Assessing the security implication of Bitcoin exchange ...
Assessing the security implication of Bitcoin exchange ...
What is Difficulty in Bitcoin?
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Wholeheartedly willing to get downvoted, but this RMT obsession has to stop.
This sub hasn't got a clue, I swear. Huge sweeping changes to the game mechanics are a terrible way to combat RMT. It's basically an admission that your anti-cheat doesn't work. Most MMOs suffer in some way from an RMT problem; WoW, Runescape, even Destiny 2 has RMT issues if you just look. Thing is, the anticheat in those games actually works worth a damn, so the entire playerbase doesn't have to suffer from endless tinkering with in-game systems. Before you hit me with 'it's a hardcore game, deal with it, it's supposed to be grindy', just stop. Just don't bother. I've heard it time and time again, and it's bullshit. You know it's bullshit just as well as I do. The changes BSG have been making recently to nerf all forms of progression only make the game 'more hardcore' for people who work full time and don't have the same amount of *time* as streamers who dedicate their entire life to this game. That's not 'hardcore'. The game's difficulty mechanically is 'hardcore' and always have been, and I love it. These changes, though, in my eyes, are just time-wasting for the sake thereof. Since when does the amount of time one has to invest in a game define how fucking hardcore it is? Would you describe WoW as more hardcore than Tarkov because of how long you have to play to progress? Or perhaps beating all three Witcher games back to back is 'hardcore' because it took a long time. Are ARMA or DCS inherently less hardcore than Tarkov because an operation can be completed in an afternoon? No, judging how hardcore a game is by the amount of time one has to invest in it is a joke. *No game* should give enormous *mechanical advantages* to those with more time on their hands. There's already an inherent skill advantage that comes from that amount of practice, designing the mechanics to also reward only those with that much time is a kick in the teeth to all the people who love this game but can't invest that level of time. And yeah, you can go ahead and say 'ummm actualllly it's a beta, so they can do what they like, stop whining', and yep. Yes, they can. You're correct. However, comma, that doesn't mean I have to pretend to like it. Yes, I did buy EoD and no, I don't regret it because of all the fun I've had til now. But suggesting people who don't like the current direction the game is going in aren't allowed to voice their opinion because the game's in beta is fucking ludicrous. What do you think the purpose of a playable beta is? Nikita is more than welcome to ignore all the people who don't like these new changes, but what gives people on this sub the right to tell me that I'm not entitled to an opinion on the product I've chosen to financially support. It's such a toxic, capital-G Gamer attitute to suggest that 'Tarkov is OUR game because we're willing to dump several full days a week into grinding for our Bitcoin farms. You should just go and play something else, this clearly isn't a game for you. Go play Call of Duty.' I shouldn't even have to express how utterly reductive and childish that is. Grow up. I'm getting HUGE red flags with the way this game is currently going, because it's all too similar to a game I used to love, The Culling. That game blew up on launch and a bunch of high profile streamers suggested changes to the game, and the devs went ahead and implemented all of them without so much as *thinking* about how they'd affect the average player. Look at where that game is now. Servers shut down, because the average player simply stopped having fun. I'm not saying BSG is even close to that bad, but this endless tinkering with mechanics for the nebulous, vague purpose of 'RMT' has to stop or I don't know if the 'little guys' are gonna stick around much longer. EDIT: I AM AWARE THAT RMT != CHEATING. But cheating is what makes RMT viable. RMTers need to keep items in supply, and to do that, they cheat. It's much more profitable. Ergo, if you stamp out cheaters, the RMT problem becomes significantly diminished. EDIT 2: u/ArxMessor makes a great point that Tarkov is an MMO and therfore should have some kind of grind. I agree. However, most MMOs use systems like weekly bounties etc to ensure even players with only maybe 10 hours a week to invest in the game can still keep up and compete. Tarkov currently rewards time investment *exponentially* which removes all possibility of catching up. EDIT 3: Yep, my DMs right now are very much confirming the things I said above about a certain subset of this community. Thanks, Gamers. EDIT 4: I get it, Destiny anti-cheat is ass. I made a mistake there, since I don't play Trials of Osiris. However, do you see Bungie making the win requirement for Trials 50 wins instead of 9 or whatever just to slow down the hackers? Of course not, because it hurts normal players more. Edit 5: My first gold! Thanks kind stranger.
Taproot, CoinJoins, and Cross-Input Signature Aggregation
It is a very common misconception that the upcoming Taproot upgrade helps CoinJoin. TLDR: The upcoming Taproot upgrade does not help equal-valued CoinJoin at all, though it potentially increases the privacy of other protocols, such as the Lightning Network, and escrow contract schemes. If you want to learn more, read on!
Let's start with equal-valued CoinJoins, the type JoinMarket and Wasabi use. What happens is that some number of participants agree on some common value all of them use. With JoinMarket the taker defines this value and pays the makers to agree to it, with Wasabi the server defines a value approximately 0.1 BTC. Then, each participant provides inputs that they unilaterally control, totaling equal or greater than the common value. Typically since each input is unilaterally controlled, each input just requires a singlesig. Each participant also provides up to two addresses they control: one of these will be paid with the common value, while the other will be used for any extra value in the inputs they provided (i.e. the change output). The participants then make a single transaction that spends all the provided inputs and pays out to the appropriate outputs. The inputs and outputs are shuffled in some secure manner. Then the unsigned transaction is distributed back to all participants. Finally, each participant checks that the transaction spends the inputs it provided (and more importantly does not spend any other coins it might own that it did not provide for this CoinJoin!) and that the transaction pays out to the appropriate address(es) it controls. Once they have validated the transaction, they ratify it by signing for each of the inputs it provided. Once every participant has provided signatures for all inputs it registered, the transaction is now completely signed and the CoinJoin transaction is now validly confirmable. CoinJoin is a very simple and direct privacy boost, it requires no SCRIPTs, needs only singlesig, etc.
Let's say we have two participants who have agreed on a common amount of 0.1 BTC. One provides a 0.105 coin as input, the other provides a 0.114 coin as input. This results in a CoinJoin with a 0.105 coin and a 0.114 coin as input, and outputs with 0.1, 0.005, 0.014, and 0.1 BTC. Now obviously the 0.005 output came from the 0.105 input, and the 0.014 output came from the 0.114 input. But the two 0.1 BTC outputs cannot be correlated with either input! There is no correlating information, since either output could have come from either input. That is how common CoinJoin implementations like Wasabi and JoinMarket gain privacy.
Unfortunately, large-scale CoinJoins like that made by Wasabi and JoinMarket are very obvious. All you have to do is look for a transactions where, say, more than 3 outputs are the same equal value, and the number of inputs is equal or larger than the number of equal-valued outputs. Thus, it is trivial to identify equal-valued CoinJoins made by Wasabi and JoinMarket. You can even trivially differentiate them: Wasabi equal-valued CoinJoins are going to have a hundred or more inputs, with outputs that are in units of approximately 0.1 BTC, while JoinMarket CoinJoins have equal-valued outputs of less than a dozen (between 4 to 6 usually) and with the common value varying wildly from as low as 0.001 BTC to as high as a dozen BTC or more. This has led to a number of anti-privacy exchanges to refuse to credit custodially-held accounts if the incoming deposit is within a few hops of an equal-valued CoinJoin, usually citing concerns about regulations. Crucially, the exchange continues to hold private keys for those "banned" deposits, and can still spend them, thus this is effectively a theft. If your exchange does this to you, you should report that exchange as stealing money from its customers. Not your keys not your coins. Thus, CoinJoins represent a privacy tradeoff:
It's very hard for everyone else to determine which output belongs to which input.
It's obvious to everyone else that the output was involved in a mixing operation.
Let's now briefly discuss that nice new shiny thing called Taproot. Taproot includes two components:
The use of Schnorr-based signature scheme, with multisignature support. Spending from a Schnorr pubkey is called a "keypath spend".
The ability to secretly commit to a set of scripts, one of which can be revealed later and its inputs provided correctly in order to spend the coin. Spending via a hidden script is called a "scriptpath spend".
This has some nice properties:
Direct multisignature support means all multisignature uses look the same. In current Bitcoin, a 2-of-2 "multisignature" is really a script which demands that two signatures be provided, from 2 different pre-specified public keys. To a cryptographer, the strict definition of multisignature is that this is a single signature that is cooperatively created by multiple parties.
A typical minimal "multisig" setup would be a 2-of-3, because that lets you lose one signing device while still being able to keep access to your money, and still providing an increase in security relative to a singlesig, since a 2-of-3 requires that potential thieves abscond with at least two signing devices. In current Bitcoin, a 2-of-3 is a SCRIPT containing 3 public keys, requiring that two signatures from those three public keys be provided.
But a Lightning Network channel has exactly two participants. Thus, it uses a 2-of-2, and is a SCRIPT containing 2 public keys, requiring that two signatures from those public keys be provided. If you look for 2-of-2 spends on the blockchain after Lightning became cool, the chances are very good that a random 2-of-2 spend is a Lightning Network channel being closed, because there are hardly ever any other uses of 2-of-2.
Just from there, you can easily differentiate the most common HODLer multisig of 2-of-3 (SCRIPT contains 3 pubkeys) from the Lightning channel 2-of-2 (SCRIPT contains 2 pubkeys).
Fortunately, with Taproot, 2-of-3 and 2-of-2 (and any arbitrary k-of-n) can look exactly the same, because Schnorr allows for the cryptographer's strict definition of "multisignature": a single signature cooperatively created by multiple parties.
Complex SCRIPTs, like HTLCs, can be hidden in a Taproot output.
For example, the output can have a keyspend branch that is a n-of-n of all participants, with hidden SCRIPTs that encode the conditions under which the output can be spent
The hidden SCRIPTs ensure that the protocol is followed. If one of the participants drops from the protocol, the rest can reveal the hidden SCRIPTs and follow their conditions.
If everyone follows the protocol correctly, and agrees to the result, they can all cooperatively sign with the keyspend n-of-n. They can just all agree on what the result of the SCRIPTs would be, and sign a transaction that performs that, without revealing any SCRIPTs. Since all of them agreed on the result, nobody should complain (if one of them believes the result is not correct, they can just refuse to sign and force everyone else to publish the SCRIPTs onchain).
If everyone agrees, they get privacy: none of the SCRIPTs they were following ever get published onchain, and it looks like every other multisignature spend.
Taproot DOES NOT HELP CoinJoin
So let's review! CoinJoin:
CoinJoin inputs are singlesig
There are no SCRIPTs involved in CoinJoin.
Improves multisig privacy.
Improves SCRIPT privacy.
There is absolutely no overlap. Taproot helps things that CoinJoin does not use. CoinJoin uses things that Taproot does not improve.
B-but They Said!!
A lot of early reporting on Taproot claimed that Taproot benefits CoinJoin. What they are confusing is that earlier drafts of Taproot included a feature called cross-input signature aggregation. In current Bitcoin, every input, to be spent, has to be signed individually. With cross-input signature aggregation, all inputs that support this feature are signed with a single signature that covers all those inputs. So for example if you would spend two inputs, current Bitcoin requires a signature for each input, but with cross-input signature aggregation you can sign both of them with a single signature. This works even if the inputs have different public keys: two inputs with cross-input signature aggregation effectively define a 2-of-2 public key, and you can only sign for that input if you know the private keys for both inputs, or if you are cooperatively signing with somebody who knows the private key of the other input. This helps CoinJoin costs. Since CoinJoins will have lots of inputs (each participant will provide at least one, and probably will provide more, and larger participant sets are better for more privacy in CoinJoin), if all of them enabled cross-input signature aggregation, such large CoinJoins can have only a single signature. This complicates the signing process for CoinJoins (the signers now have to sign cooperatively) but it can be well worth it for the reduced signature size and onchain cost. But note that the while cross-input signature aggregation improves the cost of CoinJoins, it does not improve the privacy! Equal-valued CoinJoins are still obvious and still readily bannable by privacy-hating exchanges. It does not improve the privacy of CoinJoin. Instead, see https://old.reddit.com/Bitcoin/comments/gqb3udesign_for_a_coinswap_implementation_fo
Why isn't cross-input signature aggregation in?
There's some fairly complex technical reasons why cross-input signature aggregation isn't in right now in the current Taproot proposal. The primary reason was to reduce the technical complexity of Taproot, in the hope that it would be easier to convince users to activate (while support for Taproot is quite high, developers have become wary of being hopeful that new proposals will ever activate, given the previous difficulties with SegWit). The main technical complexity here is that it interacts with future ways to extend Bitcoin. The rest of this writeup assumes you already know about how Bitcoin SCRIPT works. If you don't understand how Bitcoin SCRIPT works at the low-level, then the TLDR is that cross-input signature aggregation complicates how to extend Bitcoin in the future, so it was deferred to let the develoeprs think more about it. (this is how I understand it; perhaps pwuille or ajtowns can give a better summary.) In detail, Taproot also introduces OP_SUCCESS opcodes. If you know about the OP_NOP opcodes already defined in current Bitcoin, well, OP_SUCCESS is basically "OP_NOP done right". Now, OP_NOP is a do-nothing operation. It can be replaced in future versions of Bitcoin by having that operation check some condition, and then fail if the condition is not satisfied. For example, both OP_CHECKLOCKTIMEVERIFY and OP_CHECKSEQUENCEVERIFY were previously OP_NOP opcodes. Older nodes will see an OP_CHECKLOCKTIMEVERIFY and think it does nothing, but newer nodes will check if the nLockTime field has a correct specified value, and fail if the condition is not satisfied. Since most of the nodes on the network are using much newer versions of the node software, older nodes are protected from miners who try to misspend any OP_CHECKLOCKTIMEVERIFY/OP_CHECKSEQUENCEVERIFY, and those older nodes will still remain capable of synching with the rest of the network: a dedication to strict backward-compatibility necessary for a consensus system. Softforks basically mean that a script that passes in the latest version must also be passing in all older versions. A script cannot be passing in newer versions but failing in older versions, because that would kick older nodes off the network (i.e. it would be a hardfork). But OP_NOP is a very restricted way of adding opcodes. Opcodes that replace OP_NOP can only do one thing: check if some condition is true. They can't push new data on the stack, they can't pop items off the stack. For example, suppose instead of OP_CHECKLOCKTIMEVERIFY, we had added a OP_GETBLOCKHEIGHT opcode. This opcode would push the height of the blockchain on the stack. If this command replaced an older OP_NOP opcode, then a script like OP_GETBLOCKHEIGHT 650000 OP_EQUAL might pass in some future Bitcoin version, but older versions would see OP_NOP 650000 OP_EQUAL, which would fail because OP_EQUAL expects two items on the stack. So older versions will fail a SCRIPT that newer versions will pass, which is a hardfork and thus a backwards incompatibility. OP_SUCCESS is different. Instead, old nodes, when parsing the SCRIPT, will see OP_SUCCESS, and, without executing the body, will consider the SCRIPT as passing. So, the OP_GETBLOCKHEIGHT 650000 OP_EQUAL example will now work: a future version of Bitcoin might pass it, and existing nodes that don't understand OP_GETBLOCKHEIGHT will se OP_SUCCESS 650000 OP_EQUAL, and will not execute the SCRIPT at all, instead passing it immediately. So a SCRIPT that might pass in newer versions will pass for older versions, which keeps the back-compatibility consensus that a softfork needs. So how does OP_SUCCESS make things difficult for cross-input signatur aggregation? Well, one of the ways to ask for a signature to be verified is via the opcodes OP_CHECKSIGVERIFY. With cross-input signature aggregation, if a public key indicates it can be used for cross-input signature aggregation, instead of OP_CHECKSIGVERIFY actually requiring the signature on the stack, the stack will contain a dummy 0 value for the signature, and the public key is instead added to a "sum" public key (i.e. an n-of-n that is dynamically extended by one more pubkey for each OP_CHECKSIGVERIFY operation that executes) for the single signature that is verified later by the cross-input signature aggregation validation algorithm00. The important part here is that the OP_CHECKSIGVERIFY has to execute, in order to add its public key to the set of public keys to be checked in the single signature. But remember that an OP_SUCCESS prevents execution! As soon as the SCRIPT is parsed, if any opcode is OP_SUCCESS, that is considered as passing, without actually executing the SCRIPT, because the OP_SUCCESS could mean something completely different in newer versions and current versions should assume nothing about what it means. If the SCRIPT contains some OP_CHECKSIGVERIFY command in addition to an OP_SUCCESS, that command is not executed by current versions, and thus they cannot add any public keys given by OP_CHECKSIGVERIFY. Future versions also have to accept that: if they parsed an OP_SUCCESS command that has a new meaning in the future, and then execute an OP_CHECKSIGVERIFY in that SCRIPT, they cannot add the public key into the same "sum" public key that older nodes use, because older nodes cannot see them. This means that you might need more than one signature in the future, in the presence of an opcode that replaces some OP_SUCCESS. Thus, because of the complexity of making cross-input signature aggregation work compatibly with future extensions to the protocol, cross-input signature aggregation was deferred.
Aryacoin is a new cryptocurrency, which allows for decentralized, peer to peer transactions of electronic cash. It is like Bitcoin and Litecoin, but the trading of the coin occurs on sales platforms that have no restriction to use. Further, it was created with the goal of addressing the double spend issues of Bitcoin and does so using a timestamp server to verify transactions. It works by taking the hash of a block of items to be timestamped and widely publishing the hash. The timestamp proves that the data must have existed at the time in order to get the hash. Each timestamp then includes the previous timestamp in its hash, forming a chain. The Aryacoin team is continuously developing new use cases for the coin, including exchanges where users can exchange the coins without any fees or restrictions, and offline options where the coins can be bought and sold for cash. The coins can also be used on the company’s other platform, mrdigicoin.io. Along with the coin, there is a digital wallet that can be created and controlled by the user entirely, with no control being retained by the Aryacoin team.
The concept of Blockchain first came to fame in October 2008, as part of a proposal for Bitcoin, with the aim to create P2P money without banks. Bitcoin introduced a novel solution to the age-old human problem of trust. The underlying blockchain technology allows us to trust the outputs of the system without trusting any actor within it. People and institutions who do not know or trust each other, reside in different countries, are subject to different jurisdictions, and who have no legally binding agreements with each other, can now interact over the Internet without the need for trusted third parties like banks, Internet platforms, or other types of clearing institutions. When bitcoin was launched it was revolutionary allowing people to transfer money to anytime and anywhere with very low transaction fees . It was decentralized and their is no third party involved in the transaction , only the sender and receiver were involved. This paper provide a solution to the double-spending problem using a peer-to-peer distributed timestamp server to generate computational proof of the chronological order of transactions.The system is secure as long as honest nodes collectively control more CPU power than any cooperating group of attacker nodes. Bitcoin was made so that it would not be controlled or regulated but now exchanges and governments are regulating bitcoin and other cryptocurrencies at every step. Aryacoin was developed to overcome these restrictions on a free currency. Aryacoin is a new age cryptocurrency, which withholds the original principle on which the concept of cryptocurrency was established. Combining the best in blockchain technology since the time of its creation, Aryacoin strives to deliver the highest trading and mining standards for its community.
1.1 OVERVIEW ABOUT ARYACOIN
Aryacoin is a new age cryptocurrency, which withholds the original principle on which the concept of cryptocurrency was established. Combining the best in blockchain technology since the time of its creation, Aryacoin strives to deliver the highest trading and mining standards for its community. Aryacoin is a blockchain based project that allows users to access their wallet on the web and mobile browsers, using their login details. Aryacoin can be mined; it also can be exchanged by other digital currencies in several world-famous exchanges such as Hitbtc, CoinEx, P2pb2b, WhiteBit, Changelly and is also listed in reputable wallets such as Coinomi and Guarda. Aryacoin is a coin, which can be used by anyone looking to use cryptocurrency which allows them to keep their privacy even when buying/selling the coin along with while using the coin during transactions. Proof of work and cryptographic hashes allows transactions to verified. Stable Fee Per AYA is a unique feature of Aryacoin, so by increasing the amount or volume of the transaction, there is no change in the fee within the network, which means that the fee for sending an amount less than 1 AYA is equal to several hundred million AYA. Another unique feature of Aryacoin is the undetectability of transactions in Explorer, such as the DASH and Monero, of course, this operation is unique to Aryacoin. Using Aryacoin digital currency, like other currencies, international transactions can be done very quickly and there are no limitations in this area as the creators claim. Aryacoin aims to allow users to access the Aryacoin wallet via the web and mobile browsers using their login details. Aryacoin is a peer-to-peer electronic cash system that enables users to send and receive payments directly from one party to another, and allow them to transfer funds across borders with no restriction or third party involvement. The blockchain-based system embraces the digital signature, which prevents double spending and low transfer fees, which enables users to transfer huge amounts with very low fees. The proof-of-work consensus mechanism allows each transaction to be verified and confirmed, while anonymity enables users to use the coin anywhere at any time. According to the website of the operation, each wallet is divided into 2 or more AYA wallet addresses for each transaction, and depending on the volume of the transaction block, the origin, and destination of transactions in the network can not be traced and displayed to the public. In fact, each wallet in Aryacoin consists of a total of several wallets. The number of these wallets increases per transaction to increase both security and privacy. Aryacoin also uses the dPoW protocol. In the dPoW protocol, a second layer is added to the network to verify transactions, which makes “51% attack” impossible even with more than half of the network hash, and blocks whose Blockchain uses this second layer of security never run the risk of 51% attacks. AYA has been listed on a number of crypto exchanges, unlike other main cryptocurrencies, it cannot be directly purchased with fiats money. However, You can still easily buy this coin by first buying Bitcoin from any large exchanges and then transfer to the exchange that offers to trade this coin.
1.1.1 ARYACOIN HISTORY
Aryacoin (AYA) is a new cryptocurrency, which has been created by a group of Iranian developers, is an altcoin which allows for decentralised, peer to peer transactions of electronic cash without any fees whatsoever. Along with the coin, there is a digital wallet that can be created and managed by the user entirely, with no control being retained by the Aryacoin team. Aryacoin’s founder, Kiumars Parsa, has been a fan of alternative currencies and particularly Bitcoin. “We see people from all around the world using Blockchain technology and the great benefits that came with it and it then that I decided to solve this puzzle for find a way of bringing the last missing piece to the jigsaw. The idea for Aryacoin was born.” Parsa said. Parsa and his team of Iranian ex-pats not only persevered but expedited the project and just a year later, in the summer of 2019, the first version of Aryacoin was released. In 2020, Aryacoin is the first and only Iranian coin listed on CMC. Parsa goes on to state that it is now the strength of the community that has invested in the coin that will ultimately drive its success, alongside its robust technology and appealing 0% network fees. “We have thousands of voices behind Aryacoin. People for the people make this coin. It is a massive shout out for democracy. This had made us base the whole team strategy on the benefits for both our users and our traders.” “One key example is that the network fee on AYA Blockchain is 0%. Yes, absolutely nothing, which which differentiates us from other networks. What also differentiates us from other coins is that we have AYAPAY which is the first cryptocurrency Gateway in the world which does not save funds on third party storage with all funds being forwarded directly to any wallet address that the Gateway owner requests”. “So for the first time ever, and unlike other gateways, incoming funds will be saved on the users account with submitted withdrawal requests then made on the Gateway host website. In AYAPAY which has also been developed by the Aryacoin team, all funds without extra fees or extra costs will directly forwarded to users wallets. We have named this technology as CloudWithdrawal.” “We are continuously challenging ourselves as it is a crowded marketplace. We are striving to have a safer Blockchain against 51% attacks, faster confirmations speeds of transactions, cheaper network fee, growing the market by cooperation with Top tier Exchangers.”
1.1.2 ARYACOIN’S MAIN GOAL
Aryacoin’s main goal is to educate people and give them the freedom to use cryptocurrency in any way they want. Aryacoin empowers the users to transfer, pay, trade cryptocurrency from any country around the globe. Platforms that have been created by Aryacoin Team, as well as those that will go live in future, operate on the same principle and exclude absolutely no one.
1.1.3 PROBLEM ARYACOIN SEEKS TO SOLVE
Aryacoin aims to provide a long-term solution to the problem of double spending, which is still common in the crypto market. The developers of the system have created a peer-to-peer distributed timestamp server that generates computational proof of the transactions as they occur. Besides, the system remains secure provided honest nodes control more CPU power than any cooperating group of attacker nodes. While Bitcoin was designed not to be regulated or controlled, many exchanges and governments have put regulatory measures on the pioneer cryptocurrency at every step. Aryacoin aims to overcome these restrictions as a free digital currency.
1.1.4 BENEFITS OF USING ARYACOIN
Aryacoin solution offers the following benefits:
Real-time update: whether you’re going on a holiday or a business trip, no problem. You can access your coins all over the world.
Instant operations: Aryacoin makes it quite easy for you to use your digital wallet and perform various operations with it.
Safe and secure: all your data is stored encrypted and can only be decrypted with your private key, seed, or password.
Strong security: The system has no control over your wallet. You are 100% in charge of your wallet and funds.
1.1.5 ARYACOIN FEATURES
1. Anonymity The coin provides decent level of anonymity for all its users. The users can send their transactions to any of the public nodes to be broadcasted , the transaction sent to the nodes should be signed by the private key of the sender address . This allows the users to use the coin anywhere any time , sending transactions directly to the node allows users from any place and country . 2. Real Life Usage aryacoin’s team is continuously developing new and innovative ways to use the coins , they are currently developing exchanges where the users can exchange the coins without any fees and any restrictions . They also are currently developing other innovative technologies, which would allow users to spend our coins everywhere and anywhere. 3. Offline Exchanges They are also working with different offline vendors which would enable them to buy and sell the coins directly to our users on a fixed/variable price this would allow easy buy/sell directly using cash . This would allow the coins to be accessible to users without any restrictions which most of the online exchanges have, also increase the value and number of users along with new ways to spend the coin. This would increase anonymity level of the coin. In addition, introduce new users into the cryptomarket and technology. Creating a revolution, which educates people about crypto and introduce them to the crypto world, which introduces a completely new group of people into crypto and a move towards a Decentralized future! 4. Transactions When it comes to transactions, Aryacoin embraces a chain of digital signatures, where each owner simply transfers the coin to the next person by digitally signing a hash of the previous transaction and the public key of the next owner. The recipient can then verify the signatures to confirm the chain of ownership. Importantly, Aryacoin comes with a trusted central authority that checks every transaction for double spending. 5. Business Partner with Simplex Aryacoin is the first and only Iranian digital currency that managed to obtain a trading license in other countries. In collaboration with the foundation and financial giant Simplex, a major cryptocurrency company that has large companies such as Binance, P2P, Changelly, etc. Aryacoin has been licensed to enter the world’s major exchanges, as well as the possibility of purchasing AYA through Credit Cards, which will begin in the second half of 2020. Also, the possibility of purchasing Aryacoin through Visa and MasterCard credit cards will be activated simultaneously inside the Aryacoin site. plus, in less than a year, AYA will be placed next to big names such as CoinCapMarket, Coinomi, P2P, Coinpayments and many other world-class brands today.
1.1.6 WHY CHOOSE ARYACOIN?
If you want to use a cryptocurrency that allows you to keep your privacy online even when buying and selling the coins, the Aryacoin team claims that AYA is the way to go. Aryacoin is putting in the work: with more ways to buy and sell, and fixing the issues that were present in the original Bitcoin, plus pushing the boundaries with innovative solutions in cryptocurrencies. You can get started using Aryacoin (AYA) payments simply by having a CoinPayments account!
1.1.7 ARYANA CENTRALIZED EXCHANGE
Aryana, the first Iranian exchange is a unique platform with the following features:
The first real international Persian exchange that obtains international licenses and is listed in CoinMarketCap.
The first Iranian exchange that has been cooperating with a legal and European exchange for 3 years.
The possibility of trading in Tomans (available currency in Iran) at the user’s desired price and getting rid of the transaction prices imposed by domestic sites inside Iran.
There is an internal fee payment plan by Iranian domestic banks for depositing and withdrawing Tomans for Aryacoin holders in Aryana Exchange.
The number that you see on the monitor and in your account will be equal to the number that is transferred to your bank account without a difference of one Rial.
The last but not least, noting the fact that there is a trading in Tomans possibility in Aryana exchange.
Aryana Exchange is using the most powerful, fastest, and most expensive server in the world, Google Cloud Platform (GCP), which is currently the highest quality server for an Iranian site, so that professional traders do not lag behind the market even for a second. The feature of Smart Trading Robots is one of the most powerful features for digital currency traders. Digital cryptocurrency traders are well aware of how much they will benefit from smart trading robots. In the Aryana exchange, it is possible to connect exchange user accounts to intelligent trading bots and trade even when they are offline. The injection of $ 1 million a day in liquidity by the WhiteBite exchange to maintain and support the price of Tether and eliminate the Tether fluctuations with Bitcoin instabilities used by profiteers to become a matter of course.
1.1.8 HOW DOES ARYACOIN WORK?
Aryacoin (AYA) tries to ensure a high level of security and privacy. The team has made sure to eliminate any trading restrictions for the network users: no verification is required to carry out transactions on AYA, making the project truly anonymous, decentralized, and giving it a real use in day-to-day life. The Delayed-Proof-of-Work (dPoW) algorithm makes the Aryacoin blockchain immune to any attempts of a 51% attack. AYA defines a coin as a chain of digital signatures — each owner transfers the coin to the next owner by digitally signing the hash of the previous transaction and the public key of the next owner, and the receiver verifies the signatures and the chain of ownership.
2. ARYACOIN TECHNOLOGY
They use a proof-of-work system similar to Adam Back’s Hashcash to implement a distributed timestamp server on a peer-to-peer basis, rather than newspaper or Usenet publications. The proof-of-work involves scanning for a value that when hashed, such as with SHA-256, the hash begins with a number of zero bits. The average work required is exponential in the number of zero bits required and can be verified by executing a single hash. For their timestamp network, they implement the proof-of-work by incrementing a nonce in the block until a value is found that gives the block’s hash the required zero bits. Once the CPU effort has been expended to make it satisfy the proof-of-work, the block cannot be changed without redoing the work. As later blocks are chained after it, the work to change the block would include redoing all the blocks after it. The proof-of-work also solves the problem of determining representation in majority decision making. If the majority were based on one-IP-address-one-vote, it could be subverted by anyone able to allocate many IPs. Proof-of-work is essentially one-CPU-one-vote. The majority decision is represented by the longest chain, which has the greatest proof-of-work effort invested in it. If honest nodes control a majority of CPU power, the honest chain will grow the fastest and outpace any competing chains. To modify a past block, an attacker would have to redo the proof-of-work of the block and all blocks after it, then catch up with, and surpass the work of the honest nodes.
The steps to run the network are as follows:
New transactions are broadcast to all nodes.
Each node collects new transactions into a block.
Each node works on finding a difficult proof-of-work for its block.
When a node finds a proof-of-work, it broadcasts the block to all nodes.
Nodes accept the block only if all transactions in it are valid and not already spent.
This is a very simple system that makes the network fast and scalable, while also providing a decent level of anonymity for all users. Users can send their transactions to any of the public nodes to be broadcast, and the private key of the sender’s address should sign any transaction sent to the nodes. This way, all transaction info remains strictly confidential. It also allows users to send transactions directly to the node from any place at any time and allows the transferring of huge amounts with very low fees.
2.3 AYAPAY PAYMENT SERVICES GATEWAY:
According to creators Aryacoin, the development team has succeeded in inventing a new blockchain technology for the first time in the world, which is undoubtedly a big step and great news for all digital currency enthusiasts around the world. This new technology has been implemented on the Aryacoin AYAPAY platform and was unveiled on October 2. AYAPAY payment platform is the only payment gateway in the world that does not save money in users’ accounts and transfers incoming coins directly to any wallet address requested by the gateway owner without any additional transaction or fee. In other similar systems or even systems such as PayPal, money is stored in the user account.
2.4 CONSENSUS ALGORITHM IN ARYACOIN
The devs introduced the Delayed-Proof-of-Work (dPoW) algorithm, which represents a hybrid consensus method that allows one blockchain to take advantage of the security provided by the hashing power of another blockchain. The AYA blockchain works on dPoW and can use such consensus methods as Proof-of-Work (PoW) or Proof-of-Stake (PoS) and join to any desired PoW blockchain. The main purpose of this is to allow the blockchain to continue operating without notary nodes on the basis of its original consensus method. In this situation, additional security will no longer be provided through the attached blockchain, but this is not a particularly significant problem. dPoW can improve the security level and reduce energy consumption for any blockchain.
2.5 DOUBLE-SPEND PROBLEM AND SOLUTION
One of the main problems in the blockchain world is that a receiver is unable to verify whether or not one of the senders did not double-spend. Aryacoin provides the solution, and has established a trusted central authority, or mint, that checks every transaction for double-spending. Only the mint can issue a new coin and all the coins issued directly from the mint are trusted and cannot be double-spent. However, such a system cannot therefore be fully decentralized because it depends on the company running the mint, similar to a bank. Aryacoin implements a scheme where the receiver knows that the previous owners did not sign any earlier transactions. The mint is aware of all transactions including which of them arrived first. The developers used an interesting solution called the Timestamp Server, which works by taking a hash of a block of items to be ‘timestamped’ and publishing the hash. Each timestamp includes the previous timestamp in its hash, forming a chain. To modify a block, an attacker would have to redo the proof-of-work of all previous blocks, then catch up with, and surpass the work of the honest nodes. This is almost impossible, and makes the network processes more secure. The proof-of-work difficulty varies according to circumstances. Such an approach ensures reliability and high throughput.
3. ARYACOIN ROADMAP
April 2019: The launch of Aryacoin; AYA ICO, resulting in over 30BTC collected December 2019: The launch of AYA Pay April 2020: The successful Hamedan Hardfork, supported by all AYA exchanges, aimed at integrating the dPoW algorithm, improving the security of the AYA blockchain. June 2020: Aryana Exchange goes live, opening more trading opportunities globally July 2020: The enabling of our Coin Exchanger November 2020: The implementation of Smart Contracts into the Aryacoin Ecosystem Q1 2021: Alef B goes live (more details coming soon)
Aryacoin (AYA) is a new age cryptocurrency that combines the best of the blockchain technology and strives to deliver high trading and mining standards, enabling users to make peer-to-peer decentralized transactions of electronic cash. Aryacoin is part of an ecosystem that includes payment gateway Ayapay and the Ayabank. AYA has a partnership with the Microsoft Azure cloud platform, which provides the ability to develop applications and store data on servers located in distributed data centers. The network fee for the AYA Blockchain is 0%. In Ayapay service, which has been developed by the Aryacoin team, all funds without extra fees or costs are directly forwarded to users’ wallets with technology called CloudWithdrawal. The devs team is introducing new use cases including exchanges where users will exchange AYA without any restrictions. You can buy AYA on an exchange of your choice, create an Aryacoin wallet, and store it in Guarda.
Hey all, I've been researching coins since 2017 and have gone through 100s of them in the last 3 years. I got introduced to blockchain via Bitcoin of course, analyzed Ethereum thereafter and from that moment I have a keen interest in smart contact platforms. I’m passionate about Ethereum but I find Zilliqa to have a better risk-reward ratio. Especially because Zilliqa has found an elegant balance between being secure, decentralized and scalable in my opinion.
Below I post my analysis of why from all the coins I went through I’m most bullish on Zilliqa (yes I went through Tezos, EOS, NEO, VeChain, Harmony, Algorand, Cardano etc.). Note that this is not investment advice and although it's a thorough analysis there is obviously some bias involved. Looking forward to what you all think!
Fun fact: the name Zilliqa is a play on ‘silica’ silicon dioxide which means “Silicon for the high-throughput consensus computer.”
This post is divided into (i) Technology, (ii) Business & Partnerships, and (iii) Marketing & Community. I’ve tried to make the technology part readable for a broad audience. If you’ve ever tried understanding the inner workings of Bitcoin and Ethereum you should be able to grasp most parts. Otherwise, just skim through and once you are zoning out head to the next part.
Technology and some more:
The technology is one of the main reasons why I’m so bullish on Zilliqa. First thing you see on their website is: “Zilliqa is a high-performance, high-security blockchain platform for enterprises and next-generation applications.” These are some bold statements.
Before we deep dive into the technology let’s take a step back in time first as they have quite the history. The initial research paper from which Zilliqa originated dates back to August 2016: Elastico: A Secure Sharding Protocol For Open Blockchains where Loi Luu (Kyber Network) is one of the co-authors. Other ideas that led to the development of what Zilliqa has become today are: Bitcoin-NG, collective signing CoSi, ByzCoin and Omniledger.
The technical white paper was made public in August 2017 and since then they have achieved everything stated in the white paper and also created their own open source intermediate level smart contract language called Scilla (functional programming language similar to OCaml) too.
Mainnet is live since the end of January 2019 with daily transaction rates growing continuously. About a week ago mainnet reached 5 million transactions, 500.000+ addresses in total along with 2400 nodes keeping the network decentralized and secure. Circulating supply is nearing 11 billion and currently only mining rewards are left. The maximum supply is 21 billion with annual inflation being 7.13% currently and will only decrease with time.
Zilliqa realized early on that the usage of public cryptocurrencies and smart contracts were increasing but decentralized, secure, and scalable alternatives were lacking in the crypto space. They proposed to apply sharding onto a public smart contract blockchain where the transaction rate increases almost linear with the increase in the amount of nodes. More nodes = higher transaction throughput and increased decentralization. Sharding comes in many forms and Zilliqa uses network-, transaction- and computational sharding. Network sharding opens up the possibility of using transaction- and computational sharding on top. Zilliqa does not use state sharding for now. We’ll come back to this later.
Before we continue dissecting how Zilliqa achieves such from a technological standpoint it’s good to keep in mind that a blockchain being decentralised and secure and scalable is still one of the main hurdles in allowing widespread usage of decentralised networks. In my opinion this needs to be solved first before blockchains can get to the point where they can create and add large scale value. So I invite you to read the next section to grasp the underlying fundamentals. Because after all these premises need to be true otherwise there isn’t a fundamental case to be bullish on Zilliqa, right?
Down the rabbit hole
How have they achieved this? Let’s define the basics first: key players on Zilliqa are the users and the miners. A user is anybody who uses the blockchain to transfer funds or run smart contracts. Miners are the (shard) nodes in the network who run the consensus protocol and get rewarded for their service in Zillings (ZIL). The mining network is divided into several smaller networks called shards, which is also referred to as ‘network sharding’. Miners subsequently are randomly assigned to a shard by another set of miners called DS (Directory Service) nodes. The regular shards process transactions and the outputs of these shards are eventually combined by the DS shard as they reach consensus on the final state. More on how these DS shards reach consensus (via pBFT) will be explained later on.
The Zilliqa network produces two types of blocks: DS blocks and Tx blocks. One DS Block consists of 100 Tx Blocks. And as previously mentioned there are two types of nodes concerned with reaching consensus: shard nodes and DS nodes. Becoming a shard node or DS node is being defined by the result of a PoW cycle (Ethash) at the beginning of the DS Block. All candidate mining nodes compete with each other and run the PoW (Proof-of-Work) cycle for 60 seconds and the submissions achieving the highest difficulty will be allowed on the network. And to put it in perspective: the average difficulty for one DS node is ~ 2 Th/s equaling 2.000.000 Mh/s or 55 thousand+ GeForce GTX 1070 / 8 GB GPUs at 35.4 Mh/s. Each DS Block 10 new DS nodes are allowed. And a shard node needs to provide around 8.53 GH/s currently (around 240 GTX 1070s). Dual mining ETH/ETC and ZIL is possible and can be done via mining software such as Phoenix and Claymore. There are pools and if you have large amounts of hashing power (Ethash) available you could mine solo.
The PoW cycle of 60 seconds is a peak performance and acts as an entry ticket to the network. The entry ticket is called a sybil resistance mechanism and makes it incredibly hard for adversaries to spawn lots of identities and manipulate the network with these identities. And after every 100 Tx Blocks which corresponds to roughly 1,5 hour this PoW process repeats. In between these 1,5 hour, no PoW needs to be done meaning Zilliqa’s energy consumption to keep the network secure is low. For more detailed information on how mining works click here. Okay, hats off to you. You have made it this far. Before we go any deeper down the rabbit hole we first must understand why Zilliqa goes through all of the above technicalities and understand a bit more what a blockchain on a more fundamental level is. Because the core of Zilliqa’s consensus protocol relies on the usage of pBFT (practical Byzantine Fault Tolerance) we need to know more about state machines and their function. Navigate to Viewblock, a Zilliqa block explorer, and just come back to this article. We will use this site to navigate through a few concepts.
We have established that Zilliqa is a public and distributed blockchain. Meaning that everyone with an internet connection can send ZILs, trigger smart contracts, etc. and there is no central authority who fully controls the network. Zilliqa and other public and distributed blockchains (like Bitcoin and Ethereum) can also be defined as state machines.
Taking the liberty of paraphrasing examples and definitions given by Samuel Brooks’ medium article, he describes the definition of a blockchain (like Zilliqa) as: “A peer-to-peer, append-only datastore that uses consensus to synchronize cryptographically-secure data”.
Next, he states that: "blockchains are fundamentally systems for managing valid state transitions”. For some more context, I recommend reading the whole medium article to get a better grasp of the definitions and understanding of state machines. Nevertheless, let’s try to simplify and compile it into a single paragraph. Take traffic lights as an example: all its states (red, amber, and green) are predefined, all possible outcomes are known and it doesn’t matter if you encounter the traffic light today or tomorrow. It will still behave the same. Managing the states of a traffic light can be done by triggering a sensor on the road or pushing a button resulting in one traffic lights’ state going from green to red (via amber) and another light from red to green.
With public blockchains like Zilliqa, this isn’t so straightforward and simple. It started with block #1 almost 1,5 years ago and every 45 seconds or so a new block linked to the previous block is being added. Resulting in a chain of blocks with transactions in it that everyone can verify from block #1 to the current #647.000+ block. The state is ever changing and the states it can find itself in are infinite. And while the traffic light might work together in tandem with various other traffic lights, it’s rather insignificant comparing it to a public blockchain. Because Zilliqa consists of 2400 nodes who need to work together to achieve consensus on what the latest valid state is while some of these nodes may have latency or broadcast issues, drop offline or are deliberately trying to attack the network, etc.
Now go back to the Viewblock page take a look at the amount of transaction, addresses, block and DS height and then hit refresh. Obviously as expected you see new incremented values on one or all parameters. And how did the Zilliqa blockchain manage to transition from a previous valid state to the latest valid state? By using pBFT to reach consensus on the latest valid state.
After having obtained the entry ticket, miners execute pBFT to reach consensus on the ever-changing state of the blockchain. pBFT requires a series of network communication between nodes, and as such there is no GPU involved (but CPU). Resulting in the total energy consumed to keep the blockchain secure, decentralized and scalable being low.
pBFT stands for practical Byzantine Fault Tolerance and is an optimization on the Byzantine Fault Tolerant algorithm. To quote Blockonomi: “In the context of distributed systems, Byzantine Fault Tolerance is the ability of a distributed computer network to function as desired and correctly reach a sufficient consensus despite malicious components (nodes) of the system failing or propagating incorrect information to other peers.” Zilliqa is such a distributed computer network and depends on the honesty of the nodes (shard and DS) to reach consensus and to continuously update the state with the latest block. If pBFT is a new term for you I can highly recommend the Blockonomi article.
The idea of pBFT was introduced in 1999 - one of the authors even won a Turing award for it - and it is well researched and applied in various blockchains and distributed systems nowadays. If you want more advanced information than the Blockonomi link provides click here. And if you’re in between Blockonomi and the University of Singapore read the Zilliqa Design Story Part 2 dating from October 2017. Quoting from the Zilliqa tech whitepaper: “pBFT relies upon a correct leader (which is randomly selected) to begin each phase and proceed when the sufficient majority exists. In case the leader is byzantine it can stall the entire consensus protocol. To address this challenge, pBFT offers a view change protocol to replace the byzantine leader with another one.”
pBFT can tolerate ⅓ of the nodes being dishonest (offline counts as Byzantine = dishonest) and the consensus protocol will function without stalling or hiccups. Once there are more than ⅓ of dishonest nodes but no more than ⅔ the network will be stalled and a view change will be triggered to elect a new DS leader. Only when more than ⅔ of the nodes are dishonest (66%) double-spend attacks become possible.
If the network stalls no transactions can be processed and one has to wait until a new honest leader has been elected. When the mainnet was just launched and in its early phases, view changes happened regularly. As of today the last stalling of the network - and view change being triggered - was at the end of October 2019.
Another benefit of using pBFT for consensus besides low energy is the immediate finality it provides. Once your transaction is included in a block and the block is added to the chain it’s done. Lastly, take a look at this article where three types of finality are being defined: probabilistic, absolute and economic finality. Zilliqa falls under the absolute finality (just like Tendermint for example). Although lengthy already we skipped through some of the inner workings from Zilliqa’s consensus: read the Zilliqa Design Story Part 3 and you will be close to having a complete picture on it. Enough about PoW, sybil resistance mechanism, pBFT, etc. Another thing we haven’t looked at yet is the amount of decentralization.
Currently, there are four shards, each one of them consisting of 600 nodes. 1 shard with 600 so-called DS nodes (Directory Service - they need to achieve a higher difficulty than shard nodes) and 1800 shard nodes of which 250 are shard guards (centralized nodes controlled by the team). The amount of shard guards has been steadily declining from 1200 in January 2019 to 250 as of May 2020. On the Viewblock statistics, you can see that many of the nodes are being located in the US but those are only the (CPU parts of the) shard nodes who perform pBFT. There is no data from where the PoW sources are coming. And when the Zilliqa blockchain starts reaching its transaction capacity limit, a network upgrade needs to be executed to lift the current cap of maximum 2400 nodes to allow more nodes and formation of more shards which will allow to network to keep on scaling according to demand. Besides shard nodes there are also seed nodes. The main role of seed nodes is to serve as direct access points (for end-users and clients) to the core Zilliqa network that validates transactions. Seed nodes consolidate transaction requests and forward these to the lookup nodes (another type of nodes) for distribution to the shards in the network. Seed nodes also maintain the entire transaction history and the global state of the blockchain which is needed to provide services such as block explorers. Seed nodes in the Zilliqa network are comparable to Infura on Ethereum.
The seed nodes were first only operated by Zilliqa themselves, exchanges and Viewblock. Operators of seed nodes like exchanges had no incentive to open them for the greater public. They were centralised at first. Decentralisation at the seed nodes level has been steadily rolled out since March 2020 ( Zilliqa Improvement Proposal 3 ). Currently the amount of seed nodes is being increased, they are public-facing and at the same time PoS is applied to incentivize seed node operators and make it possible for ZIL holders to stake and earn passive yields. Important distinction: seed nodes are not involved with consensus! That is still PoW as entry ticket and pBFT for the actual consensus.
5% of the block rewards are being assigned to seed nodes (from the beginning in 2019) and those are being used to pay out ZIL stakers. The 5% block rewards with an annual yield of 10.03% translate to roughly 610 MM ZILs in total that can be staked. Exchanges use the custodial variant of staking and wallets like Moonlet will use the non-custodial version (starting in Q3 2020). Staking is being done by sending ZILs to a smart contract created by Zilliqa and audited by Quantstamp.
With a high amount of DS; shard nodes and seed nodes becoming more decentralized too, Zilliqa qualifies for the label of decentralized in my opinion.
Generalized: programming languages can be divided into being ‘object-oriented’ or ‘functional’. Here is an ELI5 given by software development academy: * “all programs have two basic components, data – what the program knows – and behavior – what the program can do with that data. So object-oriented programming states that combining data and related behaviors in one place, is called “object”, which makes it easier to understand how a particular program works. On the other hand, functional programming argues that data and behavior are different things and should be separated to ensure their clarity.” *
Scilla is on the functional side and shares similarities with OCaml: OCaml is a general-purpose programming language with an emphasis on expressiveness and safety. It has an advanced type system that helps catch your mistakes without getting in your way. It's used in environments where a single mistake can cost millions and speed matters, is supported by an active community, and has a rich set of libraries and development tools. For all its power, OCaml is also pretty simple, which is one reason it's often used as a teaching language.
Scilla is blockchain agnostic, can be implemented onto other blockchains as well, is recognized by academics and won a so-called Distinguished Artifact Award award at the end of last year.
One of the reasons why the Zilliqa team decided to create their own programming language focused on preventing smart contract vulnerabilities is that adding logic on a blockchain, programming, means that you cannot afford to make mistakes. Otherwise, it could cost you. It’s all great and fun blockchains being immutable but updating your code because you found a bug isn’t the same as with a regular web application for example. And with smart contracts, it inherently involves cryptocurrencies in some form thus value.
Another difference with programming languages on a blockchain is gas. Every transaction you do on a smart contract platform like Zilliqa or Ethereum costs gas. With gas you basically pay for computational costs. Sending a ZIL from address A to address B costs 0.001 ZIL currently. Smart contracts are more complex, often involve various functions and require more gas (if gas is a new concept click here ).
So with Scilla, similar to Solidity, you need to make sure that “every function in your smart contract will run as expected without hitting gas limits. An improper resource analysis may lead to situations where funds may get stuck simply because a part of the smart contract code cannot be executed due to gas limits. Such constraints are not present in traditional software systems”.Scilla design story part 1
Some examples of smart contract issues you’d want to avoid are: leaking funds, ‘unexpected changes to critical state variables’ (example: someone other than you setting his or her address as the owner of the smart contract after creation) or simply killing a contract.
Scilla also allows for formal verification. Wikipedia to the rescue: In the context of hardware and software systems, formal verification is the act of proving or disproving the correctness of intended algorithms underlying a system with respect to a certain formal specification or property, using formal methods of mathematics.
Formal verification can be helpful in proving the correctness of systems such as: cryptographic protocols, combinational circuits, digital circuits with internal memory, and software expressed as source code.
“Scilla is being developed hand-in-hand with formalization of its semantics and its embedding into the Coq proof assistant — a state-of-the art tool for mechanized proofs about properties of programs.”
Simply put, with Scilla and accompanying tooling developers can be mathematically sure and proof that the smart contract they’ve written does what he or she intends it to do.
Smart contract on a sharded environment and state sharding
There is one more topic I’d like to touch on: smart contract execution in a sharded environment (and what is the effect of state sharding). This is a complex topic. I’m not able to explain it any easier than what is posted here. But I will try to compress the post into something easy to digest.
Earlier on we have established that Zilliqa can process transactions in parallel due to network sharding. This is where the linear scalability comes from. We can define simple transactions: a transaction from address A to B (Category 1), a transaction where a user interacts with one smart contract (Category 2) and the most complex ones where triggering a transaction results in multiple smart contracts being involved (Category 3). The shards are able to process transactions on their own without interference of the other shards. With Category 1 transactions that is doable, with Category 2 transactions sometimes if that address is in the same shard as the smart contract but with Category 3 you definitely need communication between the shards. Solving that requires to make a set of communication rules the protocol needs to follow in order to process all transactions in a generalised fashion.
There is no strict defined roadmap but here are topics being worked on. And via the Zilliqa website there is also more information on the projects they are working on.
Business & Partnerships
It’s not only technology in which Zilliqa seems to be excelling as their ecosystem has been expanding and starting to grow rapidly. The project is on a mission to provide OpenFinance (OpFi) to the world and Singapore is the right place to be due to its progressive regulations and futuristic thinking. Singapore has taken a proactive approach towards cryptocurrencies by introducing the Payment Services Act 2019 (PS Act). Among other things, the PS Act will regulate intermediaries dealing with certain cryptocurrencies, with a particular focus on consumer protection and anti-money laundering. It will also provide a stable regulatory licensing and operating framework for cryptocurrency entities, effectively covering all crypto businesses and exchanges based in Singapore. According to PWC 82% of the surveyed executives in Singapore reported blockchain initiatives underway and 13% of them have already brought the initiatives live to the market. There is also an increasing list of organizations that are starting to provide digital payment services. Moreover, Singaporean blockchain developers Building Cities Beyond has recently created an innovation $15 million grant to encourage development on its ecosystem. This all suggests that Singapore tries to position itself as (one of) the leading blockchain hubs in the world.
Zilliqa seems to already take advantage of this and recently helped launch Hg Exchange on their platform, together with financial institutions PhillipCapital, PrimePartners and Fundnel. Hg Exchange, which is now approved by the Monetary Authority of Singapore (MAS), uses smart contracts to represent digital assets. Through Hg Exchange financial institutions worldwide can use Zilliqa's safe-by-design smart contracts to enable the trading of private equities. For example, think of companies such as Grab, Airbnb, SpaceX that are not available for public trading right now. Hg Exchange will allow investors to buy shares of private companies & unicorns and capture their value before an IPO. Anquan, the main company behind Zilliqa, has also recently announced that they became a partner and shareholder in TEN31 Bank, which is a fully regulated bank allowing for tokenization of assets and is aiming to bridge the gap between conventional banking and the blockchain world. If STOs, the tokenization of assets, and equity trading will continue to increase, then Zilliqa’s public blockchain would be the ideal candidate due to its strategic positioning, partnerships, regulatory compliance and the technology that is being built on top of it.
What is also very encouraging is their focus on banking the un(der)banked. They are launching a stablecoin basket starting with XSGD. As many of you know, stablecoins are currently mostly used for trading. However, Zilliqa is actively trying to broaden the use case of stablecoins. I recommend everybody to read this text that Amrit Kumar wrote (one of the co-founders). These stablecoins will be integrated in the traditional markets and bridge the gap between the crypto world and the traditional world. This could potentially revolutionize and legitimise the crypto space if retailers and companies will for example start to use stablecoins for payments or remittances, instead of it solely being used for trading.
Zilliqa also released their DeFi strategic roadmap (dating November 2019) which seems to be aligning well with their OpFi strategy. A non-custodial DEX is coming to Zilliqa made by Switcheo which allows cross-chain trading (atomic swaps) between ETH, EOS and ZIL based tokens. They also signed a Memorandum of Understanding for a (soon to be announced) USD stablecoin. And as Zilliqa is all about regulations and being compliant, I’m speculating on it to be a regulated USD stablecoin. Furthermore, XSGD is already created and visible on block explorer and XIDR (Indonesian Stablecoin) is also coming soon via StraitsX. Here also an overview of the Tech Stack for Financial Applications from September 2019. Further quoting Amrit Kumar on this:
There are two basic building blocks in DeFi/OpFi though: 1) stablecoins as you need a non-volatile currency to get access to this market and 2) a dex to be able to trade all these financial assets. The rest are built on top of these blocks.
So far, together with our partners and community, we have worked on developing these building blocks with XSGD as a stablecoin. We are working on bringing a USD-backed stablecoin as well. We will soon have a decentralised exchange developed by Switcheo. And with HGX going live, we are also venturing into the tokenization space. More to come in the future.”
Additionally, they also have this ZILHive initiative that injects capital into projects. There have been already 6 waves of various teams working on infrastructure, innovation and research, and they are not from ASEAN or Singapore only but global: see Grantees breakdown by country. Over 60 project teams from over 20 countries have contributed to Zilliqa's ecosystem. This includes individuals and teams developing wallets, explorers, developer toolkits, smart contract testing frameworks, dapps, etc. As some of you may know, Unstoppable Domains (UD) blew up when they launched on Zilliqa. UD aims to replace cryptocurrency addresses with a human-readable name and allows for uncensorable websites. Zilliqa will probably be the only one able to handle all these transactions onchain due to ability to scale and its resulting low fees which is why the UD team launched this on Zilliqa in the first place. Furthermore, Zilliqa also has a strong emphasis on security, compliance, and privacy, which is why they partnered with companies like Elliptic, ChainSecurity (part of PwC Switzerland), and Incognito. Their sister company Aqilliz (Zilliqa spelled backwards) focuses on revolutionizing the digital advertising space and is doing interesting things like using Zilliqa to track outdoor digital ads with companies like Foodpanda.
Zilliqa is listed on nearly all major exchanges, having several different fiat-gateways and recently have been added to Binance’s margin trading and futures trading with really good volume. They also have a very impressive team with good credentials and experience. They don't just have “tech people”. They have a mix of tech people, business people, marketeers, scientists, and more. Naturally, it's good to have a mix of people with different skill sets if you work in the crypto space.
Marketing & Community
Zilliqa has a very strong community. If you just follow their Twitter their engagement is much higher for a coin that has approximately 80k followers. They also have been ‘coin of the day’ by LunarCrush many times. LunarCrush tracks real-time cryptocurrency value and social data. According to their data, it seems Zilliqa has a more fundamental and deeper understanding of marketing and community engagement than almost all other coins. While almost all coins have been a bit frozen in the last months, Zilliqa seems to be on its own bull run. It was somewhere in the 100s a few months ago and is currently ranked #46 on CoinGecko. Their official Telegram also has over 20k people and is very active, and their community channel which is over 7k now is more active and larger than many other official channels. Their local communities also seem to be growing.
Moreover, their community started ‘Zillacracy’ together with the Zilliqa core team ( see www.zillacracy.com ). It’s a community-run initiative where people from all over the world are now helping with marketing and development on Zilliqa. Since its launch in February 2020 they have been doing a lot and will also run their own non-custodial seed node for staking. This seed node will also allow them to start generating revenue for them to become a self sustaining entity that could potentially scale up to become a decentralized company working in parallel with the Zilliqa core team. Comparing it to all the other smart contract platforms (e.g. Cardano, EOS, Tezos etc.) they don't seem to have started a similar initiative (correct me if I’m wrong though). This suggests in my opinion that these other smart contract platforms do not fully understand how to utilize the ‘power of the community’. This is something you cannot ‘buy with money’ and gives many projects in the space a disadvantage.
Zilliqa also released two social products called SocialPay and Zeeves. SocialPay allows users to earn ZILs while tweeting with a specific hashtag. They have recently used it in partnership with the Singapore Red Cross for a marketing campaign after their initial pilot program. It seems like a very valuable social product with a good use case. I can see a lot of traditional companies entering the space through this product, which they seem to suggest will happen. Tokenizing hashtags with smart contracts to get network effect is a very smart and innovative idea.
Regarding Zeeves, this is a tipping bot for Telegram. They already have 1000s of signups and they plan to keep upgrading it for more and more people to use it (e.g. they recently have added a quiz features). They also use it during AMAs to reward people in real-time. It’s a very smart approach to grow their communities and get familiar with ZIL. I can see this becoming very big on Telegram. This tool suggests, again, that the Zilliqa team has a deeper understanding of what the crypto space and community needs and is good at finding the right innovative tools to grow and scale.
To be honest, I haven’t covered everything (i’m also reaching the character limited haha). So many updates happening lately that it's hard to keep up, such as the International Monetary Fund mentioning Zilliqa in their report, custodial and non-custodial Staking, Binance Margin, Futures, Widget, entering the Indian market, and more. The Head of Marketing Colin Miles has also released this as an overview of what is coming next. And last but not least, Vitalik Buterin has been mentioning Zilliqa lately acknowledging Zilliqa and mentioning that both projects have a lot of room to grow. There is much more info of course and a good part of it has been served to you on a silver platter. I invite you to continue researching by yourself :-) And if you have any comments or questions please post here!
A classic Direct Faucet to earn your Dogecoins online without difficulty. We could define this Faucet as the "different sister" site of BitsFree. Structurally almost identical in all respects with the exception of the reference crypto: the DogeCoin. Also recently built, it shows a main screen that consists of 2 menus, one at the top and one on the side, all always well organized. To register and start earning online immediately, enter a personal Dogecoin address also registered on FaucetPay. Earning Online Dogecoin Let's now proceed with the list of components of the central menu: EARN BITS, in turn divided as follows: - Faucet, which takes you back to the dashboard, is the classic claim that can be made every 60 minutes. The awarded Bits prize will depend on the Lucky Number obtained. A couple of pop-up pages might open. - Shortlinks, divided in turn into 2 submenus. Visit Shortlinks, whose links lead to advertising pages where one or more Captchas must be resolved. Some pop-up pages will surely open. Shortlinks Contest shows the weekly ranking of users who have solved the highest number of Shortlinks. - PTC Ads, also this section now inevitable in faucet sites allows you to get a cryptocurrency reward by viewing advertising pages. It is not mandatory to keep the mouse on the page as it will be sufficient to let the required time pass. - Achievements, objectives to be achieved linked to a high use of the aforementioned earning methods. - Redeem coupon, if you have a code to use as a coupon that is occasionally sent by email. - Referrals, where your referrals URL will be shown. When we write, with the basic registration, you will get 5% on all claims, 5% on Offerwalls and 5% on Shortlinks from your subscribers. The percentages will increase by subscribing to a higher Membership subscription. There are some banners and pre-filled html codes to insert on your sites or blogs. The second part of the menu with the other gain modes OFFERS, includes the usual surveys, video viewing and the most varied tasks. The reward obtained in Dogecoin is very high but not always proportionate to the time spent since the surveys have a very low percentage of reliability. CONTESTS, which will reward users with the highest number of subscribers or with the largest amount of Shortlinks performed each month with additional Dogecoins. LOTTERY, the inevitable lottery inside the site. BLOG, the section with the latest news on DogeBits. MORE, consisting of the following items: - Withdrawals History and Deposits History, shows the last 25 transfers to your external wallets and all the deposits made on the site. - Account setting, where you can enter the Dogecoin address to which to transfer your earnings and change your registration email and password. - Membership, by signing up for a paid subscription you can level up within the site, obtaining in exchange an increase in prizes and services. And finally the side menu. The menu on the left contains many links to the sections previously described. From top to bottom you can change your account details, exit the site (Logout) or make the transfer (Withdraw). Just below is the Dogecoin equivalent of the Bits you have accumulated on the site. This is followed by the Advertise section which offers the possibility to advertise your site via links and banners by relying on the advertising circuit offered by DogeBitsFree. This is a paid service and using the Deposit button you can send the funds you want to dedicate to it. Even further below, your referral URL. In the lower part of the dashboard, the left part is dedicated to all the information on the Bits earned while the right part allows, thanks to the Share button, to share your referral URL on major social networks. The transfer of accumulated Dogecoins (Withdraw) can be made on the personal wallet or the FaucetPay account. The minimum threshold is 100 Dogecoin for the wallet and 20 Dogecoin for FaucetPay. See you soon for a new interesting article! If you liked this article and would like to contribute with a donation: Bitcoin: 1Ld9b165ZYHZcY9eUQmL9UjwzcphRE5S8Z Ethereum: 0x8D7E456A11f4D9bB9e6683A5ac52e7DB79DBbEE7 Litecoin: LamSRc1jmwgx5xwDgzZNoXYd6ENczUZViK Stellar: GBLDIRIQWRZCN5IXPIKYFQOE46OG2SI7AFVWFSLAHK52MVYDGVJ6IXGI Ripple: rUb8v4wbGWYrtXzUpj7TxCFfUWgfvym9xf By: cryptoall.it Telegram Channel: t.me/giulo75 Netbox Browser: https://netbox.global/PZn5A
As a sequel to the first paper of Blockchain & Law article series titled 'A New Digital Order - Unveiling the Interplay of Law & Blockchain Technology', this paper explores the inter-operability of India's data privacy regime and blockchain technology. In this regard, recording of a webinar conducted on 'Blockchain & Data Privacy: An India Perspective' by the AKS Partners can be viewed on YouTube here.
B. Data privacy in India
Constitution of India
Article 21 of the Indian Constitution is a comprehensive, all-encompassing provision that inheres within itself basic, fundamental rights that are absolutely essential to the existence of a human being with dignity and personal liberty. In the judgment of K.S. Puttaswamy v. Union of India,1 a nine-judge bench of the Honourable Supreme Court of India held that the right to privacy falls within the contours of Article 21 and is incidental to life and personal liberty. This right to privacy includes the right to data protection and privacy.
Information Technology Act, 2000
In India, data privacy is governed by the Information Technology Act, 2000 ("IT Act") and the Information Technology (Reasonable security practices and procedures and sensitive personal data or information) Rules, 2011 ("SPDI Rules"). Sections 43A (Compensation for failure to protect data) of the IT Act provides a statutory right to a data provider to claim compensation for unapproved disclosure of information (including in breach of a contract). Under Section 72A (Punishment for disclosure of information in breach of lawful contract) of the IT Act, wherever any person including an intermediary discloses information obtained under a lawful contract without consent shall be punished with imprisonment or with fine or both.
The SPDI Rules constitute a set of basic obligations to be adhered to in circumstances where sensitive data is being collected. It may be noted that the SPDI Rules apply only to 'Sensitive Personal Data or Information'.2 The SPDI Rules lay down guidelines for collection (Rule 5) and transfer of information (Rule 7) and also mandatorily require body corporates to adopt and implement a policy for privacy and disclosure of information (Rule 4). On 24 August 2011, the Ministry of Electronics and Information Technology issued a clarification to the SPDI Rules ("Regulatory Clarification"). The Regulatory Clarification states that the SPDI Rules are applicable only to body corporates or persons located within India. Also, where a body corporate deals in data of any legal entity located within or outside India under a contractual arrangement, the SPDI Rules pertaining to collection (Rule 5) and disclosure of information (Rule 6) would not apply. It was also clarified that requirement to obtain written consent under Rule 5(1) of the SPDI Rules includes electronic consent as well.
The Personal Data Protection Bill, 2019 ("Bill")
The Bill is inspired from and is in many ways a replica of the European Union's General Data Protection Regulations ("GDPR"). The Bill lays down several provisions including in relation to crossborder transfer of data, sandboxing, privacy by design and introduces a more robust set of obligations for entities handling sensitive personal data. The Bill is currently pending before a Joint Parliamentary Committee. The Bill applies to and categorises data into 'Personal Data', 'Sensitive Personal Data' and 'Critical Personal Data'.
Regulated sectors such as telecom and financial services have separate obligations of confidentiality which restricts disclosure and transfer of customer personal information and mandates use of such information only in the manner agreed with the customer. Certain sectoral regulators (like Reserve Bank of India) also mandate data localisation.
C. Blockchain technology and data privacy
For details on the working of a blockchain network, please refer to our previous paper here. Coverage The Bill defines 'Personal Data') as 'data about or relating to a natural person who is directly or indirectly identifiable'. This means where the origins of the data cannot be traced down to a natural person, the data would cease to be 'Personal Data'. Resultantly, storing the data in a manner where it cannot be traced to a natural person (including by introducing and implementing robust methods to address re-identification risks) may prove beneficial in reducing a blockchain network's interaction with data privacy regulations (such as by encryption or anonymisation of Personal Data). Public v. Private Blockchain Private blockchain which restricts and regulates network participation appears to be a more preferable fit when it comes to ensuring compliance with data privacy laws. Public blockchains with permissionless borders pose greater difficulty in procuring every participant to agree on and comply with relevant rules on protection of personal data. Stakeholders The Bill identifies three categories of stakeholders (similar to GDPR) viz. Data Principals, Data Fiduciary and Data Processor. The SPDI Rules only provides for data provider and body corporate or person collecting data. The term 'Processing' has been defined to include collection, storage, retrieval, adaptation, disclosure etc. (Section 3(31)). Accordingly, any data stored or transmitted on blockchain will amount to processing. Blockchain network is a decentralised system with each node / miner (i.e. network participant) spread all over the world. There is no clear demarcation between a Data Principal and a Data Fiduciary or a Data Processor over a blockchain network. The way the network functions, no single person can be said to be in-charge of the network thereby making it all the more problematic for regulators to fix the compliance burden on a party. Accordingly, the question of determining the identity status and fixing liability of various participants attains significance and complexity over a distributed ledger network like blockchain. Each node over the network functions as a Data Processor on account of participation in the verification of the data. At the same time one or more of such nodes may also be acting as a Data Principal. With respect to mining over the network while it is a single miner who is able to formulate a valid hash, all the other miners also participate in the mining activity when they attempt to arrive at the winning lottery number. Thus making such miner also a Data Processor. While fixing liability on a private blockchain network that restricts the number of network participants is comparatively less complex, the same would be quite challenging on a public blockchain network, such as Bitcoin. With regard to identifying the status and roles, the guidance issued by French data protection authority ("CNIL Guidance")3 in the context of GDPR is useful. The CNIL Guidance categorises blockchain actors into the following groups: (a) participants with full read and write access to the data; (b) participants with read only access; and (c) miners that validate the transactions. Participants falling in category (a) above are Data Controllers (equivalent to a Data Fiduciary under the Bill) while categories (b) and (c) are not. Collection and processing of data over a blockchain network The Bill sets out a number of obligations that have to be performed by the Data Fiduciaries, some key compliances being, obtaining consent of the data principals, retaining the data only till absolutely necessary (Storage Limitation), providing notice to the Data Principals, ensuring data is used only for the purpose (which has to be specific, clear and lawful) for which it has been taken (Purpose Limitation). Rule 5 of the SPDI Rules also lays down similar obligations for collection of data. Key concerns that the inherent and intrinsic nature of the blockchain technology raises are as under: Firstly, with respect to the Storage Limitation principle, the immutable nature of the technology prevents the data from being deleted once the purpose has been fulfilled. Secondly, given the decentralised nature of blockchain, it becomes challenging to determine the exact purpose for which data is collected over such a widespread network and who is to keep a check that the data so collected is used only for such predefined purposes. Thirdly, it is commonly argued that the network participants over a blockchain impliedly consent while sharing their data. This may not however fulfil the requirements under the Bill which requires consent to be clear, through an affirmative action. This gives birth to concomitant regulatory issues over a decentralised system as to who shall oblige with these compliances under the law and who should be made responsible / liable for any lapses in compliance. Lastly, the Bill also proposes certain additional requirements such as transparent and fair processing and the Purpose Limitation. The blurred distinction in the status of identities in blockchain makes determining purpose and manner of processing challenging. A detailed governance framework setting out roles and responsibilities, off-chain and on-chain personal data, may provide useful guidance towards addressing the aforementioned concerns. Key rights of Data Principals
Right to Confirmation and Access
The Bill entitles the Data Principals to seek information regarding the types and nature of personal data stored with the Data Fiduciaries, or to ascertain the nature of processing activities that has been undertaken on his/her data, or seek a brief summary of processing activities undertaken. While enforcement of this right may not be technically difficult, however, blockchain networks may establish a proper governance framework that delineates a specific authority to pass over the requisite data to the data principal as and when asked for. The network may also consider laying out methods of searching and accessing the necessary information which may be de-encrypted with the use of the private key.
Right to Correction
Section 18 of the Bill and Rule 5 of the SPDI Rules provides the right to rectify or correct the data. Given the immutable nature of the decentralised ledger maintained on a blockchain, exercising this right may not be compatible. To accomplish alteration/correction of data would be a burdensome task since it will require a majority of nodes to come together to identify the data, alter and re-hash not just the concerned block but also all previous blocks as well. Alternatively, a new block with corrected information may be added once verified through the consensus mechanism.
Right to be Forgotten
The Bill introduces 'Right to be Forgotten' ("RTF"). RTF entitles data principals to request the removal of his/her personal data, without undue delay, from any business's storage. RTF has been in loggerheads with the inherent immutability of blockchain technology. Across jurisdictions the term 'forgotten' has been pegged with erasure and is construed in various senses in different jurisdictions, ranging from data anonymisation,4 destruction of hardware,5 putting data beyond use.6 Given the distinction within the types of blockchain, the modes for exercising RTF are uniform by and large. A widely discussed solution is the destruction of the private key, thereby rendering the data encrypted by a public key inaccessible.7 Owing to the setup of blockchain, a Data Principal may reach out to any entity in the chain that qualifies as a Data Fiduciary to enforce their rights. Similar to the Google-Spain case,8 wherein data subject's action against Google remained unaffected by the fact that the data could have been removed by the newspaper's website itself.9 However, the nature of a public blockchain network that does not identify a central authority might prove somewhat problematic where the data principal seeks to enforce his/her right. As countries are yet to formulate policies with respect to regulation of blockchains, some other alternatives for exercising RTF can be programming chameleon hashes, zero knowledge proofs or a censorable blockchain, as the same would be 'forgetful'.10 Cross-Border Transfer of Data Chapter VII of the Bill, which deals with restrictions on cross-border transfer of data, requires a copy of the Sensitive Personal Data to be stored domestically while Critical Personal Data must exclusively be processed and stored in India. However, these clear demarcations blur when applied to a blockchain ecosystem where storage and processing of data can be universal. Transfer of Sensitive Personal Data, requires explicit consent and the transfer must be under a contract or an intra-group scheme approved by the data protection authority (envisaged to be established under the Bill). While both of these requirements may get fulfilled over a private blockchain easily, a public blockchain due to undefined groups and lack of a central entity / authority may find it more challenging to implement adequate safeguards on restricting such transfer. Over a private blockchain the central body may enter into e-contracts with any number of participants and also obtain their explicit consent. Under the present regime, Rule 7 of the SPDI Rules provides that a transfer outside India may only be allowed where the country offers the same level of protection to the data. Again, enforcing this may be challenging over a public blockchain network comprising of thousands of nodes across borders. An in-built cross-border transfer consent clause in the governance framework or otherwise may also provide the needed legitimacy from the perspective of data privacy.
D. Jurisdictional Issues
The present uncertainty in law (including lack of adequate legal provisions) has resulted in jurisdictional issues concerning the domestic and transnational presence of the blockchain network. While Section 1(2) read with Section 75 of the IT Act accords limited extra-territorial applicability to the Act, the SPDI Rules, as mentioned in the Regulatory Clarification are applicable only to body corporates or persons located in India. Consequently, blockchain technology may need to comply with the IT Act to a certain extent, while, the mandate under the SPDI Rules will bind only the nodes/miners operating from India. As a result, the network participants operating outside India on the same blockchain will not be required to comply with the SPDI Rules or IT Act. Section 2 of the Bill affords extra-territorial application but only in certain limited circumstances viz. where the processing which takes place outside India is in connection with any business in India, or which involves the profiling of individuals within India. This will result in a subjective assessment of blockchains and its purposes in order to ascertain the applicability of the provisions of the Bill. The Civil-Commercial Courts in India, have applied the test as to whether a website is an 'interactive website'11 for determination of jurisdiction, in relation to websites that do not have a physical place of business in a jurisdiction.12 In other words, wherever a website facilitates or even intends to facilitate active trade / commercial transactions in jurisdictions where it does not have a physical place of business, in such cases cause of action, if any, arises in all such jurisdictions where the website operates interactively. However, applying such a test on a blockchain network may not be so straightforward. The intrinsic nature of the blockchain technology allows for processing and storage of data at multiple domestic and international jurisdictions simultaneously. Resultantly, in both domestic as well as international, identification of the place of cause of action becomes complex. The complexity increases as identification of the individuals processing and storing data (nodes) would require de-anonymisation. The determination of applicable laws will also depend on the nature of a blockchain network. It is practically more difficult to regulate a public blockchain network than a private blockchain network. In a private blockchain the architect/controlling entity may determine the governing laws or the governance framework may provide for a governing law. In light of the foregoing, it may come as a mammoth task for governments to enforce their respective data protection and cyber-security legislations against such transnational networks without consensus on a multi-national treaty suggesting a model law to regulate the use of blockchain networks. In the alternative, laws may promote self-regulation by merely identifying basic tenets of regulations like governing law, data privacy, certification etc. Non-compliance may include compulsory suspension/termination of participation rights of nodes or blocking access to blockchains which do not provide for adequate self-regulation. The developers of blockchain networks may consider incorporating dispute resolution and regulatory mechanisms as integral parts of the networks. The developers may also consider coding networks with peer-to-peer decentralized courts such as 'kleros' or 'codelegit' as part of a network's dispute resolution process.
E. Way forward
Blockchain technology carries the potential of disrupting business operations right from supply, manufacturing, logistics and final consumption especially in a post Covid-19 era. Please refer to our previous article on use cases of blockchain here. Accordingly, it is crucial that data privacy laws (with adequate concessions, where necessary) be treated as an enabler and not inhibitor to continued adoption of blockchain technology. Certain additional rights like data portability and right to withdraw consent adds to the complexity of having a compliant blockchain network. Certain obligations like mandatory registration may also be problematic if the government notifies certain blockchain network as a significant data fiduciaries. Set out below are few indicative measures towards harmonious application of data privacy laws and blockchain technology: 1) Every blockchain network must provide a detailed governance framework that is in alignment with the basic requirements under data privacy regulations. Such a framework would have to be binding on all participants over a blockchain network, stating all rights, obligations and duties of parties, including a detailed mechanism for communication, security measures, cross-border data transfer, and grievance redressal and may even set out applicable laws etc. 2) Such a self-governance framework could also include a privacy by design policy and provisions for Data Protection Impact Assessment (as set out in Chapter VI of the Bill). 3) 'Pruning' is used for situations where historical blocks of data beyond a certain timeline are deleted. Similarly, where data has to be altered or rectified, the same may be done by 'forking' where data is altered or deleted, the hash changed and a new fork is created. However, over a public blockchain Pruning and Forking can be challenging and may require a huge amount of computing consensus. 4) To ensure the safeguarding of right to privacy a Memory Optimized and Flexible Blockchain (MOF-BC) can be considered as an effective measure. It enables the IoT (Internet of Things) users and service providers to edit their transactions, thereby altering the details of data entry.13
Author: Gamals Ahmed, CoinEx Business Ambassador ABSTRACT The DFINITY blockchain computer provides a secure, performant and flexible consensus mechanism. At its core, DFINITY contains a decentralized randomness beacon, which acts as a verifiable random function (VRF) that produces a stream of outputs over time. The novel technique behind the beacon relies on the existence of a unique-deterministic, non-interactive, DKG-friendly threshold signatures scheme. The only known examples of such a scheme are pairing-based and derived from BLS. The DFINITY blockchain is layered on top of the DFINITY beacon and uses the beacon as its source of randomness for leader selection and leader ranking. A “weight” is attributed to a chain based on the ranks of the leaders who propose the blocks in the chain, and that weight is used to select between competing chains. The DFINITY blockchain is layered on top of the DFINITY beacon and uses the beacon as its source of randomness for leader selection and leader ranking blockchain is further hardened by a notarization process which dramatically improves the time to finality and eliminates the nothing-at-stake and selfish mining attacks. DFINITY consensus algorithm is made to scale through continuous quorum selections driven by the random beacon. In practice, DFINITY achieves block times of a few seconds and transaction finality after only two confirmations. The system gracefully handles temporary losses of network synchrony including network splits, while it is provably secure under synchrony.
DFINITY is building a new kind of public decentralized cloud computing resource. The company’s platform uses blockchain technology which is aimed at building a new kind of public decentralized cloud computing resource with unlimited capacity, performance and algorithmic governance shared by the world, with the capability to power autonomous self-updating software systems, enabling organizations to design and deploy custom-tailored cloud computing projects, thereby reducing enterprise IT system costs by 90%. DFINITY aims to explore new territory and prove that the blockchain opportunity is far broader and deeper than anyone has hitherto realized, unlocking the opportunity with powerful new crypto. Although a standalone project, DFINITY is not maximalist minded and is a great supporter of Ethereum. The DFINITY blockchain computer provides a secure, performant and flexible consensus mechanism. At its core, DFINITY contains a decentralized randomness beacon, which acts as a verifiable random function (VRF) that produces a stream of outputs over time. The novel technique behind the beacon relies on the existence of a unique-deterministic, non-interactive, DKG-friendly threshold signatures scheme. The only known examples of such a scheme are pairing-based and derived from BLS. DFINITY’s consensus mechanism has four layers: notary (provides fast finality guarantees to clients and external observers), blockchain (builds a blockchain from validated transactions via the Probabilistic Slot Protocol driven by the random beacon), random beacon (provides the source of randomness for all higher layers like smart contract applications), and identity (provides a registry of all clients). DFINITY’s consensus mechanism has four layers Figure1: DFINITY’s consensus mechanism layers 1. Identity layer: Active participants in the DFINITY Network are called clients. Where clients are registered with permanent identities under a pseudonym. Moreover, DFINITY supports open membership by providing a protocol for registering new clients by depositing a stake with an insurance period. This is the responsibility of the first layer. 2. Random Beacon layer: Provides the source of randomness (VRF) for all higher layers including ap- plications (smart contracts). The random beacon in the second layer is an unbiasable, verifiable random function (VRF) that is produced jointly by registered clients. Each random output of the VRF is unpredictable by anyone until just before it becomes avail- able to everyone. This is a key technology of the DFINITY system, which relies on a threshold signature scheme with the properties of uniqueness and non-interactivity. https://preview.redd.it/hkcf53ic05e51.jpg?width=441&format=pjpg&auto=webp&s=44d45c9602ee630705ce92902b8a8379201d8111 3. Blockchain layer: The third layer deploys the “probabilistic slot protocol” (PSP). This protocol ranks the clients for each height of the chain, in an order that is derived determin- istically from the unbiased output of the random beacon for that height. A weight is then assigned to block proposals based on the proposer’s rank such that blocks from clients at the top of the list receive a higher weight. Forks are resolved by giving favor to the “heaviest” chain in terms of accumulated block weight — quite sim- ilar to how traditional proof-of-work consensus is based on the highest accumulated amount of work. The first advantage of the PSP protocol is that the ranking is available instantaneously, which allows for a predictable, constant block time. The second advantage is that there is always a single highest-ranked client, which allows for a homogenous network bandwidth utilization. Instead, a race between clients would favor a usage in bursts. 4. Notarization layer: Provides fast finality guarantees to clients and external observers. DFINITY deploys the novel technique of block notarization in its fourth layer to speed up finality. A notarization is a threshold signature under a block created jointly by registered clients. Only notarized blocks can be included in a chain. Of all RSA-based alternatives exist but suffer from an impracticality of setting up the thresh- old keys without a trusted dealer. DFINITY achieves its high speed and short block times exactly because notarization is not full consensus. DFINITY does not suffer from selfish mining attack or a problem nothing at stake because the authentication step is impossible for the opponent to build and maintain a series of linked and trusted blocks in secret. DFINITY’s consensus is designed to operate on a network of millions of clients. To en- able scalability to this extent, the random beacon and notarization protocols are designed such as that they can be safely and efficiently delegated to a committee
1.1 OVERVIEW ABOUT DFINITY
DFINITY is a blockchain-based cloud-computing project that aims to develop an open, public network, referred to as the “internet computer,” to host the next generation of software and data. and it is a decentralized and non-proprietary network to run the next generation of mega-applications. It dubbed this public network “Cloud 3.0”. DFINITY is a third generation virtual blockchain network that sets out to function as an “intelligent decentralised cloud,”¹ strongly focused on delivering a viable corporate cloud solution. The DFINITY project is overseen, supported and promoted by DFINITY Stiftung a not-for-profit foundation based in Zug, Switzerland. DFINITY is a decentralized network design whose protocols generate a reliable “virtual blockchain computer” running on top of a peer-to-peer network upon which software can be installed and can operate in the tamperproof mode of smart contracts. DFINITY introduces algorithmic governance in the form of a “Blockchain Nervous System” that can protect users from attacks and help restart broken systems, dynamically optimize network security and efficiency, upgrade the protocol and mitigate misuse of the platform, for example by those wishing to run illegal or immoral systems. DFINITY is an Ethereum-compatible smart contract platform that is implementing some revolutionary ideas to address blockchain performance, scaling, and governance. Whereas DFINITY could pose a credible threat to Ethereum’s extinction, the project is pursuing a coevolutionary strategy by contributing funding and effort to Ethereum projects and freely offering their technology to Ethereum for adoption. DFINITY has labeled itself Ethereum’s “crazy sister” to express it’s close genetic resemblance to Ethereum, differentiated by its obsession with performance and neuron-inspired governance model. Dfinity raised $61 million from Andreesen Horowitz and Polychain Capital in a February 2018 funding round. At the time, Dfinity said it wanted to create an “internet computer” to cut the costs of running cloud-based business applications. A further $102 million funding round in August 2018 brought the project’s total funding to $195 million. In May 2018, Dfinity announced plans to distribute around $35 million worth of Dfinity tokens in an airdrop. It was part of the company’s plan to create a “Cloud 3.0.” Because of regulatory concerns, none of the tokens went to US residents. DFINITY be broadening and strengthening the EVM ecosystem by giving applications a choice of platforms with different characteristics. However, if DFINITY succeeds in delivering a fully EVM-compatible smart contract platform with higher transaction throughput, faster confirmation times, and governance mechanisms that can resolve public disputes without causing community splits, then it will represent a clearly superior choice for deploying new applications and, as its network effects grow, an attractive place to bring existing ones. Of course the challenge for DFINITY will be to deliver on these promises while meeting the security demands of a public chain with significant value at risk.
1.1.1 DFINITY FUTURE
DFINITY aims to explore new blockchain territory related to the original goals of the Ethereum project and is sometimes considered “Ethereum’s crazy sister.”
DFINITY is developing blockchain-based infrastructure to support a new style of the internet (akin to Ethereum’s “World Computer”), one in which the internet itself will support software applications and data rather than various cloud hosting providers.
The project suggests this reinvented software platform can simplify the development of new software systems, reduce the human capital needed to maintain and secure data, and preserve user data privacy.
Dfinity aims to reduce the costs of cloud services by creating a decentralized “internet computer” which may launch in 2020
Dfinity claims transactions on its network are finalized in 3–5 seconds, compared to 1 hour for Bitcoin and 10 minutes for Ethereum.
1.1.2 DFINITY’S VISION
DFINITY’s vision is its new internet infrastructure can support a wide variety of end-user and enterprise applications. Social media, messaging, search, storage, and peer-to-peer Internet interactions are all examples of functionalities that DFINITY plans to host atop its public Web 3.0 cloud-like computing resource. In order to provide the transaction and data capacity necessary to support this ambitious vision, DFINITY features a unique consensus model (dubbed Threshold Relay) and algorithmic governance via its Blockchain Nervous System (BNS) — sometimes also referred to as the Network Nervous System or NNS.
February 15, 2017 Ethereum based community seed round raises 4M Swiss francs (CHF) The DFINITY Stiftung, a not-for-profit foundation entity based in Zug, Switzerland, raised the round. The foundation held $10M of assets as of April 2017. February 8, 2018 Dfinity announces a $61M fundraising round led by Polychain Capital and Andreessen Horowitz The round $61M round led by Polychain Capital and Andreessen Horowitz, along with an DFINITY Ecosystem Venture Fund which will be used to support projects developing on the DFINITY platform, and an Ethereum based raise in 2017 brings the total funding for the project over $100 million. This is the first cryptocurrency token that Andressen Horowitz has invested in, led by Chris Dixon. August 2018 Dfinity raises a $102,000,000 venture round from Multicoin Capital, Village Global, Aspect Ventures, Andreessen Horowitz, Polychain Capital, Scalar Capital, Amino Capital and SV Angel. January 23, 2020 Dfinity launches an open source platform aimed at the social networking giants
Dfinity is building what it calls the internet computer, a decentralized technology spread across a network of independent data centers that allows software to run anywhere on the internet rather than in server farms that are increasingly controlled by large firms, such as Amazon Web Services or Google Cloud. This week Dfinity is releasing its software to third-party developers, who it hopes will start making the internet computer’s killer apps. It is planning a public release later this year. At its core, the DFINITY consensus mechanism is a variation of the Proof of Stake (PoS) model, but offers an alternative to traditional Proof of Work (PoW) and delegated PoS (dPoS) networks. Threshold Relay intends to strike a balance between inefficiencies of decentralized PoW blockchains (generally characterized by slow block times) and the less robust game theory involved in vote delegation (as seen in dPoS blockchains). In DFINITY, a committee of “miners” is randomly selected to add a new block to the chain. An individual miner’s probability of being elected to the committee proposing and computing the next block (or blocks) is proportional to the number of dfinities the miner has staked on the network. Further, a “weight” is attributed to a DFINITY chain based on the ranks of the miners who propose blocks in the chain, and that weight is used to choose between competing chains (i.e. resolve chain forks). A decentralized random beacon manages the random selection process of temporary block producers. This beacon is a Variable Random Function (VRF), which is a pseudo-random function that provides publicly verifiable proofs of its outputs’ correctness. A core component of the random beacon is the use of Boneh-Lynn-Shacham (BLS) signatures. By leveraging the BLS signature scheme, the DFINITY protocol ensures no actor in the network can determine the outcome of the next random assignment. Dfinity is introducing a new standard, which it calls the internet computer protocol (ICP). These new rules let developers move software around the internet as well as data. All software needs computers to run on, but with ICP the computers could be anywhere. Instead of running on a dedicated server in Google Cloud, for example, the software would have no fixed physical address, moving between servers owned by independent data centers around the world. “Conceptually, it’s kind of running everywhere,” says Dfinity engineering manager Stanley Jones. DFINITY also features a native programming language, called ActorScript (name may be subject to change), and a virtual machine for smart contract creation and execution. The new smart contract language is intended to simplify the management of application state for programmers via an orthogonal persistence environment (which means active programs are not required to retrieve or save their state). All ActorScript contracts are eventually compiled down to WebAssembly instructions so the DFINITY virtual machine layer can execute the logic of applications running on the network. The advantage of using the WebAssembly standard is that all major browsers support it and a variety of programming languages can compile down to Wasm (not just ActorScript). Dfinity is moving fast. Recently, Dfinity showed off a TikTok clone called CanCan. In January it demoed a LinkedIn-alike called LinkedUp. Neither app is being made public, but they make a convincing case that apps made for the internet computer can rival the real things.
2.1 DFINITY CORE APPLICATIONS
The DFINITY cloud has two core applications:
Enabling the re-engineering of business: DFINITY ambitiously aims to facilitate the re-engineering of mass-market services (such as Web Search, Ridesharing Services, Messaging Services, Social Media, Supply Chain, etc) into open source businesses that leverage autonomous software and decentralised governance systems to operate and update themselves more efficiently.
Enable the re-engineering of enterprise IT systems to reduce costs: DFINITY seeks to re-engineer enterprise IT systems to take advantage of the unique properties that blockchain computer networks provide.
At present, computation on blockchain-based computer networks is far more expensive than traditional, centralised solutions (Amazon Web Services, Microsoft Azure, Google Cloud Platform, etc). Despite increasing computational cost, DFINITY intends to lower net costs “by 90% or more” through reducing the human capital cost associated with sustaining and supporting these services. Whilst conceptually similar to Ethereum, DFINITY employs original and new cryptography methods and protocols (crypto:3) at the network level, in concert with AI and network-fuelled systemic governance (Blockchain Nervous System — BNS) to facilitate Corporate adoption. DFINITY recognises that different users value different properties and sees itself as more of a fully compatible extension of the Ethereum ecosystem rather than a competitor of the Ethereum network. In the future, DFINITY hopes that much of their “new crypto might be used within the Ethereum network and are also working hard on shared technology components.” As the DFINITY project develops over time, the DFINITY Stiftung foundation intends to steadily increase the BNS’ decision-making responsibilities over time, eventually resulting in the dissolution of its own involvement entirely, once the BNS is sufficiently sophisticated. DFINITY consensus mechanism is a heavily optimized proof of stake (PoS) model. It places a strong emphasis on transaction finality through implementing a Threshold Relay technique in conjunction with the BLS signature scheme and a notarization method to address many of the problems associated with PoS consensus.
2.2 THRESHOLD RELAY
As a public cloud computing resource, DFINITY targets business applications by substantially reducing cloud computing costs for IT systems. They aim to achieve this with a highly scalable and powerful network with potentially unlimited capacity. The DFINITY platform is chalk full of innovative designs and features like their Blockchain Nervous System (BNS) for algorithmic governance. One of the primary components of the platform is its novel Threshold Relay Consensus model from which randomness is produced, driving the other systems that the network depends on to operate effectively. The consensus system was first designed for a permissioned participation model but can be paired with any method of Sybil resistance for an open participation model. “The Threshold Relay is the mechanism by which Dfinity randomly samples replicas into groups, sets the groups (committees) up for threshold operation, chooses the current committee, and relays from one committee to the next is called the threshold relay.” Threshold Relay consists of four layers (As mentioned previously):
Notary layer, which provides fast finality guarantees to clients and external observers and eliminates nothing-at-stake and selfish mining attacks, providing Sybil attack resistance.
Blockchain layer that builds a blockchain from validated transactions via the Probabilistic Slot Protocol driven by the random beacon.
Random beacon, which as previously covered, provides the source of randomness for all higher layers like the blockchain layer smart contract applications.
Identity layer that provides a registry of all clients.
2.2.1 HOW DOES THRESHOLD RELAY WORK?
Threshold Relay produces an endogenous random beacon, and each new value defines random group(s) of clients that may independently try and form into a “threshold group”. The composition of each group is entirely random such that they can intersect and clients can be presented in multiple groups. In DFINITY, each group is comprised of 400 members. When a group is defined, the members attempt to set up a BLS threshold signature system using a distributed key generation protocol. If they are successful within some fixed number of blocks, they then register the public key (“identity”) created for their group on the global blockchain using a special transaction, such that it will become part of the set of active groups in a following “epoch”. The network begins at “genesis” with some number of predefined groups, one of which is nominated to create a signature on some default value. Such signatures are random values — if they were not then the group’s signatures on messages would be predictable and the threshold signature system insecure — and each random value produced thus is used to select a random successor group. This next group then signs the previous random value to produce a new random value and select another group, relaying between groups ad infinitum and producing a sequence of random values. In a cryptographic threshold signature system a group can produce a signature on a message upon the cooperation of some minimum threshold of its members, which is set to 51% in the DFINITY network. To produce the threshold signature, group members sign the message individually (here the preceding group’s threshold signature) creating individual “signature shares” that are then broadcast to other group members. The group threshold signature can be constructed upon combination of a sufficient threshold of signature shares. So for example, if the group size is 400, if the threshold is set at 201 any client that collects that many shares will be able to construct the group’s signature on the message. Other group members can validate each signature share, and any client using the group’s public key can validate the single group threshold signature produced by combining them. The magic of the BLS scheme is that it is “unique and deterministic” meaning that from whatever subset of group members the required number of signature shares are collected, the single threshold signature created is always the same and only a single correct value is possible. Consequently, the sequence of random values produced is entirely deterministic and unmanipulable, and signatures generated by relaying between groups produces a Verifiable Random Function, or VRF. Although the sequence of random values is pre-determined given some set of participating groups, each new random value can only be produced upon the minimal agreement of a threshold of the current group. Conversely, in order for relaying to stall because a random number was not produced, the number of correct processes must be below the threshold. Thresholds are configured so that this is extremely unlikely. For example, if the group size is set to 400, and the threshold is 201, 200 or more of the processes must become faulty to prevent production. If there are 10,000 processes in the network, of which 3,000 are faulty, the probability this will occur is less than 10e-17.
2.3 DFINITY TOKEN
The DFINITY blockchain also supports a native token, called dfinities (DFN), which perform multiple roles within the network, including:
Fuel for deploying and running smart contracts.
Security deposits (i.e. staking) that enable participation in the BNS governance system.
Security deposits that allow client software or private DFINITY cloud networks to connect to the public network.
Although dfinities will end up being assigned a value by the market, the DFINITY team does not intend for DFN to act as a currency. Instead, the project has envisioned PHI, a “next-generation” crypto-fiat scheme, to act as a stable medium of exchange within the DFINITY ecosystem. Neuron operators can earn Dfinities by participating in network-wide votes, which could be concerning protocol upgrades, a new economic policy, etc. DFN rewards for participating in the governance system are proportional to the number of tokens staked inside a neuron.
DFINITY is constantly developing with a structure that separates consensus, validation, and storage into separate layers. The storage layer is divided into multiple strings, each of which is responsible for processing transactions that occur in the fragment state. The verification layer is responsible for combining hashes of all fragments in a Merkle-like structure that results in a global state fractionation that is stored in blocks in the top-level chain.
2.5 DFINITY CONSENSUS ALGORITHM
The single most important aspect of the user experience is certainly the time required before a transaction becomes final. This is not solved by a short block time alone — Dfinity’s team also had to reduce the number of confirmations required to a small constant. DFINITY moreover had to provide a provably secure proof-of-stake algorithm that scales to millions of active participants without compromising any bit on decentralization. Dfinity soon realized that the key to scalability lay in having an unmanipulable source of randomness available. Hence they built a scalable decentralized random beacon, based on what they call the Threshold Relay technique, right into the foundation of the protocol. This strong foundation drives a scalable and fast consensus layer: On top of the beacon runs a blockchain which utilizes notarization by threshold groups to achieve near-instant finality. Details can be found in the overview paper that we are releasing today. The roots of the DFINITY consensus mechanism date back to 2014 when thair Chief Scientist, Dominic Williams, started to look for more efficient ways to drive large consensus networks. Since then, much research has gone into the protocol and it took several iterations to reach its current design. For any practical consensus system the difficulty lies in navigating the tight terrain that one is given between the boundaries imposed by theoretical impossibility-results and practical performance limitations. The first key milestone was the novel Threshold Relay technique for decentralized, deterministic randomness, which is made possible by certain unique characteristics of the BLS signature system. The next breakthrough was the notarization technique, which allows DFINITY consensus to solve the traditional problems that come with proof-of-stake systems. Getting the security proofs sound was the final step before publication. DFINITY consensus has made the proper trade-offs between the practical side (realistic threat models and security assumptions) and the theoretical side (provable security). Out came a flexible, tunable algorithm, which we expect will establish itself as the best performing proof-of-stake algorithm. In particular, having the built-in random beacon will prove to be indispensable when building out sharding and scalable validation techniques.
The startup has rather cheekily called this “an open version of LinkedIn,” the Microsoft-owned social network for professionals. Unlike LinkedIn, LinkedUp, which runs on any browser, is not owned or controlled by a corporate entity. LinkedUp is built on Dfinity’s so-called Internet Computer, its name for the platform it is building to distribute the next generation of software and open internet services. The software is hosted directly on the internet on a Switzerland-based independent data center, but in the concept of the Internet Computer, it could be hosted at your house or mine. The compute power to run the application LinkedUp, in this case — is coming not from Amazon AWS, Google Cloud or Microsoft Azure, but is instead based on the distributed architecture that Dfinity is building. Specifically, Dfinity notes that when enterprises and developers run their web apps and enterprise systems on the Internet Computer, the content is decentralized across a minimum of four or a maximum of an unlimited number of nodes in Dfinity’s global network of independent data centers. Dfinity is an open source for LinkedUp to developers for creating other types of open internet services on the architecture it has built. “Open Social Network for Professional Profiles” suggests that on Dfinity model one can create “Open WhatsApp”, “Open eBay”, “Open Salesforce” or “Open Facebook”. The tools include a Canister Software Developer Kit and a simple programming language called Motoko that is optimized for Dfinity’s Internet Computer. “The Internet Computer is conceived as an alternative to the $3.8 trillion legacy IT stack, and empowers the next generation of developers to build a new breed of tamper-proof enterprise software systems and open internet services. We are democratizing software development,” Williams said. “The Bronze release of the Internet Computer provides developers and enterprises a glimpse into the infinite possibilities of building on the Internet Computer — which also reflects the strength of the Dfinity team we have built so far.” Dfinity says its “Internet Computer Protocol” allows for a new type of software called autonomous software, which can guarantee permanent APIs that cannot be revoked. When all these open internet services (e.g. open versions of WhatsApp, Facebook, eBay, Salesforce, etc.) are combined with other open software and services it creates “mutual network effects” where everyone benefits. On 1 November, DFINITY has released 13 new public versions of the SDK, to our second major milestone [at WEF Davos] of demoing a decentralized web app called LinkedUp on the Internet Computer. Subsequent milestones towards the public launch of the Internet Computer will involve:
On boarding a global network of independent data centers.
Fully tested economic system.
Fully tested Network Nervous Systems for configuration and upgrades
2.7 WHAT IS MOTOKO?
Motoko is a new software language being developed by the DFINITY Foundation, with an accompanying SDK, that is designed to help the broadest possible audience of developers create reliable and maintainable websites, enterprise systems and internet services on the Internet Computer with ease. By developing the Motoko language, the DFINITY Foundation will ensure that a language that is highly optimized for the new environment is available. However, the Internet Computer can support any number of different software frameworks, and the DFINITY Foundation is also working on SDKs that support the Rust and C languages. Eventually, it is expected there will be many different SDKs that target the Internet Computer. Full article
One Year after the Public Chain Takeoff, the New Era of Blockchain 3.0 has Arrived
https://preview.redd.it/gflezdzc0rh51.png?width=512&format=png&auto=webp&s=b93d52868ac1216ffc51cbf4f3e9280db500c329 Everyone said that 2019 is the year public blockchains took off, and 2020 will be the first year blockchain began to achieve business adoption. Although the coronavirus pandemic continues to wreak havoc on all walks of life worldwide, the blockchain industry is making great strides forward. In just a few years, the blockchain sector has developed from 1.0 to 3.0, and each upgrade has brought about some changes in the world. As we all know, blockchain 1.0 generally refers to cryptocurrency centered around Bitcoin. Blockchain 2.0 is public chains represented by Ethereum, which can develop smart contracts. In the era of blockchain 3.0, people think that thousands of blockchains can coexist and interoperate. In the past two years, people have had high expectations of many public chains. However, some of the so-called “blockchain 3.0” projects have either shown slow progress or failed to live up to the expectations after their mainnet went live. People then began to expect to see a killer DApp achieving wide adoption of blockchain. At the same time, as the underlying technology for blockchain connectivity, multi-chain structure and cross-chain technology have become an important part of ‘blockchain 3.0’. aelf and other Web 3.0 projects can be seen as the underlying technology providers for the Internet of Value. On the aelf blockchain, whether it is valuable information or digital currency, everything can be connected and shared, which is where the magic of cross-chain technology lies. If the consensus mechanism is the core competitiveness of blockchain, then the cross-chain technology is the key to realizing the Internet of Value for blockchain, particularly for alliance chains and private chains. It is the key to preventing different blockchains from being isolated islands and serves as a bridge connecting blockchain and the outside world.
Cross-chain technology is designed to prevent blockchain from being isolated islands of data
At present, although these public chain projects have seen their performance improved, none of them is able to build the much-anticipated “underlying blockchain highway’ singlehandedly. In particular, driven by the prevailing view that each public chain should be an independent ecosystem, public chains today have become isolated islands of data with different architectures incompatible systems, which poses real difficulty to DApp developers. The cross-chain technology, as the name suggests, is aimed to realize asset circulation, information exchange and application collaboration between different blockchain platforms. It can be likened to a bridge linking different public chains, which can help realize data transmission between different blockchain networks and greatly reduce transmission costs. It is obvious that the demand for cross-chain technology is very urgent in today’s blockchain world. Cross-chain communication can be divided into homogeneous and heterogeneous cross-chain according to different underlying blockchain technology platforms. Cross-chain interaction between homogeneous chains is simple, since their security mechanisms, consensus algorithms, network topology, block generation verification logic are consistent. Cross-chain interaction between heterogeneous chains is quite different. For example, Bitcoin uses PoW algorithm while the alliance chain Fabric uses traditional deterministic consensus algorithm, and its block form and deterministic guarantee mechanism are very different. Since designing a direct cross-chain communication mechanism is not easy, cross-chain interaction between heterogeneous chains generally requires third-party services.
aelf is doubling down on heterogeneous cross-chain research
At present, cross-chain technology mainly includes notary schemes, hash-locking, side chains or relays, and distributed private key control. aelf uses the side chain or relay scheme. aelf’s cross-chain logic is ‘main chain + side chain’, with an emphasis on ‘one chain, one scenario’, where each side chain can be a scenario, such as a DApp, or a DeFi app. aelf’s cross-chain architecture is centered around the main chain. https://preview.redd.it/n6q32zae0rh51.png?width=512&format=png&auto=webp&s=53aa5f093279c65b1a529ccefdf840a11382dc9d In the cross-chain process, aelf achieves intercommunication between different chains via indexing. An index is the transfer of data from one chain to another in a defined structure. The cross-chain index has two steps: parent chain indexing child chain and child chain indexing parent chain.
The parent chain requests data from the child-chain and the data are then sent from the child chain to the parent chain.
The parent chain processes all the child chain’s index data, generating a Merkle tree, and stores it on the chain. The child chain block has been indexed by the parent chain, and must wait for the data to be confirmed by the network.
The above steps include the whole process of the parent chain indexing the child chain’s block and the child chain re-indexing the parent chain’s block. It’s worth noting that only irreversible blocks can be indexed by other chains. https://preview.redd.it/cx381n9f0rh51.png?width=512&format=png&auto=webp&s=48bbb33731e42ba1d6c0a21a57e325274f150283 As a result, aelf does not need a Hub or a relay chain and is more of a decentralized cross-chain model. This is because communication between different chains does not necessarily require the permission of the aelf’s only main chain each time. The multi-layer child chains under the side chain can also communicate with each other with the index of the upper-layer parent chain and without the main chain getting involved. On the premise of decentralization, aelf established that only confirmed blocks can be indexed, because only irreversible data can be trusted to ensure the network’s security. aelf also has its own solution for communicating with the Ethereum ecosystem, which can be interfaced with the Ethereum and other blockchain systems via adapters, making it compatible with existing mainstream ecosystems. It can be seen that aelf has done a great job in homogeneous cross-chain technology, whereas some public chain projects have yet to pull it off. aelf has also begun to develop heterogeneous cross-chain technology, which will allow external chains such as Bitcoin and Ethereum to lock tokens into smart contracts and generate ccorresponding tokens on the aelf chain through contracts to achieve cross-chain communication. It is clear that aelf has taken the lead in cross-chain development. While it’s still too early to talk about blockchain 3.0 and most projects are still trying to figure out where the underlying technologies are heading, solving the scalability issue public chains are facing today through the cross-chain technology has become the general trend. Cross-chain technology can realize communication between different chains, greatly improve blockchain’s ability to transfer value, and promote the development of IoT and cloud computing. On the other hand, without cross-chain technology, all kinds of blockchain platforms information will just be isolated islands of data, putting a significant limit on the applications of blockchain platforms. We believe that the cross-chain mechanisms will greatly increase the value of blockchain and usher in a new era of blockchain development. With strong technical prowess and the ability to achieve commercial application, aelf will continue to explore the cross chain technology and provide strong technical support for the rapid and steady development of the industry!
Difficulty is a measure of how difficult it is to find a hash below a given target. The Bitcoin network has a global block difficulty. Valid blocks must have a hash below this target. Mining pools also have a pool-specific share difficulty setting a lower limit for shares. How often does the network difficulty change? Every 2016 blocks. As with the Bitcoin Blockchain, this difficulty may change over time. We must therefore pass this difficulty as a parameter of the mineBlock function that we will create. What is the bitcoin halving and why do many believe it's boosting bitcoin's price? Here's our introductory guide to the coming big change in bitcoin. When does the difficulty change? The difficulty adjusts every 2016 blocks (roughly every 2 weeks). ... The difficulty in bitcoin works in exactly the same way – it’s used to set a target value, and miners keep generating numbers (hashing their candidate blocks) in the hope that they will find a number lower than this target value: And seeing as miners are able to generate thousands of ... In the Bitcoin network at the time of writing the difficulty has been recalibrated 265 times which results in 265 segments. With a change in difficulty, we calculate if each of these segments can operate a profitable operation, i.e., earn a positive Rev. For each segment, we calculate the value of P t.
Trading Bitcoin - We Are Close To What I Define as a Trend Change
Remove all; Disconnect; The next video is starting This video is unavailable. Watch Queue Queue. Watch Queue Queue For more info concerning Bitcoin wallet card, litecoin wallet card, please visit site right here: http://www.cryptocoinwalletcards.com/ Tags: asic bitcoin mi... #Monero #BitCoin #Cryptocurrency Welcome to the 15th episode of CCMDL , Feburary 2 2020 We go over talk a little about the difficulty of Ethereum , Bitcoin, Monero , LiteCoins & Ethereum Classic ... Bitcoin has rebounded strongly since the capitulation lows seen in March. Since March 13th, in fact, the cryptocurrency has gained in excess of 150%, having ...