vendor/openssl/src/sha.rs - toolchain/rustc - Git at Google

 //! The SHA family of hashes.
 //!
 //! SHA, or Secure Hash Algorithms, are a family of cryptographic hashing algorithms published by
 //! the National Institute of Standards and Technology (NIST).  Hash algorithms such as those in
 //! the SHA family are used to map data of an arbitrary size to a fixed-size string of bytes.
 //! As cryptographic hashing algorithms, these mappings have the property of being irreversable.
 //! This property makes hash algorithms like these excellent for uses such as verifying the
 //! contents of a file- if you know the hash you expect beforehand, then you can verify that the
 //! data you have is correct if it hashes to the same value.
 //!
 //! # Examples
 //!
 //! When dealing with data that becomes available in chunks, such as while buffering data from IO,
 //! you can create a hasher that you can repeatedly update to add bytes to.
 //!
 //! ```rust
 //! extern crate openssl;
 //! extern crate hex;
 //!
 //! use openssl::sha;
 //!
 //! fn main() {
 //!     let mut hasher = sha::Sha256::new();
 //!
 //!     hasher.update(b"Hello, ");
 //!     hasher.update(b"world");
 //!
 //!     let hash = hasher.finish();
 //!     println!("Hashed \"Hello, world\" to {}", hex::encode(hash));
 //! }
 //! ```
 //!
 //! On the other hand, if you already have access to all of the data you woud like to hash, you
 //! may prefer to use the slightly simpler method of simply calling the hash function corresponding
 //! to the algorithm you want to use.
 //!
 //! ```rust
 //! extern crate openssl;
 //! extern crate hex;
 //!
 //! use openssl::sha::sha256;
 //!
 //! fn main() {
 //!     let hash = sha256(b"your data or message");
 //!     println!("Hash = {}", hex::encode(hash));
 //! }
 //! ```
 use libc::c_void;
 use ffi;
 use std::mem;

 /// Computes the SHA1 hash of some data.
 ///
 /// # Warning
 ///
 /// SHA1 is known to be insecure - it should not be used unless required for
 /// compatibility with existing systems.
 #[inline]
 pub fn sha1(data: &[u8]) -> [u8; 20] {
     unsafe {
         let mut hash: [u8; 20] = mem::uninitialized();
         ffi::SHA1(data.as_ptr(), data.len(), hash.as_mut_ptr());
         hash
     }
 }

 /// Computes the SHA224 hash of some data.
 #[inline]
 pub fn sha224(data: &[u8]) -> [u8; 28] {
     unsafe {
         let mut hash: [u8; 28] = mem::uninitialized();
         ffi::SHA224(data.as_ptr(), data.len(), hash.as_mut_ptr());
         hash
     }
 }

 /// Computes the SHA256 hash of some data.
 #[inline]
 pub fn sha256(data: &[u8]) -> [u8; 32] {
     unsafe {
         let mut hash: [u8; 32] = mem::uninitialized();
         ffi::SHA256(data.as_ptr(), data.len(), hash.as_mut_ptr());
         hash
     }
 }

 /// Computes the SHA384 hash of some data.
 #[inline]
 pub fn sha384(data: &[u8]) -> [u8; 48] {
     unsafe {
         let mut hash: [u8; 48] = mem::uninitialized();
         ffi::SHA384(data.as_ptr(), data.len(), hash.as_mut_ptr());
         hash
     }
 }

 /// Computes the SHA512 hash of some data.
 #[inline]
 pub fn sha512(data: &[u8]) -> [u8; 64] {
     unsafe {
         let mut hash: [u8; 64] = mem::uninitialized();
         ffi::SHA512(data.as_ptr(), data.len(), hash.as_mut_ptr());
         hash
     }
 }

 /// An object which calculates a SHA1 hash of some data.
 ///
 /// # Warning
 ///
 /// SHA1 is known to be insecure - it should not be used unless required for
 /// compatibility with existing systems.
 pub struct Sha1(ffi::SHA_CTX);

 impl Sha1 {
     /// Creates a new hasher.
     #[inline]
     pub fn new() -> Sha1 {
         unsafe {
             let mut ctx = mem::uninitialized();
             ffi::SHA1_Init(&mut ctx);
             Sha1(ctx)
         }
     }

     /// Feeds some data into the hasher.
     ///
     /// This can be called multiple times.
     #[inline]
     pub fn update(&mut self, buf: &[u8]) {
         unsafe {
             ffi::SHA1_Update(&mut self.0, buf.as_ptr() as *const c_void, buf.len());
         }
     }

     /// Returns the hash of the data.
     #[inline]
     pub fn finish(mut self) -> [u8; 20] {
         unsafe {
             let mut hash: [u8; 20] = mem::uninitialized();
             ffi::SHA1_Final(hash.as_mut_ptr(), &mut self.0);
             hash
         }
     }
 }

 /// An object which calculates a SHA224 hash of some data.
 pub struct Sha224(ffi::SHA256_CTX);

 impl Sha224 {
     /// Creates a new hasher.
     #[inline]
     pub fn new() -> Sha224 {
         unsafe {
             let mut ctx = mem::uninitialized();
             ffi::SHA224_Init(&mut ctx);
             Sha224(ctx)
         }
     }

     /// Feeds some data into the hasher.
     ///
     /// This can be called multiple times.
     #[inline]
     pub fn update(&mut self, buf: &[u8]) {
         unsafe {
             ffi::SHA224_Update(&mut self.0, buf.as_ptr() as *const c_void, buf.len());
         }
     }

     /// Returns the hash of the data.
     #[inline]
     pub fn finish(mut self) -> [u8; 28] {
         unsafe {
             let mut hash: [u8; 28] = mem::uninitialized();
             ffi::SHA224_Final(hash.as_mut_ptr(), &mut self.0);
             hash
         }
     }
 }

 /// An object which calculates a SHA256 hash of some data.
 pub struct Sha256(ffi::SHA256_CTX);

 impl Sha256 {
     /// Creates a new hasher.
     #[inline]
     pub fn new() -> Sha256 {
         unsafe {
             let mut ctx = mem::uninitialized();
             ffi::SHA256_Init(&mut ctx);
             Sha256(ctx)
         }
     }

     /// Feeds some data into the hasher.
     ///
     /// This can be called multiple times.
     #[inline]
     pub fn update(&mut self, buf: &[u8]) {
         unsafe {
             ffi::SHA256_Update(&mut self.0, buf.as_ptr() as *const c_void, buf.len());
         }
     }

     /// Returns the hash of the data.
     #[inline]
     pub fn finish(mut self) -> [u8; 32] {
         unsafe {
             let mut hash: [u8; 32] = mem::uninitialized();
             ffi::SHA256_Final(hash.as_mut_ptr(), &mut self.0);
             hash
         }
     }
 }

 /// An object which calculates a SHA384 hash of some data.
 pub struct Sha384(ffi::SHA512_CTX);

 impl Sha384 {
     /// Creates a new hasher.
     #[inline]
     pub fn new() -> Sha384 {
         unsafe {
             let mut ctx = mem::uninitialized();
             ffi::SHA384_Init(&mut ctx);
             Sha384(ctx)
         }
     }

     /// Feeds some data into the hasher.
     ///
     /// This can be called multiple times.
     #[inline]
     pub fn update(&mut self, buf: &[u8]) {
         unsafe {
             ffi::SHA384_Update(&mut self.0, buf.as_ptr() as *const c_void, buf.len());
         }
     }

     /// Returns the hash of the data.
     #[inline]
     pub fn finish(mut self) -> [u8; 48] {
         unsafe {
             let mut hash: [u8; 48] = mem::uninitialized();
             ffi::SHA384_Final(hash.as_mut_ptr(), &mut self.0);
             hash
         }
     }
 }

 /// An object which calculates a SHA512 hash of some data.
 pub struct Sha512(ffi::SHA512_CTX);

 impl Sha512 {
     /// Creates a new hasher.
     #[inline]
     pub fn new() -> Sha512 {
         unsafe {
             let mut ctx = mem::uninitialized();
             ffi::SHA512_Init(&mut ctx);
             Sha512(ctx)
         }
     }

     /// Feeds some data into the hasher.
     ///
     /// This can be called multiple times.
     #[inline]
     pub fn update(&mut self, buf: &[u8]) {
         unsafe {
             ffi::SHA512_Update(&mut self.0, buf.as_ptr() as *const c_void, buf.len());
         }
     }

     /// Returns the hash of the data.
     #[inline]
     pub fn finish(mut self) -> [u8; 64] {
         unsafe {
             let mut hash: [u8; 64] = mem::uninitialized();
             ffi::SHA512_Final(hash.as_mut_ptr(), &mut self.0);
             hash
         }
     }
 }

 #[cfg(test)]
 mod test {
     use hex;

     use super::*;

     #[test]
     fn standalone_1() {
         let data = b"abc";
         let expected = "a9993e364706816aba3e25717850c26c9cd0d89d";

         assert_eq!(hex::encode(sha1(data)), expected);
     }

     #[test]
     fn struct_1() {
         let expected = "a9993e364706816aba3e25717850c26c9cd0d89d";

         let mut hasher = Sha1::new();
         hasher.update(b"a");
         hasher.update(b"bc");
         assert_eq!(hex::encode(hasher.finish()), expected);
     }

     #[test]
     fn standalone_224() {
         let data = b"abc";
         let expected = "23097d223405d8228642a477bda255b32aadbce4bda0b3f7e36c9da7";

         assert_eq!(hex::encode(sha224(data)), expected);
     }

     #[test]
     fn struct_224() {
         let expected = "23097d223405d8228642a477bda255b32aadbce4bda0b3f7e36c9da7";

         let mut hasher = Sha224::new();
         hasher.update(b"a");
         hasher.update(b"bc");
         assert_eq!(hex::encode(hasher.finish()), expected);
     }

     #[test]
     fn standalone_256() {
         let data = b"abc";
         let expected = "ba7816bf8f01cfea414140de5dae2223b00361a396177a9cb410ff61f20015ad";

         assert_eq!(hex::encode(sha256(data)), expected);
     }

     #[test]
     fn struct_256() {
         let expected = "ba7816bf8f01cfea414140de5dae2223b00361a396177a9cb410ff61f20015ad";

         let mut hasher = Sha256::new();
         hasher.update(b"a");
         hasher.update(b"bc");
         assert_eq!(hex::encode(hasher.finish()), expected);
     }

     #[test]
     fn standalone_384() {
         let data = b"abc";
         let expected = "cb00753f45a35e8bb5a03d699ac65007272c32ab0eded1631a8b605a43ff5bed8086072ba1e\
                         7cc2358baeca134c825a7";

         assert_eq!(hex::encode(&sha384(data)[..]), expected);
     }

     #[test]
     fn struct_384() {
         let expected = "cb00753f45a35e8bb5a03d699ac65007272c32ab0eded1631a8b605a43ff5bed8086072ba1e\
                         7cc2358baeca134c825a7";

         let mut hasher = Sha384::new();
         hasher.update(b"a");
         hasher.update(b"bc");
         assert_eq!(hex::encode(&hasher.finish()[..]), expected);
     }

     #[test]
     fn standalone_512() {
         let data = b"abc";
         let expected = "ddaf35a193617abacc417349ae20413112e6fa4e89a97ea20a9eeee64b55d39a2192992a274\
                         fc1a836ba3c23a3feebbd454d4423643ce80e2a9ac94fa54ca49f";

         assert_eq!(hex::encode(&sha512(data)[..]), expected);
     }

     #[test]
     fn struct_512() {
         let expected = "ddaf35a193617abacc417349ae20413112e6fa4e89a97ea20a9eeee64b55d39a2192992a274\
                         fc1a836ba3c23a3feebbd454d4423643ce80e2a9ac94fa54ca49f";

         let mut hasher = Sha512::new();
         hasher.update(b"a");
         hasher.update(b"bc");
         assert_eq!(hex::encode(&hasher.finish()[..]), expected);
     }
 }
	//! The SHA family of hashes.
	//!
	//! SHA, or Secure Hash Algorithms, are a family of cryptographic hashing algorithms published by
	//! the National Institute of Standards and Technology (NIST). Hash algorithms such as those in
	//! the SHA family are used to map data of an arbitrary size to a fixed-size string of bytes.
	//! As cryptographic hashing algorithms, these mappings have the property of being irreversable.
	//! This property makes hash algorithms like these excellent for uses such as verifying the
	//! contents of a file- if you know the hash you expect beforehand, then you can verify that the
	//! data you have is correct if it hashes to the same value.
	//!
	//! # Examples
	//!
	//! When dealing with data that becomes available in chunks, such as while buffering data from IO,
	//! you can create a hasher that you can repeatedly update to add bytes to.
	//!
	//! ```rust
	//! extern crate openssl;
	//! extern crate hex;
	//!
	//! use openssl::sha;
	//!
	//! fn main() {
	//! let mut hasher = sha::Sha256::new();
	//!
	//! hasher.update(b"Hello, ");
	//! hasher.update(b"world");
	//!
	//! let hash = hasher.finish();
	//! println!("Hashed \"Hello, world\" to {}", hex::encode(hash));
	//! }
	//! ```
	//!
	//! On the other hand, if you already have access to all of the data you woud like to hash, you
	//! may prefer to use the slightly simpler method of simply calling the hash function corresponding
	//! to the algorithm you want to use.
	//!
	//! ```rust
	//! extern crate openssl;
	//! extern crate hex;
	//!
	//! use openssl::sha::sha256;
	//!
	//! fn main() {
	//! let hash = sha256(b"your data or message");
	//! println!("Hash = {}", hex::encode(hash));
	//! }
	//! ```
	use libc::c_void;
	use ffi;
	use std::mem;

	/// Computes the SHA1 hash of some data.
	///
	/// # Warning
	///
	/// SHA1 is known to be insecure - it should not be used unless required for
	/// compatibility with existing systems.
	#[inline]
	pub fn sha1(data: &[u8]) -> [u8; 20] {
	unsafe {
	let mut hash: [u8; 20] = mem::uninitialized();
	ffi::SHA1(data.as_ptr(), data.len(), hash.as_mut_ptr());
	hash
	}
	}

	/// Computes the SHA224 hash of some data.
	#[inline]
	pub fn sha224(data: &[u8]) -> [u8; 28] {
	unsafe {
	let mut hash: [u8; 28] = mem::uninitialized();
	ffi::SHA224(data.as_ptr(), data.len(), hash.as_mut_ptr());
	hash
	}
	}

	/// Computes the SHA256 hash of some data.
	#[inline]
	pub fn sha256(data: &[u8]) -> [u8; 32] {
	unsafe {
	let mut hash: [u8; 32] = mem::uninitialized();
	ffi::SHA256(data.as_ptr(), data.len(), hash.as_mut_ptr());
	hash
	}
	}

	/// Computes the SHA384 hash of some data.
	#[inline]
	pub fn sha384(data: &[u8]) -> [u8; 48] {
	unsafe {
	let mut hash: [u8; 48] = mem::uninitialized();
	ffi::SHA384(data.as_ptr(), data.len(), hash.as_mut_ptr());
	hash
	}
	}

	/// Computes the SHA512 hash of some data.
	#[inline]
	pub fn sha512(data: &[u8]) -> [u8; 64] {
	unsafe {
	let mut hash: [u8; 64] = mem::uninitialized();
	ffi::SHA512(data.as_ptr(), data.len(), hash.as_mut_ptr());
	hash
	}
	}

	/// An object which calculates a SHA1 hash of some data.
	///
	/// # Warning
	///
	/// SHA1 is known to be insecure - it should not be used unless required for
	/// compatibility with existing systems.
	pub struct Sha1(ffi::SHA_CTX);

	impl Sha1 {
	/// Creates a new hasher.
	#[inline]
	pub fn new() -> Sha1 {
	unsafe {
	let mut ctx = mem::uninitialized();
	ffi::SHA1_Init(&mut ctx);
	Sha1(ctx)
	}
	}

	/// Feeds some data into the hasher.
	///
	/// This can be called multiple times.
	#[inline]
	pub fn update(&mut self, buf: &[u8]) {
	unsafe {
	ffi::SHA1_Update(&mut self.0, buf.as_ptr() as *const c_void, buf.len());
	}
	}

	/// Returns the hash of the data.
	#[inline]
	pub fn finish(mut self) -> [u8; 20] {
	unsafe {
	let mut hash: [u8; 20] = mem::uninitialized();
	ffi::SHA1_Final(hash.as_mut_ptr(), &mut self.0);
	hash
	}
	}
	}

	/// An object which calculates a SHA224 hash of some data.
	pub struct Sha224(ffi::SHA256_CTX);

	impl Sha224 {
	/// Creates a new hasher.
	#[inline]
	pub fn new() -> Sha224 {
	unsafe {
	let mut ctx = mem::uninitialized();
	ffi::SHA224_Init(&mut ctx);
	Sha224(ctx)
	}
	}

	/// Feeds some data into the hasher.
	///
	/// This can be called multiple times.
	#[inline]
	pub fn update(&mut self, buf: &[u8]) {
	unsafe {
	ffi::SHA224_Update(&mut self.0, buf.as_ptr() as *const c_void, buf.len());
	}
	}

	/// Returns the hash of the data.
	#[inline]
	pub fn finish(mut self) -> [u8; 28] {
	unsafe {
	let mut hash: [u8; 28] = mem::uninitialized();
	ffi::SHA224_Final(hash.as_mut_ptr(), &mut self.0);
	hash
	}
	}
	}

	/// An object which calculates a SHA256 hash of some data.
	pub struct Sha256(ffi::SHA256_CTX);

	impl Sha256 {
	/// Creates a new hasher.
	#[inline]
	pub fn new() -> Sha256 {
	unsafe {
	let mut ctx = mem::uninitialized();
	ffi::SHA256_Init(&mut ctx);
	Sha256(ctx)
	}
	}

	/// Feeds some data into the hasher.
	///
	/// This can be called multiple times.
	#[inline]
	pub fn update(&mut self, buf: &[u8]) {
	unsafe {
	ffi::SHA256_Update(&mut self.0, buf.as_ptr() as *const c_void, buf.len());
	}
	}

	/// Returns the hash of the data.
	#[inline]
	pub fn finish(mut self) -> [u8; 32] {
	unsafe {
	let mut hash: [u8; 32] = mem::uninitialized();
	ffi::SHA256_Final(hash.as_mut_ptr(), &mut self.0);
	hash
	}
	}
	}

	/// An object which calculates a SHA384 hash of some data.
	pub struct Sha384(ffi::SHA512_CTX);

	impl Sha384 {
	/// Creates a new hasher.
	#[inline]
	pub fn new() -> Sha384 {
	unsafe {
	let mut ctx = mem::uninitialized();
	ffi::SHA384_Init(&mut ctx);
	Sha384(ctx)
	}
	}

	/// Feeds some data into the hasher.
	///
	/// This can be called multiple times.
	#[inline]
	pub fn update(&mut self, buf: &[u8]) {
	unsafe {
	ffi::SHA384_Update(&mut self.0, buf.as_ptr() as *const c_void, buf.len());
	}
	}

	/// Returns the hash of the data.
	#[inline]
	pub fn finish(mut self) -> [u8; 48] {
	unsafe {
	let mut hash: [u8; 48] = mem::uninitialized();
	ffi::SHA384_Final(hash.as_mut_ptr(), &mut self.0);
	hash
	}
	}
	}

	/// An object which calculates a SHA512 hash of some data.
	pub struct Sha512(ffi::SHA512_CTX);

	impl Sha512 {
	/// Creates a new hasher.
	#[inline]
	pub fn new() -> Sha512 {
	unsafe {
	let mut ctx = mem::uninitialized();
	ffi::SHA512_Init(&mut ctx);
	Sha512(ctx)
	}
	}

	/// Feeds some data into the hasher.
	///
	/// This can be called multiple times.
	#[inline]
	pub fn update(&mut self, buf: &[u8]) {
	unsafe {
	ffi::SHA512_Update(&mut self.0, buf.as_ptr() as *const c_void, buf.len());
	}
	}

	/// Returns the hash of the data.
	#[inline]
	pub fn finish(mut self) -> [u8; 64] {
	unsafe {
	let mut hash: [u8; 64] = mem::uninitialized();
	ffi::SHA512_Final(hash.as_mut_ptr(), &mut self.0);
	hash
	}
	}
	}

	#[cfg(test)]
	mod test {
	use hex;

	use super::*;

	#[test]
	fn standalone_1() {
	let data = b"abc";
	let expected = "a9993e364706816aba3e25717850c26c9cd0d89d";

	assert_eq!(hex::encode(sha1(data)), expected);
	}

	#[test]
	fn struct_1() {
	let expected = "a9993e364706816aba3e25717850c26c9cd0d89d";

	let mut hasher = Sha1::new();
	hasher.update(b"a");
	hasher.update(b"bc");
	assert_eq!(hex::encode(hasher.finish()), expected);
	}

	#[test]
	fn standalone_224() {
	let data = b"abc";
	let expected = "23097d223405d8228642a477bda255b32aadbce4bda0b3f7e36c9da7";

	assert_eq!(hex::encode(sha224(data)), expected);
	}

	#[test]
	fn struct_224() {
	let expected = "23097d223405d8228642a477bda255b32aadbce4bda0b3f7e36c9da7";

	let mut hasher = Sha224::new();
	hasher.update(b"a");
	hasher.update(b"bc");
	assert_eq!(hex::encode(hasher.finish()), expected);
	}

	#[test]
	fn standalone_256() {
	let data = b"abc";
	let expected = "ba7816bf8f01cfea414140de5dae2223b00361a396177a9cb410ff61f20015ad";

	assert_eq!(hex::encode(sha256(data)), expected);
	}

	#[test]
	fn struct_256() {
	let expected = "ba7816bf8f01cfea414140de5dae2223b00361a396177a9cb410ff61f20015ad";

	let mut hasher = Sha256::new();
	hasher.update(b"a");
	hasher.update(b"bc");
	assert_eq!(hex::encode(hasher.finish()), expected);
	}

	#[test]
	fn standalone_384() {
	let data = b"abc";
	let expected = "cb00753f45a35e8bb5a03d699ac65007272c32ab0eded1631a8b605a43ff5bed8086072ba1e\
	7cc2358baeca134c825a7";

	assert_eq!(hex::encode(&sha384(data)[..]), expected);
	}

	#[test]
	fn struct_384() {
	let expected = "cb00753f45a35e8bb5a03d699ac65007272c32ab0eded1631a8b605a43ff5bed8086072ba1e\
	7cc2358baeca134c825a7";

	let mut hasher = Sha384::new();
	hasher.update(b"a");
	hasher.update(b"bc");
	assert_eq!(hex::encode(&hasher.finish()[..]), expected);
	}

	#[test]
	fn standalone_512() {
	let data = b"abc";
	let expected = "ddaf35a193617abacc417349ae20413112e6fa4e89a97ea20a9eeee64b55d39a2192992a274\
	fc1a836ba3c23a3feebbd454d4423643ce80e2a9ac94fa54ca49f";

	assert_eq!(hex::encode(&sha512(data)[..]), expected);
	}

	#[test]
	fn struct_512() {
	let expected = "ddaf35a193617abacc417349ae20413112e6fa4e89a97ea20a9eeee64b55d39a2192992a274\
	fc1a836ba3c23a3feebbd454d4423643ce80e2a9ac94fa54ca49f";

	let mut hasher = Sha512::new();
	hasher.update(b"a");
	hasher.update(b"bc");
	assert_eq!(hex::encode(&hasher.finish()[..]), expected);
	}
	}