163 lines
6.3 KiB
Plaintext
163 lines
6.3 KiB
Plaintext
_section: Security @<security>
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While security should be a concern for all developers, in the
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blockchain space developers must be additionally conscious of
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many areas which can be exploited.
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Once a problem has an economic incentives to exploit it, there
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is a much larger risk and with blockchain apps it can become
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quite valuable to attack.
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In addition to many of the other security issues app developers
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may have to worry about, there are a few additional vectors
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that JavaScript developers should be aware of.
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_subsection: Side-Channel Attacks
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A [Side-Channel Attack](link-wiki-side-channel-attack) occurs
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when something orthogonal to the implementation of the algorithm
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used can be exploited to learn more about secure or private
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information.
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_heading: Released Data (Strings, Uint8Arrays, Buffers)
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In JavaScript, memory may not be securely allocated, or more
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importantly securely released.
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[Historically](https://github.com/nodejs/node/issues/4660),
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``new Buffer(16)`` would re-use old memory that had been
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released. This would mean that code runnint later, may have
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access to data that was discarded.
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As an example of the dangers, imagine if you had used a Buffer
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to store a private key, signed data and then returned from the
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function, allowing the Buffer to be de-allocated. A future
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function may be able to request a new Buffer, which would still
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have that left-over private key, which it could then use to
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steal the funds from that account.
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There are also many debugging tools and systems designed to
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assist develoeprs inspect the memory contents of JavaScript
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programs. In these cases, any //private key// or //mnemonic//
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siiting in memory may be visible to other users on the system,
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or malicious scripts.
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_heading: Timing Attack
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Timing attacks allow a malicious user or script to determine
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private data through analysing how long an operation requires
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to execute.
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In JavaScript, //Garbage Collection// occurs periodically when the
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system determines it is required. Each JavaScript implementation
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is different, with a variety of strategies and and abilities.
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Most Garbage Collection requires "stopping the world", or pausing
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all code being executed while it runs. This adds a large delay
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to any code that was currently running.
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This can be exploited by attackers to "condition cause a delay".
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They will set up a scenario where the system is on the edge of
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needing to garbage collect, and call your code with two paths,
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a simple path and complex path. The simple path won't stir things
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up enough to cause a garbage collection, while the complex one
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will. By timing how long the code took to execute, they now know
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whether garbage collection occured and therefore whether the simple
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or complex path was taken.
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Advancced timing attacks are very difficult to mitigate in any
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garbage-collection-based language. Most libraries where this
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matters will hopefully mitigated this for you as much as possible,
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but it is still good to be aware of.
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_heading: General Concerns
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- [Cross-Site Scripting](link-wiki-xss)
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- [Cross-Site Request Forgery](link-wiki-csrf)
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- [Phishing](link-wiki-phishing)
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_subsection: Key Derivation Functions @<security--pbkdf>
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This is not specific to Ethereum, but is a useful technique
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to understand and has some implications on User Experience.
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Many people are concerned that encrypting and decrypting an
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Ethereum wallet is quite slow and can take quite some time.
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It is important to understand this is intentional and provides
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much stronger security.
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The algorithm usually used for this process is [scrypt](link-wiki-scrypt),
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which is a memory and CPU intensive algorithm which computes
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a key (fixed-length pseudo-random series of bytes) for a given
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password.
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_heading: Why does it take so long?
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The goal is to use as much CPU and memory as possible during
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this algorithm, so that a single computer can only compute a
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very small number of results for some fixed amount of time. To
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scale up an attack, the attacker requires additional computers,
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increasing the cost to [brute-force attack](link-wiki-bruteforce)
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to guess the password.
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For example, if a user knows their correct password, this process
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may take 10 seconds for them to unlock their own wallet and proceed.
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But since an attacker does not know the password, they must guess; and
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each guess also requires 10 seconds. So, if they wish to try guessing 1
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million passwords, their computer would be completely tied up for 10
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million seconds, or around 115 days.
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Without using an algorithm like this, a user would be able
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to log in instantly, however, 1 million passwords would only
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take a few seconds to attempt. Even secure passwords would
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likely be broken within a short period of time. There is no way
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the algorithm can be faster for a legitimate user without also
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being faster for an attacker.
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_heading: Mitigating the User Experience
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Rather than reducing the security (see below), a better practice is to make
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the user feel better about waiting. The Ethers encryption and decryption
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API allows the developer to incorporate a progress bar, by passing in a
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progress callback which will be periodically called with a number between
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0 and 1 indication percent completion.
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In general a progress bar makes the experience feel faster, as well as
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more comfortable since there is a clear indication how much (relative) time
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is remaining. Additionally, using language like //"decrypting..."// in
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a progress bar makes a user feel like there time is not being //needlessly//
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wasted.
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_heading: Work-Arounds (not recommended)
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There are ways to reduce the time required to decrypt an Ethereum JSON
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Wallet, but please keep in mind that doing so **discards nearly all security**
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on that wallet.
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The scrypt algorithm is designed to be tuned. The main purpose of this is
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to increase the difficulty as time goes on and computers get faster, but
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it can also be tuned down in situations where the security is less important.
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_code: @LANG<javascript>
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// Our wallet object
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const wallet = Wallet.createRandom();
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// The password to encrypt with
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const password = "password123";
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// WARNING: Doing this substantially reduces the security
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// of the wallet. This is highly NOT recommended.
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// We override the default scrypt.N value, which is used
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// to indicate the difficulty to crack this wallet.
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const json = wallet.encrypt(password, {
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scrypt: {
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// The number must be a power of 2 (default: 131072)
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N: 64
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}
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});
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