openssl/src/pkcs5.rs - platform/external/rust/crates/openssl - Git at Google

 use libc::c_int;
 use std::ptr;

 use crate::cvt;
 use crate::error::ErrorStack;
 use crate::hash::MessageDigest;
 use crate::symm::Cipher;
 use openssl_macros::corresponds;

 #[derive(Clone, Eq, PartialEq, Hash, Debug)]
 pub struct KeyIvPair {
     pub key: Vec<u8>,
     pub iv: Option<Vec<u8>>,
 }

 /// Derives a key and an IV from various parameters.
 ///
 /// If specified, `salt` must be 8 bytes in length.
 ///
 /// If the total key and IV length is less than 16 bytes and MD5 is used then
 /// the algorithm is compatible with the key derivation algorithm from PKCS#5
 /// v1.5 or PBKDF1 from PKCS#5 v2.0.
 ///
 /// New applications should not use this and instead use
 /// `pbkdf2_hmac` or another more modern key derivation algorithm.
 #[corresponds(EVP_BytesToKey)]
 #[allow(clippy::useless_conversion)]
 pub fn bytes_to_key(
     cipher: Cipher,
     digest: MessageDigest,
     data: &[u8],
     salt: Option<&[u8]>,
     count: i32,
 ) -> Result<KeyIvPair, ErrorStack> {
     unsafe {
         assert!(data.len() <= c_int::max_value() as usize);
         let salt_ptr = match salt {
             Some(salt) => {
                 assert_eq!(salt.len(), ffi::PKCS5_SALT_LEN as usize);
                 salt.as_ptr()
             }
             None => ptr::null(),
         };

         ffi::init();

         let mut iv = cipher.iv_len().map(|l| vec![0; l]);

         let cipher = cipher.as_ptr();
         let digest = digest.as_ptr();

         let len = cvt(ffi::EVP_BytesToKey(
             cipher,
             digest,
             salt_ptr,
             ptr::null(),
             data.len() as c_int,
             count.into(),
             ptr::null_mut(),
             ptr::null_mut(),
         ))?;

         let mut key = vec![0; len as usize];
         let iv_ptr = iv
             .as_mut()
             .map(|v| v.as_mut_ptr())
             .unwrap_or(ptr::null_mut());

         cvt(ffi::EVP_BytesToKey(
             cipher,
             digest,
             salt_ptr,
             data.as_ptr(),
             data.len() as c_int,
             count as c_int,
             key.as_mut_ptr(),
             iv_ptr,
         ))?;

         Ok(KeyIvPair { key, iv })
     }
 }

 /// Derives a key from a password and salt using the PBKDF2-HMAC algorithm with a digest function.
 #[corresponds(PKCS5_PBKDF2_HMAC)]
 pub fn pbkdf2_hmac(
     pass: &[u8],
     salt: &[u8],
     iter: usize,
     hash: MessageDigest,
     key: &mut [u8],
 ) -> Result<(), ErrorStack> {
     unsafe {
         assert!(pass.len() <= c_int::max_value() as usize);
         assert!(salt.len() <= c_int::max_value() as usize);
         assert!(key.len() <= c_int::max_value() as usize);

         ffi::init();
         cvt(ffi::PKCS5_PBKDF2_HMAC(
             pass.as_ptr() as *const _,
             pass.len() as c_int,
             salt.as_ptr(),
             salt.len() as c_int,
             iter as c_int,
             hash.as_ptr(),
             key.len() as c_int,
             key.as_mut_ptr(),
         ))
         .map(|_| ())
     }
 }

 /// Derives a key from a password and salt using the scrypt algorithm.
 ///
 /// Requires OpenSSL 1.1.0 or newer.
 #[corresponds(EVP_PBE_scrypt)]
 #[cfg(any(ossl110))]
 pub fn scrypt(
     pass: &[u8],
     salt: &[u8],
     n: u64,
     r: u64,
     p: u64,
     maxmem: u64,
     key: &mut [u8],
 ) -> Result<(), ErrorStack> {
     unsafe {
         ffi::init();
         cvt(ffi::EVP_PBE_scrypt(
             pass.as_ptr() as *const _,
             pass.len(),
             salt.as_ptr() as *const _,
             salt.len(),
             n,
             r,
             p,
             maxmem,
             key.as_mut_ptr() as *mut _,
             key.len(),
         ))
         .map(|_| ())
     }
 }

 #[cfg(test)]
 mod tests {
     use crate::hash::MessageDigest;
     use crate::symm::Cipher;

     // Test vectors from
     // https://git.lysator.liu.se/nettle/nettle/blob/nettle_3.1.1_release_20150424/testsuite/pbkdf2-test.c
     #[test]
     fn pbkdf2_hmac_sha256() {
         let mut buf = [0; 16];

         super::pbkdf2_hmac(b"passwd", b"salt", 1, MessageDigest::sha256(), &mut buf).unwrap();
         assert_eq!(
             buf,
             &[
                 0x55_u8, 0xac_u8, 0x04_u8, 0x6e_u8, 0x56_u8, 0xe3_u8, 0x08_u8, 0x9f_u8, 0xec_u8,
                 0x16_u8, 0x91_u8, 0xc2_u8, 0x25_u8, 0x44_u8, 0xb6_u8, 0x05_u8,
             ][..]
         );

         super::pbkdf2_hmac(
             b"Password",
             b"NaCl",
             80000,
             MessageDigest::sha256(),
             &mut buf,
         )
         .unwrap();
         assert_eq!(
             buf,
             &[
                 0x4d_u8, 0xdc_u8, 0xd8_u8, 0xf6_u8, 0x0b_u8, 0x98_u8, 0xbe_u8, 0x21_u8, 0x83_u8,
                 0x0c_u8, 0xee_u8, 0x5e_u8, 0xf2_u8, 0x27_u8, 0x01_u8, 0xf9_u8,
             ][..]
         );
     }

     // Test vectors from
     // https://git.lysator.liu.se/nettle/nettle/blob/nettle_3.1.1_release_20150424/testsuite/pbkdf2-test.c
     #[test]
     fn pbkdf2_hmac_sha512() {
         let mut buf = [0; 64];

         super::pbkdf2_hmac(b"password", b"NaCL", 1, MessageDigest::sha512(), &mut buf).unwrap();
         assert_eq!(
             &buf[..],
             &[
                 0x73_u8, 0xde_u8, 0xcf_u8, 0xa5_u8, 0x8a_u8, 0xa2_u8, 0xe8_u8, 0x4f_u8, 0x94_u8,
                 0x77_u8, 0x1a_u8, 0x75_u8, 0x73_u8, 0x6b_u8, 0xb8_u8, 0x8b_u8, 0xd3_u8, 0xc7_u8,
                 0xb3_u8, 0x82_u8, 0x70_u8, 0xcf_u8, 0xb5_u8, 0x0c_u8, 0xb3_u8, 0x90_u8, 0xed_u8,
                 0x78_u8, 0xb3_u8, 0x05_u8, 0x65_u8, 0x6a_u8, 0xf8_u8, 0x14_u8, 0x8e_u8, 0x52_u8,
                 0x45_u8, 0x2b_u8, 0x22_u8, 0x16_u8, 0xb2_u8, 0xb8_u8, 0x09_u8, 0x8b_u8, 0x76_u8,
                 0x1f_u8, 0xc6_u8, 0x33_u8, 0x60_u8, 0x60_u8, 0xa0_u8, 0x9f_u8, 0x76_u8, 0x41_u8,
                 0x5e_u8, 0x9f_u8, 0x71_u8, 0xea_u8, 0x47_u8, 0xf9_u8, 0xe9_u8, 0x06_u8, 0x43_u8,
                 0x06_u8,
             ][..]
         );

         super::pbkdf2_hmac(
             b"pass\0word",
             b"sa\0lt",
             1,
             MessageDigest::sha512(),
             &mut buf,
         )
         .unwrap();
         assert_eq!(
             &buf[..],
             &[
                 0x71_u8, 0xa0_u8, 0xec_u8, 0x84_u8, 0x2a_u8, 0xbd_u8, 0x5c_u8, 0x67_u8, 0x8b_u8,
                 0xcf_u8, 0xd1_u8, 0x45_u8, 0xf0_u8, 0x9d_u8, 0x83_u8, 0x52_u8, 0x2f_u8, 0x93_u8,
                 0x36_u8, 0x15_u8, 0x60_u8, 0x56_u8, 0x3c_u8, 0x4d_u8, 0x0d_u8, 0x63_u8, 0xb8_u8,
                 0x83_u8, 0x29_u8, 0x87_u8, 0x10_u8, 0x90_u8, 0xe7_u8, 0x66_u8, 0x04_u8, 0xa4_u8,
                 0x9a_u8, 0xf0_u8, 0x8f_u8, 0xe7_u8, 0xc9_u8, 0xf5_u8, 0x71_u8, 0x56_u8, 0xc8_u8,
                 0x79_u8, 0x09_u8, 0x96_u8, 0xb2_u8, 0x0f_u8, 0x06_u8, 0xbc_u8, 0x53_u8, 0x5e_u8,
                 0x5a_u8, 0xb5_u8, 0x44_u8, 0x0d_u8, 0xf7_u8, 0xe8_u8, 0x78_u8, 0x29_u8, 0x6f_u8,
                 0xa7_u8,
             ][..]
         );

         super::pbkdf2_hmac(
             b"passwordPASSWORDpassword",
             b"salt\0\0\0",
             50,
             MessageDigest::sha512(),
             &mut buf,
         )
         .unwrap();
         assert_eq!(
             &buf[..],
             &[
                 0x01_u8, 0x68_u8, 0x71_u8, 0xa4_u8, 0xc4_u8, 0xb7_u8, 0x5f_u8, 0x96_u8, 0x85_u8,
                 0x7f_u8, 0xd2_u8, 0xb9_u8, 0xf8_u8, 0xca_u8, 0x28_u8, 0x02_u8, 0x3b_u8, 0x30_u8,
                 0xee_u8, 0x2a_u8, 0x39_u8, 0xf5_u8, 0xad_u8, 0xca_u8, 0xc8_u8, 0xc9_u8, 0x37_u8,
                 0x5f_u8, 0x9b_u8, 0xda_u8, 0x1c_u8, 0xcd_u8, 0x1b_u8, 0x6f_u8, 0x0b_u8, 0x2f_u8,
                 0xc3_u8, 0xad_u8, 0xda_u8, 0x50_u8, 0x54_u8, 0x12_u8, 0xe7_u8, 0x9d_u8, 0x89_u8,
                 0x00_u8, 0x56_u8, 0xc6_u8, 0x2e_u8, 0x52_u8, 0x4c_u8, 0x7d_u8, 0x51_u8, 0x15_u8,
                 0x4b_u8, 0x1a_u8, 0x85_u8, 0x34_u8, 0x57_u8, 0x5b_u8, 0xd0_u8, 0x2d_u8, 0xee_u8,
                 0x39_u8,
             ][..]
         );
     }

     #[test]
     fn bytes_to_key() {
         let salt = [16_u8, 34_u8, 19_u8, 23_u8, 141_u8, 4_u8, 207_u8, 221_u8];

         let data = [
             143_u8, 210_u8, 75_u8, 63_u8, 214_u8, 179_u8, 155_u8, 241_u8, 242_u8, 31_u8, 154_u8,
             56_u8, 198_u8, 145_u8, 192_u8, 64_u8, 2_u8, 245_u8, 167_u8, 220_u8, 55_u8, 119_u8,
             233_u8, 136_u8, 139_u8, 27_u8, 71_u8, 242_u8, 119_u8, 175_u8, 65_u8, 207_u8,
         ];

         let expected_key = vec![
             249_u8, 115_u8, 114_u8, 97_u8, 32_u8, 213_u8, 165_u8, 146_u8, 58_u8, 87_u8, 234_u8,
             3_u8, 43_u8, 250_u8, 97_u8, 114_u8, 26_u8, 98_u8, 245_u8, 246_u8, 238_u8, 177_u8,
             229_u8, 161_u8, 183_u8, 224_u8, 174_u8, 3_u8, 6_u8, 244_u8, 236_u8, 255_u8,
         ];
         let expected_iv = vec![
             4_u8, 223_u8, 153_u8, 219_u8, 28_u8, 142_u8, 234_u8, 68_u8, 227_u8, 69_u8, 98_u8,
             107_u8, 208_u8, 14_u8, 236_u8, 60_u8,
         ];

         assert_eq!(
             super::bytes_to_key(
                 Cipher::aes_256_cbc(),
                 MessageDigest::sha1(),
                 &data,
                 Some(&salt),
                 1,
             )
             .unwrap(),
             super::KeyIvPair {
                 key: expected_key,
                 iv: Some(expected_iv),
             }
         );
     }

     #[test]
     #[cfg(any(ossl110))]
     fn scrypt() {
         let pass = "pleaseletmein";
         let salt = "SodiumChloride";
         let expected =
             "7023bdcb3afd7348461c06cd81fd38ebfda8fbba904f8e3ea9b543f6545da1f2d5432955613\
              f0fcf62d49705242a9af9e61e85dc0d651e40dfcf017b45575887";

         let mut actual = [0; 64];
         super::scrypt(
             pass.as_bytes(),
             salt.as_bytes(),
             16384,
             8,
             1,
             0,
             &mut actual,
         )
         .unwrap();
         assert_eq!(hex::encode(&actual[..]), expected);
     }
 }
	use libc::c_int;
	use std::ptr;

	use crate::cvt;
	use crate::error::ErrorStack;
	use crate::hash::MessageDigest;
	use crate::symm::Cipher;
	use openssl_macros::corresponds;

	#[derive(Clone, Eq, PartialEq, Hash, Debug)]
	pub struct KeyIvPair {
	pub key: Vec<u8>,
	pub iv: Option<Vec<u8>>,
	}

	/// Derives a key and an IV from various parameters.
	///
	/// If specified, `salt` must be 8 bytes in length.
	///
	/// If the total key and IV length is less than 16 bytes and MD5 is used then
	/// the algorithm is compatible with the key derivation algorithm from PKCS#5
	/// v1.5 or PBKDF1 from PKCS#5 v2.0.
	///
	/// New applications should not use this and instead use
	/// `pbkdf2_hmac` or another more modern key derivation algorithm.
	#[corresponds(EVP_BytesToKey)]
	#[allow(clippy::useless_conversion)]
	pub fn bytes_to_key(
	cipher: Cipher,
	digest: MessageDigest,
	data: &[u8],
	salt: Option<&[u8]>,
	count: i32,
	) -> Result<KeyIvPair, ErrorStack> {
	unsafe {
	assert!(data.len() <= c_int::max_value() as usize);
	let salt_ptr = match salt {
	Some(salt) => {
	assert_eq!(salt.len(), ffi::PKCS5_SALT_LEN as usize);
	salt.as_ptr()
	}
	None => ptr::null(),
	};

	ffi::init();

	let mut iv = cipher.iv_len().map(\|l\| vec![0; l]);

	let cipher = cipher.as_ptr();
	let digest = digest.as_ptr();

	let len = cvt(ffi::EVP_BytesToKey(
	cipher,
	digest,
	salt_ptr,
	ptr::null(),
	data.len() as c_int,
	count.into(),
	ptr::null_mut(),
	ptr::null_mut(),
	))?;

	let mut key = vec![0; len as usize];
	let iv_ptr = iv
	.as_mut()
	.map(\|v\| v.as_mut_ptr())
	.unwrap_or(ptr::null_mut());

	cvt(ffi::EVP_BytesToKey(
	cipher,
	digest,
	salt_ptr,
	data.as_ptr(),
	data.len() as c_int,
	count as c_int,
	key.as_mut_ptr(),
	iv_ptr,
	))?;

	Ok(KeyIvPair { key, iv })
	}
	}

	/// Derives a key from a password and salt using the PBKDF2-HMAC algorithm with a digest function.
	#[corresponds(PKCS5_PBKDF2_HMAC)]
	pub fn pbkdf2_hmac(
	pass: &[u8],
	salt: &[u8],
	iter: usize,
	hash: MessageDigest,
	key: &mut [u8],
	) -> Result<(), ErrorStack> {
	unsafe {
	assert!(pass.len() <= c_int::max_value() as usize);
	assert!(salt.len() <= c_int::max_value() as usize);
	assert!(key.len() <= c_int::max_value() as usize);

	ffi::init();
	cvt(ffi::PKCS5_PBKDF2_HMAC(
	pass.as_ptr() as *const _,
	pass.len() as c_int,
	salt.as_ptr(),
	salt.len() as c_int,
	iter as c_int,
	hash.as_ptr(),
	key.len() as c_int,
	key.as_mut_ptr(),
	))
	.map(\|_\| ())
	}
	}

	/// Derives a key from a password and salt using the scrypt algorithm.
	///
	/// Requires OpenSSL 1.1.0 or newer.
	#[corresponds(EVP_PBE_scrypt)]
	#[cfg(any(ossl110))]
	pub fn scrypt(
	pass: &[u8],
	salt: &[u8],
	n: u64,
	r: u64,
	p: u64,
	maxmem: u64,
	key: &mut [u8],
	) -> Result<(), ErrorStack> {
	unsafe {
	ffi::init();
	cvt(ffi::EVP_PBE_scrypt(
	pass.as_ptr() as *const _,
	pass.len(),
	salt.as_ptr() as *const _,
	salt.len(),
	n,
	r,
	p,
	maxmem,
	key.as_mut_ptr() as *mut _,
	key.len(),
	))
	.map(\|_\| ())
	}
	}

	#[cfg(test)]
	mod tests {
	use crate::hash::MessageDigest;
	use crate::symm::Cipher;

	// Test vectors from
	// https://git.lysator.liu.se/nettle/nettle/blob/nettle_3.1.1_release_20150424/testsuite/pbkdf2-test.c
	#[test]
	fn pbkdf2_hmac_sha256() {
	let mut buf = [0; 16];

	super::pbkdf2_hmac(b"passwd", b"salt", 1, MessageDigest::sha256(), &mut buf).unwrap();
	assert_eq!(
	buf,
	&[
	0x55_u8, 0xac_u8, 0x04_u8, 0x6e_u8, 0x56_u8, 0xe3_u8, 0x08_u8, 0x9f_u8, 0xec_u8,
	0x16_u8, 0x91_u8, 0xc2_u8, 0x25_u8, 0x44_u8, 0xb6_u8, 0x05_u8,
	][..]
	);

	super::pbkdf2_hmac(
	b"Password",
	b"NaCl",
	80000,
	MessageDigest::sha256(),
	&mut buf,
	)
	.unwrap();
	assert_eq!(
	buf,
	&[
	0x4d_u8, 0xdc_u8, 0xd8_u8, 0xf6_u8, 0x0b_u8, 0x98_u8, 0xbe_u8, 0x21_u8, 0x83_u8,
	0x0c_u8, 0xee_u8, 0x5e_u8, 0xf2_u8, 0x27_u8, 0x01_u8, 0xf9_u8,
	][..]
	);
	}

	// Test vectors from
	// https://git.lysator.liu.se/nettle/nettle/blob/nettle_3.1.1_release_20150424/testsuite/pbkdf2-test.c
	#[test]
	fn pbkdf2_hmac_sha512() {
	let mut buf = [0; 64];

	super::pbkdf2_hmac(b"password", b"NaCL", 1, MessageDigest::sha512(), &mut buf).unwrap();
	assert_eq!(
	&buf[..],
	&[
	0x73_u8, 0xde_u8, 0xcf_u8, 0xa5_u8, 0x8a_u8, 0xa2_u8, 0xe8_u8, 0x4f_u8, 0x94_u8,
	0x77_u8, 0x1a_u8, 0x75_u8, 0x73_u8, 0x6b_u8, 0xb8_u8, 0x8b_u8, 0xd3_u8, 0xc7_u8,
	0xb3_u8, 0x82_u8, 0x70_u8, 0xcf_u8, 0xb5_u8, 0x0c_u8, 0xb3_u8, 0x90_u8, 0xed_u8,
	0x78_u8, 0xb3_u8, 0x05_u8, 0x65_u8, 0x6a_u8, 0xf8_u8, 0x14_u8, 0x8e_u8, 0x52_u8,
	0x45_u8, 0x2b_u8, 0x22_u8, 0x16_u8, 0xb2_u8, 0xb8_u8, 0x09_u8, 0x8b_u8, 0x76_u8,
	0x1f_u8, 0xc6_u8, 0x33_u8, 0x60_u8, 0x60_u8, 0xa0_u8, 0x9f_u8, 0x76_u8, 0x41_u8,
	0x5e_u8, 0x9f_u8, 0x71_u8, 0xea_u8, 0x47_u8, 0xf9_u8, 0xe9_u8, 0x06_u8, 0x43_u8,
	0x06_u8,
	][..]
	);

	super::pbkdf2_hmac(
	b"pass\0word",
	b"sa\0lt",
	1,
	MessageDigest::sha512(),
	&mut buf,
	)
	.unwrap();
	assert_eq!(
	&buf[..],
	&[
	0x71_u8, 0xa0_u8, 0xec_u8, 0x84_u8, 0x2a_u8, 0xbd_u8, 0x5c_u8, 0x67_u8, 0x8b_u8,
	0xcf_u8, 0xd1_u8, 0x45_u8, 0xf0_u8, 0x9d_u8, 0x83_u8, 0x52_u8, 0x2f_u8, 0x93_u8,
	0x36_u8, 0x15_u8, 0x60_u8, 0x56_u8, 0x3c_u8, 0x4d_u8, 0x0d_u8, 0x63_u8, 0xb8_u8,
	0x83_u8, 0x29_u8, 0x87_u8, 0x10_u8, 0x90_u8, 0xe7_u8, 0x66_u8, 0x04_u8, 0xa4_u8,
	0x9a_u8, 0xf0_u8, 0x8f_u8, 0xe7_u8, 0xc9_u8, 0xf5_u8, 0x71_u8, 0x56_u8, 0xc8_u8,
	0x79_u8, 0x09_u8, 0x96_u8, 0xb2_u8, 0x0f_u8, 0x06_u8, 0xbc_u8, 0x53_u8, 0x5e_u8,
	0x5a_u8, 0xb5_u8, 0x44_u8, 0x0d_u8, 0xf7_u8, 0xe8_u8, 0x78_u8, 0x29_u8, 0x6f_u8,
	0xa7_u8,
	][..]
	);

	super::pbkdf2_hmac(
	b"passwordPASSWORDpassword",
	b"salt\0\0\0",
	50,
	MessageDigest::sha512(),
	&mut buf,
	)
	.unwrap();
	assert_eq!(
	&buf[..],
	&[
	0x01_u8, 0x68_u8, 0x71_u8, 0xa4_u8, 0xc4_u8, 0xb7_u8, 0x5f_u8, 0x96_u8, 0x85_u8,
	0x7f_u8, 0xd2_u8, 0xb9_u8, 0xf8_u8, 0xca_u8, 0x28_u8, 0x02_u8, 0x3b_u8, 0x30_u8,
	0xee_u8, 0x2a_u8, 0x39_u8, 0xf5_u8, 0xad_u8, 0xca_u8, 0xc8_u8, 0xc9_u8, 0x37_u8,
	0x5f_u8, 0x9b_u8, 0xda_u8, 0x1c_u8, 0xcd_u8, 0x1b_u8, 0x6f_u8, 0x0b_u8, 0x2f_u8,
	0xc3_u8, 0xad_u8, 0xda_u8, 0x50_u8, 0x54_u8, 0x12_u8, 0xe7_u8, 0x9d_u8, 0x89_u8,
	0x00_u8, 0x56_u8, 0xc6_u8, 0x2e_u8, 0x52_u8, 0x4c_u8, 0x7d_u8, 0x51_u8, 0x15_u8,
	0x4b_u8, 0x1a_u8, 0x85_u8, 0x34_u8, 0x57_u8, 0x5b_u8, 0xd0_u8, 0x2d_u8, 0xee_u8,
	0x39_u8,
	][..]
	);
	}

	#[test]
	fn bytes_to_key() {
	let salt = [16_u8, 34_u8, 19_u8, 23_u8, 141_u8, 4_u8, 207_u8, 221_u8];

	let data = [
	143_u8, 210_u8, 75_u8, 63_u8, 214_u8, 179_u8, 155_u8, 241_u8, 242_u8, 31_u8, 154_u8,
	56_u8, 198_u8, 145_u8, 192_u8, 64_u8, 2_u8, 245_u8, 167_u8, 220_u8, 55_u8, 119_u8,
	233_u8, 136_u8, 139_u8, 27_u8, 71_u8, 242_u8, 119_u8, 175_u8, 65_u8, 207_u8,
	];

	let expected_key = vec![
	249_u8, 115_u8, 114_u8, 97_u8, 32_u8, 213_u8, 165_u8, 146_u8, 58_u8, 87_u8, 234_u8,
	3_u8, 43_u8, 250_u8, 97_u8, 114_u8, 26_u8, 98_u8, 245_u8, 246_u8, 238_u8, 177_u8,
	229_u8, 161_u8, 183_u8, 224_u8, 174_u8, 3_u8, 6_u8, 244_u8, 236_u8, 255_u8,
	];
	let expected_iv = vec![
	4_u8, 223_u8, 153_u8, 219_u8, 28_u8, 142_u8, 234_u8, 68_u8, 227_u8, 69_u8, 98_u8,
	107_u8, 208_u8, 14_u8, 236_u8, 60_u8,
	];

	assert_eq!(
	super::bytes_to_key(
	Cipher::aes_256_cbc(),
	MessageDigest::sha1(),
	&data,
	Some(&salt),
	1,
	)
	.unwrap(),
	super::KeyIvPair {
	key: expected_key,
	iv: Some(expected_iv),
	}
	);
	}

	#[test]
	#[cfg(any(ossl110))]
	fn scrypt() {
	let pass = "pleaseletmein";
	let salt = "SodiumChloride";
	let expected =
	"7023bdcb3afd7348461c06cd81fd38ebfda8fbba904f8e3ea9b543f6545da1f2d5432955613\
	f0fcf62d49705242a9af9e61e85dc0d651e40dfcf017b45575887";

	let mut actual = [0; 64];
	super::scrypt(
	pass.as_bytes(),
	salt.as_bytes(),
	16384,
	8,
	1,
	0,
	&mut actual,
	)
	.unwrap();
	assert_eq!(hex::encode(&actual[..]), expected);
	}
	}