mirror of
https://github.com/bitcoinbook/bitcoinbook
synced 2024-12-23 15:18:11 +00:00
744 lines
36 KiB
Plaintext
744 lines
36 KiB
Plaintext
[[ch02_bitcoin_overview]]
|
||
== How Bitcoin Works
|
||
|
||
((("bitcoin", "overview of", id="BCover02")))((("central trusted
|
||
authority")))((("decentralized systems", "bitcoin overview",
|
||
id="DCSover02")))The Bitcoin system, unlike traditional banking and
|
||
payment systems, does not require trust in third parties. Instead of a central
|
||
trusted authority, in Bitcoin, each user can use software running on
|
||
their own computer to verify the correct operation of every
|
||
aspect of the Bitcoin system.
|
||
In this chapter, we will examine bitcoin from a high level by tracking a
|
||
single transaction through the Bitcoin system and watch as it
|
||
is recorded on the blockchain, the distributed ledger of all
|
||
transactions. Subsequent chapters will delve into the technology behind
|
||
transactions, the network, and mining.
|
||
|
||
=== Bitcoin Overview
|
||
|
||
In the overview diagram shown in <<bitcoin-overview>>, we see that the
|
||
Bitcoin system consists of users with wallets containing keys,
|
||
transactions that are propagated across the network, and miners who
|
||
produce (through competitive computation) the consensus blockchain,
|
||
which is the authoritative ledger of all transactions.
|
||
|
||
((("blockchain explorer sites")))Each example in this chapter is based
|
||
on an actual transaction made on the Bitcoin network, simulating the
|
||
interactions between the users (Joe, Alice, Bob, and Gopesh) by sending
|
||
funds from one wallet to another. While tracking a transaction through
|
||
the Bitcoin network to the blockchain, we will use a _blockchain
|
||
explorer_ site to visualize each step. A blockchain explorer is a web
|
||
application that operates as a bitcoin search engine, in that it allows
|
||
you to search for addresses, transactions, and blocks and see the
|
||
relationships and flows between them.
|
||
|
||
[[bitcoin-overview]]
|
||
.Bitcoin overview
|
||
image::images/mbc2_0201.png["Bitcoin Overview"]
|
||
|
||
((("Bitcoin Block Explorer")))((("BlockCypher Explorer")))((("blockchain.info")))((("BitPay Insight")))Popular blockchain explorers include:
|
||
|
||
* https://blockstream.info/[Blockstream Explorer]
|
||
* https://mempool.space[Mempool.Space]
|
||
* https://live.blockcypher.com[BlockCypher Explorer]
|
||
|
||
Each of these has a search function that can take a Bitcoin address,
|
||
transaction hash, block number, or block hash and retrieve corresponding
|
||
information from the Bitcoin network. With each transaction or block
|
||
example, we will provide a URL so you can look it up yourself and study
|
||
it in detail.
|
||
|
||
[[block-explorer-privacy]]
|
||
.Block explorer privacy warning
|
||
[WARNING]
|
||
====
|
||
Searching information on a block explorer may disclose to its operator
|
||
that you're interested in that information, allowing them to associate
|
||
it with your IP address, browser fingerprint, past searches, or other
|
||
identifiable information. If you look up the transactions in this book,
|
||
the operator of the block explorer might guess that you're learning
|
||
about Bitcoin, which shouldn't be a problem. But if you look up your
|
||
own transactions, the operator may be able to guess how many bitcoins
|
||
you've received, spent, and currently own.
|
||
====
|
||
|
||
[[spending_bitcoin]]
|
||
==== Buying from an Online Store
|
||
|
||
Alice, introduced in the previous chapter, is a new user who has just
|
||
acquired her first bitcoins. In <<getting_first_bitcoin>>, Alice met with
|
||
her friend Joe to exchange some cash for bitcoins. Since then, Alice has
|
||
bought additional bitcoins. Now Alice will make
|
||
her first retail transaction, buying access to a premium podcast episode from Bob's online store.
|
||
|
||
Bob's web store recently started accepting bitcoin payments by adding a
|
||
bitcoin option to its website. The prices at Bob's store are listed in
|
||
the local currency (US dollars), but at checkout, customers have the
|
||
option of paying in either dollars or bitcoin.
|
||
|
||
Alice finds the podcast episode she wants to buy and proceeds to the checkout page. At checkout,
|
||
Alice is offered the option to pay with bitcoin, in addition to the
|
||
usual options. The checkout cart displays the price in US dollars and
|
||
also in bitcoin (BTC), at Bitcoin's prevailing exchange rate.
|
||
|
||
((("payment requests")))((("QR codes", "payment requests")))Bob's
|
||
e-commerce system will automatically create a QR code containing an
|
||
_invoice_ (<<invoice-QR>>).
|
||
|
||
Unlike a QR code that simply contains a destination Bitcoin address, this
|
||
invoice is a QR-encoded URI that contains a destination address,
|
||
a payment amount, and a description.
|
||
This allows a bitcoin wallet application to prefill the
|
||
information used to send the payment while showing a human-readable
|
||
description to the user. You can scan the QR code with a bitcoin wallet
|
||
application to see what Alice would see.
|
||
|
||
////
|
||
TODO: Replace QR code with test-BTC address
|
||
////
|
||
|
||
[[invoice-QR]]
|
||
.Invoice QR code
|
||
image::images/mbc2_0202.png["payment-request"]
|
||
|
||
[TIP]
|
||
====
|
||
((("QR codes", "warnings and cautions")))((("transactions", "warnings
|
||
and cautions")))((("warnings and cautions", "avoid sending money to
|
||
addresses appearing in book")))Try to scan this with your wallet to see
|
||
the address and amount but DO NOT SEND MONEY.
|
||
====
|
||
[[invoice-URI]]
|
||
.The invoice QR code encodes the following URI, defined in BIP21:
|
||
----
|
||
bitcoin:bc1qk2g6u8p4qm2s2lh3gts5cpt2mrv5skcuu7u3e4?amount=0.01577764&
|
||
label=Bob%27s%20Store&
|
||
message=Purchase%20at%20Bob%27s%20Store
|
||
|
||
Components of the URI
|
||
|
||
A Bitcoin address: "bc1qk2g6u8p4qm2s2lh3gts5cpt2mrv5skcuu7u3e4"
|
||
The payment amount: "0.01577764"
|
||
A label for the recipient address: "Bob's Store"
|
||
A description for the payment: "Purchase at Bob's Store"
|
||
----
|
||
|
||
Alice uses her smartphone to scan the barcode on display. Her smartphone
|
||
shows a payment for the correct amount to +Bob's Store+ and she selects Send to
|
||
authorize the payment. Within a few seconds (about the same amount of
|
||
time as a credit card authorization), Bob sees the transaction on the
|
||
register.
|
||
|
||
[NOTE]
|
||
====
|
||
((("fractional values")))((("milli-bitcoin")))((("satoshis")))The
|
||
Bitcoin network can transact in fractional values, e.g., from
|
||
millibitcoin (1/1000th of a bitcoin) down to 1/100,000,000th of a
|
||
bitcoin, which is known as a satoshi. This book uses the same
|
||
pluralization rules used for dollars and other traditional currencies
|
||
when talking about amounts greater than one bitcoin and when using
|
||
decimal notation, such as "10 bitcoins" or "0.001 bitcoins." The same
|
||
rules also apply to other bitcoin bookkeeping units, such as
|
||
millibitcoins and satoshis.
|
||
====
|
||
|
||
You can examine Alice's transaction to Bob's Store on the blockchain
|
||
using a block explorer site (<<view_alice_transaction>>):
|
||
|
||
[[view_alice_transaction]]
|
||
.View Alice's transaction on https://blockstream.info/tx/674616f1fbc6cc748213648754724eebff0fc04506f2c81efb1349d1ebc8a2ef[Blockstream Explorer]
|
||
====
|
||
----
|
||
https://blockstream.info/tx/674616f1fbc6cc748213648754724eebff0fc04506f2c81efb1349d1ebc8a2ef
|
||
----
|
||
====
|
||
|
||
In the following sections, we will examine this transaction in more
|
||
detail. We'll see how Alice's wallet constructed it, how it was
|
||
propagated across the network, how it was verified, and finally, how Bob
|
||
can spend that amount in subsequent transactions.
|
||
|
||
=== Bitcoin Transactions
|
||
|
||
((("transactions", "defined")))In simple terms, a transaction tells the
|
||
network that the owner of some bitcoin value has authorized the transfer
|
||
of that value to another owner. The new owner can now spend the bitcoin
|
||
by creating another transaction that authorizes the transfer to another
|
||
owner, and so on, in a chain of ownership.
|
||
|
||
==== Transaction Inputs and Outputs
|
||
|
||
((("transactions", "overview of", id="Tover02")))((("outputs and
|
||
inputs", "basics of")))Transactions are like lines in a double-entry
|
||
bookkeeping ledger. Each transaction contains one or more "inputs,"
|
||
which are like debits against a bitcoin account. On the other side of
|
||
the transaction, there are one or more "outputs," which are like credits
|
||
added to a bitcoin account. ((("fees", "transaction fees")))The inputs
|
||
and outputs (debits and credits) do not necessarily add up to the same
|
||
amount. Instead, outputs add up to slightly less than inputs and the
|
||
difference represents an implied _transaction fee_, which is a small
|
||
payment collected by the miner who includes the transaction in the
|
||
ledger. A bitcoin transaction is shown as a bookkeeping ledger entry in
|
||
<<transaction-double-entry>>.
|
||
|
||
The transaction also contains proof of ownership for each amount of
|
||
bitcoin (inputs) whose value is being spent, in the form of a digital
|
||
signature from the owner, which can be independently validated by
|
||
anyone. ((("spending bitcoin", "defined")))In bitcoin terms, "spending"
|
||
is signing a transaction that transfers value from a previous
|
||
transaction over to a new owner identified by a Bitcoin address.
|
||
|
||
[[transaction-double-entry]]
|
||
.Transaction as double-entry bookkeeping
|
||
image::images/mbc2_0203.png["Transaction Double-Entry"]
|
||
|
||
==== Transaction Chains
|
||
|
||
((("chain of transactions")))Alice's payment to Bob's Store uses a
|
||
previous transaction's output as its input. In the previous chapter,
|
||
Alice received bitcoin from her friend Joe in return for cash.
|
||
We've labeled that as _Transaction 1_ (Tx1) in <<transaction-chain>>.
|
||
|
||
Tx1 sent 0.001 bitcoins (100,000 satoshis) to an output locked by
|
||
Alice's key. Her new transaction to Bob's Store (Tx2) references the
|
||
previous output as an input. In the illustration, we show that
|
||
reference using an arrow and by labeling the input as "Tx1:0". In an
|
||
actual transaction, the reference is the 32-byte transaction identifier
|
||
(txid) for the transaction where Alice received the money from Joe. The
|
||
":0" indicates the position of the output where Alice received the
|
||
money; in this case, the first position (position 0).
|
||
|
||
As shown, actual Bitcoin transactions don't
|
||
explicitly include the value of their input. To determine the value of
|
||
an input, software needs to use the input's reference to find the
|
||
previous transaction output being spent.
|
||
|
||
Alice's Tx2 contains two new outputs, one paying 75,000 satoshis for the
|
||
podcast and another paying 20,000 satoshis back to Alice to receive
|
||
change.
|
||
|
||
////
|
||
@startditaa
|
||
Transaction 1 Tx2 Tx3
|
||
Inputs Outputs In Out In Out
|
||
+-------+---------+ +-------+--------+ +-------+--------+
|
||
| | | | | cDDD | | | |
|
||
<--+ Tx0꞉0 | 100,000 |<--+ Tx1꞉0 | 20,000 | +-+ Tx2꞉1 | 67,000 |
|
||
| | | | | | | | | |
|
||
+-------+---------+ +-------+--------+ | +-------+--------+
|
||
| | cDDD | | | | | | | |
|
||
| | 500,000 | | | 75,000 |<-+ | | |
|
||
| | | | | | | | |
|
||
+-------+---------+ +-------+--------+ +-------+--------+
|
||
Fee꞉ (unknown) Fee꞉ 5,000 Fee꞉ 8,000
|
||
@enddittaa
|
||
////
|
||
|
||
[[transaction-chain]]
|
||
.A chain of transactions, where the output of one transaction is the input of the next transaction
|
||
image::images/transaction-chain.png["Transaction chain"]
|
||
|
||
[TIP]
|
||
====
|
||
Serialized Bitcoin transactions---the data format that software uses for
|
||
sending transactions---encodes the value to transfer using an integer
|
||
of the smallest defined onchain unit of value. When Bitcoin was first
|
||
created, this unit didn't have a name and some developers simply called
|
||
it the _base unit._ Later many users began calling this unit a
|
||
_satoshi_ (sat) in honor of Bitcoin's creator. In <<transaction-chain>>
|
||
and some other illustrations in this book, we use satoshi values because
|
||
that's what the protocol itself uses.
|
||
====
|
||
|
||
==== Making Change
|
||
|
||
((("change, making")))((("change addresses")))((("addresses", "change
|
||
addresses")))In addition to one or more outputs that pay the receiver of
|
||
bitcoins, many transactions will also include an output that pays the
|
||
spender of the bitcoins, called a _change_ output.
|
||
This is because transaction inputs,
|
||
like currency notes, cannot be divided. If you purchase a $5 US dollar
|
||
item in a store but use a $20 dollar bill to pay for the item, you
|
||
expect to receive $15 dollars in change. The same concept applies to
|
||
bitcoin transaction inputs. If you purchased an item that costs 5
|
||
bitcoins but only had an input worth 20 bitcoins to use, you would send one
|
||
output of 5 bitcoins to the store owner and one output of 15 bitcoins back
|
||
to yourself as change (not counting your transaction fee).
|
||
|
||
At the level of the Bitcoin protocol, there is no difference between a
|
||
change output (and the address it pays, called a _change address_) and a
|
||
payment output.
|
||
|
||
Importantly, the change address does not have to be the
|
||
same address as that of the input and for privacy reasons is often a new
|
||
address from the owner's wallet. In ideal circumstances, the two
|
||
different uses of outputs both use never-before-been addresses and
|
||
otherwise look identical, preventing any third party from determining
|
||
which outputs are change and which are payments. However, for
|
||
illustration purposes, we've added shading to the change outputs in
|
||
<<transaction-chain>>.
|
||
|
||
==== Coin selection
|
||
|
||
Different wallets use different strategies when choosing which
|
||
inputs to use to a payment, called _coin selection_.
|
||
|
||
They might aggregate many small
|
||
inputs, or use one that is equal to or larger than the desired payment.
|
||
Unless the wallet can aggregate inputs in such a way to exactly match
|
||
the desired payment plus transaction fees, the wallet will need to
|
||
generate some change. This is very similar to how people handle cash. If
|
||
you always use the largest bill in your pocket, you will end up with a
|
||
pocket full of loose change. If you only use the loose change, you'll
|
||
always have only big bills. People subconsciously find a balance between
|
||
these two extremes, and bitcoin wallet developers strive to program this
|
||
balance.
|
||
|
||
==== Common Transaction Forms
|
||
|
||
A very common form of transaction is a simple payment. This type of
|
||
transaction has one input and two outputs and is shown in
|
||
<<transaction-common>>.
|
||
|
||
[[transaction-common]]
|
||
.Most common transaction
|
||
image::images/mbc2_0205.png["Common Transaction"]
|
||
|
||
Another common form of transaction is a _consolidation transaction_ one that spends several inputs
|
||
into a single output (<<transaction-consolidating>>). This represents
|
||
the real-world equivalent of exchanging a pile of coins and currency
|
||
notes for a single larger note. Transactions like these are sometimes
|
||
generated by wallets and business to clean up lots of smaller amounts.
|
||
|
||
[[transaction-consolidating]]
|
||
.Transaction aggregating funds
|
||
image::images/mbc2_0206.png["Aggregating Transaction"]
|
||
|
||
Finally, another transaction form that is seen often on the bitcoin
|
||
ledger is _payment batching_ that pays to multiple outputs
|
||
representing multiple recipients (<<transaction-distributing>>).
|
||
This type of transaction is sometimes used by commercial entities to
|
||
distribute funds, such as when processing payroll payments to multiple
|
||
employees.((("", startref="Tover02")))
|
||
|
||
[[transaction-distributing]]
|
||
.Transaction distributing funds
|
||
image::images/mbc2_0207.png["Distributing Transaction"]
|
||
|
||
=== Constructing a Transaction
|
||
|
||
((("transactions", "constructing", id="Tconstruct02")))((("wallets",
|
||
"constructing transactions")))Alice's wallet application contains all
|
||
the logic for selecting inputs and generating outputs to build a
|
||
transaction to Alice's specification. Alice only needs to choose a
|
||
destination, amount, and transaction fee, and the rest happens in the wallet
|
||
application without her seeing the details. Importantly, if a wallet
|
||
already knows what inputs it controls, it can construct transactions
|
||
even if it is completely offline.
|
||
Like writing a check at home and later sending it to the bank in an
|
||
envelope, the transaction does not need to be constructed and signed
|
||
while connected to the Bitcoin network.
|
||
|
||
==== Getting the Right Inputs
|
||
|
||
((("outputs and inputs", "locating and tracking inputs")))Alice's wallet
|
||
application will first have to find inputs that can pay the amount she
|
||
wants to send to Bob. Most wallets keep track of all the available
|
||
outputs belonging to addresses in the wallet. Therefore, Alice's wallet
|
||
would contain a copy of the transaction output from Joe's transaction,
|
||
which was created in exchange for cash (see <<getting_first_bitcoin>>).
|
||
A bitcoin wallet application that runs on a full node actually
|
||
contains a copy of every confirmed transaction's unspent outputs, called
|
||
_Unspent Transaction Outputs_ (UTXOs).
|
||
However, because full nodes use more resources, most
|
||
user wallets run "lightweight" clients that track only the user's own
|
||
UTXOs.
|
||
|
||
If the wallet application does not maintain a copy of all UTXOs, it can
|
||
query the Bitcoin network to retrieve this
|
||
information using a variety of APIs available by different providers or
|
||
by asking a full node using an application programming interface (API)
|
||
call. <<example_2-2>> shows an API request, constructed as an HTTP GET
|
||
command to a specific URL. This URL will return all the unspent
|
||
transaction outputs for an address, giving any application the
|
||
information it needs to construct transaction inputs for spending. We
|
||
use the simple command-line HTTP client _cURL_ to retrieve the response.
|
||
Note that looking up information using a third-party API like this is similar to
|
||
using a block explorer; see the privacy warning in
|
||
<<block-explorer-privacy>>.
|
||
|
||
[[example_2-2]]
|
||
.Look up all the unspent outputs for Alice's Bitcoin address
|
||
====
|
||
[source,bash]
|
||
----
|
||
$ address=bc1pyfw56zu5vsq0ulu9kytasgw4xwnm3eysll6tfdz8d9gtht97k7tqxsz78n
|
||
$ curl https://blockchain.info/unspent?active=$address
|
||
----
|
||
====
|
||
|
||
[source,json]
|
||
----
|
||
{
|
||
"notice": "",
|
||
"unspent_outputs": [
|
||
{
|
||
"tx_hash_big_endian": "4ac541802679866935a19d4f40728bb89204d0cac90d85f3a51a19278fe33aeb",
|
||
"tx_hash": "eb3ae38f27191aa5f3850dc9cad00492b88b72404f9da135698679268041c54a",
|
||
"tx_output_n": 1,
|
||
"script": "5120225d4d0b946400fe7f85b117d821d533a7b8e490fff4b4b4476950bbacbeb796",
|
||
"value": 100000,
|
||
"value_hex": "0186a0",
|
||
"confirmations": 111,
|
||
"tx_index": 8276421070086947
|
||
}
|
||
]
|
||
}
|
||
----
|
||
|
||
The response in <<example_2-2>> shows one unspent output (one that has
|
||
not been redeemed yet) under the ownership of Alice's address.
|
||
The response includes the reference to the transaction in which this
|
||
UTXO is contained (the payment from Joe), the output index
|
||
number, its value in satoshis, and the script derived from Alice's
|
||
address. With this information, Alice's wallet
|
||
application can construct a transaction to transfer that value to new
|
||
owner addresses.
|
||
|
||
[TIP]
|
||
====
|
||
View the https://blockstream.info/tx/4ac541802679866935a19d4f40728bb89204d0cac90d85f3a51a19278fe33aeb[transaction from Joe to Alice].
|
||
====
|
||
|
||
In this case, this single
|
||
UTXO is sufficient to pay for the podcast. Had this not been the case,
|
||
Alice's wallet application might have to combine several
|
||
smaller UTXOs, like picking coins from a purse until it could
|
||
find enough to pay for the podcast. In both cases, there might be a need
|
||
to get some change back, which we will see in the next section, as the
|
||
wallet application creates the transaction outputs (payments).
|
||
|
||
|
||
==== Creating the Outputs
|
||
|
||
((("outputs and inputs", "creating outputs")))A transaction output is
|
||
created in the form of a script that creates an encumbrance on the value
|
||
and can only be redeemed by the introduction of a solution to the
|
||
script. In simpler terms, Alice's transaction output will contain a
|
||
script that says something like, "This output is payable to whoever can
|
||
present a signature from the key corresponding to Bob's public address."
|
||
Because only Bob has the wallet with the keys corresponding to that
|
||
address, only Bob's wallet can present such a signature to redeem this
|
||
output. Alice will therefore "encumber" the output value with a demand
|
||
for a signature from Bob.
|
||
|
||
This transaction will also include a second output, because Alice's
|
||
funds contain more money than the cost of the
|
||
podcast. Alice's change
|
||
output is created in the very same
|
||
transaction as the payment to Bob. Essentially, Alice's wallet breaks
|
||
her funds into two outputs: one to Bob and one back to herself. She can
|
||
then spend the change output in a subsequent transaction.
|
||
|
||
Finally, for the transaction to be processed by the network in a timely
|
||
fashion, Alice's wallet application will add a small fee. This is not
|
||
explicit in the transaction; it is implied by the difference in value between
|
||
inputs and outputs. This _transaction fee_ is collected by the
|
||
miner as a fee for validating and including the transaction in a block
|
||
to be recorded on the blockchain.
|
||
|
||
[[transaction-alice-url]]
|
||
[TIP]
|
||
====
|
||
View the https://blockstream.info/tx/466200308696215bbc949d5141a49a4138ecdfdfaa2a8029c1f9bcecd1f96177[transaction from Alice to Bob's Store].
|
||
====
|
||
|
||
==== Adding the Transaction to the Ledger
|
||
|
||
The transaction created by Alice's wallet application
|
||
contains everything necessary to confirm ownership of the funds and
|
||
assign new owners. Now, the transaction must be transmitted to the
|
||
Bitcoin network where it will become part of the blockchain. In the next
|
||
section we will see how a transaction becomes part of a new block and
|
||
how the block is mined. Finally, we will see how the new block, once
|
||
added to the blockchain, is increasingly trusted by the network as more
|
||
blocks are added.
|
||
|
||
===== Transmitting the transaction
|
||
|
||
((("propagation", "process of")))Because the transaction contains all
|
||
the information necessary to process, it does not matter how or where it
|
||
is transmitted to the Bitcoin network. The Bitcoin network is a
|
||
peer-to-peer network, with each Bitcoin peer participating by
|
||
connecting to several other Bitcoin peers. The purpose of the Bitcoin
|
||
network is to propagate transactions and blocks to all participants.
|
||
|
||
===== How it propagates
|
||
|
||
((("Bitcoin nodes", "defined")))((("nodes", see="Bitcoin nodes")))
|
||
Peers in the Bitcoin peer-to-peer network are programs that have both
|
||
the software logic and the data necessary for them to fully verify the
|
||
correctness of a new transaction. The connections between peers are
|
||
often visualized as edges (lines) in a graph, with the peers themselves
|
||
being the nodes (dots). For that reason, Bitcoin peers are commonly
|
||
called "full verification nodes", or _full nodes_ for short.
|
||
|
||
Alice's wallet application can send the new
|
||
transaction to any Bitcoin node it is connected to over any type of
|
||
connection: wired, WiFi, mobile, etc. It can also send the transaction
|
||
to another program (such as a block explorer) that will relay it to a
|
||
node. Her bitcoin wallet does not have
|
||
to be connected to Bob's bitcoin wallet directly and she does not have
|
||
to use the internet connection offered by the cafe, though both those
|
||
options are possible, too. ((("propagation", "flooding
|
||
technique")))((("flooding technique")))Any Bitcoin node that receives a
|
||
valid transaction it has not seen before will immediately forward it to
|
||
all other nodes to which it is connected, a propagation technique known
|
||
as _gossiping_. Thus, the transaction rapidly propagates out across the
|
||
peer-to-peer network, reaching a large percentage of the nodes within a
|
||
few seconds.
|
||
|
||
===== Bob's view
|
||
|
||
If Bob's bitcoin wallet application is directly connected to Alice's
|
||
wallet application, Bob's wallet application might be the first to
|
||
receive the transaction. However, even if Alice's wallet sends the
|
||
transaction through other nodes, it will reach Bob's wallet within a few
|
||
seconds. Bob's wallet will immediately identify Alice's transaction as
|
||
an incoming payment because it contains an output redeemable by Bob's
|
||
keys. Bob's wallet application can also independently verify that the
|
||
transaction is well formed. If Bob is using his own full node, his
|
||
wallet can further verify Alice's transaction only spends valid UTXOs.
|
||
|
||
=== Bitcoin Mining
|
||
|
||
((("mining and consensus", "overview of",
|
||
id="MACover02")))((("blockchain (the)", "overview of mining",
|
||
id="BToverview02")))Alice's transaction is now propagated on the Bitcoin
|
||
network. It does not become part of the _blockchain_ until it is
|
||
verified and included in a block by a process called _mining_. See
|
||
<<mining>> for a detailed explanation.
|
||
|
||
The Bitcoin system of counterfeit protection is based on computation.
|
||
Transactions are bundled into _blocks_. Blocks have a very small header
|
||
that must be formed in a very specific way, requiring an enormous
|
||
amount of computation to get right--but only a small amount of
|
||
computation to verify as correct.
|
||
The mining process serves two purposes in bitcoin:
|
||
|
||
* ((("mining and consensus", "consensus rules", "security provided
|
||
by")))((("consensus", see="mining and consensus")))Miners can only
|
||
receive honest income from creating blocks that follow all of Bitcoin's
|
||
_consensus rules_. Therefore, miners are normally incentivized to
|
||
only include valid transactions in their blocks and the blocks they
|
||
build upon. This allows users to optionally trust that any transaction
|
||
in a block is a valid transaction.
|
||
|
||
* Mining currently creates new bitcoin in each block, almost like a central bank
|
||
printing new money. The amount of bitcoin created per block is limited
|
||
and diminishes with time, following a fixed issuance schedule.
|
||
|
||
|
||
Mining achieves a fine balance between cost and reward. Mining uses
|
||
electricity to solve a computational problem. A successful miner will
|
||
collect a _reward_ in the form of new bitcoin and transaction fees.
|
||
However, the reward will only be collected if the miner has correctly
|
||
validated all the transactions, to the satisfaction of the rules of
|
||
_consensus_. This delicate balance provides security for bitcoin without
|
||
a central authority.
|
||
|
||
Mining is designed to be a decentralized lottery. Each miner can create
|
||
their own lottery ticket by creating a _block template_ that includes
|
||
the new transactions they want to mine plus some additional data fields.
|
||
The miner inputs their template into a specially-designed algorithm that
|
||
scrambles (or "hashes") the data, producing output that looks nothing
|
||
like the input data. This _hash_ function will always produce the same
|
||
output for the same input--but nobody can predict what the output will
|
||
look like for a new input, even if it is only slighly different from a
|
||
previous input. If the output of hash function matches a template
|
||
determined by the Bitcoin protocol, the miner wins the lottery and
|
||
Bitcoin users will accept the block template with its transactions as a
|
||
valid block. If the output doesn't match the template, the miner makes
|
||
a small change to their block template and tries again. As of this
|
||
writing, the number of block templates miners need to try before finding
|
||
a winning combination is about 168 billion trillions. That's also how
|
||
many times the hash function needs to be run.
|
||
|
||
However, once a winning combination has been found, anyone can verify
|
||
the block is valid by running the hash function just once. That makes a
|
||
valid block something that requires an incredible amount of work to
|
||
create but only a trivial amount of work to verify. The simple
|
||
verification process is able to probabalistically prove the work was
|
||
done, so the data necessary to generate that proof--in this case, the
|
||
block--is called Proof-of-Work (PoW).
|
||
|
||
((("mining and consensus", "mining farms and pools")))In
|
||
<<user-stories>>, we introduced ((("use cases", "mining for
|
||
bitcoin")))Jing, an entrepreneur in Shanghai. Jing runs a _mining farm_,
|
||
which is a business that runs thousands of specialized mining computers,
|
||
competing for the block reward. Jing's mining
|
||
computers compete against thousands of similar systems in the global
|
||
lottery to create the next block.
|
||
|
||
Jing started mining in 2010 using a very fast desktop computer to find a
|
||
suitable Proof-of-Work for new blocks. As more miners started joining
|
||
the Bitcoin network, the Bitcoin protocol automatically increased the
|
||
difficulty of finding a new block.
|
||
Soon, Jing and other miners upgraded to more specialized hardware, such
|
||
as high-end dedicated graphical processing units (GPUs)
|
||
used in gaming desktops. At the time of this writing,
|
||
the difficulty is so high that it is profitable only to mine with
|
||
((("application-specific integrated circuits
|
||
(ASIC)")))application-specific integrated circuits (ASIC), essentially
|
||
hundreds of mining algorithms printed in hardware, running in parallel
|
||
on a single silicon chip. ((("mining pools", "defined")))Jing's company
|
||
also participates in a _mining pool_, which much like a lottery pool
|
||
allows several participants to share their efforts and rewards. Jing's
|
||
company now runs a warehouse containing thousands of ASIC miners to
|
||
mine for bitcoin 24 hours a day. The company pays its electricity costs
|
||
by selling the bitcoin it is able to generate from mining, creating some
|
||
income from the profits.
|
||
|
||
=== Mining Transactions in Blocks
|
||
|
||
((("blocks", "mining transactions in")))New transactions are constantly
|
||
flowing into the network from user wallets and other applications. As
|
||
these are seen by the Bitcoin network nodes, they get added to a
|
||
temporary pool of unverified transactions maintained by each node. As
|
||
miners construct a new block, they add unverified transactions from this
|
||
pool to the new block and then attempt to prove the validity of that new
|
||
block, with the mining algorithm (Proof-of-Work). The process of mining
|
||
is explained in detail in <<mining>>.
|
||
|
||
Transactions are added to the new block, prioritized by the highest-fee
|
||
transactions first and a few other criteria. Each miner starts the
|
||
process of mining a new block of transactions as soon as he receives the
|
||
previous block from the network, knowing he has lost that previous round
|
||
of competition. He immediately creates a new block, fills it with
|
||
transactions and the fingerprint of the previous block, and starts
|
||
calculating the Proof-of-Work for the new block. Each miner includes a
|
||
special transaction in his block, one that pays his own Bitcoin address
|
||
the block reward (currently 12.5 newly created bitcoin) plus the sum of
|
||
transaction fees from all the transactions included in the block. If he
|
||
finds a solution that makes that block valid, he "wins" this reward
|
||
because his successful block is added to the global blockchain and the
|
||
reward transaction he included becomes spendable. ((("mining pools",
|
||
"operation of")))Jing, who participates in a mining pool, has set up his
|
||
software to create new blocks that assign the reward to a pool address.
|
||
From there, a share of the reward is distributed to Jing and other
|
||
miners in proportion to the amount of work they contributed in the last
|
||
round.
|
||
|
||
((("candidate blocks")))((("blocks", "candidate blocks")))Alice's
|
||
transaction was picked up by the network and included in the pool of
|
||
unverified transactions. Once validated by a full node, it was
|
||
included in a block template generated by Jing's
|
||
mining pool. All the miners participating in that mining pool
|
||
immediately start trying to generate a Proof-of-Work for the block template.
|
||
Approximately five minutes after the transaction was first transmitted
|
||
by Alice's wallet, one of Jing's ASIC miners found a solution for the
|
||
block and announced it to the network. After other miners
|
||
validated the winning block, they started a new lottery to generate the next
|
||
block.
|
||
|
||
Jing's winning block containing Alice's transaction became part of the
|
||
blockchain. The block containing Alice's transaction is counted as one
|
||
"confirmation" of that transaction. After the block containing Alice's
|
||
transaction has propagated through the network, creating an alternative
|
||
block with a different version of Alice's transaction (such as a
|
||
transaction that doesn't pay Bob) would require performing the same
|
||
amount of work as it will take all Bitcoin miners to create an entirely
|
||
new block. For the entire network to accept an alternative block, an
|
||
additional new block would need to be mined on top of the alternative.
|
||
|
||
That means miners have a choice. They can work with Alice on an
|
||
alternative version of the transaction where she pays Bob, perhaps with
|
||
Alice paying miners a share of the money she previously paid Bob. This
|
||
dishonest behavior will require they expend the effort required to
|
||
create two new blocks. Instead, miners who behave honestly can create a
|
||
single new block and and receive all of the fees from the transactions
|
||
they include in it, plus the block reward. Normally, the high cost of
|
||
dishonestly creating two blocks for a small additional payment is much
|
||
less profitable than honestly creating a new block, making it unlikely
|
||
that a confirmed transaction will be deliberately changed. For Bob, this
|
||
means that he can begin to believe that the payment from Alice can be
|
||
relied upon.
|
||
|
||
[TIP]
|
||
====
|
||
You can see the block that includes
|
||
https://blockstream.info/block/000000000000000000027d39da52dd790d98f85895b02e764611cb7acf552e90[Alice's transaction].
|
||
====
|
||
|
||
((("confirmations", "role in transactions")))Approximately 19 minutes
|
||
after Jing's block, a new block is mined by another miner. Because this
|
||
new block is built on top of the block that contained Alice's
|
||
transaction (giving Alice's transaction two confirmations) Alice's
|
||
transaction can now only be changed if two alternative blocks are
|
||
mined--plus a new block built on top of them--for a total of three
|
||
blocks that would need to be mined for Alice to take back the money she
|
||
sent Bob. Each block mined on top of the one containing Alice's
|
||
transaction counts as an additional confirmation. As the blocks pile on
|
||
top of each other, it becomes harder to reverse the transaction, thereby
|
||
giving Bob more and more confidence that Alice's payment is secure.
|
||
|
||
((("genesis block")))((("blocks", "genesis block")))((("blockchain
|
||
(the)", "genesis block")))In <<block-alice1>>, we can
|
||
the block which contains Alice's transaction. Below it are
|
||
hundreds of thousands of blocks, linked to each other in a chain of
|
||
blocks (blockchain) all the way back to block #0, known as the _genesis
|
||
block_. Over time, as the "height" of new blocks increases, so does the
|
||
computation difficulty for the chain as a whole.
|
||
By convention, any block with more than six confirmations
|
||
is considered very hard to change, because it would require an immense amount of
|
||
computation to recalculate six blocks (plus one new block). We will examine
|
||
the process of mining and the way it builds confidence in more detail in
|
||
<<mining>>.((("", startref="BToverview02")))((("",
|
||
startref="MACover02")))
|
||
|
||
[[block-alice1]]
|
||
.Alice's transaction included in a block
|
||
image::images/mbc2_0209.png["Alice's transaction included in a block"]
|
||
|
||
=== Spending the Transaction
|
||
|
||
((("spending bitcoin", "simple-payment-verification
|
||
(SPV)")))((("simple-payment-verification (SPV)")))Now that Alice's
|
||
transaction has been embedded in the blockchain as part of a block, it
|
||
is part of the distributed ledger of Bitcoin and visible to all Bitcoin
|
||
applications. Each bitcoin full node can independently verify the
|
||
transaction as valid and spendable. Full nodes validate every transfer
|
||
of the funds from the moment the bitcoin were first generated in
|
||
a block through each subsequent transaction until they reach
|
||
Bob's address. Lightweight clients can do what is called a simplified
|
||
payment verification (see <<spv_nodes>>) by confirming that the
|
||
transaction is in the blockchain and has several blocks mined after it,
|
||
thus providing assurance that the miners expended significant effort
|
||
committing to it.
|
||
|
||
Bob can now spend the output from this and other transactions. For
|
||
example, Bob can pay a contractor or supplier by transferring value from
|
||
Alice's podcast payment to these new owners. Bob's bitcoin
|
||
software might consolidate many small payments into a larger payment,
|
||
perhaps concentrating all the day's bitcoin revenue into a single
|
||
transaction. This would consolidate the various payments into a single
|
||
output (and a single address). For a diagram of a consolidation
|
||
transaction, see <<transaction-consolidating>>.
|
||
|
||
As Bob spends the payments received from Alice and other customers, he
|
||
extends the chain of transactions. Let's assume that Bob pays his web
|
||
designer Gopesh((("use cases", "offshore contract services"))) in
|
||
Bangalore for a new website page. Now the chain of transactions will
|
||
look like <<block-alice2>>.
|
||
|
||
[[block-alice2]]
|
||
.Alice's transaction as part of a transaction chain from Joe to Gopesh
|
||
image::images/mbc2_0210.png["Alice's transaction as part of a transaction chain"]
|
||
|
||
In this chapter, we saw how transactions build a chain that moves value
|
||
from owner to owner. We also tracked Alice's transaction, from the
|
||
moment it was created in her wallet, through the Bitcoin network and to
|
||
the miners who recorded it on the blockchain. In the rest of this book,
|
||
we will examine the specific technologies behind wallets, addresses,
|
||
signatures, transactions, the network, and finally mining.
|