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crypto(3) Erlang Module Definition crypto(3)
NAME
crypto - Crypto Functions
DESCRIPTION
This module provides a set of cryptographic functions.
Hash functions:
SHA1, SHA2:
Secure Hash Standard [FIPS PUB 180-4]
SHA3:
SHA-3 Standard: Permutation-Based Hash and Extendable-Output
Functions [FIPS PUB 202]
BLAKE2:
BLAKE2 -- fast secure hashing
MD5:
The MD5 Message Digest Algorithm [RFC 1321]
MD4:
The MD4 Message Digest Algorithm [RFC 1320]
MACs - Message Authentication Codes:
Hmac functions:
Keyed-Hashing for Message Authentication [RFC 2104]
Cmac functions:
The AES-CMAC Algorithm [RFC 4493]
POLY1305:
ChaCha20 and Poly1305 for IETF Protocols [RFC 7539]
Symmetric Ciphers:
DES, 3DES and AES:
Block Cipher Techniques [NIST]
Blowfish:
Fast Software Encryption, Cambridge Security Workshop
Proceedings (December 1993), Springer-Verlag, 1994, pp. 191-204.
Chacha20:
ChaCha20 and Poly1305 for IETF Protocols [RFC 7539]
Chacha20_poly1305:
ChaCha20 and Poly1305 for IETF Protocols [RFC 7539]
Modes:
ECB, CBC, CFB, OFB and CTR:
CCM:
Recommendation for Block Cipher Modes of Operation: The CCM Mode
for Authentication and Confidentiality [NIST SP 800-38C]
Asymmetric Ciphers - Public Key Techniques:
RSA:
PKCS #1: RSA Cryptography Specifications [RFC 3447]
DSS:
Digital Signature Standard (DSS) [FIPS 186-4]
ECDSA:
Elliptic Curve Digital Signature Algorithm [ECDSA]
SRP:
The SRP Authentication and Key Exchange System [RFC 2945]
Note:
The actual supported algorithms and features depends on their
availability in the actual libcrypto used. See the crypto (App) about
dependencies.
Enabling FIPS mode will also disable algorithms and features.
The CRYPTO User's Guide has more information on FIPS, Engines and
Algorithm Details like key lengths.
DATA TYPES
Ciphers
cipher() = cipher_no_iv() | cipher_iv() | cipher_aead()
cipher_no_iv() =
aes_128_ecb | aes_192_ecb | aes_256_ecb | aes_ecb |
blowfish_ecb | des_ecb | rc4
cipher_iv() =
aes_128_cbc | aes_192_cbc | aes_256_cbc | aes_cbc |
aes_128_ofb | aes_192_ofb | aes_256_ofb | aes_128_cfb128 |
aes_192_cfb128 | aes_256_cfb128 | aes_cfb128 | aes_128_cfb8 |
aes_192_cfb8 | aes_256_cfb8 | aes_cfb8 | aes_128_ctr |
aes_192_ctr | aes_256_ctr | aes_ctr | blowfish_cbc |
blowfish_cfb64 | blowfish_ofb64 | chacha20 | des_ede3_cbc |
des_ede3_cfb | des_cbc | des_cfb | rc2_cbc
cipher_aead() =
aes_128_ccm | aes_192_ccm | aes_256_ccm | aes_ccm |
aes_128_gcm | aes_192_gcm | aes_256_gcm | aes_gcm |
chacha20_poly1305
Ciphers known by the CRYPTO application.
Note that this list might be reduced if the underlying libcrypto
does not support all of them.
crypto_opts() = boolean() | [crypto_opt()]
This option handles padding in the last block. If not set, no
padding is done and any bytes in the last unfilled block is
silently discarded.
cryptolib_padding() = none | pkcs_padding
The cryptolib_padding are paddings that may be present in the
underlying cryptolib linked to the Erlang/OTP crypto app.
For OpenSSL, see the OpenSSL documentation. and find
EVP_CIPHER_CTX_set_padding() in cryptolib for your linked
version.
otp_padding() = zero | random
Erlang/OTP adds a either padding of zeroes or padding with
random bytes.
Digests and hash
hash_algorithm() =
sha1() |
sha2() |
sha3() |
blake2() |
ripemd160 |
compatibility_only_hash()
hmac_hash_algorithm() =
sha1() | sha2() | sha3() | compatibility_only_hash()
cmac_cipher_algorithm() =
aes_128_cbc | aes_192_cbc | aes_256_cbc | aes_cbc |
aes_128_cfb128 | aes_192_cfb128 | aes_256_cfb128 |
aes_cfb128 | aes_128_cfb8 | aes_192_cfb8 | aes_256_cfb8 |
aes_cfb8 | blowfish_cbc | des_cbc | des_ede3_cbc | rc2_cbc
rsa_digest_type() = sha1() | sha2() | md5 | ripemd160
dss_digest_type() = sha1() | sha2()
ecdsa_digest_type() = sha1() | sha2()
sha1() = sha
sha2() = sha224 | sha256 | sha384 | sha512
sha3() = sha3_224 | sha3_256 | sha3_384 | sha3_512
blake2() = blake2b | blake2s
compatibility_only_hash() = md5 | md4
The compatibility_only_hash() algorithms are recommended only
for compatibility with existing applications.
Elliptic Curves
ec_named_curve() =
c2tnb191v3 | c2tnb239v1 | c2tnb239v2 | c2tnb239v3 |
c2tnb359v1 | c2tnb431r1 | ipsec3 | ipsec4 | prime192v1 |
prime192v2 | prime192v3 | prime239v1 | prime239v2 |
prime239v3 | prime256v1 | secp112r1 | secp112r2 | secp128r1 |
secp128r2 | secp160k1 | secp160r1 | secp160r2 | secp192k1 |
secp192r1 | secp224k1 | secp224r1 | secp256k1 | secp256r1 |
secp384r1 | secp521r1 | sect113r1 | sect113r2 | sect131r1 |
sect131r2 | sect163k1 | sect163r1 | sect163r2 | sect193r1 |
sect193r2 | sect233k1 | sect233r1 | sect239k1 | sect283k1 |
sect283r1 | sect409k1 | sect409r1 | sect571k1 | sect571r1 |
wtls1 | wtls10 | wtls11 | wtls12 | wtls3 | wtls4 | wtls5 |
wtls6 | wtls7 | wtls8 | wtls9
edwards_curve_dh() = x25519 | x448
edwards_curve_ed() = ed25519 | ed448
Note that some curves are disabled if FIPS is enabled.
ec_explicit_curve() =
{Field :: ec_field(),
Curve :: ec_curve(),
BasePoint :: binary(),
Order :: binary(),
CoFactor :: none | binary()}
ec_field() = ec_prime_field() | ec_characteristic_two_field()
ec_curve() =
{A :: binary(), B :: binary(), Seed :: none | binary()}
Parametric curve definition.
ec_prime_field() = {prime_field, Prime :: integer()}
ec_characteristic_two_field() =
{characteristic_two_field,
M :: integer(),
Basis :: ec_basis()}
ec_basis() =
{tpbasis, K :: integer() >= 0} |
{ppbasis,
K1 :: integer() >= 0,
K2 :: integer() >= 0,
K3 :: integer() >= 0} |
onbasis
Curve definition details.
Keys
key_integer() = integer() | binary()
Always binary() when used as return value
Public/Private Keys
rsa_public() = [key_integer()]
rsa_public() = [E, N]
rsa_private() = [E, N, D] | [E, N, D, P1, P2, E1, E2, C]
Where E is the public exponent, N is public modulus and D is the
private exponent. The longer key format contains redundant
information that will make the calculation faster. P1 and P2 are
first and second prime factors. E1 and E2 are first and second
exponents. C is the CRT coefficient. The terminology is taken
from RFC 3447.
dss_public() = [key_integer()]
dss_private() = [key_integer()]
dss_public() = [P, Q, G, Y]
Where P, Q and G are the dss parameters and Y is the public key.
dss_private() = [P, Q, G, X]
Where P, Q and G are the dss parameters and X is the private
key.
ecdsa_public() = key_integer()
ecdsa_private() = key_integer()
ecdsa_params() = ec_named_curve() | ec_explicit_curve()
eddsa_public() = key_integer()
eddsa_private() = key_integer()
eddsa_params() = edwards_curve_ed()
srp_public() = key_integer()
srp_private() = key_integer()
srp_public() = key_integer()
Where is A or B from SRP design
srp_private() = key_integer()
Where is a or b from SRP design
srp_gen_params() =
{user, srp_user_gen_params()} | {host, srp_host_gen_params()}
srp_comp_params() =
{user, srp_user_comp_params()} |
{host, srp_host_comp_params()}
srp_user_gen_params() = [DerivedKey::binary(), Prime::binary(), Generator::binary(), Version::atom()]
srp_host_gen_params() = [Verifier::binary(), Prime::binary(), Version::atom() ]
Public Key Ciphers
pk_encrypt_decrypt_algs() = rsa
Algorithms for public key encrypt/decrypt. Only RSA is
supported.
pk_encrypt_decrypt_opts() = [rsa_opt()] | rsa_compat_opts()
rsa_opt() =
{rsa_padding, rsa_padding()} |
{signature_md, atom()} |
{rsa_mgf1_md, sha} |
{rsa_oaep_label, binary()} |
{rsa_oaep_md, sha}
rsa_padding() =
rsa_pkcs1_padding | rsa_pkcs1_oaep_padding |
rsa_sslv23_padding | rsa_x931_padding | rsa_no_padding
Options for public key encrypt/decrypt. Only RSA is supported.
Warning:
The RSA options are experimental.
The exact set of options and there syntax may be changed without
prior notice.
rsa_compat_opts() = [{rsa_pad, rsa_padding()}] | rsa_padding()
Those option forms are kept only for compatibility and should
not be used in new code.
Public Key Sign and Verify
pk_sign_verify_algs() = rsa | dss | ecdsa | eddsa
Algorithms for sign and verify.
pk_sign_verify_opts() = [rsa_sign_verify_opt()]
rsa_sign_verify_opt() =
{rsa_padding, rsa_sign_verify_padding()} |
{rsa_pss_saltlen, integer()} |
{rsa_mgf1_md, sha2()}
rsa_sign_verify_padding() =
rsa_pkcs1_padding | rsa_pkcs1_pss_padding | rsa_x931_padding |
rsa_no_padding
Options for sign and verify.
Warning:
The RSA options are experimental.
The exact set of options and there syntax may be changed without
prior notice.
dh_params() = [key_integer()]
dh_params() = [P, G] | [P, G, PrivateKeyBitLength]
ecdh_public() = key_integer()
ecdh_private() = key_integer()
ecdh_params() =
ec_named_curve() | edwards_curve_dh() | ec_explicit_curve()
Types for Engines
engine_key_ref() =
#{engine := engine_ref(),
key_id := key_id(),
password => password(),
term() => term()}
engine_ref() = term()
The result of a call to engine_load/3.
key_id() = string() | binary()
Identifies the key to be used. The format depends on the loaded
engine. It is passed to the ENGINE_load_(private|public)_key
functions in libcrypto.
password() = string() | binary()
The password of the key stored in an engine.
engine_method_type() =
engine_method_rsa | engine_method_dsa | engine_method_dh |
engine_method_rand | engine_method_ecdh |
engine_method_ecdsa | engine_method_ciphers |
engine_method_digests | engine_method_store |
engine_method_pkey_meths | engine_method_pkey_asn1_meths |
engine_method_ec
engine_cmnd() = {unicode:chardata(), unicode:chardata()}
Pre and Post commands for engine_load/3 and /4.
Internal data types
crypto_state()
hash_state()
mac_state()
Contexts with an internal state that should not be manipulated
but passed between function calls.
EXCEPTIONS
Atoms - the older style
For a list of supported algorithms, see supports(ciphers).
3-tuples - the new style
The exception is:
error:{Tag, C_FileInfo, Description}
Tag = badarg | notsup | error
C_FileInfo = term() % Usually only useful for the OTP maintainer
Description = string() % Clear text, sometimes only useful for the OTP maintainer
The exception tags are:
badarg:
Signifies that one or more arguments are of wrong data type or are
otherwise badly formed.
notsup:
Signifies that the algorithm is known but is not supported by
current underlying libcrypto or explicitly disabled when building
that one.
error:
An error condition that should not occur, for example a memory
allocation failed or the underlying cryptolib returned an error
code, for example "Can't initialize context, step 1". Those text
usually needs searching the C-code to be understood.
Usually there are more information in the call stack about which
argument caused the exception and what the values where.
To catch the exception, use for example:
try crypto:crypto_init(Ciph, Key, IV, true)
catch
error:{Tag, _C_FileInfo, Description} ->
do_something(......)
.....
end
EXPORTS
crypto_init(Cipher, Key, FlagOrOptions) -> State
Types:
Cipher = cipher_no_iv()
Key = iodata()
FlagOrOptions = crypto_opts() | boolean()
State = crypto_state()
Uses the 3-tuple style for error handling.
Equivalent to the call crypto_init(Cipher, Key, <<>>,
FlagOrOptions). It is intended for ciphers without an IV
Cipher = cipher_iv()
Key = IV = iodata()
FlagOrOptions = crypto_opts()
State = crypto_state()
Uses the 3-tuple style for error handling.
Initializes a series of encryptions or decryptions and creates
an internal state with a reference that is returned.
If IV = <<>>, no IV is used. This is intended for ciphers
without an IV (nounce). See crypto_init/3.
If IV = undefined, the IV must be added by calls to
crypto_dyn_iv_update/3. This is intended for cases where the IV
(nounce) need to be changed for each encryption and decryption.
See crypto_dyn_iv_init/3.
The actual encryption or decryption is done by crypto_update/2
(or crypto_dyn_iv_update/3 ).
For encryption, set the FlagOrOptions to true or
[{encrypt,true}]. For decryption, set it to false or
[{encrypt,false}].
Padding could be enabled with the option {padding,Padding}. The
cryptolib_padding enables pkcs_padding or no padding (none). The
paddings zero or random fills the last part of the last block
with zeroes or random bytes. If the last block is already full,
nothing is added.
In decryption, the cryptolib_padding removes such padding, if
present. The otp_padding is not removed - it has to be done
elsewhere.
If padding is {padding,none} or not specified and the total data
from all subsequent crypto_updates does not fill the last block
fully, that last data is lost. In case of {padding,none} there
will be an error in this case. If padding is not specified, the
bytes of the unfilled block is silently discarded.
The actual padding is performed by crypto_final/1.
For blocksizes call cipher_info/1.
See examples in the User's Guide.
crypto_update(State, Data) -> Result
Types:
State = crypto_state()
Data = iodata()
Result = binary()
Uses the 3-tuple style for error handling.
It does an actual crypto operation on a part of the full text.
crypto_dyn_iv_init(Cipher, Key, FlagOrOptions) -> State
Types:
Cipher = cipher_iv()
Key = iodata()
FlagOrOptions = crypto_opts() | boolean()
State = crypto_state()
Uses the 3-tuple style for error handling.
Initializes a series of encryptions or decryptions where the IV
is provided later. The actual encryption or decryption is done
by crypto_dyn_iv_update/3.
The function is equivalent to crypto_init(Cipher, Key,
undefined, FlagOrOptions).
crypto_final(State) -> FinalResult
Types:
State = crypto_state()
FinalResult = binary()
Uses the 3-tuple style for error handling.
Finalizes a series of encryptions or decryptions and delivers
the final bytes of the final block. The data returned from this
function may be empty if no padding was enabled in
crypto_init/3,4 or crypto_dyn_iv_init/3.
crypto_get_data(State) -> Result
Types:
State = crypto_state()
Result = map()
Uses the 3-tuple style for error handling.
Returns information about the State in the argument. The
information is the form of a map, which currently contains at
least:
size:
The number of bytes encrypted or decrypted so far.
padding_size:
After a call to crypto_final/1 it contains the number of
bytes padded. Otherwise 0.
padding_type:
The type of the padding as provided in the call to
crypto_init/3,4.
State = crypto_state()
Data = IV = iodata()
Result = binary()
Uses the 3-tuple style for error handling.
Do an actual crypto operation on a part of the full text and the
IV is supplied for each part. The State should be created with
crypto_dyn_iv_init/3.
crypto_one_time(Cipher, Key, Data, FlagOrOptions) -> Result
Types:
Cipher = cipher_no_iv()
Key = Data = iodata()
FlagOrOptions = crypto_opts() | boolean()
Result = binary()
Uses the 3-tuple style for error handling.
As crypto_one_time/5 but for ciphers without IVs.
crypto_one_time(Cipher, Key, IV, Data, FlagOrOptions) -> Result
Types:
Cipher = cipher_iv()
Key = IV = Data = iodata()
FlagOrOptions = crypto_opts() | boolean()
Result = binary()
Uses the 3-tuple style for error handling.
Do a complete encrypt or decrypt of the full text in the
argument Data.
For encryption, set the FlagOrOptions to true. For decryption,
set it to false. For setting other options, see crypto_init/4.
See examples in the User's Guide.
crypto_one_time_aead(Cipher, Key, IV, InText, AAD,
EncFlag :: true) ->
Result
crypto_one_time_aead(Cipher, Key, IV, InText, AAD, TagOrTagLength,
EncFlag) ->
Result
Types:
Cipher = cipher_aead()
Key = IV = InText = AAD = iodata()
TagOrTagLength = EncryptTagLength | DecryptTag
Uses the 3-tuple style for error handling.
Do a complete encrypt or decrypt with an AEAD cipher of the full
text.
For encryption, set the EncryptFlag to true and set the
TagOrTagLength to the wanted size (in bytes) of the tag, that
is, the tag length. If the default length is wanted, the
crypto_aead/6 form may be used.
For decryption, set the EncryptFlag to false and put the tag to
be checked in the argument TagOrTagLength.
See examples in the User's Guide.
supports(Type) -> Support
Types:
Type = hashs | ciphers | public_keys | macs | curves |
rsa_opts
Support = Hashs | Ciphers | PKs | Macs | Curves | RSAopts
Hashs =
[sha1() |
sha2() |
sha3() |
blake2() |
ripemd160 |
compatibility_only_hash()]
Ciphers = [cipher()]
PKs = [rsa | dss | ecdsa | dh | ecdh | eddh | ec_gf2m]
Macs = [hmac | cmac | poly1305]
Curves =
[ec_named_curve() | edwards_curve_dh() |
edwards_curve_ed()]
RSAopts = [rsa_sign_verify_opt() | rsa_opt()]
Can be used to determine which crypto algorithms that are
supported by the underlying libcrypto library
See hash_info/1 and cipher_info/1 for information about the hash
and cipher algorithms.
mac(Type :: poly1305, Key, Data) -> Mac
Types:
Key = Data = iodata()
Mac = binary()
Uses the 3-tuple style for error handling.
Short for mac(Type, undefined, Key, Data).
mac(Type, SubType, Key, Data) -> Mac
Key = Data = iodata()
Mac = binary()
Uses the 3-tuple style for error handling.
Computes a MAC (Message Authentication Code) of type Type from
Data.
SubType depends on the MAC Type:
* For hmac it is a hash algorithm, see Algorithm Details in
the User's Guide.
* For cmac it is a cipher suitable for cmac, see Algorithm
Details in the User's Guide.
* For poly1305 it should be set to undefined or the mac/2
function could be used instead, see Algorithm Details in the
User's Guide.
Key is the authentication key with a length according to the
Type and SubType. The key length could be found with the
hash_info/1 (hmac) for and cipher_info/1 (cmac) functions. For
poly1305 the key length is 32 bytes. Note that the cryptographic
quality of the key is not checked.
The Mac result will have a default length depending on the Type
and SubType. To set a shorter length, use macN/4 or macN/5
instead. The default length is documented in Algorithm Details
in the User's Guide.
macN(Type :: poly1305, Key, Data, MacLength) -> Mac
Types:
Key = Data = iodata()
Mac = binary()
MacLength = integer() >= 1
Uses the 3-tuple style for error handling.
Short for macN(Type, undefined, Key, Data, MacLength).
macN(Type, SubType, Key, Data, MacLength) -> Mac
Types:
Type = hmac | cmac | poly1305
SubType =
hmac_hash_algorithm() | cmac_cipher_algorithm() |
undefined
Key = Data = iodata()
Mac = binary()
MacLength = integer() >= 1
Computes a MAC (Message Authentication Code) as mac/3 and mac/4
but MacLength will limit the size of the resultant Mac to at
mac_init(Type :: poly1305, Key) -> State
Types:
Key = iodata()
State = mac_state()
Uses the 3-tuple style for error handling.
Short for mac_init(Type, undefined, Key).
mac_init(Type, SubType, Key) -> State
Types:
Type = hmac | cmac | poly1305
SubType =
hmac_hash_algorithm() | cmac_cipher_algorithm() |
undefined
Key = iodata()
State = mac_state()
Uses the 3-tuple style for error handling.
Initializes the context for streaming MAC operations.
Type determines which mac algorithm to use in the MAC operation.
SubType depends on the MAC Type:
* For hmac it is a hash algorithm, see Algorithm Details in
the User's Guide.
* For cmac it is a cipher suitable for cmac, see Algorithm
Details in the User's Guide.
* For poly1305 it should be set to undefined or the mac/2
function could be used instead, see Algorithm Details in the
User's Guide.
Key is the authentication key with a length according to the
Type and SubType. The key length could be found with the
hash_info/1 (hmac) for and cipher_info/1 (cmac) functions. For
poly1305 the key length is 32 bytes. Note that the cryptographic
quality of the key is not checked.
The returned State should be used in one or more subsequent
calls to mac_update/2. The MAC value is finally returned by
calling mac_final/1 or mac_finalN/2.
See examples in the User's Guide.
mac_update(State0, Data) -> State
Types:
The State0 is the State value originally from a MAC init
function, that is mac_init/2, mac_init/3 or a previous call of
mac_update/2. The value State0 is returned unchanged by the
function as State.
mac_final(State) -> Mac
Types:
State = mac_state()
Mac = binary()
Uses the 3-tuple style for error handling.
Finalizes the MAC operation referenced by State. The Mac result
will have a default length depending on the Type and SubType in
the mac_init/2,3 call. To set a shorter length, use mac_finalN/2
instead. The default length is documented in Algorithm Details
in the User's Guide.
mac_finalN(State, MacLength) -> Mac
Types:
State = mac_state()
MacLength = integer() >= 1
Mac = binary()
Uses the 3-tuple style for error handling.
Finalizes the MAC operation referenced by State.
Mac will be a binary with at most MacLength bytes. Note that if
MacLength is greater than the actual number of bytes returned
from the underlying hash, the returned hash will have that
shorter length instead.
The max MacLength is documented in Algorithm Details in the
User's Guide.
bytes_to_integer(Bin :: binary()) -> integer()
Convert binary representation, of an integer, to an Erlang
integer.
compute_key(Type, OthersPublicKey, MyPrivateKey, Params) ->
SharedSecret
Types:
Type = dh | ecdh | eddh | srp
SharedSecret = binary()
OthersPublicKey = dh_public() | ecdh_public() | srp_public()
MyPrivateKey =
party's public key. See also public_key:compute_key/2
exor(Bin1 :: iodata(), Bin2 :: iodata()) -> binary()
Performs bit-wise XOR (exclusive or) on the data supplied.
generate_key(Type, Params) -> {PublicKey, PrivKeyOut}
generate_key(Type, Params, PrivKeyIn) -> {PublicKey, PrivKeyOut}
Types:
Type = dh | ecdh | eddh | eddsa | rsa | srp
PublicKey =
dh_public() | ecdh_public() | rsa_public() | srp_public()
PrivKeyIn =
undefined |
dh_private() |
ecdh_private() |
rsa_private() |
{srp_public(), srp_private()}
PrivKeyOut =
dh_private() |
ecdh_private() |
rsa_private() |
{srp_public(), srp_private()}
Params =
dh_params() |
ecdh_params() |
eddsa_params() |
rsa_params() |
srp_comp_params()
Uses the 3-tuple style for error handling.
Generates a public key of type Type. See also
public_key:generate_key/1.
Note:
If the linked version of cryptolib is OpenSSL 3.0
* and the Type is dh (diffie-hellman)
* and the parameter P (in dh_params()) is one of the MODP
groups (see RFC 3526)
* and the optional PrivateKeyBitLength parameter (in
dh_params()) is present,
then the optional key length parameter must be at least 224,
256, 302, 352 and 400 for group sizes of 2048, 3072, 4096, 6144
and 8192, respectively.
Note:
RSA key generation is only available if the runtime was built
with dirty scheduler support. Otherwise, attempting to generate
an RSA key will raise the exception error:notsup.
Data = iodata()
Digest = binary()
Uses the 3-tuple style for error handling.
Computes a message digest of type Type from Data.
hash_init(Type) -> State
Types:
Type = hash_algorithm()
State = hash_state()
Uses the 3-tuple style for error handling.
Initializes the context for streaming hash operations. Type
determines which digest to use. The returned context should be
used as argument to hash_update.
hash_update(State, Data) -> NewState
Types:
State = NewState = hash_state()
Data = iodata()
Uses the 3-tuple style for error handling.
Updates the digest represented by Context using the given Data.
Context must have been generated using hash_init or a previous
call to this function. Data can be any length. NewContext must
be passed into the next call to hash_update or hash_final.
hash_final(State) -> Digest
Types:
State = hash_state()
Digest = binary()
Uses the 3-tuple style for error handling.
Finalizes the hash operation referenced by Context returned from
a previous call to hash_update. The size of Digest is determined
by the type of hash function used to generate it.
info_fips() -> not_supported | not_enabled | enabled
Provides information about the FIPS operating status of crypto
and the underlying libcrypto library. If crypto was built with
FIPS support this can be either enabled (when running in FIPS
mode) or not_enabled. For other builds this value is always
not_supported.
enable_fips_mode(Enable) -> Result
Types:
Enable = Result = boolean()
Enables (Enable = true) or disables (Enable = false) FIPS mode.
Returns true if the operation was successful or false otherwise.
Note that to enable FIPS mode successfully, OTP must be built
with the configure option --enable-fips, and the underlying
libcrypto must also support FIPS.
See also info_fips/0.
info() ->
#{compile_type := normal | debug | valgrind | asan,
cryptolib_version_compiled => string() | undefined,
cryptolib_version_linked := string(),
link_type := dynamic | static,
otp_crypto_version := string()}
Provides a map with information about the compilation and
linking of crypto.
Example:
1> crypto:info().
#{compile_type => normal,
cryptolib_version_compiled => "OpenSSL 3.0.0 7 sep 2021",
cryptolib_version_linked => "OpenSSL 3.0.0 7 sep 2021",
link_type => dynamic,
otp_crypto_version => "5.0.2"}
2>
More association types than documented may be present in the
map.
info_lib() -> [{Name, VerNum, VerStr}]
Types:
Name = binary()
VerNum = integer()
VerStr = binary()
Provides the name and version of the libraries used by crypto.
Name is the name of the library. VerNum is the numeric version
according to the library's own versioning scheme. VerStr
contains a text variant of the version.
> info_lib().
taken from the library.
hash_info(Type) -> Result
Types:
Type = hash_algorithm()
Result =
#{size := integer(),
block_size := integer(),
type := integer()}
Provides a map with information about block_size, size and
possibly other properties of the hash algorithm in question.
For a list of supported hash algorithms, see supports(hashs).
cipher_info(Type) -> Result
Types:
Type = cipher()
Result =
#{key_length := integer(),
iv_length := integer(),
block_size := integer(),
mode := CipherModes,
type := undefined | integer(),
prop_aead := boolean()}
CipherModes =
undefined | cbc_mode | ccm_mode | cfb_mode | ctr_mode |
ecb_mode | gcm_mode | ige_mode | ocb_mode | ofb_mode |
wrap_mode | xts_mode
Provides a map with information about block_size, key_length,
iv_length, aead support and possibly other properties of the
cipher algorithm in question.
Note:
The ciphers aes_cbc, aes_cfb8, aes_cfb128, aes_ctr, aes_ecb,
aes_gcm and aes_ccm has no keylength in the Type as opposed to
for example aes_128_ctr. They adapt to the length of the key
provided in the encrypt and decrypt function. Therefore it is
impossible to return a valid keylength in the map.
Always use a Type with an explicit key length,
For a list of supported cipher algorithms, see
supports(ciphers).
mod_pow(N, P, M) -> Result
Types:
N = P = M = binary() | integer()
Types:
Algorithm = pk_encrypt_decrypt_algs()
CipherText = binary()
PrivateKey = rsa_private() | engine_key_ref()
Options = pk_encrypt_decrypt_opts()
PlainText = binary()
Uses the 3-tuple style for error handling.
Decrypts the CipherText, encrypted with public_encrypt/4 (or
equivalent function) using the PrivateKey, and returns the
plaintext (message digest). This is a low level signature
verification operation used for instance by older versions of
the SSL protocol. See also public_key:decrypt_private/[2,3]
private_encrypt(Algorithm, PlainText, PrivateKey, Options) ->
CipherText
Types:
Algorithm = pk_encrypt_decrypt_algs()
PlainText = binary()
PrivateKey = rsa_private() | engine_key_ref()
Options = pk_encrypt_decrypt_opts()
CipherText = binary()
Uses the 3-tuple style for error handling.
Encrypts the PlainText using the PrivateKey and returns the
ciphertext. This is a low level signature operation used for
instance by older versions of the SSL protocol. See also
public_key:encrypt_private/[2,3]
public_decrypt(Algorithm, CipherText, PublicKey, Options) ->
PlainText
Types:
Algorithm = pk_encrypt_decrypt_algs()
CipherText = binary()
PublicKey = rsa_public() | engine_key_ref()
Options = pk_encrypt_decrypt_opts()
PlainText = binary()
Uses the 3-tuple style for error handling.
Decrypts the CipherText, encrypted with private_encrypt/4(or
equivalent function) using the PrivateKey, and returns the
plaintext (message digest). This is a low level signature
verification operation used for instance by older versions of
the SSL protocol. See also public_key:decrypt_public/[2,3]
public_encrypt(Algorithm, PlainText, PublicKey, Options) ->
CipherText
CipherText = binary()
Uses the 3-tuple style for error handling.
Encrypts the PlainText (message digest) using the PublicKey and
returns the CipherText. This is a low level signature operation
used for instance by older versions of the SSL protocol. See
also public_key:encrypt_public/[2,3]
rand_seed(Seed :: binary()) -> ok
Set the seed for PRNG to the given binary. This calls the
RAND_seed function from openssl. Only use this if the system you
are running on does not have enough "randomness" built in.
Normally this is when strong_rand_bytes/1 raises
error:low_entropy
rand_uniform(Lo, Hi) -> N
Types:
Lo, Hi, N = integer()
Generate a random number N, Lo =< N < Hi. Uses the crypto
library pseudo-random number generator. Hi must be larger than
Lo.
start() -> ok | {error, Reason :: term()}
Equivalent to application:start(crypto).
stop() -> ok | {error, Reason :: term()}
Equivalent to application:stop(crypto).
strong_rand_bytes(N :: integer() >= 0) -> binary()
Generates N bytes randomly uniform 0..255, and returns the
result in a binary. Uses a cryptographically secure prng seeded
and periodically mixed with operating system provided entropy.
By default this is the RAND_bytes method from OpenSSL.
May raise exception error:low_entropy in case the random
generator failed due to lack of secure "randomness".
rand_seed() -> rand:state()
Creates state object for random number generation, in order to
generate cryptographically strong random numbers (based on
OpenSSL's BN_rand_range), and saves it in the process dictionary
before returning it as well. See also rand:seed/1 and
rand_seed_s/0.
When using the state object from this function the rand
_IntegerValue = rand:uniform(42), % [1; 42]
_FloatValue = rand:uniform(). % [0.0; 1.0[
rand_seed_s() -> rand:state()
Creates state object for random number generation, in order to
generate cryptographically strongly random numbers (based on
OpenSSL's BN_rand_range). See also rand:seed_s/1.
When using the state object from this function the rand
functions using it may raise exception error:low_entropy in case
the random generator failed due to lack of secure "randomness".
Note:
The state returned from this function cannot be used to get a
reproducible random sequence as from the other rand functions,
since reproducibility does not match cryptographically safe.
The only supported usage is to generate one distinct random
sequence from this start state.
rand_seed_alg(Alg) -> rand:state()
Types:
Alg = crypto | crypto_cache
Creates state object for random number generation, in order to
generate cryptographically strong random numbers, and saves it
in the process dictionary before returning it as well. See also
rand:seed/1 and rand_seed_alg_s/1.
When using the state object from this function the rand
functions using it may raise exception error:low_entropy in case
the random generator failed due to lack of secure "randomness".
Example
_ = crypto:rand_seed_alg(crypto_cache),
_IntegerValue = rand:uniform(42), % [1; 42]
_FloatValue = rand:uniform(). % [0.0; 1.0[
rand_seed_alg(Alg, Seed) -> rand:state()
Types:
Alg = crypto_aes
Creates a state object for random number generation, in order to
generate cryptographically unpredictable random numbers, and
saves it in the process dictionary before returning it as well.
See also rand_seed_alg_s/2.
Example
_ = crypto:rand_seed_alg(crypto_aes, "my seed"),
rand_seed_alg_s(Alg) -> rand:state()
Types:
Alg = crypto | crypto_cache
Creates state object for random number generation, in order to
generate cryptographically strongly random numbers. See also
rand:seed_s/1.
If Alg is crypto this function behaves exactly like
rand_seed_s/0.
If Alg is crypto_cache this function fetches random data with
OpenSSL's RAND_bytes and caches it for speed using an internal
word size of 56 bits that makes calculations fast on 64 bit
machines.
When using the state object from this function the rand
functions using it may raise exception error:low_entropy in case
the random generator failed due to lack of secure "randomness".
The cache size can be changed from its default value using the
crypto app's configuration parameter rand_cache_size.
When using the state object from this function the rand
functions using it may throw exception low_entropy in case the
random generator failed due to lack of secure "randomness".
Note:
The state returned from this function cannot be used to get a
reproducible random sequence as from the other rand functions,
since reproducibility does not match cryptographically safe.
In fact since random data is cached some numbers may get
reproduced if you try, but this is unpredictable.
The only supported usage is to generate one distinct random
sequence from this start state.
rand_seed_alg_s(Alg, Seed) -> rand:state()
Types:
Alg = crypto_aes
Creates a state object for random number generation, in order to
generate cryptographically unpredictable random numbers. See
also rand_seed_alg/1.
To get a long period the Xoroshiro928 generator from the rand
module is used as a counter (with period 2^928 - 1) and the
generator states are scrambled through AES to create 58-bit
pseudo random values.
The result should be statistically completely unpredictable
random values, since the scrambling is cryptographically strong
and the period is ridiculously long. But the generated numbers
are not to be regarded as cryptographically strong since there
function.
* If you do not need the statistical quality of this function,
there are faster algorithms in the rand module.
Thanks to the used generator the state object supports the
rand:jump/0,1 function with distance 2^512.
Numbers are generated in batches and cached for speed reasons.
The cache size can be changed from its default value using the
crypto app's configuration parameter rand_cache_size.
ec_curves() -> [EllipticCurve]
Types:
EllipticCurve =
ec_named_curve() | edwards_curve_dh() |
edwards_curve_ed()
Can be used to determine which named elliptic curves are
supported.
ec_curve(CurveName) -> ExplicitCurve
Types:
CurveName = ec_named_curve()
ExplicitCurve = ec_explicit_curve()
Return the defining parameters of a elliptic curve.
sign(Algorithm, DigestType, Msg, Key) -> Signature
sign(Algorithm, DigestType, Msg, Key, Options) -> Signature
Types:
Algorithm = pk_sign_verify_algs()
DigestType =
rsa_digest_type() |
dss_digest_type() |
ecdsa_digest_type() |
none
Msg = iodata() | {digest, iodata()}
Key =
rsa_private() |
dss_private() |
[ecdsa_private() | ecdsa_params()] |
[eddsa_private() | eddsa_params()] |
engine_key_ref()
Options = pk_sign_verify_opts()
Signature = binary()
Uses the 3-tuple style for error handling.
See also public_key:sign/3.
verify(Algorithm, DigestType, Msg, Signature, Key) -> Result
verify(Algorithm, DigestType, Msg, Signature, Key, Options) ->
Result
Types:
Algorithm = pk_sign_verify_algs()
DigestType =
rsa_digest_type() |
dss_digest_type() |
ecdsa_digest_type() |
none
Msg = iodata() | {digest, iodata()}
Signature = binary()
Key =
rsa_public() |
dss_public() |
[ecdsa_public() | ecdsa_params()] |
[eddsa_public() | eddsa_params()] |
engine_key_ref()
Options = pk_sign_verify_opts()
Result = boolean()
Uses the 3-tuple style for error handling.
Verifies a digital signature
The msg is either the binary "cleartext" data to be signed or it
is the hashed value of "cleartext" i.e. the digest (plaintext).
Algorithm dss can only be used together with digest type sha.
See also public_key:verify/4.
ENGINE API
EXPORTS
privkey_to_pubkey(Type, EnginePrivateKeyRef) -> PublicKey
Types:
Type = rsa | dss
EnginePrivateKeyRef = engine_key_ref()
PublicKey = rsa_public() | dss_public()
Fetches the corresponding public key from a private key stored
in an Engine. The key must be of the type indicated by the Type
parameter.
engine_get_all_methods() -> Result
Types:
Result = [engine_method_type()]
engine_load(EngineId, PreCmds, PostCmds) -> Result
Types:
EngineId = unicode:chardata()
PreCmds = PostCmds = [engine_cmnd()]
Result =
{ok, Engine :: engine_ref()} | {error, Reason :: term()}
Loads the OpenSSL engine given by EngineId if it is available
and intialize it. Returns ok and an engine handle, if the engine
can't be loaded an error tuple is returned.
The function raises a error:badarg if the parameters are in
wrong format. It may also raise the exception error:notsup in
case there is no engine support in the underlying OpenSSL
implementation.
See also the chapter Engine Load in the User's Guide.
engine_unload(Engine) -> Result
Types:
Engine = engine_ref()
Result = ok | {error, Reason :: term()}
Unloads the OpenSSL engine given by Engine. An error tuple is
returned if the engine can't be unloaded.
The function raises a error:badarg if the parameter is in wrong
format. It may also raise the exception error:notsup in case
there is no engine support in the underlying OpenSSL
implementation.
See also the chapter Engine Load in the User's Guide.
engine_by_id(EngineId) -> Result
Types:
EngineId = unicode:chardata()
Result =
{ok, Engine :: engine_ref()} | {error, Reason :: term()}
Get a reference to an already loaded engine with EngineId. An
error tuple is returned if the engine can't be unloaded.
The function raises a error:badarg if the parameter is in wrong
format. It may also raise the exception error:notsup in case
there is no engine support in the underlying OpenSSL
implementation.
See also the chapter Engine Load in the User's Guide.
Result = ok | {error, Reason :: term()}
Sends ctrl commands to the OpenSSL engine given by Engine. This
function is the same as calling engine_ctrl_cmd_string/4 with
Optional set to false.
The function raises a error:badarg if the parameters are in
wrong format. It may also raise the exception error:notsup in
case there is no engine support in the underlying OpenSSL
implementation.
engine_ctrl_cmd_string(Engine, CmdName, CmdArg, Optional) ->
Result
Types:
Engine = term()
CmdName = CmdArg = unicode:chardata()
Optional = boolean()
Result = ok | {error, Reason :: term()}
Sends ctrl commands to the OpenSSL engine given by Engine.
Optional is a boolean argument that can relax the semantics of
the function. If set to true it will only return failure if the
ENGINE supported the given command name but failed while
executing it, if the ENGINE doesn't support the command name it
will simply return success without doing anything. In this case
we assume the user is only supplying commands specific to the
given ENGINE so we set this to false.
The function raises a error:badarg if the parameters are in
wrong format. It may also raise the exception error:notsup in
case there is no engine support in the underlying OpenSSL
implementation.
engine_add(Engine) -> Result
Types:
Engine = engine_ref()
Result = ok | {error, Reason :: term()}
Add the engine to OpenSSL's internal list.
The function raises a error:badarg if the parameters are in
wrong format. It may also raise the exception error:notsup in
case there is no engine support in the underlying OpenSSL
implementation.
engine_remove(Engine) -> Result
Types:
Engine = engine_ref()
Result = ok | {error, Reason :: term()}
engine_register(Engine, EngineMethods) -> Result
Types:
Engine = engine_ref()
EngineMethods = [engine_method_type()]
Result = ok | {error, Reason :: term()}
Register engine to handle some type of methods, for example
engine_method_digests.
The function raises a error:badarg if the parameters are in
wrong format. It may also raise the exception error:notsup in
case there is no engine support in the underlying OpenSSL
implementation.
engine_unregister(Engine, EngineMethods) -> Result
Types:
Engine = engine_ref()
EngineMethods = [engine_method_type()]
Result = ok | {error, Reason :: term()}
Unregister engine so it don't handle some type of methods.
The function raises a error:badarg if the parameters are in
wrong format. It may also raise the exception error:notsup in
case there is no engine support in the underlying OpenSSL
implementation.
engine_get_id(Engine) -> EngineId
Types:
Engine = engine_ref()
EngineId = unicode:chardata()
Return the ID for the engine, or an empty binary if there is no
id set.
The function raises a error:badarg if the parameters are in
wrong format. It may also raise the exception error:notsup in
case there is no engine support in the underlying OpenSSL
implementation.
engine_get_name(Engine) -> EngineName
Types:
Engine = engine_ref()
EngineName = unicode:chardata()
Return the name (eg a description) for the engine, or an empty
binary if there is no name set.
engine_list() -> Result
Types:
Result = [EngineId :: unicode:chardata()]
List the id's of all engines in OpenSSL's internal list.
It may also raise the exception error:notsup in case there is no
engine support in the underlying OpenSSL implementation.
See also the chapter Engine Load in the User's Guide.
May raise exception error:notsup in case engine functionality is
not supported by the underlying OpenSSL implementation.
ensure_engine_loaded(EngineId, LibPath) -> Result
Types:
EngineId = LibPath = unicode:chardata()
Result =
{ok, Engine :: engine_ref()} | {error, Reason :: term()}
Loads an engine given by EngineId and the path to the dynamic
library implementing the engine. An error tuple is returned if
the engine can't be loaded.
This function differs from the normal engine_load in the sense
that it also add the engine id to OpenSSL's internal engine
list. The difference between the first call and the following is
that the first loads the engine with the dynamical engine and
the following calls fetch it from the OpenSSL's engine list. All
references that is returned are equal.
Use engine_unload/1 function to remove the references. But
remember that engine_unload/1 just removes the references to the
engine and not the tag in OpenSSL's engine list. That has to be
done with the engine_remove/1 function when needed (just called
once, from any of the references you got).
The function raises a error:badarg if the parameters are in
wrong format. It may also raise the exception error:notsup in
case there is no engine support in the underlying OpenSSL
implementation.
See also the chapter Engine Load in the User's Guide.
hash_equals(BinA, BinB) -> Result
Types:
BinA = BinB = binary()
Result = boolean()
Constant time memory comparison for fixed length binaries, such
as results of HMAC computations.
Types:
Digest = sha | sha224 | sha256 | sha384 | sha512
Pass = Salt = binary()
Iter = KeyLen = integer() >= 1
Result = binary()
Uses the 3-tuple style for error handling.
PKCS #5 PBKDF2 (Password-Based Key Derivation Function 2) in
combination with HMAC.
Ericsson AB crypto 5.1.3 crypto(3)