sodium-native-android
v2.2.3
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Low level bindings for libsodium
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sodium-native
Low level bindings for libsodium.
npm install sodium-native
The goal of this project is to be thin, stable, unopionated wrapper around libsodium.
All methods exposed are more or less a direct translation of the libsodium c-api. This means that most data types are buffers and you have to manage allocating return values and passing them in as arguments intead of receiving them as return values.
This makes this API harder to use than other libsodium wrappers out there, but also means that you'll be able to get a lot of perf / memory improvements as you can do stuff like inline encryption / decryption, re-use buffers etc.
This also makes this library useful as a foundation for more high level crypto abstractions that you want to make.
Usage
var sodium = require('sodium-native')
var nonce = Buffer.alloc(sodium.crypto_secretbox_NONCEBYTES)
var key = sodium.sodium_malloc(sodium.crypto_secretbox_KEYBYTES) // secure buffer
var message = Buffer.from('Hello, World!')
var ciphertext = Buffer.alloc(message.length + sodium.crypto_secretbox_MACBYTES)
sodium.randombytes_buf(nonce) // insert random data into nonce
sodium.randombytes_buf(key) // insert random data into key
// encrypted message is stored in ciphertext.
sodium.crypto_secretbox_easy(ciphertext, message, nonce, key)
console.log('Encrypted message:', ciphertext)
var plainText = Buffer.alloc(ciphertext.length - sodium.crypto_secretbox_MACBYTES)
if (!sodium.crypto_secretbox_open_easy(plainText, ciphertext, nonce, key)) {
console.log('Decryption failed!')
} else {
console.log('Decrypted message:', plainText, '(' + plainText.toString() + ')')
}
API
Go to docs for the latest release (The following docs may be for a unreleased version)
var sodium = require('sodium-native')
Loads the bindings. If you get an module version error you probably need to reinstall the module because you switched node versions.
Memory Protection
Bindings to the secure memory API. See the libsodium "Securing memory allocations" docs for more information.
sodium.sodium_memzero(buffer)
Zero out the data in buffer
.
sodium.sodium_mlock(buffer)
Lock the memory contained in buffer
sodium.sodium_munlock(buffer)
Unlock previously sodium_mlock
ed memory contained in buffer
. This will also sodium_memzero
buffer
var buffer = sodium.sodium_malloc(size)
Allocate a buffer of size
which is memory protected. See libsodium docs for details. Be aware that many Buffer methods may break the security guarantees of sodium.sodium_malloc
'ed memory. To check if a Buffer
is a "secure" buffer,
you can call access the getter buffer.secure
which will be true
.
sodium.sodium_mprotect_noaccess(buffer)
Make buffer
allocated using sodium.sodium_malloc
inaccessible, crashing the process if any access is attempted.
Note that this will have no effect for normal Buffer
s.
sodium.sodium_mprotect_readonly(buffer)
Make buffer
allocated using sodium.sodium_malloc
read-only, crashing the process if any writing is attempted.
Note that this will have no effect for normal Buffer
s.
sodium.sodium_mprotect_readwrite(buffer)
Make buffer
allocated using sodium.sodium_malloc
read-write, undoing sodium_mprotect_noaccess
or sodium_mprotect_readonly
.
Note that this will have no effect for normal Buffer
s.
Generating random data
Bindings to the random data generation API. See the libsodium randombytes docs for more information.
var uint32 = sodium.randombytes_random()
Generate a random 32-bit unsigned integer [0, 0xffffffff]
(both inclusive)
var uint = sodium.randombytes_uniform(upper_bound)
Generate a random 32-bit unsigned integer [0, upper_bound)
(last exclusive).
upper_bound
must be 0xffffffff
at most.
sodium.randombytes_buf(buffer)
Fill buffer
with random data.
sodium.randombytes_buf_deterministic(buffer, seed)
Fill buffer
with random data, generated from seed
. seed
must be a Buffer
of at least sodium.randombytes_SEEDBYTES
length
Helpers
Bindings to various helper functions. See the libsodium padding docs for more information.
var bool = sodium.sodium_memcmp(b1, b2)
Compare b1
with b2
, in constant-time for b1.length
.
b1
must beBuffer
b2
must beBuffer
and must beb1.length
bytes
Returns true
when equal, otherwise false
.
var direction = sodium.sodium_compare(b1, b2)
Compare b1
with b2
, regarding either as little-endian encoded number.
b1
must beBuffer
b2
must beBuffer
and must beb1.length
bytes
Returns 1
, 0
or -1
on whether b1
is greater, equal or less than b2
.
This is the same scheme as Array.prototype.sort
expect.
sodium.sodium_add(a, b)
Adds b
to a
(wrapping), regarding either as little-endian encoded number,
and writing the result into a
.
a
must beBuffer
b
must beBuffer
and must bea.length
bytes
sodium.sodium_increment(buf)
Increment buf
as a little-endian number. This operation is constant-time
for the length of buf
.
buf
must beBuffer
var bool = sodium.sodium_is_zero(buf, len)
Test whether buf
is all zero for len
bytes. This operation is
constant-time for len
.
len
must be integer at most the length ofbuf
Returns true
if all len
bytes are zero, otherwise false
.
Padding
Bindings to the padding API. See the libsodium padding docs for more information.
var paddedLength = sodium.sodium_pad(buf, unpaddedLength, blocksize)
Pad buf
with random data from index unpaddedLength
up to closest multiple of
blocksize
.
buf
must beBuffer
unpadded_buflen
must be integer at mostbuf.length
blocksize
must be integer greater than 1 but at mostbuf.length
Returns the length of the padded data (so you may .slice
the buffer to here).
var unpaddedLength = sodium.sodium_unpad(buf, paddedLength, blocksize)
Calculate unpaddedLength
from a padded buf
with blocksize
buf
must beBuffer
padded_buflen
must be integer at mostbuf.length
blocksize
must be integer greater than 1 but at mostbuf.length
Returns the length of the unpadded data (so you may .slice
the buffer to here).
Signing
Bindings for the crypto_sign API. See the libsodium crypto_sign docs for more information.
crypto_sign_seed_keypair(publicKey, secretKey, seed)
Create a new keypair based on a seed.
publicKey
should be a buffer with lengthcrypto_sign_PUBLICKEYBYTES
.secretKey
should be a buffer with lengthcrypto_sign_SECRETKEYBYTES
.seed
should be a buffer with lengthcrypto_sign_SEEDBYTES
.
The generated public and secret key will be stored in passed in buffers.
crypto_sign_keypair(publicKey, secretKey)
Create a new keypair.
publicKey
should be a buffer with lengthcrypto_sign_PUBLICKEYBYTES
.secretKey
should be a buffer with lengthcrypto_sign_SECRETKEYBYTES
.
The generated public and secret key will be stored in passed in buffers.
crypto_sign(signedMessage, message, secretKey)
Sign a message.
signedMessage
should be a buffer with lengthcrypto_sign_BYTES + message.length
.message
should be a buffer of any length.secretKey
should be a secret key.
The generated signed message will be stored in signedMessage
.
var bool = crypto_sign_open(message, signedMessage, publicKey)
Verify and open a message.
message
should be a buffer with lengthsignedMessage.length - crypto_sign_BYTES
.signedMessage
at leastcrypto_sign_BYTES
length.publicKey
should be a public key.
Will return true
if the message could be verified. Otherwise false
.
If verified the originally signed message is stored in the message
buffer.
crypto_sign_detached(signature, message, secretKey)
Same as crypto_sign
except it only stores the signature.
signature
should be a buffer with lengthcrypto_sign_BYTES
.message
should be a buffer of any length.secretKey
should be a secret key.
The generated signature is stored in signature
.
var bool = crypto_sign_verify_detached(signature, message, publicKey)
Verify a signature.
signature
should be a buffer with lengthcrypto_sign_BYTES
.message
should be a buffer of any length.publicKey
should be a public key.
Will return true
if the message could be verified. Otherwise false
.
crypto_sign_ed25519_pk_to_curve25519(curve_pk, ed_pk)
convert a ed25519 public key to curve25519 (which can be used with box
and scalarmult
)
curve_pk
should be a buffer with lengthcrypto_box_PUBLICKEYBYTES
ed_pk
should be a buffer with lengthcrypto_sign_PUBLICKEYBYTES
crypto_sign_ed25519_sk_to_curve25519(curve_sk, ed_sk)
convert a ed25519 secret key to curve25519 (which can be used with box
and scalarmult
)
curve_sk
should be a buffer with lengthcrypto_box_SECRETKEYBYTES
ed_sk
should be a buffer with lengthcrypto_sign_SECRETKEYBYTES
Generic hashing
Bindings for the crypto_generichash API. See the libsodium crypto_generichash docs for more information.
crypto_generichash(output, input, [key])
Hash a value with an optional key using the generichash method.
output
should be a buffer with length withincrypto_generichash_BYTES_MIN
-crypto_generichash_BYTES_MAX
.input
should be a buffer of any length.key
is an optional buffer of length withincrypto_generichash_KEYBYTES_MIN
-crypto_generichash_KEYBYTES_MAX
.
The generated hash is stored in output
.
Also exposes crypto_generichash_BYTES
and crypto_generichash_KEYBYTES
that can be used as "default" buffer sizes.
crypto_generichash_batch(output, inputArray, [key])
Same as crypto_generichash
except this hashes an array of buffers instead of a single one.
var instance = crypto_generichash_instance([key], [outputLength])
Create a generichash instance that can hash a stream of input buffers.
key
is an optional buffer as above.outputLength
the buffer size of your output.
instance.update(input)
Update the instance with a new piece of data.
input
should be a buffer of any size.
instance.final(output)
Finalize the instance.
output
should be a buffer as above with the same length you gave when creating the instance.
The generated hash is stored in output
.
Public / secret key box encryption
Bindings for the crypto_box API. See the libsodium crypto_box docs for more information.
crypto_box_seed_keypair(publicKey, secretKey, seed)
Create a new keypair based on a seed.
publicKey
should be a buffer with lengthcrypto_box_PUBLICKEYBYTES
.secretKey
should be a buffer with lengthcrypto_box_SECRETKEYBYTES
.seed
should be a buffer with lengthcrypto_box_SEEDBYTES
.
The generated public and secret key will be stored in passed in buffers.
crypto_box_keypair(publicKey, secretKey)
Create a new keypair.
publicKey
should be a buffer with lengthcrypto_box_PUBLICKEYBYTES
.secretKey
should be a buffer with lengthcrypto_box_SECRETKEYBYTES
.
The generated public and secret key will be stored in passed in buffers.
crypto_box_detached(ciphertext, mac, message, nonce, publicKey, secretKey)
Encrypt a message.
ciphertext
should be a buffer with lengthmessage.length
.mac
should be a buffer with lengthcrypto_box_MACBYTES
.message
should be a buffer of any length.nonce
should be a buffer with lengthcrypto_box_NONCEBYTES
.publicKey
should be a public key.secretKey
should be a secret key.
The encrypted message will be stored in ciphertext
and the authentification code will be stored in mac
.
crypto_box_easy(ciphertext, message, nonce, publicKey, secretKey)
Same as crypto_box_detached
except it encodes the mac in the message.
ciphertext
should be a buffer with lengthmessage.length + crypto_box_MACBYTES
.message
should be a buffer of any length.nonce
should be a buffer with lengthcrypto_box_NONCEBYTES
.publicKey
should be a public key.secretKey
should be a secret key.
The encrypted message and authentification code will be stored in ciphertext
.
var bool = crypto_box_open_detached(message, ciphertext, mac, nonce, publicKey, secretKey)
Decrypt a message.
message
should be a buffer with lengthciphertext.length
.mac
should be a buffer with lengthcrypto_box_MACBYTES
.ciphertext
should be a buffer of any length.nonce
should be a buffer with lengthcrypto_box_NONCEBYTES
.publicKey
should be a public key.secretKey
should be a secret key.
Returns true
if the message could be decrypted. Otherwise false
.
The decrypted message will be stored in message
.
var bool = crypto_box_open_easy(message, ciphertext, nonce, publicKey, secretKey)
Decrypt a message encoded with the easy method.
message
should be a buffer with lengthciphertext.length - crypto_box_MACBYTES
.ciphertext
should be a buffer with length at leastcrypto_box_MACBYTES
.nonce
should be a buffer with lengthcrypto_box_NONCEBYTES
.publicKey
should be a public key.secretKey
should be a secret key.
Returns true
if the message could be decrypted. Otherwise false
.
The decrypted message will be stored in message
.
Sealed box encryption
Bindings for the crypto_box_seal API. See the libsodium crypto_box_seal docs for more information.
Keypairs can be generated with crypto_box_keypair()
or crypto_box_seed_keypair()
.
crypto_box_seal(ciphertext, message, publicKey)
Encrypt a message in a sealed box using a throwaway keypair. The ciphertext cannot be associated with the sender due to the sender's key being a single use keypair that is overwritten during encryption.
ciphertext
should be a buffer with length at leastmessage.length + crypto_box_SEALBYTES
.message
should be a buffer with any length.publicKey
should be the receipent's public key.
var bool = crypto_box_seal_open(message, ciphertext, publicKey, secretKey)
Decrypt a message encoded with the sealed box method.
message
should be a buffer with length at leastciphertext.length - crypto_box_SEALBYTES
.ciphertext
should be a buffer with length at leastcrypto_box_SEALBYTES
.publicKey
should be the receipient's public key.secretKey
should be the receipient's secret key.
Note: the keypair of the recipient is required here, both public and secret key.
This is because during encryption the recipient's public key is used to generate
the nonce. The throwaway public key generated by the sender is stored in the first
crypto_box_PUBLICKEYBYTE
's of the ciphertext.
Secret key box encryption
Bindings for the crypto_secretbox API. See the libsodium crypto_secretbox docs for more information.
crypto_secretbox_detached(ciphertext, mac, message, nonce, secretKey)
Encrypt a message.
ciphertext
should be a buffer with lengthmessage.length
.mac
should be a buffer with lengthcrypto_secretbox_MACBYTES
.message
should be a buffer of any length.nonce
should be a buffer with lengthcrypto_secretbox_NONCEBYTES
.secretKey
should be a secret key with legnthcrypto_secretbox_KEYBYTES
.
The encrypted message will be stored in ciphertext
and the authentification code will be stored in mac
.
crypto_secretbox_easy(ciphertext, message, nonce, secretKey)
Same as crypto_secretbox_detached
except it encodes the mac in the message.
ciphertext
should be a buffer with lengthmessage.length + crypto_secretbox_MACBYTES
.message
should be a buffer of any length.nonce
should be a buffer with lengthcrypto_secretbox_NONCEBYTES
.secretKey
should be a secret key with legnthcrypto_secretbox_KEYBYTES
.
var bool = crypto_secretbox_open_detached(message, ciphertext, mac, nonce, secretKey)
Decrypt a message.
message
should be a buffer with lengthciphertext.length
.mac
should be a buffer with lengthcrypto_secretbox_MACBYTES
.ciphertext
should be a buffer of any length.nonce
should be a buffer with lengthcrypto_secretbox_NONCEBYTES
.secretKey
should be a secret key.
Returns true
if the message could be decrypted. Otherwise false
.
The decrypted message will be stored in message
.
var bool = crypto_secretbox_open_easy(message, ciphertext, nonce, secretKey)
Decrypt a message encoded with the easy method.
message
should be a buffer with lengthciphertext.length - crypto_secretbox_MACBYTES
.ciphertext
should be a buffer with length at leastcrypto_secretbox_MACBYTES
.nonce
should be a buffer with lengthcrypto_secretbox_NONCEBYTES
.secretKey
should be a secret key.
Returns true
if the message could be decrypted. Otherwise false
.
The decrypted message will be stored in message
.
AEAD (Authenticated Encryption with Additional Data)
Bindings for the crypto_aead_* APIs. See the libsodium AEAD docs for more information.
Currently only crypto_aead_xchacha20poly1305_ietf
is exposed.
Constants
Buffer lengths (Integer)
crypto_aead_xchacha20poly1305_ietf_ABYTES
crypto_aead_xchacha20poly1305_ietf_KEYBYTES
crypto_aead_xchacha20poly1305_ietf_NPUBBYTES
crypto_aead_xchacha20poly1305_ietf_NSECBYTES
crypto_aead_xchacha20poly1305_ietf_MESSAGEBYTES_MAX
- Note this isNumber.MAX_SAFE_INTEGER
for now
crypto_aead_xchacha20poly1305_ietf_keygen(key)
Generate a new encryption key.
key
should be a buffer of lengthcrypto_aead_xchacha20poly1305_ietf_KEYBYTES
.
The generated key is stored in key
.
var clen = crypto_aead_xchacha20poly1305_ietf_encrypt(ciphertext, message, [ad], null, npub, key)
Encrypt a message with (npub
, key
) and optional additional data ad
.
ciphertext
should be aBuffer
of sizemessage.length + crypto_aead_xchacha20poly1305_ietf_ABYTES
.message
should be aBuffer
.ad
is optional and should benull
orBuffer
. Included in the computation of authentication tag appended to the message.null
is in the position of the unusednsec
argument. This should always benull
.npub
should beBuffer
of lengthcrypto_aead_xchacha20poly1305_ietf_NPUBBYTES
.key
should be aBuffer
of lengthcrypto_aead_xchacha20poly1305_ietf_KEYBYTES
.
Returns how many bytes were written to ciphertext
. Note that in-place
encryption is possible.
var mlen = crypto_aead_xchacha20poly1305_ietf_decrypt(message, null, ciphertext, [ad], npub, key)
Decrypt a message with (npub
, key
) and optional additional data ad
.
message
should be aBuffer
of sizeciphertext.length - crypto_aead_xchacha20poly1305_ietf_ABYTES
.null
is in the position of the unusednsec
argument. This should always benull
.ciphertext
should be aBuffer
.ad
is optional and should benull
orBuffer
. Included in the computation of authentication tag appended to the message.npub
should beBuffer
of lengthcrypto_aead_xchacha20poly1305_ietf_NPUBBYTES
.key
should be aBuffer
of lengthcrypto_aead_xchacha20poly1305_ietf_KEYBYTES
.
Returns how many bytes were written to message
. Note that in-place
encryption is possible.
var maclen = crypto_aead_xchacha20poly1305_ietf_encrypt_detached(ciphertext, mac, message, [ad], null, npub, key)
Encrypt a message with (npub
, key
) and optional additional data ad
.
ciphertext
should be aBuffer
of sizemessage.length
.mac
should beBuffer
of sizecrypto_aead_xchacha20poly1305_ietf_ABYTES
.message
should be aBuffer
.ad
is optional and should benull
orBuffer
. Included in the computation of authentication tag appended to the message.null
is in the position of the unusednsec
argument. This should always benull
.npub
should beBuffer
of lengthcrypto_aead_xchacha20poly1305_ietf_NPUBBYTES
.key
should be aBuffer
of lengthcrypto_aead_xchacha20poly1305_ietf_KEYBYTES
.
Returns how many bytes were written to mac
. Note that in-place
encryption is possible.
crypto_aead_xchacha20poly1305_ietf_decrypt_detached(message, null, ciphertext, mac, [ad], npub, key)
Decrypt a message with (npub
, key
) and optional additional data ad
.
message
should be aBuffer
of sizeciphertext.length
.null
is in the position of the unusednsec
argument. This should always benull
.ciphertext
should be aBuffer
.mac
should beBuffer
of sizecrypto_aead_xchacha20poly1305_ietf_ABYTES
.ad
is optional and should benull
orBuffer
. Included in the computation of authentication tag appended to the message.npub
should beBuffer
of lengthcrypto_aead_xchacha20poly1305_ietf_NPUBBYTES
.key
should be aBuffer
of lengthcrypto_aead_xchacha20poly1305_ietf_KEYBYTES
.
Returns nothing, but will throw on in case the MAC cannot be authenticated. Note that in-place encryption is possible.
Non-authenticated streaming encryption
Bindings for the crypto_stream API. See the libsodium crypto_stream docs for more information.
crypto_stream(ciphertext, nonce, key)
Generate random data based on a nonce and key into the ciphertext.
ciphertext
should be a buffer of any size.nonce
should be a buffer with lengthcrypto_stream_NONCEBYTES
.key
should be a secret key with lengthcrypto_stream_KEYBYTES
.
The generated data is stored in ciphertext
.
crypto_stream_xor(ciphertext, message, nonce, key)
or
crypto_stream_chacha20_xor(ciphertext, message, nonce, key)
Encrypt, but not authenticate, a message based on a nonce and key
ciphertext
should be a buffer with lengthmessage.length
.message
should be a buffer of any size.nonce
should be a buffer with lengthcrypto_stream_NONCEBYTES
.key
should be a secret key with lengthcrypto_stream_KEYBYTES
.
The encrypted data is stored in ciphertext
. To decrypt, swap ciphertext
and message
.
Also supports in-place encryption where you use the same buffer as ciphertext
and message
.
Encryption defaults to XSalsa20, use crypto_stream_chacha20_xor
if you want
to encrypt/decrypt with ChaCha20 instead.
var instance = crypto_stream_xor_instance(nonce, key)
or
var instance = crypto_stream_chacha20_xor_instance(nonce, key)
A streaming instance to the crypto_stream_xor
api. Pass a nonce and key in the constructor.
Encryption defaults to XSalsa20, use crypto_stream_chacha20_xor_instance
if
you want to encrypt/decrypt with ChaCha20 instead.
instance.update(ciphertext, message)
Encrypt the next message
instance.final()
Finalize the stream. Zeros out internal state.
Authentication
Bindings for the crypto_auth API. See the libsodium crypto_auth docs for more information.
crypto_auth(output, input, key)
Create an authentication token.
output
should be a buffer of lengthcrypto_auth_BYTES
.input
should be a buffer of any size.key
should be a buffer of lenghtcrypto_auth_KEYBYTES
.
The generated token is stored in output
.
var bool = crypto_auth_verify(output, input, key)
Verify a token.
output
should be a buffer of lengthcrypto_auth_BYTES
.input
should be a buffer of any size.key
should be a buffer of lenghtcrypto_auth_KEYBYTES
.
Returns true
if the token could be verified. Otherwise false
.
Stream encryption
Bindings for the crypto_secretstream API. See the libsodium crypto_secretstream docs for more information.
Constants
Buffer lengths (Integer)
crypto_secretstream_xchacha20poly1305_ABYTES
crypto_secretstream_xchacha20poly1305_HEADERBYTES
crypto_secretstream_xchacha20poly1305_KEYBYTES
crypto_secretstream_xchacha20poly1305_MESSAGEBYTES_MAX
crypto_secretstream_xchacha20poly1305_TAGBYTES
- NOTE: Unofficial constant
Message tags (Buffer
)
crypto_secretstream_xchacha20poly1305_TAG_MESSAGE
crypto_secretstream_xchacha20poly1305_TAG_PUSH
crypto_secretstream_xchacha20poly1305_TAG_REKEY
crypto_secretstream_xchacha20poly1305_TAG_FINAL
crypto_secretstream_xchacha20poly1305_keygen(key)
Generate a new encryption key.
key
should be a buffer of lengthcrypto_secretstream_xchacha20poly1305_KEYBYTES
.
The generated key is stored in key
.
var state = crypto_secretstream_xchacha20poly1305_state_new()
Create a new stream state. Returns an opaque object used in the next methods.
crypto_secretstream_xchacha20poly1305_init_push(state, header, key)
Initialise state
from the writer side with message header
and
encryption key key
. The header must be sent or stored with the stream.
The key must be exchanged securely with the receiving / reading side.
state
should be an opaque state object.header
should be a buffer of sizecrypto_secretstream_xchacha20poly1305_HEADERBYTES
.key
should be a buffer of lengthcrypto_secretstream_xchacha20poly1305_KEYBYTES
.
var mlen = crypto_secretstream_xchacha20poly1305_push(state, ciphertext, message, [ad], tag)
Encrypt a message with a certain tag and optional additional data ad
.
state
should be an opaque state object.ciphertext
should be a buffer of sizemessage.length + crypto_secretstream_xchacha20poly1305_ABYTES
.message
should be a buffer.ad
is optional and should benull
orBuffer
. Included in the computation of authentication tag appended to the message.tag
should beBuffer
of lengthcrypto_secretstream_xchacha20poly1305_TAGBYTES
Note that tag
should be one of the crypto_secretstream_xchacha20poly1305_TAG_*
constants.
Returns number of encrypted bytes written to ciphertext
.
crypto_secretstream_xchacha20poly1305_init_pull(state, header, key)
Initialise state
from the reader side with message header
and
encryption key key
. The header must be retrieved from somewhere.
The key must be exchanged securely with the sending / writing side.
state
should be an opaque state object.header
should be a buffer of sizecrypto_secretstream_xchacha20poly1305_HEADERBYTES
.key
should be a buffer of lengthcrypto_secretstream_xchacha20poly1305_KEYBYTES
.
var clen = crypto_secretstream_xchacha20poly1305_pull(state, message, tag, ciphertext, [ad])
Decrypt a message with optional additional data ad
, and write message tag to
tag
. Make sure to check this!
state
should be an opaque state object.message
should be a buffer of sizeciphertext.length - crypto_secretstream_xchacha20poly1305_ABYTES
.tag
should be a buffer ofcrypto_secretstream_xchacha20poly1305_TAGBYTES
.ad
is optional and should benull
orBuffer
. Included in the computation of the authentication tag appended to the message.
Note that tag
should be one of the crypto_secretstream_xchacha20poly1305_TAG_*
constants.
Returns number of decrypted bytes written to message
.
crypto_secretstream_xchacha20poly1305_rekey(state)
Rekey the opaque state
object.
One-time Authentication
Bindings for the crypto_onetimeauth API. See the libsodium crypto_onetimeauth docs for more information.
crypto_onetimeauth(output, input, key)
Create a authentication token based on a onetime key.
output
should be a buffer of lengthcrypto_onetimauth_BYTES
.input
should be a buffer of any size.key
should be a buffer of lenghtcrypto_onetimeauth_KEYBYTES
.
The generated token is stored in output
.
var bool = crypto_onetimeauth_verify(output, input, key)
Verify a token.
output
should be a buffer of lengthcrypto_onetimeauth_BYTES
.input
should be a buffer of any size.key
should be a buffer of lenghtcrypto_onetimeauth_KEYBYTES
.
Returns true
if the token could be verified. Otherwise false
.
var instance = crypto_onetimeauth_instance(key)
Create an instance that create a token from a onetime key and a stream of input data.
key
should be a buffer of lengthcrypto_onetimeauth_KEYBYTES
.
instance.update(input)
Update the instance with a new piece of data.
input
should be a buffer of any size.
instance.final(output)
Finalize the instance.
output
should be a buffer of lengthcrypto_onetimeauth_BYTES
.
The generated hash is stored in output
.
Password Hashing
Bindings for the crypto_pwhash API. See the libsodium crypto_pwhash docs for more information.
crypto_pwhash(output, password, salt, opslimit, memlimit, algorithm)
Create a password hash.
output
should be a buffer with length withincrypto_pwhash_BYTES_MIN
-crypto_pwhash_BYTES_MAX
.password
should be a buffer of any size.salt
should be a buffer with lengthcrypto_pwhash_SALTBYTES
.opslimit
should a be number containing your ops limit setting in the rangecrypto_pwhash_OPSLIMIT_MIN
-crypto_pwhash_OPSLIMIT_MAX
.memlimit
should a be number containing your mem limit setting in the rangecrypto_pwhash_MEMLIMIT_MIN
-crypto_pwhash_OPSLIMIT_MAX
.algorithm
should be a number specifying the algorithm you want to use.
Available default ops and mem limits are
crypto_pwhash_OPSLIMIT_INTERACTIVE
crypto_pwhash_OPSLIMIT_MODERATE
crypto_pwhash_OPSLIMIT_SENSITIVE
crypto_pwhash_MEMLIMIT_INTERACTIVE
crypto_pwhash_MEMLIMIT_MODERATE
crypto_pwhash_MEMLIMIT_SENSITIVE
The available algorithms are
crypto_pwhash_ALG_DEFAULT
crypto_pwhash_ALG_ARGON2ID13
crypto_pwhash_ALG_ARGON2I13
The generated hash will be stored in output
and the entire output
buffer will be used.
crypto_pwhash_str(output, password, opslimit, memlimit)
Create a password hash with a random salt.
output
should be a buffer with lengthcrypto_pwhash_STRBYTES
.password
should be a buffer of any size.opslimit
should a be number containing your ops limit setting in the rangecrypto_pwhash_OPSLIMIT_MIN
-crypto_pwhash_OPSLIMIT_MAX
.memlimit
should a be number containing your mem limit setting in the rangecrypto_pwhash_MEMLIMIT_MIN
-crypto_pwhash_OPSLIMIT_MAX
.
The generated hash, settings, salt, version and algorithm will be stored in output
and the entire output
buffer will be used.
var bool = crypto_pwhash_str_verify(str, password)
Verify a password hash generated with the above method.
str
should be a buffer with lengthcrypto_pwhash_STRBYTES
.password
should be a buffer of any size.
Returns true
if the hash could be verified with the settings contained in str
. Otherwise false
.
var bool = crypto_pwhash_str_needs_rehash(hash, opslimit, memlimit)
Check if a password hash needs rehash, either because the default algorithm changed, opslimit or memlimit increased or because the hash is malformed.
hash
should be a buffer with lengthcrypto_pwhash_STRBYTES
.opslimit
should a be number containing your ops limit setting in the rangecrypto_pwhash_OPSLIMIT_MIN
-crypto_pwhash_OPSLIMIT_MAX
.memlimit
should a be number containing your mem limit setting in the rangecrypto_pwhash_MEMLIMIT_MIN
-crypto_pwhash_OPSLIMIT_MAX
.
Returns true
if the hash should be rehashed the settings contained in str
.
Otherwise false
if it is still good.
crypto_pwhash_async(output, password, salt, opslimit, memlimit, algorithm, callback)
Just like crypto_pwhash
but will run password hashing on a seperate worker so it will not block the event loop. callback(err)
will receive any errors from the hashing but all argument errors will throw
. The resulting hash is written to output
. This function also supports async_hook
s as the type sodium-native:crypto_pwhash_async
crypto_pwhash_str_async(output, password, opslimit, memlimit, callback)
Just like crypto_pwhash_str
but will run password hashing on a seperate worker so it will not block the event loop. callback(err)
will receive any errors from the hashing but all argument errors will throw
. The resulting hash with parameters is written to output
. This function also supports async_hook
s as the type sodium-native:crypto_pwhash_str_async
crypto_pwhash_str_verify_async(str, password, callback)
Just like crypto_pwhash_str_verify
but will run password hashing on a seperate worker so it will not block the event loop. callback(err, bool)
will receive any errors from the hashing but all argument errors will throw
. If the verification succeeds bool
is true
, otherwise false
. Due to an issue with libsodium err
is currently never set. This function also supports async_hook
s as the type sodium-native:crypto_pwhash_str_verify_async
Key exchange
Bindings for the crypto_kx API. See the libsodium crypto_kx docs for more information.
crypto_kx_keypair(publicKey, secretKey)
Create a key exchange key pair.
publicKey
should be a buffer of lengthcrypto_kx_PUBLICKEYBYTES
.secretKey
should be a buffer of lengthcrypto_kx_SECRETKEYBYTES
.
crypto_kx_seed_keypair(publicKey, secretKey, seed)
Create a key exchange key pair based on a seed.
publicKey
should be a buffer of lengthcrypto_kx_PUBLICKEYBYTES
.secretKey
should be a buffer of lengthcrypto_kx_SECRETKEYBYTES
.seed
should be a buffer of lengthcrypto_kx_SEEDBYTES
crypto_kx_client_session_keys(rx, tx, clientPublicKey, clientSecretKey, serverPublicKey)
Generate a session receive and transmission key for a client. The public / secret keys should be generated using the key pair method above.
rx
should be a buffer of lengthcrypto_kx_SESSIONKEYBYTES
ornull
.tx
should be a buffer of lengthcrypto_kx_SESSIONKEYBYTES
ornull
.
You should use the rx
to decrypt incoming data and tx
to encrypt outgoing.
If you need to make a one-way or half-duplex channel you can give only one of
rx
or tx
.
crypto_kx_server_session_keys(rx, tx, serverPublicKey, serverSecretKey, clientPublicKey)
Generate a session receive and transmission key for a server. The public / secret keys should be generated using the key pair method above.
rx
should be a buffer of lengthcrypto_kx_SESSIONKEYBYTES
ornull
.tx
should be a buffer of lengthcrypto_kx_SESSIONKEYBYTES
ornull
.
You should use the rx
to decrypt incoming data and tx
to encrypt outgoing.
If you need to make a one-way or half-duplex channel you can give only one of
rx
or tx
.
Diffie-Hellman (Scalar multiplication)
Bindings for the crypto_scalarmult API. See the libsodium crypto_scalarmult docs for more information.
crypto_scalarmult_base(publicKey, secretKey)
Create a scalar multiplication public key based on a secret key
publicKey
should be a buffer of lengthcrypto_scalarmult_BYTES
.secretKey
should be a buffer of lengthcrypto_scalarmult_SCALARBYTES
.
The generated public key is stored in publicKey
.
crypto_scalarmult(sharedSecret, secretKey, remotePublicKey)
Derive a shared secret from a local secret key and a remote public key.
sharedSecret
shoudl be a buffer of lengthcrypto_scalarmult_BYTES
.secretKey
should be a buffer of lengthcrypto_scalarmult_SCALARBYTES
.remotePublicKey
should be a buffer of lengthcrypto_scalarmult_BYTES
.
The generated shared secret is stored in sharedSecret
.
Elliptic curve point aritmhetic
Bindings for the crypto_core_ed25519 and crypto_co_ed25519 API. See the libsodium crypto_core_ed25519 docs for more information.
Constants
crypto_scalarmult_ed25519_BYTES
crypto_scalarmult_ed25519_SCALARBYTES
crypto_core_ed25519_BYTES
crypto_core_ed25519_UNIFORMBYTES
var bool = crypto_core_ed25519_is_valid_point(p)
The crypto_core_ed25519_is_valid_point() function checks that p represents a point on the edwards25519 curve, in canonical form, on the main subgroup, and that the point doesn't have a small order.
p
must beBuffer
of at leastcrypto_core_ed25519_BYTES
bytes
Returns true
or false
crypto_core_ed25519_from_uniform(p, r)
Maps a crypto_core_ed25519_UNIFORMBYTES
bytes vector (usually the output of
a hash function) to a a valid curve point and stores its compressed
representation in p
.
The point is guaranteed to be on the main subgroup.
p
must beBuffer
of at leastcrypto_core_ed25519_BYTES
bytesr
must beBuffer
of at leastcrypto_core_ed25519_UNIFORMBYTES
bytes
crypto_scalarmult_ed25519(q, n, p)
Multiply point p
by scalar n
and store its compressed representation in q
.
q
must beBuffer
of at leastcrypto_scalarmult_ed25519_BYTES
bytesn
must beBuffer
of at leastcrypto_scalarmult_ed25519_SCALARBYTES
bytesp
must beBuffer
of at leastcrypto_scalarmult_ed25519_BYTES
bytes
Note this function will throw if n
is zero or p
is an invalid curve point.
crypto_scalarmult_ed25519_base(q, n)
Multiply the basepoint by scalar n
and store its compressed representation in
q
. Note that n
will be clamped.
q
must beBuffer
of at leastcrypto_scalarmult_ed25519_BYTES
bytesn
must beBuffer
of at leastcrypto_scalarmult_ed25519_SCALARBYTES
bytes
Note this function will throw if n
is zero
crypto_core_ed25519_add(r, p, q)
Add point q
to p
, storing the result to r
.
r
must beBuffer
of at leastcrypto_core_ed25519_BYTES
bytesp
must beBuffer
of at leastcrypto_core_ed25519_BYTES
bytesq
must beBuffer
of at leastcrypto_core_ed25519_BYTES
bytes
Will throw if p
, q
are not valid curve points
crypto_core_ed25519_sub(r, p, q)
Subtract point q
to p
, storing the result to r
.
r
must beBuffer
of at leastcrypto_core_ed25519_BYTES
bytesp
must beBuffer
of at leastcrypto_core_ed25519_BYTES
bytesq
must beBuffer
of at leastcrypto_core_ed25519_BYTES
bytes
Will throw if p
, q
are not valid curve points
Short hashes
Bindings for the crypto_shorthash API. See the libsodium crypto_shorthash docs for more information.
crypto_shorthash(output, input, key)
Hash a value to a short hash based on a key.
output
should be a buffer of lengthcrypto_shorthash_BYTES
.input
should be a buffer of any size.key
should be a buffer of lengthcrypto_shorthash_KEYBYTES
.
The generated short hash is stored in output
.
Key derivation
Bindings for the crypto_kdf API. See the libsodium crypto_kdf docs for more information.
crypto_kdf_keygen(key)
Generate a new master key.
key
should be a buffer of lengthcrypto_kdf_KEYBYTES
crypto_kdf_derive_from_key(subkey, subkeyId, context, key)
Derive a new key from a master key.
subkey
should be a buffer betweencrypto_kdf_BYTES_MIN
andcrypto_kdf_BYTES_MAX
.subkeyId
should be an integer.context
should be a buffer of lengthcrypto_kdf_CONTEXTBYTES
key
should by a buffer of lengthcrypto_kdf_KEYBYTES
SHA
crypto_hash_sha256(output, input)
Hash a value to a short hash based on a key.
output
should be a buffer of lengthcrypto_hash_sha256_BYTES
.input
should be a buffer of any size.
The generated short hash is stored in output
.
var instance = crypto_hash_sha256_instance()
Create an instance that has stream of input data to sha256.
instance.update(input)
Update the instance with a new piece of data.
input
should be a buffer of any size.
instance.final(output)
Finalize the instance.
output
should be a buffer of lengthcrypto_hash_sha256_BYTES
.
The generated hash is stored in output
.
crypto_hash_sha512(output, input)
Hash a value to a short hash based on a key.
output
should be a buffer of lengthcrypto_hash_sha512_BYTES
.input
should be a buffer of any size.
The generated short hash is stored in output
.
var instance = crypto_hash_sha512_instance()
Create an instance that has stream of input data to sha512.
instance.update(input)
Update the instance with a new piece of data.
input
should be a buffer of any size.
instance.final(output)
Finalize the instance.
output
should be a buffer of lengthcrypto_hash_sha512_BYTES
.
The generated hash is stored in output
.
License
MIT