Founded by former Qualcomm, Intel, and Dropbox engineers in late-2017, Solana is a single-chain, delegated-Proof-of-Stake protocol whose focus is on delivering scalability without sacrificing decentralization or security.
Core to Solana's scaling solution is a decentralized clock titled Proof-of-History (PoH), built to solve the problem of time in distributed networks in where there is not a single, trusted, source of time. By using Verifiable Delay Functions, PoH allows each node to locally generate timestamps with SHA256 computations. This eliminates the need for the broadcasts of timestamps accross the network, improving overall network efficiency.
Solana’s mission is to support all high-growth and high-frequency blockchain applications, and to democratize the world’s financial systems.
At its core, Solana offers:
|Circulating Supply||16,350,633 SOL (3.35%)|
|Current Total Supply*||488,634,933 SOL|
|Initial Total Supply||500,000,000 SOL|
*11,365,067 SOL tokens are burnt and removed from supply.
SOL is the native asset of the Solana blockchain. It is used for:
Solana's highly performant blockchain is built using 8 major innovations highlighted below:
One challenge of distributed networks is finding agreement on the time and sequence in which events occurred, as nodes within the network cannot simply trust an external source of time or any timestamp that appears in a message. Solana requires all validators to constantly solve SHA256-based Verifiable Delay Functions (VDF). A VDF requires a specific number of sequential steps to evaluate, yet produces a unique output that can be efficiently and publicly verified.
The VDFs can only be solved by a single CPU core applying a particular set of sequential steps. The team notes that since for a SHA256 hash function, parallel processing is impossible without a brute force attack using 2¹²⁸ cores, it is not difficult to define exactly how long it takes to apply those steps.
Solana's specific implementation uses a sequential hash that runs over itself continuously with the previous output used as the next input. With the computational output of the current function "X", a validator will be able to calculate the output for the next function "Y". Since the computation is universal, meaning all validators need to solve the same function "X", and will be able to derive the output for the next function "Y" in around the same time, Solana is able to create a synchronized "clock" across the whole network.
The team also believes that the use of Application Specific Integrated Circuits ("ASICs") would not pose a significant threat to the current PoH design, since an ASIC device would only be within 30% faster than general purpose equipments. An attack from ASIC devices, per the Solana team, can be quickly addressed.
Tower BFT leverages Solana’s PoH as a clock before consensus to reduce communication overhead and latency.
Each time a node on the network votes on a particular fork, voting is restricted to a fixed period of hashes, which is called a slot. The current network setting has around 400ms for one slot. Every 400ms, the network has a potential rollback point, but every subsequent vote doubles the amount of time that the network would have to stall before it can unroll that vote.
For instance, each validator has voted 32 times in the last 12 seconds. The vote 12 seconds ago now will have a timeout of 2³² slots, or roughly 54 years. Effectively, this vote will never be rolled back by the network. Whereas the most recent vote has a timeout of 2 slots, or about 800ms. As new blocks are added to the ledger, old blocks are increasingly likely to be confirmed because the number of slots old votes are committed to doubles every slot, or every 400ms. Tower BTF offers finality as Once ⅔ of validators have voted on some order of events, it will be canonicalized and cannot be rolled back.
The Solana mainnet is planned to operate in delegated-Proof-of-Stake (dPoS), in which token holders can participate in the block production process and earn rewards by either stake token and become a validator themselves, or delegate their tokens to validators they trust.
Often times in a distributed system, increasing the node count will increase the amount of time necessary to propagate all the data to all nodes. Turbine is a block propagation protocol aimed to solve this issue.
With Turbine, if a node were to propagate a very large message to the 1,000 peers, it would not transmit the information 1,000 times itself. Instead, the message would be broken down into very small packets, transmitting each packet to a different validator.
In turn, each validator retransmits the packet to a group of peers that are called a neighborhood. Each neighborhood is responsible for transmitting a portion of its data to each neighborhood next to it. If each neighborhood is comprised of 200 nodes, a 3-level network, starting with a single leader at the root, can reach 40,000 validators in 2 hops.
To handle adversarial nodes who might choose not to rebroadcast data, the leader generates Reed-Solomon erasure codes. Erasure codes allow each validator to reconstruct the entire block without receiving all the packets. If the leader transmits 33% of the block’s packets as erasure codes, then the network can drop any 33% of the packets without losing the block. Leaders can also adjust this number dynamically based on network conditions.
For each block production process, the upcoming network leaders will also be determined according to their stakes. Clients and validators can forward transactions to the expected leader ahead of time. This allows validators to execute transactions ahead of time, reduce confirmation times, switch leaders faster, and reduce the memory pressure on validators from the unprocessed transaction pool.
Sealevel, is a hyper-parallelized transaction processing engine designed to scale horizontally across GPUs and SSDs. Note that all other blockchains are single-threaded computers. Solana is the only chain to support parallel transaction execution (not just signature verification) in a single shard.
The solution to this problem borrows heavily from an operating system driver technique called scatter-gather. Transactions specify up front what state they will read and write while executing. Sealevel is able to find all the non-overlapping transactions occurring in a block and execute them in parallel — what is called parallel execution — while optimizing how read and writes to the state are scheduled across an array of RAID 0 SSDs.
Although Sealevel itself is a VM that schedules transactions, Sealevel doesn’t actually execute transactions in the VM. Instead, Sealevel hands off transactions to be executed on hardware natively using an industry-proven bytecode called the Berkeley Packet Filter (BPF), which is designed for high-performance packet filters. This bytecode has been optimized since the early 90s, and has been deployed in production in millions of switches worldwide to handle 60 million packets per second on a 40-gigabit network in a single switch.
The process of transaction validation on the Solana network makes extensive use of an optimization common in CPU design called pipelining. Pipelining is an appropriate process when there is a stream of input data that needs to be processed by a sequence of steps and there’s different hardware responsible for each. This mechanism ensures that all parts of the hardware are efficiently at work all the time.
On the Solana network, the Transaction Processing Unit (TPU) progresses through data fetching at the kernel level, signature verification at the GPU level, banking at the CPU level, and writing at the kernel space. By the time the TPU starts to send blocks out to the validators, it’s already fetched in the next set of packets, verified their signatures, and begun crediting tokens.
In a distributed system, memory is used to keep track of accounts, and can struggle to maintain performance due to a lack of memory size and limited access speeds.
Therefore Cloudbreak was designed to optimize for concurrent reads and writes spread across a RAID 0 configuration of SSDs. Each additional disk adds storage capacity available to on-chain programs, while also increasing the number of concurrent reads and writes programs can perform when executing.
On Solana, data storage is offloaded from validators to a network of nodes called Archivers. Archivers do not participate in consensus. The history of the state is broken into many pieces and erasure coded. Archivers store small parts of the state. Every so often, the network will ask the Archivers to prove that they’re storing the data they are supposed to.
SOL is the native token of the Solana blockchain. Solana uses a delegated-Proof-of-Stake consensus algorithm that incentivizes token holders to validate transactions. As part of Solana's security design, all fees will be paid in SOL and will be burnt, reducing total supply. This deflationary mechanism to SOL supply incentivizes more token holders to stake, which results in increased network security.
|Seed Sale Token Price||0.040 USD|
|Seed Sale Date||April 5th, 2018|
|Amount Raised Seed Sale||3.17 MM USD|
|Seed Sale Allocation||16.23% of total token supply|
|Founding Sale Token Price||0.200 USD|
|Founding Sale Date||June 3rd, 2018|
|Amount Raised Founding Sale||12.63 MM USD|
|Founding Sale Allocation||12.92% of total token supply|
|Validator Sale Token Price||0.225 USD|
|Validator Sale Date||July 9th, 2019|
|Amount Raised Validator Sale||5.70 MM USD|
|Validator Sale Allocation||5.18% of total token supply|
|Strategic Sale Token Price||0.250 USD|
|Strategic Sale Date||January 2nd 2020|
|Amount Raised Strategic Sale||2.29 MM USD|
|Strategic Sale Allocation||1.88% of total token supply|
|CoinList Auction Sale Price||0.220 USD|
|CoinList Auction Sale Date||March 23rd, 2020|
|Amount Raised CoinList Auction Sale||1.76 MM USD|
|CoinList Auction Sale Allocation||1.64% of total token supply|
Solana has implemented a staker price guarantee for users who purchase SOL tokens, register them, and stake them to secure the network. The staker price guarantee is 0.198 USD (90% of the Coinlist auction reserve price of 0.220, which was established on March 24, 2020). Further details on the Staker Price Guarantee can be found in the FAQ accompanying Solana’s CoinList auction.
The token supply distribution is as follows:
Seed Sale overview: the Seed Sale was conducted on April 5th, 2018 for 79,290,466 SOL at a rate of 0.040 USD = 1 SOL, at an average rate of 451.34 USD = 1 ETH, and 6,600 USD = 1 BTC and raised a total of 3.17 MM USD, selling 16.23% of the total token supply. The Seed Sale was conducted in ETH, BTC, and USD, and raised a total of 762.2 ETH, 60.6 BTC, and 2,427,619 USD.
Founding Sale overview: the Founding Sale was conducted on June 3rd, 2018 for 63,151,982 SOL at a rate of 0.200 USD = 1 SOL, at an average rate of 552.96 USD = 1 ETH, and 6,290 USD = 1 BTC, and raised a total of 12.63 MM USD, selling 12.92% of the total token supply. The Founding Sale was conducted in ETH, BTC, and USD, and raised a total of 16,964.1 ETH, 15.9 BTC, and 3,149,880 USD.
Validator Sale overview: the Validator Sale was conducted on July 9th, 2019 for 25,331,653 SOL at a rate of 0.225 USD = 1 SOL, at an average rate of 220.46 USD = 1 ETH, and 9,774.97 USD = 1 BTC, and raised a total of 5.70 MM USD, selling 5.18% of the total token supply. The Validator Sale was conducted in ETH, BTC, and USD, and raised a total of 9,630.7 ETH, 20.5 BTC, and 3,374,000 USD.
Strategic Sale overview: the Strategic Sale was conducted on February 18th, 2020 for 9,175,520 SOL at a rate of 0.250 USD = 1 SOL, at an average rate of 194.48 USD = 1 ETH, and 9,376.50 USD = 1 BTC and raised a total of 2.29 MM USD, selling 1.88% of the total token supply. The Strategic Sale was conducted in ETH, BTC, and USD, and raised a total of 77.1 ETH, 15.3 BTC, and 2,135,000 USD.
CoinList Auction Sale overview: the CoinList Auction was conducted on March 24th, 2020 for 8,000,000 SOL at a rate of 0.220 USD = 1 SOL, and raised a total of 1.76 MM USD, selling 1.64% of total token supply in a dutch auction via CoinList.
As of writing, Solana has used approximately 11.79MM USD (46.12%) of token sale funds, according to the allocations below:
Community tokens are held by the Swiss Foundation, which is run by an independent board. This token pool is used for bounties, incentives programs, marketing, and grants. Tokens held by the Foundation are held in Coinbase Custody, on hardware wallets, and in cold storage. The team stores all of its funds in an USD bank account.
The Solana team plans to implement token inflation as mainnet goes live. All tokens from inflation will be distributed to token holders in the form of delegation and staking rewards.
The following chart represents the number and breakdown of all SOL tokens that are to be released into circulation on a monthly basis. The token schedule does not include token inflation.
|Planned Date||Milestone||Actual Date||Early / Late||Commentary|
|2018 Q1||Release of Whitepaper||2017 Q4||Early||Whitepaper|
|2018 Q1||Release of Single Node Private Testnet||2018 Q1||On Time||Github|
|2018 Q2||Release of Multi Node Private Testnet||2018 Q2||On Time||Github|
|2018 Q3||Release of Payments SDK||2018 Q3||On Time||Github|
|2018 Q3||Release of Smart Contracts SDK||2018 Q3||On Time||Github|
|2019 Q1||Release of On-Chain Programs||2019 Q1||On Time||Github|
|2019 Q2||Implementation of the Move Virtual Machine developed by Libra||2019 Q2||On Time||Github|
|2019 Q2||Release of Multi region, multi cloud testnet||2019 Q2||On Time||Github|
|2019 Q2||Release of Smart Contracts Engine||2019 Q2||On Time||Github|
|2019 Q3||Release of Incentivized Testnet||2019 Q4||Late||Github|
|2020 Q1||Release of Mainnet Beta||2020 Q1||On Time||Github|
|2020 Q3||Mainnet Launch||N/A||In Progress||N/A|
Break Solana Game
The Solana Website
Solana drives engagement across three core communities: end users, developers, and validators. Solana has a strong focus in core geographies across China, Russia, South Korea, Japan, and the United States. Solana continues to grow its presence in Asia as they rapidly expand their presence across Europe.
Solana's current global community strategies include:
Solana's current regional community strategies include:
Solana's future global community strategies include:
Solana's future local community strategies include:
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