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

 //! Digital Signatures
 //!
 //! DSA ensures a message originated from a known sender, and was not modified.
 //! DSA uses asymmetrical keys and an algorithm to output a signature of the message
 //! using the private key that can be validated with the public key but not be generated
 //! without the private key.

 use cfg_if::cfg_if;
 use foreign_types::{ForeignType, ForeignTypeRef};
 use libc::{c_int, c_uint};
 use std::fmt;
 use std::mem;
 use std::ptr;

 use crate::bn::{BigNum, BigNumRef};
 use crate::error::ErrorStack;
 use crate::pkey::{HasParams, HasPrivate, HasPublic, Private, Public};
 use crate::util::ForeignTypeRefExt;
 use crate::{cvt, cvt_p};
 use openssl_macros::corresponds;

 generic_foreign_type_and_impl_send_sync! {
     type CType = ffi::DSA;
     fn drop = ffi::DSA_free;

     /// Object representing DSA keys.
     ///
     /// A DSA object contains the parameters p, q, and g.  There is a private
     /// and public key.  The values p, g, and q are:
     ///
     /// * `p`: DSA prime parameter
     /// * `q`: DSA sub-prime parameter
     /// * `g`: DSA base parameter
     ///
     /// These values are used to calculate a pair of asymmetrical keys used for
     /// signing.
     ///
     /// OpenSSL documentation at [`DSA_new`]
     ///
     /// [`DSA_new`]: https://www.openssl.org/docs/man1.1.0/crypto/DSA_new.html
     ///
     /// # Examples
     ///
     /// ```
     /// use openssl::dsa::Dsa;
     /// use openssl::error::ErrorStack;
     /// use openssl::pkey::Private;
     ///
     /// fn create_dsa() -> Result<Dsa<Private>, ErrorStack> {
     ///     let sign = Dsa::generate(2048)?;
     ///     Ok(sign)
     /// }
     /// # fn main() {
     /// #    create_dsa();
     /// # }
     /// ```
     pub struct Dsa<T>;
     /// Reference to [`Dsa`].
     ///
     /// [`Dsa`]: struct.Dsa.html
     pub struct DsaRef<T>;
 }

 impl<T> Clone for Dsa<T> {
     fn clone(&self) -> Dsa<T> {
         (**self).to_owned()
     }
 }

 impl<T> ToOwned for DsaRef<T> {
     type Owned = Dsa<T>;

     fn to_owned(&self) -> Dsa<T> {
         unsafe {
             ffi::DSA_up_ref(self.as_ptr());
             Dsa::from_ptr(self.as_ptr())
         }
     }
 }

 impl<T> DsaRef<T>
 where
     T: HasPublic,
 {
     to_pem! {
         /// Serializes the public key into a PEM-encoded SubjectPublicKeyInfo structure.
         ///
         /// The output will have a header of `-----BEGIN PUBLIC KEY-----`.
         #[corresponds(PEM_write_bio_DSA_PUBKEY)]
         public_key_to_pem,
         ffi::PEM_write_bio_DSA_PUBKEY
     }

     to_der! {
         /// Serializes the public key into a DER-encoded SubjectPublicKeyInfo structure.
         #[corresponds(i2d_DSA_PUBKEY)]
         public_key_to_der,
         ffi::i2d_DSA_PUBKEY
     }

     /// Returns a reference to the public key component of `self`.
     #[corresponds(DSA_get0_key)]
     pub fn pub_key(&self) -> &BigNumRef {
         unsafe {
             let mut pub_key = ptr::null();
             DSA_get0_key(self.as_ptr(), &mut pub_key, ptr::null_mut());
             BigNumRef::from_const_ptr(pub_key)
         }
     }
 }

 impl<T> DsaRef<T>
 where
     T: HasPrivate,
 {
     private_key_to_pem! {
         /// Serializes the private key to a PEM-encoded DSAPrivateKey structure.
         ///
         /// The output will have a header of `-----BEGIN DSA PRIVATE KEY-----`.
         #[corresponds(PEM_write_bio_DSAPrivateKey)]
         private_key_to_pem,
         /// Serializes the private key to a PEM-encoded encrypted DSAPrivateKey structure.
         ///
         /// The output will have a header of `-----BEGIN DSA PRIVATE KEY-----`.
         #[corresponds(PEM_write_bio_DSAPrivateKey)]
         private_key_to_pem_passphrase,
         ffi::PEM_write_bio_DSAPrivateKey
     }

     /// Returns a reference to the private key component of `self`.
     #[corresponds(DSA_get0_key)]
     pub fn priv_key(&self) -> &BigNumRef {
         unsafe {
             let mut priv_key = ptr::null();
             DSA_get0_key(self.as_ptr(), ptr::null_mut(), &mut priv_key);
             BigNumRef::from_const_ptr(priv_key)
         }
     }
 }

 impl<T> DsaRef<T>
 where
     T: HasParams,
 {
     /// Returns the maximum size of the signature output by `self` in bytes.
     #[corresponds(DSA_size)]
     pub fn size(&self) -> u32 {
         unsafe { ffi::DSA_size(self.as_ptr()) as u32 }
     }

     /// Returns the DSA prime parameter of `self`.
     #[corresponds(DSA_get0_pqg)]
     pub fn p(&self) -> &BigNumRef {
         unsafe {
             let mut p = ptr::null();
             DSA_get0_pqg(self.as_ptr(), &mut p, ptr::null_mut(), ptr::null_mut());
             BigNumRef::from_const_ptr(p)
         }
     }

     /// Returns the DSA sub-prime parameter of `self`.
     #[corresponds(DSA_get0_pqg)]
     pub fn q(&self) -> &BigNumRef {
         unsafe {
             let mut q = ptr::null();
             DSA_get0_pqg(self.as_ptr(), ptr::null_mut(), &mut q, ptr::null_mut());
             BigNumRef::from_const_ptr(q)
         }
     }

     /// Returns the DSA base parameter of `self`.
     #[corresponds(DSA_get0_pqg)]
     pub fn g(&self) -> &BigNumRef {
         unsafe {
             let mut g = ptr::null();
             DSA_get0_pqg(self.as_ptr(), ptr::null_mut(), ptr::null_mut(), &mut g);
             BigNumRef::from_const_ptr(g)
         }
     }
 }
 #[cfg(boringssl)]
 type BitType = c_uint;
 #[cfg(not(boringssl))]
 type BitType = c_int;

 impl Dsa<Private> {
     /// Generate a DSA key pair.
     ///
     /// Calls [`DSA_generate_parameters_ex`] to populate the `p`, `g`, and `q` values.
     /// These values are used to generate the key pair with [`DSA_generate_key`].
     ///
     /// The `bits` parameter corresponds to the length of the prime `p`.
     ///
     /// [`DSA_generate_parameters_ex`]: https://www.openssl.org/docs/man1.1.0/crypto/DSA_generate_parameters_ex.html
     /// [`DSA_generate_key`]: https://www.openssl.org/docs/man1.1.0/crypto/DSA_generate_key.html
     pub fn generate(bits: u32) -> Result<Dsa<Private>, ErrorStack> {
         ffi::init();
         unsafe {
             let dsa = Dsa::from_ptr(cvt_p(ffi::DSA_new())?);
             cvt(ffi::DSA_generate_parameters_ex(
                 dsa.0,
                 bits as BitType,
                 ptr::null(),
                 0,
                 ptr::null_mut(),
                 ptr::null_mut(),
                 ptr::null_mut(),
             ))?;
             cvt(ffi::DSA_generate_key(dsa.0))?;
             Ok(dsa)
         }
     }

     /// Create a DSA key pair with the given parameters
     ///
     /// `p`, `q` and `g` are the common parameters.
     /// `priv_key` is the private component of the key pair.
     /// `pub_key` is the public component of the key. Can be computed via `g^(priv_key) mod p`
     pub fn from_private_components(
         p: BigNum,
         q: BigNum,
         g: BigNum,
         priv_key: BigNum,
         pub_key: BigNum,
     ) -> Result<Dsa<Private>, ErrorStack> {
         ffi::init();
         unsafe {
             let dsa = Dsa::from_ptr(cvt_p(ffi::DSA_new())?);
             cvt(DSA_set0_pqg(dsa.0, p.as_ptr(), q.as_ptr(), g.as_ptr()))?;
             mem::forget((p, q, g));
             cvt(DSA_set0_key(dsa.0, pub_key.as_ptr(), priv_key.as_ptr()))?;
             mem::forget((pub_key, priv_key));
             Ok(dsa)
         }
     }
 }

 impl Dsa<Public> {
     from_pem! {
         /// Decodes a PEM-encoded SubjectPublicKeyInfo structure containing a DSA key.
         ///
         /// The input should have a header of `-----BEGIN PUBLIC KEY-----`.
         #[corresponds(PEM_read_bio_DSA_PUBKEY)]
         public_key_from_pem,
         Dsa<Public>,
         ffi::PEM_read_bio_DSA_PUBKEY
     }

     from_der! {
         /// Decodes a DER-encoded SubjectPublicKeyInfo structure containing a DSA key.
         #[corresponds(d2i_DSA_PUBKEY)]
         public_key_from_der,
         Dsa<Public>,
         ffi::d2i_DSA_PUBKEY
     }

     /// Create a new DSA key with only public components.
     ///
     /// `p`, `q` and `g` are the common parameters.
     /// `pub_key` is the public component of the key.
     pub fn from_public_components(
         p: BigNum,
         q: BigNum,
         g: BigNum,
         pub_key: BigNum,
     ) -> Result<Dsa<Public>, ErrorStack> {
         ffi::init();
         unsafe {
             let dsa = Dsa::from_ptr(cvt_p(ffi::DSA_new())?);
             cvt(DSA_set0_pqg(dsa.0, p.as_ptr(), q.as_ptr(), g.as_ptr()))?;
             mem::forget((p, q, g));
             cvt(DSA_set0_key(dsa.0, pub_key.as_ptr(), ptr::null_mut()))?;
             mem::forget(pub_key);
             Ok(dsa)
         }
     }
 }

 impl<T> fmt::Debug for Dsa<T> {
     fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
         write!(f, "DSA")
     }
 }

 cfg_if! {
     if #[cfg(any(ossl110, libressl273))] {
         use ffi::{DSA_get0_key, DSA_get0_pqg, DSA_set0_key, DSA_set0_pqg};
     } else {
         #[allow(bad_style)]
         unsafe fn DSA_get0_pqg(
             d: *mut ffi::DSA,
             p: *mut *const ffi::BIGNUM,
             q: *mut *const ffi::BIGNUM,
             g: *mut *const ffi::BIGNUM)
         {
             if !p.is_null() {
                 *p = (*d).p;
             }
             if !q.is_null() {
                 *q = (*d).q;
             }
             if !g.is_null() {
                 *g = (*d).g;
             }
         }

         #[allow(bad_style)]
         unsafe fn DSA_get0_key(
             d: *mut ffi::DSA,
             pub_key: *mut *const ffi::BIGNUM,
             priv_key: *mut *const ffi::BIGNUM)
         {
             if !pub_key.is_null() {
                 *pub_key = (*d).pub_key;
             }
             if !priv_key.is_null() {
                 *priv_key = (*d).priv_key;
             }
         }

         #[allow(bad_style)]
         unsafe fn DSA_set0_key(
             d: *mut ffi::DSA,
             pub_key: *mut ffi::BIGNUM,
             priv_key: *mut ffi::BIGNUM) -> c_int
         {
             (*d).pub_key = pub_key;
             (*d).priv_key = priv_key;
             1
         }

         #[allow(bad_style)]
         unsafe fn DSA_set0_pqg(
             d: *mut ffi::DSA,
             p: *mut ffi::BIGNUM,
             q: *mut ffi::BIGNUM,
             g: *mut ffi::BIGNUM) -> c_int
         {
             (*d).p = p;
             (*d).q = q;
             (*d).g = g;
             1
         }
     }
 }

 #[cfg(test)]
 mod test {
     use super::*;
     use crate::bn::BigNumContext;
     use crate::hash::MessageDigest;
     use crate::pkey::PKey;
     use crate::sign::{Signer, Verifier};

     #[test]
     pub fn test_generate() {
         Dsa::generate(1024).unwrap();
     }

     #[test]
     fn test_pubkey_generation() {
         let dsa = Dsa::generate(1024).unwrap();
         let p = dsa.p();
         let g = dsa.g();
         let priv_key = dsa.priv_key();
         let pub_key = dsa.pub_key();
         let mut ctx = BigNumContext::new().unwrap();
         let mut calc = BigNum::new().unwrap();
         calc.mod_exp(g, priv_key, p, &mut ctx).unwrap();
         assert_eq!(&calc, pub_key)
     }

     #[test]
     fn test_priv_key_from_parts() {
         let p = BigNum::from_u32(283).unwrap();
         let q = BigNum::from_u32(47).unwrap();
         let g = BigNum::from_u32(60).unwrap();
         let priv_key = BigNum::from_u32(15).unwrap();
         let pub_key = BigNum::from_u32(207).unwrap();

         let dsa = Dsa::from_private_components(p, q, g, priv_key, pub_key).unwrap();
         assert_eq!(dsa.pub_key(), &BigNum::from_u32(207).unwrap());
         assert_eq!(dsa.priv_key(), &BigNum::from_u32(15).unwrap());
         assert_eq!(dsa.p(), &BigNum::from_u32(283).unwrap());
         assert_eq!(dsa.q(), &BigNum::from_u32(47).unwrap());
         assert_eq!(dsa.g(), &BigNum::from_u32(60).unwrap());
     }

     #[test]
     fn test_pub_key_from_parts() {
         let p = BigNum::from_u32(283).unwrap();
         let q = BigNum::from_u32(47).unwrap();
         let g = BigNum::from_u32(60).unwrap();
         let pub_key = BigNum::from_u32(207).unwrap();

         let dsa = Dsa::from_public_components(p, q, g, pub_key).unwrap();
         assert_eq!(dsa.pub_key(), &BigNum::from_u32(207).unwrap());
         assert_eq!(dsa.p(), &BigNum::from_u32(283).unwrap());
         assert_eq!(dsa.q(), &BigNum::from_u32(47).unwrap());
         assert_eq!(dsa.g(), &BigNum::from_u32(60).unwrap());
     }

     #[test]
     #[cfg(not(boringssl))]
     fn test_signature() {
         const TEST_DATA: &[u8] = &[0, 1, 2, 3, 4, 5, 6, 7, 8, 9];
         let dsa_ref = Dsa::generate(1024).unwrap();

         let p = dsa_ref.p();
         let q = dsa_ref.q();
         let g = dsa_ref.g();

         let pub_key = dsa_ref.pub_key();
         let priv_key = dsa_ref.priv_key();

         let priv_key = Dsa::from_private_components(
             BigNumRef::to_owned(p).unwrap(),
             BigNumRef::to_owned(q).unwrap(),
             BigNumRef::to_owned(g).unwrap(),
             BigNumRef::to_owned(priv_key).unwrap(),
             BigNumRef::to_owned(pub_key).unwrap(),
         )
         .unwrap();
         let priv_key = PKey::from_dsa(priv_key).unwrap();

         let pub_key = Dsa::from_public_components(
             BigNumRef::to_owned(p).unwrap(),
             BigNumRef::to_owned(q).unwrap(),
             BigNumRef::to_owned(g).unwrap(),
             BigNumRef::to_owned(pub_key).unwrap(),
         )
         .unwrap();
         let pub_key = PKey::from_dsa(pub_key).unwrap();

         let mut signer = Signer::new(MessageDigest::sha256(), &priv_key).unwrap();
         signer.update(TEST_DATA).unwrap();

         let signature = signer.sign_to_vec().unwrap();
         let mut verifier = Verifier::new(MessageDigest::sha256(), &pub_key).unwrap();
         verifier.update(TEST_DATA).unwrap();
         assert!(verifier.verify(&signature[..]).unwrap());
     }

     #[test]
     #[allow(clippy::redundant_clone)]
     fn clone() {
         let key = Dsa::generate(2048).unwrap();
         drop(key.clone());
     }
 }
	//! Digital Signatures
	//!
	//! DSA ensures a message originated from a known sender, and was not modified.
	//! DSA uses asymmetrical keys and an algorithm to output a signature of the message
	//! using the private key that can be validated with the public key but not be generated
	//! without the private key.

	use cfg_if::cfg_if;
	use foreign_types::{ForeignType, ForeignTypeRef};
	use libc::{c_int, c_uint};
	use std::fmt;
	use std::mem;
	use std::ptr;

	use crate::bn::{BigNum, BigNumRef};
	use crate::error::ErrorStack;
	use crate::pkey::{HasParams, HasPrivate, HasPublic, Private, Public};
	use crate::util::ForeignTypeRefExt;
	use crate::{cvt, cvt_p};
	use openssl_macros::corresponds;

	generic_foreign_type_and_impl_send_sync! {
	type CType = ffi::DSA;
	fn drop = ffi::DSA_free;

	/// Object representing DSA keys.
	///
	/// A DSA object contains the parameters p, q, and g. There is a private
	/// and public key. The values p, g, and q are:
	///
	/// * `p`: DSA prime parameter
	/// * `q`: DSA sub-prime parameter
	/// * `g`: DSA base parameter
	///
	/// These values are used to calculate a pair of asymmetrical keys used for
	/// signing.
	///
	/// OpenSSL documentation at [`DSA_new`]
	///
	/// [`DSA_new`]: https://www.openssl.org/docs/man1.1.0/crypto/DSA_new.html
	///
	/// # Examples
	///
	/// ```
	/// use openssl::dsa::Dsa;
	/// use openssl::error::ErrorStack;
	/// use openssl::pkey::Private;
	///
	/// fn create_dsa() -> Result<Dsa<Private>, ErrorStack> {
	/// let sign = Dsa::generate(2048)?;
	/// Ok(sign)
	/// }
	/// # fn main() {
	/// # create_dsa();
	/// # }
	/// ```
	pub struct Dsa<T>;
	/// Reference to [`Dsa`].
	///
	/// [`Dsa`]: struct.Dsa.html
	pub struct DsaRef<T>;
	}

	impl<T> Clone for Dsa<T> {
	fn clone(&self) -> Dsa<T> {
	(**self).to_owned()
	}
	}

	impl<T> ToOwned for DsaRef<T> {
	type Owned = Dsa<T>;

	fn to_owned(&self) -> Dsa<T> {
	unsafe {
	ffi::DSA_up_ref(self.as_ptr());
	Dsa::from_ptr(self.as_ptr())
	}
	}
	}

	impl<T> DsaRef<T>
	where
	T: HasPublic,
	{
	to_pem! {
	/// Serializes the public key into a PEM-encoded SubjectPublicKeyInfo structure.
	///
	/// The output will have a header of `-----BEGIN PUBLIC KEY-----`.
	#[corresponds(PEM_write_bio_DSA_PUBKEY)]
	public_key_to_pem,
	ffi::PEM_write_bio_DSA_PUBKEY
	}

	to_der! {
	/// Serializes the public key into a DER-encoded SubjectPublicKeyInfo structure.
	#[corresponds(i2d_DSA_PUBKEY)]
	public_key_to_der,
	ffi::i2d_DSA_PUBKEY
	}

	/// Returns a reference to the public key component of `self`.
	#[corresponds(DSA_get0_key)]
	pub fn pub_key(&self) -> &BigNumRef {
	unsafe {
	let mut pub_key = ptr::null();
	DSA_get0_key(self.as_ptr(), &mut pub_key, ptr::null_mut());
	BigNumRef::from_const_ptr(pub_key)
	}
	}
	}

	impl<T> DsaRef<T>
	where
	T: HasPrivate,
	{
	private_key_to_pem! {
	/// Serializes the private key to a PEM-encoded DSAPrivateKey structure.
	///
	/// The output will have a header of `-----BEGIN DSA PRIVATE KEY-----`.
	#[corresponds(PEM_write_bio_DSAPrivateKey)]
	private_key_to_pem,
	/// Serializes the private key to a PEM-encoded encrypted DSAPrivateKey structure.
	///
	/// The output will have a header of `-----BEGIN DSA PRIVATE KEY-----`.
	#[corresponds(PEM_write_bio_DSAPrivateKey)]
	private_key_to_pem_passphrase,
	ffi::PEM_write_bio_DSAPrivateKey
	}

	/// Returns a reference to the private key component of `self`.
	#[corresponds(DSA_get0_key)]
	pub fn priv_key(&self) -> &BigNumRef {
	unsafe {
	let mut priv_key = ptr::null();
	DSA_get0_key(self.as_ptr(), ptr::null_mut(), &mut priv_key);
	BigNumRef::from_const_ptr(priv_key)
	}
	}
	}

	impl<T> DsaRef<T>
	where
	T: HasParams,
	{
	/// Returns the maximum size of the signature output by `self` in bytes.
	#[corresponds(DSA_size)]
	pub fn size(&self) -> u32 {
	unsafe { ffi::DSA_size(self.as_ptr()) as u32 }
	}

	/// Returns the DSA prime parameter of `self`.
	#[corresponds(DSA_get0_pqg)]
	pub fn p(&self) -> &BigNumRef {
	unsafe {
	let mut p = ptr::null();
	DSA_get0_pqg(self.as_ptr(), &mut p, ptr::null_mut(), ptr::null_mut());
	BigNumRef::from_const_ptr(p)
	}
	}

	/// Returns the DSA sub-prime parameter of `self`.
	#[corresponds(DSA_get0_pqg)]
	pub fn q(&self) -> &BigNumRef {
	unsafe {
	let mut q = ptr::null();
	DSA_get0_pqg(self.as_ptr(), ptr::null_mut(), &mut q, ptr::null_mut());
	BigNumRef::from_const_ptr(q)
	}
	}

	/// Returns the DSA base parameter of `self`.
	#[corresponds(DSA_get0_pqg)]
	pub fn g(&self) -> &BigNumRef {
	unsafe {
	let mut g = ptr::null();
	DSA_get0_pqg(self.as_ptr(), ptr::null_mut(), ptr::null_mut(), &mut g);
	BigNumRef::from_const_ptr(g)
	}
	}
	}
	#[cfg(boringssl)]
	type BitType = c_uint;
	#[cfg(not(boringssl))]
	type BitType = c_int;

	impl Dsa<Private> {
	/// Generate a DSA key pair.
	///
	/// Calls [`DSA_generate_parameters_ex`] to populate the `p`, `g`, and `q` values.
	/// These values are used to generate the key pair with [`DSA_generate_key`].
	///
	/// The `bits` parameter corresponds to the length of the prime `p`.
	///
	/// [`DSA_generate_parameters_ex`]: https://www.openssl.org/docs/man1.1.0/crypto/DSA_generate_parameters_ex.html
	/// [`DSA_generate_key`]: https://www.openssl.org/docs/man1.1.0/crypto/DSA_generate_key.html
	pub fn generate(bits: u32) -> Result<Dsa<Private>, ErrorStack> {
	ffi::init();
	unsafe {
	let dsa = Dsa::from_ptr(cvt_p(ffi::DSA_new())?);
	cvt(ffi::DSA_generate_parameters_ex(
	dsa.0,
	bits as BitType,
	ptr::null(),
	0,
	ptr::null_mut(),
	ptr::null_mut(),
	ptr::null_mut(),
	))?;
	cvt(ffi::DSA_generate_key(dsa.0))?;
	Ok(dsa)
	}
	}

	/// Create a DSA key pair with the given parameters
	///
	/// `p`, `q` and `g` are the common parameters.
	/// `priv_key` is the private component of the key pair.
	/// `pub_key` is the public component of the key. Can be computed via `g^(priv_key) mod p`
	pub fn from_private_components(
	p: BigNum,
	q: BigNum,
	g: BigNum,
	priv_key: BigNum,
	pub_key: BigNum,
	) -> Result<Dsa<Private>, ErrorStack> {
	ffi::init();
	unsafe {
	let dsa = Dsa::from_ptr(cvt_p(ffi::DSA_new())?);
	cvt(DSA_set0_pqg(dsa.0, p.as_ptr(), q.as_ptr(), g.as_ptr()))?;
	mem::forget((p, q, g));
	cvt(DSA_set0_key(dsa.0, pub_key.as_ptr(), priv_key.as_ptr()))?;
	mem::forget((pub_key, priv_key));
	Ok(dsa)
	}
	}
	}

	impl Dsa<Public> {
	from_pem! {
	/// Decodes a PEM-encoded SubjectPublicKeyInfo structure containing a DSA key.
	///
	/// The input should have a header of `-----BEGIN PUBLIC KEY-----`.
	#[corresponds(PEM_read_bio_DSA_PUBKEY)]
	public_key_from_pem,
	Dsa<Public>,
	ffi::PEM_read_bio_DSA_PUBKEY
	}

	from_der! {
	/// Decodes a DER-encoded SubjectPublicKeyInfo structure containing a DSA key.
	#[corresponds(d2i_DSA_PUBKEY)]
	public_key_from_der,
	Dsa<Public>,
	ffi::d2i_DSA_PUBKEY
	}

	/// Create a new DSA key with only public components.
	///
	/// `p`, `q` and `g` are the common parameters.
	/// `pub_key` is the public component of the key.
	pub fn from_public_components(
	p: BigNum,
	q: BigNum,
	g: BigNum,
	pub_key: BigNum,
	) -> Result<Dsa<Public>, ErrorStack> {
	ffi::init();
	unsafe {
	let dsa = Dsa::from_ptr(cvt_p(ffi::DSA_new())?);
	cvt(DSA_set0_pqg(dsa.0, p.as_ptr(), q.as_ptr(), g.as_ptr()))?;
	mem::forget((p, q, g));
	cvt(DSA_set0_key(dsa.0, pub_key.as_ptr(), ptr::null_mut()))?;
	mem::forget(pub_key);
	Ok(dsa)
	}
	}
	}

	impl<T> fmt::Debug for Dsa<T> {
	fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
	write!(f, "DSA")
	}
	}

	cfg_if! {
	if #[cfg(any(ossl110, libressl273))] {
	use ffi::{DSA_get0_key, DSA_get0_pqg, DSA_set0_key, DSA_set0_pqg};
	} else {
	#[allow(bad_style)]
	unsafe fn DSA_get0_pqg(
	d: *mut ffi::DSA,
	p: mut const ffi::BIGNUM,
	q: mut const ffi::BIGNUM,
	g: mut const ffi::BIGNUM)
	{
	if !p.is_null() {
	p = (d).p;
	}
	if !q.is_null() {
	q = (d).q;
	}
	if !g.is_null() {
	g = (d).g;
	}
	}

	#[allow(bad_style)]
	unsafe fn DSA_get0_key(
	d: *mut ffi::DSA,
	pub_key: mut const ffi::BIGNUM,
	priv_key: mut const ffi::BIGNUM)
	{
	if !pub_key.is_null() {
	pub_key = (d).pub_key;
	}
	if !priv_key.is_null() {
	priv_key = (d).priv_key;
	}
	}

	#[allow(bad_style)]
	unsafe fn DSA_set0_key(
	d: *mut ffi::DSA,
	pub_key: *mut ffi::BIGNUM,
	priv_key: *mut ffi::BIGNUM) -> c_int
	{
	(*d).pub_key = pub_key;
	(*d).priv_key = priv_key;
	1
	}

	#[allow(bad_style)]
	unsafe fn DSA_set0_pqg(
	d: *mut ffi::DSA,
	p: *mut ffi::BIGNUM,
	q: *mut ffi::BIGNUM,
	g: *mut ffi::BIGNUM) -> c_int
	{
	(*d).p = p;
	(*d).q = q;
	(*d).g = g;
	1
	}
	}
	}

	#[cfg(test)]
	mod test {
	use super::*;
	use crate::bn::BigNumContext;
	use crate::hash::MessageDigest;
	use crate::pkey::PKey;
	use crate::sign::{Signer, Verifier};

	#[test]
	pub fn test_generate() {
	Dsa::generate(1024).unwrap();
	}

	#[test]
	fn test_pubkey_generation() {
	let dsa = Dsa::generate(1024).unwrap();
	let p = dsa.p();
	let g = dsa.g();
	let priv_key = dsa.priv_key();
	let pub_key = dsa.pub_key();
	let mut ctx = BigNumContext::new().unwrap();
	let mut calc = BigNum::new().unwrap();
	calc.mod_exp(g, priv_key, p, &mut ctx).unwrap();
	assert_eq!(&calc, pub_key)
	}

	#[test]
	fn test_priv_key_from_parts() {
	let p = BigNum::from_u32(283).unwrap();
	let q = BigNum::from_u32(47).unwrap();
	let g = BigNum::from_u32(60).unwrap();
	let priv_key = BigNum::from_u32(15).unwrap();
	let pub_key = BigNum::from_u32(207).unwrap();

	let dsa = Dsa::from_private_components(p, q, g, priv_key, pub_key).unwrap();
	assert_eq!(dsa.pub_key(), &BigNum::from_u32(207).unwrap());
	assert_eq!(dsa.priv_key(), &BigNum::from_u32(15).unwrap());
	assert_eq!(dsa.p(), &BigNum::from_u32(283).unwrap());
	assert_eq!(dsa.q(), &BigNum::from_u32(47).unwrap());
	assert_eq!(dsa.g(), &BigNum::from_u32(60).unwrap());
	}

	#[test]
	fn test_pub_key_from_parts() {
	let p = BigNum::from_u32(283).unwrap();
	let q = BigNum::from_u32(47).unwrap();
	let g = BigNum::from_u32(60).unwrap();
	let pub_key = BigNum::from_u32(207).unwrap();

	let dsa = Dsa::from_public_components(p, q, g, pub_key).unwrap();
	assert_eq!(dsa.pub_key(), &BigNum::from_u32(207).unwrap());
	assert_eq!(dsa.p(), &BigNum::from_u32(283).unwrap());
	assert_eq!(dsa.q(), &BigNum::from_u32(47).unwrap());
	assert_eq!(dsa.g(), &BigNum::from_u32(60).unwrap());
	}

	#[test]
	#[cfg(not(boringssl))]
	fn test_signature() {
	const TEST_DATA: &[u8] = &[0, 1, 2, 3, 4, 5, 6, 7, 8, 9];
	let dsa_ref = Dsa::generate(1024).unwrap();

	let p = dsa_ref.p();
	let q = dsa_ref.q();
	let g = dsa_ref.g();

	let pub_key = dsa_ref.pub_key();
	let priv_key = dsa_ref.priv_key();

	let priv_key = Dsa::from_private_components(
	BigNumRef::to_owned(p).unwrap(),
	BigNumRef::to_owned(q).unwrap(),
	BigNumRef::to_owned(g).unwrap(),
	BigNumRef::to_owned(priv_key).unwrap(),
	BigNumRef::to_owned(pub_key).unwrap(),
	)
	.unwrap();
	let priv_key = PKey::from_dsa(priv_key).unwrap();

	let pub_key = Dsa::from_public_components(
	BigNumRef::to_owned(p).unwrap(),
	BigNumRef::to_owned(q).unwrap(),
	BigNumRef::to_owned(g).unwrap(),
	BigNumRef::to_owned(pub_key).unwrap(),
	)
	.unwrap();
	let pub_key = PKey::from_dsa(pub_key).unwrap();

	let mut signer = Signer::new(MessageDigest::sha256(), &priv_key).unwrap();
	signer.update(TEST_DATA).unwrap();

	let signature = signer.sign_to_vec().unwrap();
	let mut verifier = Verifier::new(MessageDigest::sha256(), &pub_key).unwrap();
	verifier.update(TEST_DATA).unwrap();
	assert!(verifier.verify(&signature[..]).unwrap());
	}

	#[test]
	#[allow(clippy::redundant_clone)]
	fn clone() {
	let key = Dsa::generate(2048).unwrap();
	drop(key.clone());
	}
	}