR²), Multi-format Data Rights Confirmation (MDRC), and decentralized proxy re-encryption. CESS aims to be the first decentralized storage network that supports large-scale commercial applications.

CESS is also compatible with EVM and WASM, and the underlying development framework Substrate is also friendly to cross-chain applications. Its technology stack can support most Web3 applications and the development needs of enterprise-level applications.

Important Technological Deliveries

Blockchain Network:

Current testnet: v0.7.4* consists of consensus and storage nodes. ​​Consensus nodes maintain the world state of the CESS network (by CESS Node) and serve as the “data authentication station” (by TEE Worker). Storage nodes provide verifiable storage space and serve as the “data storage pool” in the CESS network.*

• Implemented user payment for space purchase in the chain network, offering robust support for expanding the application layer in the future.

• Upgraded on-chain storage node registration to enhance network security.

• Updated random challenge-related parameter configurations to reduce instances of node failure due to insufficient time.

• Adjusted the frequency of initiating random challenges to alleviate workload on storage nodes and TEE Worker.

• Optimized file upload functionality to significantly improve the efficiency of persisting user files on storage nodes.

• Introduced file fragment tagging in the chain network for precise management of file fragments.

• Optimized code structure in the chain network, reducing the storage burden on the blockchain by simplifying storage order metadata.

• Integrated and tested multi-signature functionality in the chain network.

• Upgraded user payment for space purchase in the chain network, allowing users to customize order expiration time.

• Resolved data overflow issues in the chain network’s operation of file Bloom filters used to record stored user files.

• Resolved inaccuracies in global computing power calculations caused by errors when handling offline node space lockup in the chain network.

• Resolved issues with file tag calculation tasks during the file upload process in the chain network.

• Optimized TEE Worker network architecture in the chain network by separating it from the p2p network for easier maintenance and upgrades.

• Transferred the TEE Worker registration process from Kaleido internal systems to the rotator program, reducing unnecessary performance overhead.

• Added validation functionality for various TEE Worker service interfaces in the chain network to intercept invalid requests.

• Enhanced TEE Worker log module for clearer logs and added service execution time displays.

Storage Miner [v0.7.5]

• Repaired issues in storage nodes where challenges couldn’t be passed due to erroneous deletion of active data.

• Resolved anomalies occurring in some storage nodes while retrieving external IP addresses.

• Upgraded the storage node’s storage space expansion feature to increment staking amounts correspondingly when scaling up.

• Fixed network glitches causing blockages in storage node space authentication processes.

• Enabled reporting of previously stored user files by storage nodes using a new file upload mechanism.

• Fixed storage nodes’ inability to retrieve idle space proof keys from TEE Worker.

• Enhanced the interaction process between storage nodes and TEE Worker by implementing a dedicated network to boost data transmission efficiency.

• Addressed data type conflicts in protobuf within the storage node’s libp2p library.

• Updated gRPC methods for communication between storage nodes’ p2p-go library and TEE Worker to resolve network connection failures.

• Fixed issues in the storage node’s idle space proof recovery module causing data read failures.

• Resolved address resolution failures when storage nodes requested idle space proof keys from TEE Worker.

• Addressed issues where challenges couldn’t be passed due to delayed completion of file tag calculations in storage nodes.

• Resolved space authentication failures due to inconsistent signature data in storage nodes.

• Fixed issues where locks in the storage node’s idle space proof module caused program blockages, hindering other functionalities.

The mission of CESS is to provide Web3 with practical storage services. The product ecosystem of the current CESS network is becoming more robust and prosperous. Innovative applications such as Decentralized Object Storage Service (DeOSS), online file sharing tool (DeShare), and public chain snapshot storage service have been incubated. Users can experience these functions.

DeOSS (Decentralized Object Storage Service)

• Optimized and released the gateway’s blacklist and whitelist feature, enabling users to customize access policies.

• Updated node registration-related data structures and transaction processes in the Go SDK to accommodate future upgrades.

• Enhanced the file upload process, allowing the gateway to select the most efficient storage nodes for storing user files.

• Removed data transmission restrictions in ShareSwap mechanism, boosting data sharing efficiency among gateways.

• Resolved version conflicts encountered when using the p2p-go library.

• Fixed signature verification failures during file uploads using the JS SDK.

• Addressed compatibility issues between ShareSwap and the p2p-go library.

• Conducted successful testing of the ShareSwap functionality, ensuring its reliable usage.

• Completed testing of the new file upload process, ensuring efficient and accurate storage of uploaded files across various storage nodes.

DeShare (Files sharing URL generator Tool)

• Implemented the functionality to allow users to send file information to their email addresses.

• Upgraded the file information display feature to support more detailed information, including file names.

Technical Solution

The technical team addressed the growing complexity in the current file upload process, which has resulted in higher development costs for subsequent iterations. They proposed a “Code Refactoring for File Upload” technical solution to mitigate this issue. After discussions and confirmation within the community, this plan will be implemented in future versions.

Technical Documentation and References

http://github.com/CESSProject

https://github.com/CESSProject/cess/wiki

https://github.com/CESSProject/CIPs

Join us

CESS website | Twitter | Telegram | Discord | Github | Medium | LinkedIn | Instagram

CESS Introduction

CESS (Cumulus Encrypted Storage System) is a blockchain powered decentralized storage and content delivery network (CDN) infrastructure for Web3. Users and creators alike use the platform for on-chain data sharing, whilst builders can develop and deploy DApps.

Offering the most optimal Web3 solution for storing and retrieving high-frequency dynamic data, CESS reshapes the value distribution and circulation of data assets whilst ensuring data sovereignty and user privacy. By utilizing a decentralized physical infrastructure network (DePIN) model, CESS drives mass deployment of network nodes globally through incentives.

CESS network consists of four layers: blockchain, data storage, content distribution, and application layer. CESS’s R²S consensus mechanism coordinates the network resources and network load, guarantees data security and integrity through proprietary technologies with data ownership protection, technologies such as Proof of Data Reduplication and Recovery (PoDR²), Multi-format Data Rights Confirmation (MDRC), and decentralized proxy re-encryption. CESS aims to be the first decentralized storage network that supports large-scale commercial applications.

CESS is also compatible with EVM and WASM, and the underlying development framework Substrate is also friendly to cross-chain applications. Its technology stack can support most Web3 applications and the development needs of enterprise-level applications.

Important Technological Deliveries

Blockchain Network:

Current testnet: v0.7.4* consists of consensus and storage nodes. ​​Consensus nodes maintain the world state of the CESS network (by CESS Node) and serve as the “data authentication station” (by TEE Worker). Storage nodes provide verifiable storage space and serve as the “data storage pool” in the CESS network.*

• Implemented user payment for space purchase in the chain network, offering robust support for expanding the application layer in the future.

• Upgraded on-chain storage node registration to enhance network security.

• Updated random challenge-related parameter configurations to reduce instances of node failure due to insufficient time.

• Adjusted the frequency of initiating random challenges to alleviate workload on storage nodes and TEE Worker.

• Optimized file upload functionality to significantly improve the efficiency of persisting user files on storage nodes.

• Introduced file fragment tagging in the chain network for precise management of file fragments.

• Optimized code structure in the chain network, reducing the storage burden on the blockchain by simplifying storage order metadata.

• Integrated and tested multi-signature functionality in the chain network.

• Upgraded user payment for space purchase in the chain network, allowing users to customize order expiration time.

• Resolved data overflow issues in the chain network’s operation of file Bloom filters used to record stored user files.

• Resolved inaccuracies in global computing power calculations caused by errors when handling offline node space lockup in the chain network.

• Resolved issues with file tag calculation tasks during the file upload process in the chain network.

• Optimized TEE Worker network architecture in the chain network by separating it from the p2p network for easier maintenance and upgrades.

• Transferred the TEE Worker registration process from Kaleido internal systems to the rotator program, reducing unnecessary performance overhead.

• Added validation functionality for various TEE Worker service interfaces in the chain network to intercept invalid requests.

• Enhanced TEE Worker log module for clearer logs and added service execution time displays.

Storage Miner [v0.7.5]

• Repaired issues in storage nodes where challenges couldn’t be passed due to erroneous deletion of active data.

• Resolved anomalies occurring in some storage nodes while retrieving external IP addresses.

• Upgraded the storage node’s storage space expansion feature to increment staking amounts correspondingly when scaling up.

• Fixed network glitches causing blockages in storage node space authentication processes.

• Enabled reporting of previously stored user files by storage nodes using a new file upload mechanism.

• Fixed storage nodes’ inability to retrieve idle space proof keys from TEE Worker.

• Enhanced the interaction process between storage nodes and TEE Worker by implementing a dedicated network to boost data transmission efficiency.

• Addressed data type conflicts in protobuf within the storage node’s libp2p library.

• Updated gRPC methods for communication between storage nodes’ p2p-go library and TEE Worker to resolve network connection failures.

• Fixed issues in the storage node’s idle space proof recovery module causing data read failures.

• Resolved address resolution failures when storage nodes requested idle space proof keys from TEE Worker.

• Addressed issues where challenges couldn’t be passed due to delayed completion of file tag calculations in storage nodes.

• Resolved space authentication failures due to inconsistent signature data in storage nodes.

• Fixed issues where locks in the storage node’s idle space proof module caused program blockages, hindering other functionalities.

The mission of CESS is to provide Web3 with practical storage services. The product ecosystem of the current CESS network is becoming more robust and prosperous. Innovative applications such as Decentralized Object Storage Service (DeOSS), online file sharing tool (DeShare), and public chain snapshot storage service have been incubated. Users can experience these functions.

DeOSS (Decentralized Object Storage Service)

• Optimized and released the gateway’s blacklist and whitelist feature, enabling users to customize access policies.

• Updated node registration-related data structures and transaction processes in the Go SDK to accommodate future upgrades.

• Enhanced the file upload process, allowing the gateway to select the most efficient storage nodes for storing user files.

• Removed data transmission restrictions in ShareSwap mechanism, boosting data sharing efficiency among gateways.

• Resolved version conflicts encountered when using the p2p-go library.

• Fixed signature verification failures during file uploads using the JS SDK.

• Addressed compatibility issues between ShareSwap and the p2p-go library.

• Conducted successful testing of the ShareSwap functionality, ensuring its reliable usage.

• Completed testing of the new file upload process, ensuring efficient and accurate storage of uploaded files across various storage nodes.

DeShare (Files sharing URL generator Tool)

• Implemented the functionality to allow users to send file information to their email addresses.

• Upgraded the file information display feature to support more detailed information, including file names.

Technical Solution

The technical team addressed the growing complexity in the current file upload process, which has resulted in higher development costs for subsequent iterations. They proposed a “Code Refactoring for File Upload” technical solution to mitigate this issue. After discussions and confirmation within the community, this plan will be implemented in future versions.

Technical Documentation and References

http://github.com/CESSProject

https://github.com/CESSProject/cess/wiki

https://github.com/CESSProject/CIPs

Join us

CESS website | Twitter | Telegram | Discord | Github | Medium | LinkedIn | Instagram