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# crypto-secret.cr
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[![Docs ](https://img.shields.io/badge/docs-available-brightgreen.svg )](https://didactic-drunk.github.io/crypto-secret.cr/main)
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Secrets hold sensitive information
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The Secret interface manages limited time access to a secret and securely erases the secret when no longer needed.
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Secret providers may implement additional protections via:
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* `#noaccess` , `#readonly` or `#readwrite`
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* Using [mprotect]() to control access
* Encrypting the data when not in use
* Deriving keys on demand from a HSM
* Preventing the Secret from entering swap ([mlock]())
* Preventing the Secret from entering core dumps
* Other
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## Installation
1. Add the dependency to your `shard.yml` :
```yaml
dependencies:
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crypto-secret:
github: didactic-drunk/crypto-secret
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```
2. Run `shards install`
## Usage
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#### Rules:
1. Secrets are only available within a readonly or readwrite block
2. Secrets are not thread safe except for the provided `Bytes` (only when reading) within a single readonly or readwrite block
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```crystal
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require "crypto-secret/not"
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# `Not` isn't actually a secret and does none of what the comments say
# Replace `Not` with a secure implementation like [Sodium::SecureBuffer](https://didactic-drunk.github.io/sodium.cr/master/Sodium/SecureBuffer.html)
secret = Crypto::Secret::Not.new 32
secret.wipe do
secret.readonly do |slice|
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# May only read slice
end
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secret.readwrite do |slice|
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# May read or write to slice
end
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end # secret is erased
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```
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#### Breaking the rules:
If you need thread safety :
1. Switch to a Stateless Secret
2. Or switch the Secret's state to readonly or readwrite after construction and never switch it again. [sodium.cr]() makes use of this technique to provide thread safe encryption/decryption
3. Or wrap all access in a Mutex
If you need more better performance:
* Consider 1. or 2.
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## What is a Secret?
< strike > Secrets are Keys< / strike >
That's complicated and specific to the application. Some examples:
* Passwords
* A crypto key is always a Secret. Except when used for verification (sometimes)
* A decrypted password vault (but it's not a Key)
Not secrets:
* Digest output. Except when used for key derivation, then it's a Secret, including the Digest state
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* IO::Memory or writing a file. Except when the file is a password vault, cryptocurrency wallet, encrypted mail/messages, goat porn, maybe "normal" porn, sometimes scat porn, occassionally furry, not vanilla porn
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## Why?
The Secret interface is designed to handle varied levels of confidentiality with a unified API for cryptography libraries.
There is no one size fits all solution. Different applications have different security requirements. Sometimes for the same algorithm.
A master key (kgk) may reside on a HSM and generate subkeys on demand.
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Or for most applications the master key may use a best effort approach using a combination of [guard pages, mlock, mprotect].
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Other keys in the same application may handle a high volume of messages where [guard pages, mlock, mprotect] overhead is too high.
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A key verifying a public key signature may not be Secret (but is a Secret::Not).
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## How do I use a Secret returned by a shard?
That depends on what you use it for.
#### Using a Secret key
TODO
#### Using a Secret to hold decrypted file contents:
```
key = ...another Secret...
encrypted_str = File.read("filename")
decrypted_size = encrypted_str.bytesize - mac_size
file_secret = Crypto::Secret::Default.new decrypted_size
file_secret.wipe do
file_secrets.readwrite do |slice|
decrypt(key: key, src: encrypted_str, dst: slice)
# Do something with file contents in slice
end
end # Decrypted data is erased
```
## When should I use a Secret?
When implementing an encryption class return `Secret` keys with a sane default implementation that suits the average use for your class. Several default implementations will be provided.
Allow overriding the default returned key and/or allow users of your class to provide their own `Secret` for cases where they need more or less protection.
Example:
```
class SimplifiedEncryption
# Allow users of your library to provide their own Secret key. Also provide a sane default.
def encrypt(data : Bytes | String, key : Secret? = nil) : {Secret, Bytes}
key ||= Crypto::Secret::Default.random
...
{key, encrypted_slice}
end
end
```
## What attacks does a Secret protect against?
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* Timing attacks when comparing secrets by overriding `==`
* Leaking data in to logs by overriding `inspect`
* Wiping memory when the secret is no longer in use
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TODO: describe implementations
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## Other languages/libraries
* rust: [secrets ](https://github.com/stouset/secrets/ )
* c: [libsodium ](https://github.com/jedisct1/libsodium-doc/blob/master/helpers/memory_management.md#guarded_heap_allocations )
* go: [memguard ](https://github.com/awnumar/memguard )
* haskell: [securemem ](https://hackage.haskell.org/package/securemem )
* c#: [SecureString ](https://docs.microsoft.com/en-us/dotnet/api/system.security.securestring )
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## Implementing a new Secret holding class
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**Only intended for use by crypto library authors**
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```
class MySecret
include Crypto::Secret
def initialize(size)
# allocate storage
# optionally mlock
end
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def to_slice(& : Bytes -> Nil)
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# The yielded Slice only needs to be valid within the block
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# yield Slice.new(pointer, size)
ensure
# optionally reencrypt or signal HSM
end
def bytesize : Int32
# return the size
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end
# optionally override [noaccess, readonly, readwrite]
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# optionally override (almost) any other method with an implementation specific version
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end
```
## Contributing
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**Open a discussion or issue before creating PR's**
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1. Fork it (< https: // github . com / your-github-user / crypto-secret / fork > )
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2. Create your feature branch (`git checkout -b my-new-feature`)
3. Commit your changes (`git commit -am 'Add some feature'`)
4. Push to the branch (`git push origin my-new-feature`)
5. Create a new Pull Request
## Contributors
- [didactic-drunk ](https://github.com/didactic-drunk ) - current maintainer