A distributed contract is a method of using Bitcoin to form agreements with people via the block chain. Contracts don't make anything possible that was previously impossible, but rather, they allow you to solve common problems in a way that minimizes trust. Minimal trust often makes things more convenient by allowing human judgements to be taken out of the loop, thus allowing complete automation.
Many of the ideas underlying Bitcoin contracts were first described by Nick Szabó in his seminal paper, Formalizing and Securing Relationships on Public Networks.
This page was written by Mike Hearn. Contact him if you have an idea for a new type of contract.
Every transaction in Bitcoin has one or more inputs and outputs. Each input/output has a small, pure function associated with it called a script. Scripts can contain signatures over simplified forms of the transaction itself.
Every transaction can have a lock time associated with it. This allows the transaction to be pending and replaceable until an agreed-upon future time, specified either as a block index or as a timestamp (the same field is used for both, but values less than 500 million are interpreted as a block index). If a transaction's lock time has been reached, we say it is final.
Each transaction input has a sequence number. In a normal transaction that just moves value around, the sequence numbers are all UINT_MAX and the lock time is zero. If the lock time has not yet been reached, but all the sequence numbers are UINT_MAX, the transaction is also considered final. Sequence numbers can be used to issue new versions of a transaction without invalidating other inputs signatures, e.g., in the case where each input on a transaction comes from a different party, each input may start with a sequence number of zero, and those numbers can be incremented independently.
Signature checking is flexible because the form of transaction that is signed can be controlled through the use of SIGHASH flags, which are stuck on the end of a signature. In this way, contracts can be constructed in which each party signs only a part of it, allowing other parts to be changed without their involvement. The SIGHASH flags have two parts, a mode and the ANYONECANPAY modifier:
- SIGHASH_ALL: This is the default. It indicates that everything about the transaction is signed, except for the input scripts. Signing the input scripts as well would obviously make it impossible to construct a transaction, so they are always blanked out. Note, though, that other properties of the input, like the connected output and sequence numbers, are signed; it's only the scripts that are not. Intuitively, it means "I agree to put my money in, if everyone puts their money in and the outputs are this".
- SIGHASH_NONE: The outputs are not signed and can be anything. Use this to indicate "I agree to put my money in, as long as everyone puts their money in, but I don't care what's done with the output". This mode allows others to update the transaction by changing their inputs sequence numbers.
- SIGHASH_SINGLE: Like SIGHASH_NONE, the inputs are signed, but the sequence numbers are blanked, so others can create new versions of the transaction. However, the only output that is signed is the one at the same position as the input. Use this to indicate "I agree, as long as my output is what I want; I don't care about the others".
The SIGHASH_ANYONECANPAY modifier can be combined with the above three modes. When set, only that input is signed and the other inputs can be anything.
Scripts can contain the CHECKMULTISIG opcode. This opcode provides n-of-m checking: you provide multiple public keys, and specify the number of valid signatures that must be present. The number of signatures can be less than the number of public keys. An output can require two signatures to be spent by setting it to something like this:
2 <pubkey1> <pubkey2> 2 CHECKMULTISIGVERIFY
There are two general patterns for safely creating contracts:
- Transactions are passed around outside of the P2P network, in partially-complete or invalid forms.
- Two transactions are used: one (the contract) is created and signed but not broadcast right away. Instead, the other transaction (the payment) is broadcast after the contract is agreed to lock in the money, and then the contract is broadcast.
This is to ensure that people always know what they are agreeing to.
Together, these features let us build interesting new financial tools on top of the block chain.
Example 1: Providing a deposit
Imagine that you open an account on a website (eg, a forum or wiki) and wish to establish your trustworthiness with the operators, but you don't have any pre-existing reputation to leverage. One solution is to buy trust by paying the website some money. But if at some point you close your account, you'd probably like that money back. You may not trust the site enough to give them a deposit that they are tempted to spend. Another risk is that the site might just disappear one day.
The goal is to prove that you made a sacrifice of some kind so the site knows you're not a spambot, but you don't want them to be able to spend the money. And if the operators disappear, you'd eventually like the coins back without needing anything from them.
We can solve this problem with a contract:
- The user and website send each other a newly-generated public key.
- The user creates transaction Tx1 (the payment) putting 10 BTC into an output that requires both user and website to sign, but does not broadcast it. They use the key from the previous step for the site.
- User sends the hash of Tx1 to the website.
- The website creates a transaction Tx2 (the contract). Tx2 spends Tx1 and pays it back to the user via the address he provided in the first step. Note that Tx1 requires two signatures, so this transaction can't be complete. nLockTime is set to some date in the future (eg, six months). The sequence number on the input is set to zero.
- Finally, the incomplete (half-signed) transaction is sent back to the user. The user checks that the contract is as expected - that the coins will eventually come back to him - but, unless things are changed, only after six months. Because the sequence number is zero, the contract can be amended in future if both parties agree. The script in the input isn't finished though; there are only zeros where the user's signature should be. He fixes that by signing the contract and putting the new signature in the appropriate spot.
- The user broadcasts Tx1, then broadcasts Tx2.
At this stage, the 10 BTC are in a state where neither the user nor the website can spend them independently. After six months, the contract will complete and the user will get the coins back, even if the website disappears.
What if the user wishes to close his account early? The website creates a new version of Tx2 with nLockTime set to zero and the input sequence number set to UINT_MAX, then he re-signs it. The site hands the tx back to the user, who signs it as well. The user then broadcasts the transaction, terminating the contract early and releasing the coins.
What if the six months is nearly up and the user wishes to keep his account? The same thing applies: the contract can be resigned with a newer nLockTime, a sequence number 1 higher than the previous and rebroadcast 2^32 times. No matter what happens, both parties must agree for the contract to change.
Obviously, if the user turns out to be abusive (i.e., a spammer), the website will not allow an early close of the contract. If too much abuse is getting through, the size of the deposit can be raised or the length of the contract can be increased.
Example 2: Escrow and dispute mediation
A buyer wants to trade with somebody he doesn't know or trust. In the common case where the transaction goes well, the client doesn't want any third parties involved. If something goes wrong though, he'd like a third party to decide who gets the money - perhaps a professional dispute mediation service. Note that this concept can apply to either buyer or seller. The mediator might request proof of postage from the merchant, for example.
In other words, one wants to lock up some coins so a third party has to agree in order for them to be spent:
- Agree with the merchant on a dispute mediator (e.g., ClearCoin).
- Ask the merchant for a public key (K1). Ask the mediator for a public key (K2). Create a new key for yourself (K3).
- Send the merchant K2. The merchant challenges the mediator with a random nonce. The mediator signs the nonce with the private form of K2, thus proving it really belongs to merchant.
- Create a transaction (Tx1) with an output script as follows and broadcast it:
2 <K1> <K2> <K3> 3 CHECKMULTISIGVERIFY
Now the coins are locked in such a way that they can only be spent by the following methods:
- Client and the merchant agree (either a successful trade, or merchant agrees to reimburse client without mediation)
- Client and the mediator agree (failed trade, mediator sides with client, like a charge-back)
- The mediator and the merchant agree (goods delivered, merchant gets client's coins despite the dispute)
When signing an input, the contents are set to the connected output. Thus, to redeem this transaction, the client creates a scriptSig containing zeros where the other signature should be, signs it, and then sets one of the slots to his new signature. The partially-complete transaction can then be sent to the merchant or mediator for the second signature.
Example 3: Assurance contracts
An assurance contract is a way of funding the creation of a public good, that is, a good that, once created, anyone can benefit from for free. The standard example is a lighthouse: whilst everyone may agree that one should be built, it’s too expensive for an individual sailor to justify building one, given that it will also benefit all his competitors.
One solution is for everyone to pledge money towards the creation of the public good, such that the pledges are only committed if the total value of all pledges is above the cost of creation. If not enough people contribute, nobody has to pay anything.
Examples where Bitcoin is superior to traditional payment methods for assurance contract fundraising include applications where frequent, small pledges need to be made automatically, for instance internet radio station funding and web page translation. Consider a browser extension that you send a bit of money to. It detects the current language of the page and broadcasts a pledge for a translation into your language to be prepared. If enough users with the extension land on the same page at the same time (eg, it was linked to from somewhere high traffic), then enough pledges are broadcast to trigger a payment to a company who prepares a high quality translation. When complete it automatically loads in your browser.
We can model this in Bitcoin as follows:
- An entrepreneur creates a new address and announces that the good will be created if at least 1000 BTC is raised. Anyone can contribute.
- Each party wishing to pledge creates a new transaction spending some of their coins to the announced address, but they do not broadcast it. The transaction is similar to a regular transaction except for three differences: Firstly, there cannot be any change. If you don’t have any outputs of the right size, you must create one first by spending to one of your own addresses. Secondly, the input script signature is signed with SIGHASH_ALL | SIGHASH_ANYONECANPAY. Finally, the output value is set to 1000 BTC. Note that this is not a valid transaction because the output value is larger than the input value.
- The transaction is uploaded to the entrepreneur's server, which saves it to disk and updates its count of how many coins have been pledged.
- Once the server has enough coins, it merges the separate transactions together into a new transaction. The new transaction has a single output that simply spends to the announced address - it is the same as the outputs on each contributed transaction. The inputs to the transaction are collected from the contributed pledges.
- The finished transaction is broadcast, sending the pledged coins to the announced address.
This scheme relies on several aspects of the protocol. The first is the SIGHASH flags used. SIGHASH_ALL is the default and means the entire contents of the transaction are signed, except for the input scripts. SIGHASH_ANYONECANPAY is an additional modifier that means the signature only covers the input it’s found in - the other inputs are not signed and thus can be anything.
By combining these flags together, we are able to create a signature that is valid even when other inputs are added, but breaks if the outputs or other properties of the transaction are changed.
The second aspect we exploit is the fact that a transaction in which the output values are larger than the input values is invalid (for obvious reasons). This means it’s safe to send the entrepreneur a transaction that spends such coins - it’s impossible for him to claim the coins unless he has other inputs that sum to the output value or more.
It's possible to create assurance contracts without using SIGHASH_ANYONECANPAY. Instead, a two step process is used in which pledges are collected without transactions, and once the total value is reached, a transaction with an input for each pledger is created and passed around until all signatures are collected. However, using SIGHASH_ANYONECANPAY and then merging is probably more convenient.
An assurance contract can be prepared that funds network security. Instead of a single announced address for everyone to contribute to, the entrepreneur provides a set of outputs that are signed by each party in their pledge. The entrepreneur also prepares a number of transactions equivalent to the number of outputs, each one spending a single contract output to a null output of zero value and an OP_FALSE script, i.e., the entire value is consumed as fees. The lock time of each transaction is set to N+M, where N is a pre-agreed time at which the contract becomes valid (measured in block numbers) and M is the index of a contract output. In this way, an array of transactions is prepared that do nothing other than incentivize mining in a series of blocks.
An elaboration of this concept is described by Tabarrok in his paper, “The private provision of public goods via dominant assurance contracts”. In a dominant assurance contract, if a contract fails (not enough pledges within a set time window) the entrepreneur pays a fee to those who pledged so far. This type of contract attempts to arrange incentives such that taking part is always the right strategy. A scheme for dominant assurance contracts in Bitcoin has been proposed.
Example 4: Using external state
Scripts are, by design, pure functions. They cannot poll external servers or import any state that may change as it would allow an attacker to outrun the block chain. But we can make transactions connected to the world in other ways.
Consider the example of an old man who wishes to give an inheritance to his grandson, either on the grandson's 18th birthday or when the man dies, whichever comes first.
To solve this, the man first sends the amount of the inheritance to himself so there is a single output of the right amount. Then he creates a transaction with a lock time of the grandson's 18th birthday that pays the coins to another key owned by the grandson, signs it, and gives it to him - but does not broadcast it. This takes care of the 18th birthday condition. If the date passes, the grandson broadcasts the transaction and claims the coins. He could do it before then, but it doesn't let him get the coins any earlier, and some nodes may choose to drop transactions in the memory pool with lock times far in the future.
The death condition is harder. As Bitcoin nodes cannot measure arbitrary conditions, we must rely on an oracle. An oracle is a server that has a keypair, and signs transactions on request when a user-provided expression evaluates to true.
Here is an example. The man creates a transaction spending his output, and sets the output to:
<sons pubkey> CHECKSIGVERIFY <oracle pubkey> CHECKSIGVERIFY <hash> OP_TRUE
This is the oracle script. It has an unusual form - after signature checking it pushes data to the stack then does not use it. The pubkey is published on the oracle's website and is well-known. The hash is set to be the hash of the user-provided expression stating that he has died, written in a form the oracle knows how to evaluate. For example, it could be the hash of the string:
if (has_died('john smith', born_on=1950/01/02)) return 1JxgRXEHBi86zYzHN2U4KMyRCg4LvwNUrp;
This little language is hypothetical, it'd be defined by the oracle and could be anything. The return value is an address owned by the grandson.
Once more, the man creates this transaction but gives it directly to his grandson instead of broadcasting it. He also provides the expression that is hashed into the transaction and the name of the oracle that can unlock it.
It is used in the following algorithm:
- The oracle accepts a measurement request. The request contains the user-provided expression, a copy of the output script, and a partially complete transaction provided by the user. Everything in this transaction is finished except for the scriptSig, which contains just one signature (the grandson's) - not enough to unlock the output.
- The oracle checks the user-provided expression hashes to the value in the provided output script. If it doesn't, it returns an error.
- The oracle evaluates the expression. If the result is not the destination address of the output, it returns an error.
- Otherwise the oracle signs the transaction and inserts the signature into the scriptSig. Note that when signing a Bitcoin transaction, the input script is set to the connected output script. The reason is that when OP_CHECKSIG runs, the script containing the opcode is put in the input being evaluated, _not_ the script containing the signature itself. The oracle has never seen the full output it is being asked to sign, but it doesn't have to. It knows the output script, its own public key, and the hash of the user-provided expression, which is everything it needs to check the output script and finish the transaction.
- The oracle returns the newly signed, unbroadcast transaction to the user.
If, and only if, the oracle agrees that the man is dead, the grandson can broadcast the two transactions (the contract and the claim) and take the coins.
The oracle does not need to be highly trusted. It has not seen the transaction the grandson is trying to unlock, as it was never broadcast, thus, the oracle cannot hold the grandson to ransom because it does not know whether the transaction it's signing for even exists. People can, and should, regularly challenge the oracle in an automated fashion to ensure it always outputs what is expected. The challenges can be done without spending any coins because the tx to be signed can be invalid (ie, connected to transactions that don't exist). The oracle has no way to know whether a request to be signed is random or real. CHECKSIGVERIFY can be replaced with CHECKMULTISIGVERIFY to allow for n-of-m oracles if need be.
Oracles can potentially evaluate anything, yet the output script form in the block chain can always be the same. Consider the following possibilities:
today() == 2011/09/25 && exchange_rate(mtgoxUSD) >= 12.5 && exchange_rate(mtgoxUSD) <= 13.5 Require exchange rate to be between two values on a given date google_results_count(site:www.google.com/hostednews 'Mike Hearn' olympic gold medal) > 0 A bet on me doing something that I will never actually do // Choose between one of two winners of a bet on the outcome of the Eurovision song contest. if (eurovision_winner() == 'Azerbaijan') return 1Lj9udBVDwptFffGSJSC2sohCfudQgSTPD; else return 1JxgRXEHBi86zYzHN2U4KMyRCg4LvwNUrp;
The conditions that control whether the oracle signs can be arbitrarily complex, but the block chain never needs to contain more than a single hash.
Example 5: Trading across chains
The Bitcoin technology can be adapted to create multiple, independent currencies. NameCoin is an example of one such currency that operates under a slightly different set of rules, and can also be used to rent names in a namespace. Currencies that implement the same ideas as Bitcoin can be traded freely against each other without trust. For example, imagine a consortium of companies that issue EURcoins, a crypto-currency that is backed 1:1 by deposits in the consortium's bank accounts. Such a currency would have a different set of tradeoffs to Bitcoin: more centralized, but without FX risk. People might wish to trade Bitcoins for EURcoins back and forth, with the companies only getting involved when cashing in/out of the regular banking system.
To implement this, a protocol proposed by luxgladius can be used:
- Both parties generate a new key and some random data (the secret).
- Party 'B' sends a hash of his secret to 'A' along with his public key.
- Party 'A' generates Tx1 (the payment) containing an output with the chain-trade script in it. See below for this script and a discussion of it. It allows coin release either by signing with the two keys (key 'A' and key 'B') or with (secret 'A', secret 'B', key 'B'). This transaction is not broadcast. The chain release script contains hashes, not the actual secrets themselves.
- Party 'A' generates Tx2 (the contract), which spends Tx1 and has an output going back to key 'A'. It has a lock time in the future and the input has a sequence number of zero, so it can be replaced. 'A' signs Tx2 and sends it to 'B', who also signs it and sends it back. Alternatively, they can simply agree on what form the contract takes, e.g., by using the same software, and then 'A' can simply send 'B' the hash of Tx1 and receive back a signature.
- 'A' broadcasts Tx1 and Tx2. Party 'B' can now see the coins but cannot spend them because it does not have an output going to him, and the tx is not finalized anyway.
- 'B' performs the same scheme in reverse on the alternative chain. Both sides of the trade are now pending but incomplete.
- 'A' sends his secret (random data) to 'B', who then uses it to re-issue the now-finalized contract using (secret 'A', secret 'B', key 'B') and an output of his choice. 'B' now owns the coins, but in the process of claiming them, revealed his secret, allowing 'A' to claim the other side of the trade.
Because the protocol is trust-free, it would be feasible to do trades automatically in an entirely peer-to-peer manner, which should ensure good liquidity.
The chain-trade script could look like this:
IF 2 <key A> <key B> 2 CHECKMULTISIGVERIFY ELSE <key B> CHECKSIGVERIFY SHA256 <hash of secret A> EQUALVERIFY <hash of secret B> EQUALVERIFY ENDIF
The contract input script looks like either:
<sig A> <sig B> 1
<secret B> <secret A> <sig B> 0
i.e., the first data element selects which phase is being used.
Example 6: Smart property
It's possible to make physical property, like houses, cars or phones, be atomically tradeable and lendable via the block chain. This topic has its own article: learn more about smart property.
Example 7: Rapidly-adjusted (micro)payments to a pre-determined party
Bitcoin transactions are very cheap relative to traditional payment systems, but still have a cost due to the need for it to be mined and stored. There are some cases in which you want to rapidly and cheaply adjust the amount of money sent to a particular recipient without incurring the cost of a broadcast transaction.
For example, consider an untrusted internet access point, like a WiFi hotspot in a cafe you never visited before. You'd like to pay 0.001 BTC per 10 kilobytes of usage, without opening an account with the cafe. A zero-trust solution means it could be fully automatic, so you could just pre-allocate a budget on your phone's mobile wallet at the start of the month, and then your device automatically negotiates and pays for internet access on demand. The cafe also wants to allow anyone to pay them without the fear of being ripped off.
To do this, a protocol similar to one proposed by hashcoin can be used:
- Request a public key from the access point.
- Create, but do not sign, a transaction (T1) that sets up a payment of (for example) 10 BTC to an output requiring both the access point's public key and one of your own to be used. The value to be used is chosen as an efficiency tradeoff.
- Create, but do not sign, another transaction (T2) that has two outputs, one to the access point's key and another that goes back to you. The initial value is 0.001 BTC to the access point and the rest back to you. Use a sequence number of zero on the input and a lock time in the future (e.g., 1 day).
- Send both unsigned transactions to the access point. It sees that T1 and T2 are of the expected form and signs T2. It hands T2 back to you.
- Check that T2 is signed correctly, sign T1 and T2. Send them to the access point, which broadcasts them, thus locking in the agreement. Note that T2 won't get included into a block for at least one day, unless it's replaced by a newer transaction, as determined by the sequence numbers.
- Each time you want 10kb of data quota, sign a new version of T2 with a higher sequence number, the same lock time, and adjust the outputs so more value is allocated to the access point, and send it. The AP sees that the output sizes are correct, signs it, and keeps it (does not broadcast).
This continues until the session ends, or the 1-day period is getting close to expiry. The AP broadcasts the last transaction it saw, replacing the original that was pending. Once the lock time passes, the value transfer is committed. Alternatively, if the session end is negotiated cleanly, the user can sign a transaction that's final (sequence number of UINT_MAX), which signals that no more data quota will be purchased, allowing instant commitment of the transaction.
The lock time and sequence numbers avoid an attack in which the AP provides connectivity, and then the user double-spends the output back to themselves using the first version of TX2, thus preventing the cafe from claiming the bill. If the user does try this, the TX won't be included right away, giving the access point a window of time in which it can observe the TX broadcast, and then broadcast the last version it saw, overriding the user's attempted double-spend.