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<year>1999</year><year>2016</year>
<holder>Ericsson AB. All Rights Reserved.</holder>
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Licensed under the Apache License, Version 2.0 (the "License");
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<title>crypto</title>
</header>
<module>crypto</module>
<modulesummary>Crypto Functions</modulesummary>
<description>
<p>This module provides a set of cryptographic functions.
</p>
<list type="bulleted">
<item>
<p>Hash functions -
<url href="http://csrc.nist.gov/publications/fips/fips180-4/fips-180-4.pdf"> Secure Hash Standard</url>,
<url href="http://www.ietf.org/rfc/rfc1321.txt"> The MD5 Message Digest Algorithm (RFC 1321)</url> and
<url href="http://www.ietf.org/rfc/rfc1320.txt">The MD4 Message Digest Algorithm (RFC 1320)</url>
</p>
</item>
<item>
<p>Hmac functions - <url href="http://www.ietf.org/rfc/rfc2104.txt"> Keyed-Hashing for Message Authentication (RFC 2104) </url></p>
</item>
<item>
<p>Block ciphers - <url href="http://csrc.nist.gov/groups/ST/toolkit/block_ciphers.html"> </url> DES and AES in
Block Cipher Modes - <url href="http://csrc.nist.gov/groups/ST/toolkit/BCM/index.html"> ECB, CBC, CFB, OFB, CTR and GCM </url></p>
</item>
<item>
<p><url href="http://www.ietf.org/rfc/rfc1321.txt"> RSA encryption RFC 1321 </url> </p>
</item>
<item>
<p>Digital signatures <url href="http://csrc.nist.gov/publications/drafts/fips186-3/fips_186-3.pdf">Digital Signature Standard (DSS)</url> and<url href="http://csrc.nist.gov/groups/STM/cavp/documents/dss2/ecdsa2vs.pdf"> Elliptic Curve Digital
Signature Algorithm (ECDSA) </url> </p>
</item>
<item>
<p><url href="http://www.ietf.org/rfc/rfc2945.txt"> Secure Remote Password Protocol (SRP - RFC 2945) </url></p>
</item>
<item>
<p>gcm: Dworkin, M., "Recommendation for Block Cipher Modes of
Operation: Galois/Counter Mode (GCM) and GMAC",
National Institute of Standards and Technology SP 800-
38D, November 2007.</p>
</item>
</list>
</description>
<section>
<title>DATA TYPES </title>
<code>key_value() = integer() | binary() </code>
<p>Always <c>binary()</c> when used as return value</p>
<code>rsa_public() = [key_value()] = [E, N] </code>
<p> Where E is the public exponent and N is public modulus. </p>
<code>rsa_private() = [key_value()] = [E, N, D] | [E, N, D, P1, P2, E1, E2, C] </code>
<p>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,P2 are first
and second prime factors. E1,E2 are first and second exponents. C
is the CRT coefficient. Terminology is taken from <url href="http://www.ietf.org/rfc/rfc3477.txt"> RFC 3447</url>.</p>
<code>dss_public() = [key_value()] = [P, Q, G, Y] </code>
<p>Where P, Q and G are the dss parameters and Y is the public key.</p>
<code>dss_private() = [key_value()] = [P, Q, G, X] </code>
<p>Where P, Q and G are the dss parameters and X is the private key.</p>
<code>srp_public() = key_value() </code>
<p>Where is <c>A</c> or <c>B</c> from <url href="http://srp.stanford.edu/design.html">SRP design</url></p>
<code>srp_private() = key_value() </code>
<p>Where is <c>a</c> or <c>b</c> from <url href="http://srp.stanford.edu/design.html">SRP design</url></p>
<p>Where Verifier is <c>v</c>, Generator is <c>g</c> and Prime is<c> N</c>, DerivedKey is <c>X</c>, and Scrambler is
<c>u</c> (optional will be generated if not provided) from <url href="http://srp.stanford.edu/design.html">SRP design</url>
Version = '3' | '6' | '6a'
</p>
<code>dh_public() = key_value() </code>
<code>dh_private() = key_value() </code>
<code>dh_params() = [key_value()] = [P, G] </code>
<code>ecdh_public() = key_value() </code>
<code>ecdh_private() = key_value() </code>
<code>ecdh_params() = ec_named_curve() | ec_explicit_curve()</code>
<code>ec_explicit_curve() =
{ec_field(), Prime :: key_value(), Point :: key_value(), Order :: integer(), CoFactor :: none | integer()} </code>
<code>ec_field() = {prime_field, Prime :: integer()} |
{characteristic_two_field, M :: integer(), Basis :: ec_basis()}</code>
<code>ec_basis() = {tpbasis, K :: non_neg_integer()} |
{ppbasis, K1 :: non_neg_integer(), K2 :: non_neg_integer(), K3 :: non_neg_integer()} |
onbasis</code>
<code>ec_named_curve() ->
sect571r1| sect571k1| sect409r1| sect409k1| secp521r1| secp384r1| secp224r1| secp224k1|
secp192k1| secp160r2| secp128r2| secp128r1| sect233r1| sect233k1| sect193r2| sect193r1|
sect131r2| sect131r1| sect283r1| sect283k1| sect163r2| secp256k1| secp160k1| secp160r1|
secp112r2| secp112r1| sect113r2| sect113r1| sect239k1| sect163r1| sect163k1| secp256r1|
secp192r1|
brainpoolP160r1| brainpoolP160t1| brainpoolP192r1| brainpoolP192t1| brainpoolP224r1|
brainpoolP224t1| brainpoolP256r1| brainpoolP256t1| brainpoolP320r1| brainpoolP320t1|
brainpoolP384r1| brainpoolP384t1| brainpoolP512r1| brainpoolP512t1
</code>
<p>Note that the <em>sect</em> curves are GF2m (characteristic two) curves and are only supported if the
underlying OpenSSL has support for them.
See also <seealso marker="#supports-0">crypto:supports/0</seealso>
</p>
<code>stream_cipher() = rc4 | aes_ctr </code>
<code>block_cipher() = aes_cbc | aes_cfb8 | aes_cfb128 | aes_ige256 | blowfish_cbc |
blowfish_cfb64 | des_cbc | des_cfb | des3_cbc | des3_cfb | des_ede3 | rc2_cbc </code>
<code>aead_cipher() = aes_gcm | chacha20_poly1305 </code>
<code>stream_key() = aes_key() | rc4_key() </code>
<code>block_key() = aes_key() | blowfish_key() | des_key()| des3_key() </code>
<code>aes_key() = iodata() </code> <p>Key length is 128, 192 or 256 bits</p>
<code>rc4_key() = iodata() </code> <p>Variable key length from 8 bits up to 2048 bits (usually between 40 and 256)</p>
<code>blowfish_key() = iodata() </code> <p>Variable key length from 32 bits up to 448 bits</p>
<code>des_key() = iodata() </code> <p>Key length is 64 bits (in CBC mode only 8 bits are used)</p>
<code>des3_key() = [binary(), binary(), binary()] </code> <p>Each key part is 64 bits (in CBC mode only 8 bits are used)</p>
<code>digest_type() = md5 | sha | sha224 | sha256 | sha384 | sha512</code>
<code> hash_algorithms() = md5 | ripemd160 | sha | sha224 | sha256 | sha384 | sha512 </code> <p>md4 is also supported for hash_init/1 and hash/2.
Note that both md4 and md5 are recommended only for compatibility with existing applications.
</p>
<code> cipher_algorithms() = aes_cbc | aes_cfb8 | aes_cfb128 | aes_ctr | aes_gcm |
aes_ige256 | blowfish_cbc | blowfish_cfb64 | chacha20_poly1305 | des_cbc | des_cfb |
des3_cbc | des3_cfb | des_ede3 | rc2_cbc | rc4 </code>
<code> public_key_algorithms() = rsa |dss | ecdsa | dh | ecdh | ec_gf2m</code>
<p>Note that ec_gf2m is not strictly a public key algorithm, but a restriction on what curves are supported
with ecdsa and ecdh.
</p>
</section>
<funcs>
<func>
<name>block_encrypt(Type, Key, PlainText) -> CipherText</name>
<fsummary>Encrypt <c>PlainText</c> according to <c>Type</c> block cipher</fsummary>
<type>
<v>Type = des_ecb | blowfish_ecb | aes_ecb </v>
<v>Key = block_key() </v>
<v>PlainText = iodata() </v>
</type>
<desc>
<p>Encrypt <c>PlainText</c> according to <c>Type</c> block cipher.</p>
<p>May throw exception <c>notsup</c> in case the chosen <c>Type</c>
is not supported by the underlying OpenSSL implementation.</p>
</desc>
</func>
<func>
<name>block_decrypt(Type, Key, CipherText) -> PlainText</name>
<fsummary>Decrypt <c>CipherText</c> according to <c>Type</c> block cipher</fsummary>
<type>
<v>Type = des_ecb | blowfish_ecb | aes_ecb </v>
<v>Key = block_key() </v>
<v>PlainText = iodata() </v>
</type>
<desc>
<p>Decrypt <c>CipherText</c> according to <c>Type</c> block cipher.</p>
<p>May throw exception <c>notsup</c> in case the chosen <c>Type</c>
is not supported by the underlying OpenSSL implementation.</p>
</desc>
</func>
<func>
<name>block_encrypt(Type, Key, Ivec, PlainText) -> CipherText</name>
<name>block_encrypt(AeadType, Key, Ivec, {AAD, PlainText}) -> {CipherText, CipherTag}</name>
<name>block_encrypt(aes_gcm, Key, Ivec, {AAD, PlainText, TagLength}) -> {CipherText, CipherTag}</name>
<fsummary>Encrypt <c>PlainText</c> according to <c>Type</c> block cipher</fsummary>
<type>
<v>Type = block_cipher() </v>
<v>AeadType = aead_cipher() </v>
<v>Key = block_key() </v>
<v>PlainText = iodata() </v>
<v>AAD = IVec = CipherText = CipherTag = binary()</v>
<v>TagLength = 1..16</v>
</type>
<desc>
<p>Encrypt <c>PlainText</c> according to <c>Type</c> block cipher.
<c>IVec</c> is an arbitrary initializing vector.</p>
<p>In AEAD (Authenticated Encryption with Associated Data) mode, encrypt
<c>PlainText</c>according to <c>Type</c> block cipher and calculate
<c>CipherTag</c> that also authenticates the <c>AAD</c> (Associated Authenticated Data).</p>
<p>May throw exception <c>notsup</c> in case the chosen <c>Type</c>
is not supported by the underlying OpenSSL implementation.</p>
</desc>
</func>
<func>
<name>block_decrypt(Type, Key, Ivec, CipherText) -> PlainText</name>
<name>block_decrypt(AeadType, Key, Ivec, {AAD, CipherText, CipherTag}) -> PlainText | error</name>
<fsummary>Decrypt <c>CipherText</c> according to <c>Type</c> block cipher</fsummary>
<type>
<v>Type = block_cipher() </v>
<v>AeadType = aead_cipher() </v>
<v>Key = block_key() </v>
<v>PlainText = iodata() </v>
<v>AAD = IVec = CipherText = CipherTag = binary()</v>
</type>
<desc>
<p>Decrypt <c>CipherText</c> according to <c>Type</c> block cipher.
<c>IVec</c> is an arbitrary initializing vector.</p>
<p>In AEAD (Authenticated Encryption with Associated Data) mode, decrypt
<c>CipherText</c>according to <c>Type</c> block cipher and check the authenticity
the <c>PlainText</c> and <c>AAD</c> (Associated Authenticated Data) using the
<c>CipherTag</c>. May return <c>error</c> if the decryption or validation fail's</p>
<p>May throw exception <c>notsup</c> in case the chosen <c>Type</c>
is not supported by the underlying OpenSSL implementation.</p>
</desc>
</func>
<func>
<name>bytes_to_integer(Bin) -> Integer </name>
<fsummary>Convert binary representation, of an integer, to an Erlang integer.</fsummary>
<type>
<v>Bin = binary() - as returned by crypto functions</v>
<v>Integer = integer() </v>
</type>
<desc>
<p>Convert binary representation, of an integer, to an Erlang integer.
</p>
</desc>
</func>
<func>
<name>compute_key(Type, OthersPublicKey, MyKey, Params) -> SharedSecret</name>
<fsummary>Computes the shared secret</fsummary>
<type>
<v> Type = dh | ecdh | srp </v>
<v>OthersPublicKey = dh_public() | ecdh_public() | srp_public() </v>
<v>MyKey = dh_private() | ecdh_private() | {srp_public(),srp_private()}</v>
<v>Params = dh_params() | ecdh_params() | SrpUserParams | SrpHostParams</v>
<v>SrpUserParams = {user, [DerivedKey::binary(), Prime::binary(), Generator::binary(), Version::atom() | [Scrambler:binary()]]} </v>
<v>SrpHostParams = {host, [Verifier::binary(), Prime::binary(), Version::atom() | [Scrambler::binary]]} </v>
<v>SharedSecret = binary()</v>
</type>
<desc>
<p>Computes the shared secret from the private key and the other party's public key.
See also <seealso marker="public_key:public_key#compute_key-2">public_key:compute_key/2</seealso>
</p>
</desc>
</func>
<func>
<name>exor(Data1, Data2) -> Result</name>
<fsummary>XOR data</fsummary>
<type>
<v>Data1, Data2 = iodata()</v>
<v>Result = binary()</v>
</type>
<desc>
<p>Performs bit-wise XOR (exclusive or) on the data supplied.</p>
</desc>
</func>
<func>
<name>generate_key(Type, Params) -> {PublicKey, PrivKeyOut} </name>
<name>generate_key(Type, Params, PrivKeyIn) -> {PublicKey, PrivKeyOut} </name>
<fsummary>Generates a public keys of type <c>Type</c></fsummary>
<type>
<v> Type = dh | ecdh | srp </v>
<v>Params = dh_params() | ecdh_params() | SrpUserParams | SrpHostParams </v>
<v>SrpUserParams = {user, [Generator::binary(), Prime::binary(), Version::atom()]}</v>
<v>SrpHostParams = {host, [Verifier::binary(), Generator::binary(), Prime::binary(), Version::atom()]}</v>
<v>PublicKey = dh_public() | ecdh_public() | srp_public() </v>
<v>PrivKeyIn = undefined | dh_private() | ecdh_private() | srp_private() </v>
<v>PrivKeyOut = dh_private() | ecdh_private() | srp_private() </v>
</type>
<desc>
<p>Generates public keys of type <c>Type</c>.
See also <seealso marker="public_key:public_key#generate_key-1">public_key:generate_key/1</seealso>
May throw exception <c>low_entropy</c> in case the random generator
failed due to lack of secure "randomness".
</p>
</desc>
</func>
<func>
<name>hash(Type, Data) -> Digest</name>
<fsummary></fsummary>
<type>
<v>Type = md4 | hash_algorithms()</v>
<v>Data = iodata()</v>
<v>Digest = binary()</v>
</type>
<desc>
<p>Computes a message digest of type <c>Type</c> from <c>Data</c>.</p>
<p>May throw exception <c>notsup</c> in case the chosen <c>Type</c>
is not supported by the underlying OpenSSL implementation.</p>
</desc>
</func>
<func>
<name>hash_init(Type) -> Context</name>
<fsummary></fsummary>
<type>
<v>Type = md4 | hash_algorithms()</v>
</type>
<desc>
<p>Initializes the context for streaming hash operations. <c>Type</c> determines
which digest to use. The returned context should be used as argument
to <seealso marker="#hash_update-2">hash_update</seealso>.</p>
<p>May throw exception <c>notsup</c> in case the chosen <c>Type</c>
is not supported by the underlying OpenSSL implementation.</p>
</desc>
</func>
<func>
<name>hash_update(Context, Data) -> NewContext</name>
<fsummary></fsummary>
<type>
<v>Data = iodata()</v>
</type>
<desc>
<p>Updates the digest represented by <c>Context</c> using the given <c>Data</c>. <c>Context</c>
must have been generated using <seealso marker="#hash_init-1">hash_init</seealso>
or a previous call to this function. <c>Data</c> can be any length. <c>NewContext</c>
must be passed into the next call to <c>hash_update</c>
or <seealso marker="#hash_final-1">hash_final</seealso>.</p>
</desc>
</func>
<func>
<name>hash_final(Context) -> Digest</name>
<fsummary></fsummary>
<type>
<v>Digest = binary()</v>
</type>
<desc>
<p>Finalizes the hash operation referenced by <c>Context</c> returned
from a previous call to <seealso marker="#hash_update-2">hash_update</seealso>.
The size of <c>Digest</c> is determined by the type of hash
function used to generate it.</p>
</desc>
</func>
<func>
<name>hmac(Type, Key, Data) -> Mac</name>
<name>hmac(Type, Key, Data, MacLength) -> Mac</name>
<fsummary></fsummary>
<type>
<v>Type = hash_algorithms() - except ripemd160</v>
<v>Key = iodata()</v>
<v>Data = iodata()</v>
<v>MacLength = integer()</v>
<v>Mac = binary()</v>
</type>
<desc>
<p>Computes a HMAC of type <c>Type</c> from <c>Data</c> using
<c>Key</c> as the authentication key.</p> <p><c>MacLength</c>
will limit the size of the resultant <c>Mac</c>.</p>
</desc>
</func>
<func>
<name>hmac_init(Type, Key) -> Context</name>
<fsummary></fsummary>
<type>
<v>Type = hash_algorithms() - except ripemd160</v>
<v>Key = iodata()</v>
<v>Context = binary()</v>
</type>
<desc>
<p>Initializes the context for streaming HMAC operations. <c>Type</c> determines
which hash function to use in the HMAC operation. <c>Key</c> is the authentication
key. The key can be any length.</p>
</desc>
</func>
<func>
<name>hmac_update(Context, Data) -> NewContext</name>
<fsummary></fsummary>
<type>
<v>Context = NewContext = binary()</v>
<v>Data = iodata()</v>
</type>
<desc>
<p>Updates the HMAC represented by <c>Context</c> using the given <c>Data</c>. <c>Context</c>
must have been generated using an HMAC init function (such as
<seealso marker="#hmac_init-2">hmac_init</seealso>). <c>Data</c> can be any length. <c>NewContext</c>
must be passed into the next call to <c>hmac_update</c>
or to one of the functions <seealso marker="#hmac_final-1">hmac_final</seealso> and
<seealso marker="#hmac_final_n-2">hmac_final_n</seealso>
</p>
<warning><p>Do not use a <c>Context</c> as argument in more than one
call to hmac_update or hmac_final. The semantics of reusing old contexts
in any way is undefined and could even crash the VM in earlier releases.
The reason for this limitation is a lack of support in the underlying
OpenSSL API.</p></warning>
</desc>
</func>
<func>
<name>hmac_final(Context) -> Mac</name>
<fsummary></fsummary>
<type>
<v>Context = Mac = binary()</v>
</type>
<desc>
<p>Finalizes the HMAC operation referenced by <c>Context</c>. The size of the resultant MAC is
determined by the type of hash function used to generate it.</p>
</desc>
</func>
<func>
<name>hmac_final_n(Context, HashLen) -> Mac</name>
<fsummary></fsummary>
<type>
<v>Context = Mac = binary()</v>
<v>HashLen = non_neg_integer()</v>
</type>
<desc>
<p>Finalizes the HMAC operation referenced by <c>Context</c>. <c>HashLen</c> must be greater than
zero. <c>Mac</c> will be a binary with at most <c>HashLen</c> bytes. Note that if HashLen is greater than the actual number of bytes returned from the underlying hash, the returned hash will have fewer than <c>HashLen</c> bytes.</p>
</desc>
</func>
<func>
<name>info_lib() -> [{Name,VerNum,VerStr}]</name>
<fsummary>Provides information about the libraries used by crypto.</fsummary>
<type>
<v>Name = binary()</v>
<v>VerNum = integer()</v>
<v>VerStr = binary()</v>
</type>
<desc>
<p>Provides the name and version of the libraries used by crypto.</p>
<p><c>Name</c> is the name of the library. <c>VerNum</c> is
the numeric version according to the library's own versioning
scheme. <c>VerStr</c> contains a text variant of the version.</p>
<pre>
> <input>info_lib().</input>
[{<<"OpenSSL">>,9469983,<<"OpenSSL 0.9.8a 11 Oct 2005">>}]
</pre>
<note><p>
From OTP R16 the <em>numeric version</em> represents the version of the OpenSSL
<em>header files</em> (<c>openssl/opensslv.h</c>) used when crypto was compiled.
The text variant represents the OpenSSL library used at runtime.
In earlier OTP versions both numeric and text was taken from the library.
</p></note>
</desc>
</func>
<func>
<name>mod_pow(N, P, M) -> Result</name>
<fsummary>Computes the function: N^P mod M</fsummary>
<type>
<v>N, P, M = binary() | integer()</v>
<v>Result = binary() | error</v>
</type>
<desc>
<p>Computes the function <c>N^P mod M</c>.</p>
</desc>
</func>
<func>
<name>next_iv(Type, Data) -> NextIVec</name>
<name>next_iv(Type, Data, IVec) -> NextIVec</name>
<fsummary></fsummary>
<type>
<v>Type = des_cbc | des3_cbc | aes_cbc | des_cfb</v>
<v>Data = iodata()</v>
<v>IVec = NextIVec = binary()</v>
</type>
<desc>
<p>Returns the initialization vector to be used in the next
iteration of encrypt/decrypt of type <c>Type</c>. <c>Data</c> is the
encrypted data from the previous iteration step. The <c>IVec</c>
argument is only needed for <c>des_cfb</c> as the vector used
in the previous iteration step.</p>
</desc>
</func>
<func>
<name>private_decrypt(Type, CipherText, PrivateKey, Padding) -> PlainText</name>
<fsummary>Decrypts CipherText using the private Key.</fsummary>
<type>
<v>Type = rsa</v>
<v>CipherText = binary()</v>
<v>PrivateKey = rsa_private()</v>
<v>Padding = rsa_pkcs1_padding | rsa_pkcs1_oaep_padding | rsa_no_padding</v>
<v>PlainText = binary()</v>
</type>
<desc>
<p>Decrypts the <c>CipherText</c>, encrypted with
<seealso marker="#public_encrypt-4">public_encrypt/4</seealso> (or equivalent function)
using the <c>PrivateKey</c>, 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 <seealso marker="public_key:public_key#decrypt_private-2">public_key:decrypt_private/[2,3]</seealso>
</p>
</desc>
</func>
<func>
<name>private_encrypt(Type, PlainText, PrivateKey, Padding) -> CipherText</name>
<fsummary>Encrypts PlainText using the private Key.</fsummary>
<type>
<v>Type = rsa</v>
<v>PlainText = binary()</v>
<d> The size of the <c>PlainText</c> must be less
than <c>byte_size(N)-11</c> if <c>rsa_pkcs1_padding</c> is
used, and <c>byte_size(N)</c> if <c>rsa_no_padding</c> is
used, where N is public modulus of the RSA key.</d>
<v>PrivateKey = rsa_private()</v>
<v>Padding = rsa_pkcs1_padding | rsa_no_padding</v>
<v>CipherText = binary()</v>
</type>
<desc>
<p>Encrypts the <c>PlainText</c> using the <c>PrivateKey</c>
and returns the ciphertext. This is a low level signature operation
used for instance by older versions of the SSL protocol. See
also <seealso
marker="public_key:public_key#encrypt_private-2">public_key:encrypt_private/[2,3]</seealso>
</p>
</desc>
</func>
<func>
<name>public_decrypt(Type, CipherText, PublicKey, Padding) -> PlainText</name>
<fsummary>Decrypts CipherText using the public Key.</fsummary>
<type>
<v>Type = rsa</v>
<v>CipherText = binary()</v>
<v>PublicKey = rsa_public() </v>
<v>Padding = rsa_pkcs1_padding | rsa_no_padding</v>
<v>PlainText = binary()</v>
</type>
<desc>
<p>Decrypts the <c>CipherText</c>, encrypted with
<seealso marker="#private_encrypt-4">private_encrypt/4</seealso>(or equivalent function)
using the <c>PrivateKey</c>, 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 <seealso marker="public_key:public_key#decrypt_public-2">public_key:decrypt_public/[2,3]</seealso>
</p>
</desc>
</func>
<func>
<name>public_encrypt(Type, PlainText, PublicKey, Padding) -> CipherText</name>
<fsummary>Encrypts PlainText using the public Key.</fsummary>
<type>
<v>Type = rsa</v>
<v>PlainText = binary()</v>
<d> The size of the <c>PlainText</c> must be less
than <c>byte_size(N)-11</c> if <c>rsa_pkcs1_padding</c> is
used, and <c>byte_size(N)</c> if <c>rsa_no_padding</c> is
used, where N is public modulus of the RSA key.</d>
<v>PublicKey = rsa_public()</v>
<v>Padding = rsa_pkcs1_padding | rsa_pkcs1_oaep_padding | rsa_no_padding</v>
<v>CipherText = binary()</v>
</type>
<desc>
<p>Encrypts the <c>PlainText</c> (message digest) using the <c>PublicKey</c>
and returns the <c>CipherText</c>. This is a low level signature operation
used for instance by older versions of the SSL protocol. See also <seealso
marker="public_key:public_key#encrypt_public-2">public_key:encrypt_public/[2,3]</seealso>
</p>
</desc>
</func>
<func>
<name>rand_seed(Seed) -> ok</name>
<fsummary>Set the seed for random bytes generation</fsummary>
<type>
<v>Seed = binary()</v>
</type>
<desc>
<p>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 <seealso marker="#strong_rand_bytes/1">
strong_rand_bytes/1</seealso> returns <c>low_entropy</c></p>
</desc>
</func>
<func>
<name>rand_uniform(Lo, Hi) -> N</name>
<fsummary>Generate a random number</fsummary>
<type>
<v>Lo, Hi, N = integer()</v>
</type>
<desc>
<p>Generate a random number <c><![CDATA[N, Lo =< N < Hi.]]></c> Uses the
<c>crypto</c> library pseudo-random number generator.
<c>Hi</c> must be larger than <c>Lo</c>.</p>
</desc>
</func>
<func>
<name>sign(Algorithm, DigestType, Msg, Key) -> binary()</name>
<fsummary> Create digital signature.</fsummary>
<type>
<v>Algorithm = rsa | dss | ecdsa </v>
<v>Msg = binary() | {digest,binary()}</v>
<d>The msg is either the binary "cleartext" data to be
signed or it is the hashed value of "cleartext" i.e. the
digest (plaintext).</d>
<v>DigestType = digest_type()</v>
<v>Key = rsa_private() | dss_private() | [ecdh_private(),ecdh_params()]</v>
</type>
<desc>
<p>Creates a digital signature.</p>
<p>Algorithm <c>dss</c> can only be used together with digest type
<c>sha</c>.</p>
<p>See also <seealso marker="public_key:public_key#sign-3">public_key:sign/3</seealso>.</p>
</desc>
</func>
<func>
<name>start() -> ok</name>
<fsummary> Equivalent to application:start(crypto). </fsummary>
<desc>
<p> Equivalent to application:start(crypto).</p>
</desc>
</func>
<func>
<name>stop() -> ok</name>
<fsummary> Equivalent to application:stop(crypto).</fsummary>
<desc>
<p> Equivalent to application:stop(crypto).</p>
</desc>
</func>
<func>
<name>strong_rand_bytes(N) -> binary()</name>
<fsummary>Generate a binary of random bytes</fsummary>
<type>
<v>N = integer()</v>
</type>
<desc>
<p>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 <c>RAND_bytes</c> method from OpenSSL.</p>
<p>May throw exception <c>low_entropy</c> in case the random generator
failed due to lack of secure "randomness".</p>
</desc>
</func>
<func>
<name>stream_init(Type, Key) -> State</name>
<fsummary></fsummary>
<type>
<v>Type = rc4 </v>
<v>State = opaque() </v>
<v>Key = iodata()</v>
</type>
<desc>
<p>Initializes the state for use in RC4 stream encryption
<seealso marker="#stream_encrypt-2">stream_encrypt</seealso> and
<seealso marker="#stream_decrypt-2">stream_decrypt</seealso></p>
</desc>
</func>
<func>
<name>stream_init(Type, Key, IVec) -> State</name>
<fsummary></fsummary>
<type>
<v>Type = aes_ctr </v>
<v>State = opaque() </v>
<v>Key = iodata()</v>
<v>IVec = binary()</v>
</type>
<desc>
<p>Initializes the state for use in streaming AES encryption using Counter mode (CTR).
<c>Key</c> is the AES key and must be either 128, 192, or 256 bits long. <c>IVec</c> is
an arbitrary initializing vector of 128 bits (16 bytes). This state is for use with
<seealso marker="#stream_encrypt-2">stream_encrypt</seealso> and
<seealso marker="#stream_decrypt-2">stream_decrypt</seealso>.</p>
</desc>
</func>
<func>
<name>stream_encrypt(State, PlainText) -> { NewState, CipherText}</name>
<fsummary></fsummary>
<type>
<v>Text = iodata()</v>
<v>CipherText = binary()</v>
</type>
<desc>
<p>Encrypts <c>PlainText</c> according to the stream cipher <c>Type</c> specified in stream_init/3.
<c>Text</c> can be any number of bytes. The initial <c>State</c> is created using
<seealso marker="#stream_init-2">stream_init</seealso>.
<c>NewState</c> must be passed into the next call to <c>stream_encrypt</c>.</p>
</desc>
</func>
<func>
<name>stream_decrypt(State, CipherText) -> { NewState, PlainText }</name>
<fsummary></fsummary>
<type>
<v>CipherText = iodata()</v>
<v>PlainText = binary()</v>
</type>
<desc>
<p>Decrypts <c>CipherText</c> according to the stream cipher <c>Type</c> specified in stream_init/3.
<c>PlainText</c> can be any number of bytes. The initial <c>State</c> is created using
<seealso marker="#stream_init-2">stream_init</seealso>.
<c>NewState</c> must be passed into the next call to <c>stream_decrypt</c>.</p>
</desc>
</func>
<func>
<name>supports() -> AlgorithmList </name>
<fsummary>Provide a list of available crypto algorithms.</fsummary>
<type>
<v> AlgorithmList = [{hashs, [hash_algorithms()]},
{ciphers, [cipher_algorithms()]},
{public_keys, [public_key_algorithms()]}
</v>
</type>
<desc>
<p> Can be used to determine which crypto algorithms that are supported
by the underlying OpenSSL library</p>
</desc>
</func>
<func>
<name>ec_curves() -> EllipticCurveList </name>
<fsummary>Provide a list of available named elliptic curves.</fsummary>
<type>
<v>EllipticCurveList = [ec_named_curve()]</v>
</type>
<desc>
<p>Can be used to determine which named elliptic curves are supported.</p>
</desc>
</func>
<func>
<name>ec_curve(NamedCurve) -> EllipticCurve </name>
<fsummary>Get the defining parameters of a elliptic curve.</fsummary>
<type>
<v>NamedCurve = ec_named_curve()</v>
<v>EllipticCurve = ec_explicit_curve()</v>
</type>
<desc>
<p>Return the defining parameters of a elliptic curve.</p>
</desc>
</func>
<func>
<name>verify(Algorithm, DigestType, Msg, Signature, Key) -> boolean()</name>
<fsummary>Verifies a digital signature.</fsummary>
<type>
<v> Algorithm = rsa | dss | ecdsa </v>
<v>Msg = binary() | {digest,binary()}</v>
<d>The msg is either the binary "cleartext" data
or it is the hashed value of "cleartext" i.e. the digest (plaintext).</d>
<v>DigestType = digest_type()</v>
<v>Signature = binary()</v>
<v>Key = rsa_public() | dss_public() | [ecdh_public(),ecdh_params()]</v>
</type>
<desc>
<p>Verifies a digital signature</p>
<p>Algorithm <c>dss</c> can only be used together with digest type
<c>sha</c>.</p>
<p>See also <seealso marker="public_key:public_key#verify-4">public_key:verify/4</seealso>.</p>
</desc>
</func>
</funcs>
<!-- Maybe put this in the users guide -->
<!-- <section> -->
<!-- <title>DES in CBC mode</title> -->
<!-- <p>The Data Encryption Standard (DES) defines an algorithm for -->
<!-- encrypting and decrypting an 8 byte quantity using an 8 byte key -->
<!-- (actually only 56 bits of the key is used). -->
<!-- </p> -->
<!-- <p>When it comes to encrypting and decrypting blocks that are -->
<!-- multiples of 8 bytes various modes are defined (NIST SP -->
<!-- 800-38A). One of those modes is the Cipher Block Chaining (CBC) -->
<!-- mode, where the encryption of an 8 byte segment depend not only -->
<!-- of the contents of the segment itself, but also on the result of -->
<!-- encrypting the previous segment: the encryption of the previous -->
<!-- segment becomes the initializing vector of the encryption of the -->
<!-- current segment. -->
<!-- </p> -->
<!-- <p>Thus the encryption of every segment depends on the encryption -->
<!-- key (which is secret) and the encryption of the previous -->
<!-- segment, except the first segment which has to be provided with -->
<!-- an initial initializing vector. That vector could be chosen at -->
<!-- random, or be a counter of some kind. It does not have to be -->
<!-- secret. -->
<!-- </p> -->
<!-- <p>The following example is drawn from the old FIPS 81 standard -->
<!-- (replaced by NIST SP 800-38A), where both the plain text and the -->
<!-- resulting cipher text is settled. The following code fragment -->
<!-- returns `true'. -->
<!-- </p> -->
<!-- <pre><![CDATA[ -->
<!-- Key = <<16#01,16#23,16#45,16#67,16#89,16#ab,16#cd,16#ef>>, -->
<!-- IVec = <<16#12,16#34,16#56,16#78,16#90,16#ab,16#cd,16#ef>>, -->
<!-- P = "Now is the time for all ", -->
<!-- C = crypto:des_cbc_encrypt(Key, IVec, P), -->
<!-- % Which is the same as -->
<!-- P1 = "Now is t", P2 = "he time ", P3 = "for all ", -->
<!-- C1 = crypto:des_cbc_encrypt(Key, IVec, P1), -->
<!-- C2 = crypto:des_cbc_encrypt(Key, C1, P2), -->
<!-- C3 = crypto:des_cbc_encrypt(Key, C2, P3), -->
<!-- C = <<C1/binary, C2/binary, C3/binary>>, -->
<!-- C = <<16#e5,16#c7,16#cd,16#de,16#87,16#2b,16#f2,16#7c, -->
<!-- 16#43,16#e9,16#34,16#00,16#8c,16#38,16#9c,16#0f, -->
<!-- 16#68,16#37,16#88,16#49,16#9a,16#7c,16#05,16#f6>>, -->
<!-- <<"Now is the time for all ">> == -->
<!-- crypto:des_cbc_decrypt(Key, IVec, C). -->
<!-- ]]></pre> -->
<!-- <p>The following is true for the DES CBC mode. For all -->
<!-- decompositions <c>P1 ++ P2 = P</c> of a plain text message -->
<!-- <c>P</c> (where the length of all quantities are multiples of 8 -->
<!-- bytes), the encryption <c>C</c> of <c>P</c> is equal to <c>C1 ++ -->
<!-- C2</c>, where <c>C1</c> is obtained by encrypting <c>P1</c> with -->
<!-- <c>Key</c> and the initializing vector <c>IVec</c>, and where -->
<!-- <c>C2</c> is obtained by encrypting <c>P2</c> with <c>Key</c> -->
<!-- and the initializing vector <c>last8(C1)</c>, -->
<!-- where <c>last(Binary)</c> denotes the last 8 bytes of the -->
<!-- binary <c>Binary</c>. -->
<!-- </p> -->
<!-- <p>Similarly, for all decompositions <c>C1 ++ C2 = C</c> of a -->
<!-- cipher text message <c>C</c> (where the length of all quantities -->
<!-- are multiples of 8 bytes), the decryption <c>P</c> of <c>C</c> -->
<!-- is equal to <c>P1 ++ P2</c>, where <c>P1</c> is obtained by -->
<!-- decrypting <c>C1</c> with <c>Key</c> and the initializing vector -->
<!-- <c>IVec</c>, and where <c>P2</c> is obtained by decrypting -->
<!-- <c>C2</c> with <c>Key</c> and the initializing vector -->
<!-- <c>last8(C1)</c>, where <c>last8(Binary)</c> is as above. -->
<!-- </p> -->
<!-- <p>For DES3 (which uses three 64 bit keys) the situation is the -->
<!-- same. -->
<!-- </p> -->
<!-- </section> -->
</erlref>