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|
<?xml version="1.0" encoding="utf-8" ?>
<!DOCTYPE erlref SYSTEM "erlref.dtd">
<erlref>
<header>
<copyright>
<year>1999</year><year>2013</year>
<holder>Ericsson AB. All Rights Reserved.</holder>
</copyright>
<legalnotice>
The contents of this file are subject to the Erlang Public License,
Version 1.1, (the "License"); you may not use this file except in
compliance with the License. You should have received a copy of the
Erlang Public License along with this software. If not, it can be
retrieved online at http://www.erlang.org/.
Software distributed under the License is distributed on an "AS IS"
basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See
the License for the specific language governing rights and limitations
under the License.
</legalnotice>
<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 and CTR </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>
</list>
</description>
<section>
<title>DATA TYPES </title>
<p><code>key_value() = integer() | binary() </code></p>
<p>Always <c>binary()</c> when used as return value</p>
<p><code>rsa_public() = [key_value()] = [E, N] </code></p>
<p> Where E is the public exponent and N is public modulus. </p>
<p><code>rsa_private() = [key_value()] = [E, N, D] | [E, N, D, P1, P2, E1, E2, C] </code></p>
<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>
<p><code>dss_public() = [key_value()] = [P, Q, G, Y] </code></p>
<p>Where P, Q and G are the dss parameters and Y is the public key.</p>
<p><code>dss_private() = [key_value()] = [P, Q, G, X] </code></p>
<p>Where P, Q and G are the dss parameters and X is the private key.</p>
<p><code>srp_public() = key_value() </code></p>
<p>Where is <c>A</c> or <c>B</c> from <url href="http://srp.stanford.edu/design.html">SRP design</url></p>
<p><code>srp_private() = key_value() </code></p>
<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>
<p><code>dh_public() = key_value() </code></p>
<p><code>dh_private() = key_value() </code></p>
<p><code>dh_params() = [key_value()] = [P, G] </code></p>
<p><code>ecdh_public() = key_value() </code></p>
<p><code>ecdh_private() = key_value() </code></p>
<p><code>ecdh_params() = ec_named_curve() |
{ec_field(), Prime :: key_value(), Point :: key_value(), Order :: integer(), CoFactor :: none | integer()} </code></p>
<p><code>ec_field() = {prime_field, Prime :: integer()} |
{characteristic_two_field, M :: integer(), Basis :: ec_basis()}</code></p>
<p><code>ec_basis() = {tpbasis, K :: non_neg_integer()} |
{ppbasis, K1 :: non_neg_integer(), K2 :: non_neg_integer(), K3 :: non_neg_integer()} |
onbasis</code></p>
<p><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 </code></p>
<p><code>stream_cipher() = rc4 | aes_ctr </code></p>
<p><code>block_cipher() = aes_cbc128 | aes_cfb128 | aes_ige256 | blowfish_cbc |
blowfish_cfb64 | des_cbc | des_cfb | des3_cbc | des3_cbf
| des_ede3 | rc2_cbc </code></p>
<p><code>stream_key() = aes_key() | rc4_key() </code></p>
<p><code>block_key() = aes_key() | blowfish_key() | des_key()| des3_key() </code></p>
<p><code>aes_key() = iodata() </code> Key length is 128, 192 or 256 bits</p>
<p><code>rc4_key() = iodata() </code> Variable key length from 8 bits up to 2048 bits (usually between 40 and 256)</p>
<p><code>blowfish_key() = iodata() </code> Variable key length from 32 bits up to 448 bits</p>
<p><code>des_key() = iodata() </code> Key length is 64 bits (in CBC mode only 8 bits are used)</p>
<p><code>des3_key() = [binary(), binary(), binary()] </code> Each key part is 64 bits (in CBC mode only 8 bits are used)</p>
<p><code>digest_type() = md5 | sha | sha224 | sha256 | sha384 | sha512</code></p>
<p><code> hash_algorithms() = md5 | ripemd160 | sha | sha224 | sha256 | sha384 | sha512 </code> 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>
<p><code> cipher_algorithms() = des_cbc | des_cfb | des3_cbc | des3_cbf | des_ede3 |
blowfish_cbc | blowfish_cfb64 | aes_cbc128 | aes_cfb128| aes_cbc256 | aes_ige256 | rc2_cbc | aes_ctr| rc4 </code> </p>
<p><code> public_key_algorithms() = rsa |dss | ecdsa | dh | ecdh </code> </p>
</section>
<funcs>
<func>
<name>block_encrypt(Type, Key, Ivec, PlainText) -> CipherText</name>
<fsummary>Encrypt <c>PlainText</c>according to <c>Type</c> block cipher</fsummary>
<type>
<v>Type = block_cipher() </v>
<v>Key = block_key() </v>
<v>PlainText = iodata() </v>
<v>IVec = CipherText = binary()</v>
</type>
<desc>
<p>Encrypt <c>PlainText</c>according to <c>Type</c> block cipher.
<c>IVec</c> is an arbitrary initializing vector.
</p>
</desc>
</func>
<func>
<name>block_decrypt(Type, Key, Ivec, CipherText) -> PlainText</name>
<fsummary>Decrypt <c>CipherText</c>according to <c>Type</c> block cipher</fsummary>
<type>
<v>Type = block_cipher() </v>
<v>Key = block_key() </v>
<v>PlainText = iodata() </v>
<v>IVec = CipherText = 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>
</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() | 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>
</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> <c>MacLength</c>
will limit the size of the resultant <c>Mac</c>.
</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>
</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, ChipherText, PrivateKey, Padding) -> PlainText</name>
<fsummary>Decrypts ChipherText using the private Key.</fsummary>
<type>
<v>Type = rsa</v>
<v>ChipherText = 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>ChipherText</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) -> ChipherText</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>ChipherText = 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, ChipherText, PublicKey, Padding) -> PlainText</name>
<fsummary>Decrypts ChipherText using the public Key.</fsummary>
<type>
<v>Type = rsa</v>
<v>ChipherText = 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>ChipherText</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) -> ChipherText</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>ChipherText = 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_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 the <c>crypto</c> library pseudo-random
number generator.</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>
See also <seealso marker="public_key:public_key#sign-3">public_key:sign/3</seealso>
</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 bts 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_encrypt</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>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>
See also <seealso marker="public_key:public_key#verify-4">public_key:verify/4</seealso>
</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>
|