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Class: OpenSSL::PKey::RSA

Relationships & Source Files
Super Chains via Extension / Inclusion / Inheritance
Class Chain:
self, PKey
Instance Chain:
self, ::OpenSSL::Marshal, PKey
Inherits: OpenSSL::PKey::PKey
Defined in: ext/openssl/ossl_pkey_rsa.c,
ext/openssl/lib/openssl/pkey.rb

Overview

RSA is an asymmetric public key algorithm that has been formalized in RFC 3447. It is in widespread use in public key infrastructures (PKI) where certificates (cf. ::OpenSSL::X509::Certificate) often are issued on the basis of a public/private RSA key pair. RSA is used in a wide field of applications such as secure (symmetric) key exchange, e.g. when establishing a secure TLS/SSL connection. It is also used in various digital signature schemes.

Constant Summary

Class Method Summary

PKey - Inherited

.new

Because PKey is an abstract class, actually calling this method explicitly will raise a NotImplementedError.

Instance Attribute Summary

Instance Method Summary

::OpenSSL::Marshal - Included

#_dump

PKey - Inherited

#compare?

Used primarily to check if an X509::Certificate#public_key compares to its private key.
#decrypt

Performs a public key decryption operation using pkey.
#derive

Derives a shared secret from pkey and peer_pkey.
#encrypt

Performs a public key encryption operation using pkey.
#initialize_copy,
#inspect

Returns a string describing the PKey object.
#oid

Returns the short name of the OID associated with pkey.
#private_to_der

Serializes the private key to DER-encoded PKCS #8 format.
#private_to_pem

Serializes the private key to PEM-encoded PKCS #8 format.
#public_to_der

Serializes the public key to DER-encoded X.509 SubjectPublicKeyInfo format.
#public_to_pem

Serializes the public key to PEM-encoded X.509 SubjectPublicKeyInfo format.
#raw_private_key

See the ::OpenSSL documentation for EVP_PKEY_get_raw_private_key().
#raw_public_key

See the ::OpenSSL documentation for EVP_PKEY_get_raw_public_key().
#sign

Hashes and signs the data using a message digest algorithm digest and a private key pkey.
#sign_raw

Signs data using a private key pkey.
#to_text

Dumps key parameters, public key, and private key components contained in the key into a human-readable text.
#verify

Verifies the signature for the data using a message digest algorithm digest and a public key pkey.
#verify_raw

Verifies the signature for the data using a public key pkey.
#verify_recover

Recovers the signed data from signature using a public key pkey.

Constructor Details

.newRSA .new(encoded_key [, password ]) ⇒ RSA .new(encoded_key) ⇒ RSA .new(size [, exponent]) ⇒ RSA

This method is for internal use only.

Generates or loads an RSA keypair.

If called without arguments, creates a new instance with no key components set. They can be set individually by #set_key, #set_factors, and #set_crt_params.

If called with a String, tries to parse as DER or PEM encoding of an RSA key. Note that if password is not specified, but the key is encrypted with a password, OpenSSL will prompt for it. See also OpenSSL::PKey.read which can parse keys of any kind.

If called with a number, generates a new key pair. This form works as an alias of .generate.

Examples:

OpenSSL::PKey::RSA.new 2048
OpenSSL::PKey::RSA.new File.read 'rsa.pem'
OpenSSL::PKey::RSA.new File.read('rsa.pem'), 'my password'
[ GitHub ] 

  


# File 'ext/openssl/ossl_pkey_rsa.c', line 76



static VALUE
ossl_rsa_initialize(int argc, VALUE *argv, VALUE self)
{
    EVP_PKEY *pkey;
    RSA *rsa;
    BIO *in = NULL;
    VALUE arg, pass;
    int type;

    TypedData_Get_Struct(self, EVP_PKEY, &ossl_evp_pkey_type, pkey);
    if (pkey)
        rb_raise(rb_eTypeError, "pkey already initialized");

    /* The RSA.new(size, generator) form is handled by lib/openssl/pkey.rb */
    rb_scan_args(argc, argv, "02", &arg, &pass);
    if (argc == 0) {
	rsa = RSA_new();
        if (!rsa)
            ossl_raise(eRSAError, "RSA_new");
        goto legacy;
    }

    pass = ossl_pem_passwd_value(pass);
    arg = ossl_to_der_if_possible(arg);
    in = ossl_obj2bio(&arg);

    /* First try RSAPublicKey format */
    rsa = d2i_RSAPublicKey_bio(in, NULL);
    if (rsa)
        goto legacy;
    OSSL_BIO_reset(in);
    rsa = PEM_read_bio_RSAPublicKey(in, NULL, NULL, NULL);
    if (rsa)
        goto legacy;
    OSSL_BIO_reset(in);

    /* Use the generic routine */
    pkey = ossl_pkey_read_generic(in, pass);
    BIO_free(in);
    if (!pkey)
        ossl_raise(eRSAError, "Neither PUB key nor PRIV key");

    type = EVP_PKEY_base_id(pkey);
    if (type != EVP_PKEY_RSA) {
        EVP_PKEY_free(pkey);
        rb_raise(eRSAError, "incorrect pkey type: %s", OBJ_nid2sn(type));
    }
    RTYPEDDATA_DATA(self) = pkey;
    return self;

  legacy:
    BIO_free(in);
    pkey = EVP_PKEY_new();
    if (!pkey || EVP_PKEY_assign_RSA(pkey, rsa) != 1) {
        EVP_PKEY_free(pkey);
        RSA_free(rsa);
        ossl_raise(eRSAError, "EVP_PKEY_assign_RSA");
    }
    RTYPEDDATA_DATA(self) = pkey;
    return self;
}


  







Class Method Details



  

    .generate(size, exponent = 65537)  ⇒ RSA   



  

    

Generates an RSA keypair.



See also OpenSSL::PKey.generate_key.


size



The desired key size in bits.


exponent



An odd Integer, normally 3, 17, or 65537.




  



  [ GitHub ]


  

  


# File 'ext/openssl/lib/openssl/pkey.rb', line 343



def generate(size, exp = 0x10001, &blk)
  OpenSSL::PKey.generate_key("RSA", {
    "rsa_keygen_bits" => size,
    "rsa_keygen_pubexp" => exp,
  }, &blk)
end


  







Instance Attribute Details



  

    #private?Boolean  (readonly)  



  

    

Does this keypair contain a private key?


  



  [ GitHub ]


  

  


# File 'ext/openssl/ossl_pkey_rsa.c', line 193



static VALUE
ossl_rsa_is_private(VALUE self)
{
    OSSL_3_const RSA *rsa;

    GetRSA(self, rsa);

    return RSA_PRIVATE(self, rsa) ? Qtrue : Qfalse;
}


  








  

    #public?Boolean  (readonly)  



  

    

The return value is always true since every private key is also a public key.


  



  [ GitHub ]


  

  


# File 'ext/openssl/ossl_pkey_rsa.c', line 174



static VALUE
ossl_rsa_is_public(VALUE self)
{
    OSSL_3_const RSA *rsa;

    GetRSA(self, rsa);
    /*
     * This method should check for n and e.  BUG.
     */
    (void)rsa;
    return Qtrue;
}


  







Instance Method Details



  

    

      #export([cipher, password])  ⇒ PEM-format String 
      #to_pem([cipher, password])  ⇒ PEM-format String 
      #to_s([cipher, password])  ⇒ PEM-format String 
    

  



  

    

Alias for #to_s.


  





  








  

    #initialize_copy(other)  
  

  [ GitHub ]


  

  


# File 'ext/openssl/ossl_pkey_rsa.c', line 139



static VALUE
ossl_rsa_initialize_copy(VALUE self, VALUE other)
{
    EVP_PKEY *pkey;
    RSA *rsa, *rsa_new;

    TypedData_Get_Struct(self, EVP_PKEY, &ossl_evp_pkey_type, pkey);
    if (pkey)
        rb_raise(rb_eTypeError, "pkey already initialized");
    GetRSA(other, rsa);

    rsa_new = (RSA *)ASN1_dup((i2d_of_void *)i2d_RSAPrivateKey,
                              (d2i_of_void *)d2i_RSAPrivateKey,
                              (char *)rsa);
    if (!rsa_new)
	ossl_raise(eRSAError, "ASN1_dup");

    pkey = EVP_PKEY_new();
    if (!pkey || EVP_PKEY_assign_RSA(pkey, rsa_new) != 1) {
        RSA_free(rsa_new);
        ossl_raise(eRSAError, "EVP_PKEY_assign_RSA");
    }
    RTYPEDDATA_DATA(self) = pkey;

    return self;
}


  








  

    #paramsHash   



  

    

THIS METHOD IS INSECURE, PRIVATE INFORMATION CAN LEAK OUT!!!



Stores all parameters of key to the hash.  The hash has keys ‘n’, ‘e’, ‘d’, ‘p’, ‘q’, ‘dmp1’, ‘dmq1’, ‘iqmp’.



Don’t use :-)) (It’s up to you)


  



  [ GitHub ]


  

  


# File 'ext/openssl/ossl_pkey_rsa.c', line 508



static VALUE
ossl_rsa_get_params(VALUE self)
{
    OSSL_3_const RSA *rsa;
    VALUE hash;
    const BIGNUM *n, *e, *d, *p, *q, *dmp1, *dmq1, *iqmp;

    GetRSA(self, rsa);
    RSA_get0_key(rsa, &n, &e, &d);
    RSA_get0_factors(rsa, &p, &q);
    RSA_get0_crt_params(rsa, &dmp1, &dmq1, &iqmp);

    hash = rb_hash_new();
    rb_hash_aset(hash, rb_str_new2("n"), ossl_bn_new(n));
    rb_hash_aset(hash, rb_str_new2("e"), ossl_bn_new(e));
    rb_hash_aset(hash, rb_str_new2("d"), ossl_bn_new(d));
    rb_hash_aset(hash, rb_str_new2("p"), ossl_bn_new(p));
    rb_hash_aset(hash, rb_str_new2("q"), ossl_bn_new(q));
    rb_hash_aset(hash, rb_str_new2("dmp1"), ossl_bn_new(dmp1));
    rb_hash_aset(hash, rb_str_new2("dmq1"), ossl_bn_new(dmq1));
    rb_hash_aset(hash, rb_str_new2("iqmp"), ossl_bn_new(iqmp));

    return hash;
}


  








  

    

      #private_decrypt(string)  ⇒ String 
      #private_decrypt(string, padding)  ⇒ String 
    

  



  

    

Decrypt string, which has been encrypted with the public key, with the private key. padding defaults to PKCS1_PADDING, which is known to be insecure but is kept for backwards compatibility.



Deprecated in version 3.0. Consider using PKey#encrypt and PKey#decrypt instead.


  





  


  [ GitHub ]


  

  


# File 'ext/openssl/lib/openssl/pkey.rb', line 439



def private_decrypt(data, padding = PKCS1_PADDING)
  n or raise OpenSSL::PKey::RSAError, "incomplete RSA"
  private? or raise OpenSSL::PKey::RSAError, "private key needed."
  begin
    decrypt(data, {
      "rsa_padding_mode" => translate_padding_mode(padding),
    })
  rescue OpenSSL::PKey::PKeyError
    raise OpenSSL::PKey::RSAError, $!.message
  end
end


  








  

    

      #private_encrypt(string)  ⇒ String 
      #private_encrypt(string, padding)  ⇒ String 
    

  



  

    

Encrypt string with the private key.  padding defaults to PKCS1_PADDING, which is known to be insecure but is kept for backwards compatibility. The encrypted string output can be decrypted using #public_decrypt.



Deprecated in version 3.0. Consider using PKey#sign_raw and PKey#verify_raw, and PKey#verify_recover instead.


  





  


  [ GitHub ]


  

  


# File 'ext/openssl/lib/openssl/pkey.rb', line 373



def private_encrypt(string, padding = PKCS1_PADDING)
  n or raise OpenSSL::PKey::RSAError, "incomplete RSA"
  private? or raise OpenSSL::PKey::RSAError, "private key needed."
  begin
    sign_raw(nil, string, {
      "rsa_padding_mode" => translate_padding_mode(padding),
    })
  rescue OpenSSL::PKey::PKeyError
    raise OpenSSL::PKey::RSAError, $!.message
  end
end


  








  

    

      #public_decrypt(string)  ⇒ String 
      #public_decrypt(string, padding)  ⇒ String 
    

  



  

    

Decrypt string, which has been encrypted with the private key, with the public key.  padding defaults to PKCS1_PADDING which is known to be insecure but is kept for backwards compatibility.



Deprecated in version 3.0. Consider using PKey#sign_raw and PKey#verify_raw, and PKey#verify_recover instead.


  





  


  [ GitHub ]


  

  


# File 'ext/openssl/lib/openssl/pkey.rb', line 396



def public_decrypt(string, padding = PKCS1_PADDING)
  n or raise OpenSSL::PKey::RSAError, "incomplete RSA"
  begin
    verify_recover(nil, string, {
      "rsa_padding_mode" => translate_padding_mode(padding),
    })
  rescue OpenSSL::PKey::PKeyError
    raise OpenSSL::PKey::RSAError, $!.message
  end
end


  








  

    

      #public_encrypt(string)  ⇒ String 
      #public_encrypt(string, padding)  ⇒ String 
    

  



  

    

Encrypt string with the public key.  padding defaults to PKCS1_PADDING, which is known to be insecure but is kept for backwards compatibility. The encrypted string output can be decrypted using #private_decrypt.



Deprecated in version 3.0. Consider using PKey#encrypt and PKey#decrypt instead.


  





  


  [ GitHub ]


  

  


# File 'ext/openssl/lib/openssl/pkey.rb', line 418



def public_encrypt(data, padding = PKCS1_PADDING)
  n or raise OpenSSL::PKey::RSAError, "incomplete RSA"
  begin
    encrypt(data, {
      "rsa_padding_mode" => translate_padding_mode(padding),
    })
  rescue OpenSSL::PKey::PKeyError
    raise OpenSSL::PKey::RSAError, $!.message
  end
end


  








  

    #public_keyRSA   



  

    

Returns a new RSA instance that carries just the public key components.



This method is provided for backwards compatibility. In most cases, there is no need to call this method.



For the purpose of serializing the public key, to PEM or DER encoding of X.509 SubjectPublicKeyInfo format, check PKey#public_to_pem and PKey#public_to_der.


  



  [ GitHub ]


  

  


# File 'ext/openssl/lib/openssl/pkey.rb', line 327



def public_key
  OpenSSL::PKey.read(public_to_der)
end


  








  

    #set_crt_params(dmp1, dmq1, iqmp)  ⇒ self   



  

    

Sets dmp1, dmq1, iqmp for the RSA instance. They are calculated by d mod (p - 1), d mod (q - 1) and q^(-1) mod p respectively.


  



  [ GitHub ]






  

    #set_factors(p, q)  ⇒ self   



  

    

Sets p, q for the RSA instance.


  



  [ GitHub ]






  

    #set_key(n, e, d)  ⇒ self   



  

    

Sets n, e, d for the RSA instance.


  



  [ GitHub ]






  

    #sign_pss(digest, data, salt_length:, mgf1_hash:)  ⇒ String   



  

    

Signs data using the Probabilistic Signature Scheme (RSA-PSS) and returns the calculated signature.



RSAError will be raised if an error occurs.



See #verify_pss for the verification operation.



Parameters


digest



A String containing the message digest algorithm name.


data



A String. The data to be signed.


salt_length



The length in octets of the salt. Two special values are reserved: :digest means the digest length, and :max means the maximum possible length for the combination of the private key and the selected message digest algorithm.


mgf1_hash



The hash algorithm used in MGF1 (the currently supported mask generation function (MGF)).





Example



data = "Sign me!"
pkey = OpenSSL::PKey::RSA.new(2048)
signature = pkey.sign_pss("SHA256", data, salt_length: :max, mgf1_hash: "SHA256")
pub_key = OpenSSL::PKey.read(pkey.public_to_der)
puts pub_key.verify_pss("SHA256", signature, data,
                        salt_length: :auto, mgf1_hash: "SHA256") # => true


  



  [ GitHub ]


  

  


# File 'ext/openssl/ossl_pkey_rsa.c', line 340



static VALUE
ossl_rsa_sign_pss(int argc, VALUE *argv, VALUE self)
{
    VALUE digest, data, options, kwargs[2], signature;
    static ID kwargs_ids[2];
    EVP_PKEY *pkey;
    EVP_PKEY_CTX *pkey_ctx;
    const EVP_MD *md, *mgf1md;
    EVP_MD_CTX *md_ctx;
    size_t buf_len;
    int salt_len;

    if (!kwargs_ids[0]) {
	kwargs_ids[0] = rb_intern_const("salt_length");
	kwargs_ids[1] = rb_intern_const("mgf1_hash");
    }
    rb_scan_args(argc, argv, "2:", &digest, &data, &options);
    rb_get_kwargs(options, kwargs_ids, 2, 0, kwargs);
    if (kwargs[0] == ID2SYM(rb_intern("max")))
	salt_len = -2; /* RSA_PSS_SALTLEN_MAX_SIGN */
    else if (kwargs[0] == ID2SYM(rb_intern("digest")))
	salt_len = -1; /* RSA_PSS_SALTLEN_DIGEST */
    else
	salt_len = NUM2INT(kwargs[0]);
    mgf1md = ossl_evp_get_digestbyname(kwargs[1]);

    pkey = GetPrivPKeyPtr(self);
    buf_len = EVP_PKEY_size(pkey);
    md = ossl_evp_get_digestbyname(digest);
    StringValue(data);
    signature = rb_str_new(NULL, (long)buf_len);

    md_ctx = EVP_MD_CTX_new();
    if (!md_ctx)
	goto err;

    if (EVP_DigestSignInit(md_ctx, &pkey_ctx, md, NULL, pkey) != 1)
	goto err;

    if (EVP_PKEY_CTX_set_rsa_padding(pkey_ctx, RSA_PKCS1_PSS_PADDING) != 1)
	goto err;

    if (EVP_PKEY_CTX_set_rsa_pss_saltlen(pkey_ctx, salt_len) != 1)
	goto err;

    if (EVP_PKEY_CTX_set_rsa_mgf1_md(pkey_ctx, mgf1md) != 1)
	goto err;

    if (EVP_DigestSignUpdate(md_ctx, RSTRING_PTR(data), RSTRING_LEN(data)) != 1)
	goto err;

    if (EVP_DigestSignFinal(md_ctx, (unsigned char *)RSTRING_PTR(signature), &buf_len) != 1)
	goto err;

    rb_str_set_len(signature, (long)buf_len);

    EVP_MD_CTX_free(md_ctx);
    return signature;

  err:
    EVP_MD_CTX_free(md_ctx);
    ossl_raise(eRSAError, NULL);
}


  








  

    #to_derDER-format String   



  

    

Serializes a private or public key to a DER-encoding.



See #to_pem for details.



This method is kept for compatibility. This should only be used when the PKCS #1 RSAPrivateKey format is required.



Consider using #public_to_der or #private_to_der instead.


  



  [ GitHub ]


  

  


# File 'ext/openssl/ossl_pkey_rsa.c', line 298



static VALUE
ossl_rsa_to_der(VALUE self)
{
    if (can_export_rsaprivatekey(self))
        return ossl_pkey_export_traditional(0, NULL, self, 1);
    else
        return ossl_pkey_export_spki(self, 1);
}


  








  

    

      #export([cipher, password])  ⇒ PEM-format String 
      #to_pem([cipher, password])  ⇒ PEM-format String 
      #to_s([cipher, password])  ⇒ PEM-format String 
    

  



  

    

Alias for #to_s.


  









  

    

      #export([cipher, password])  ⇒ PEM-format String 
      #to_pem([cipher, password])  ⇒ PEM-format String 
      #to_s([cipher, password])  ⇒ PEM-format String 
    

    Also known as: #export, #to_pem
  



  

    

Serializes a private or public key to a PEM-encoding.


When the key contains public components only



Serializes it into an X.509 SubjectPublicKeyInfo. The parameters cipher and password are ignored.



A PEM-encoded key will look like:



-----BEGIN PUBLIC KEY-----
[...]
-----END PUBLIC KEY-----



Consider using #public_to_pem instead. This serializes the key into an X.509 SubjectPublicKeyInfo regardless of whether the key is a public key or a private key.


When the key contains private components, and no parameters are given



Serializes it into a PKCS #1 RSAPrivateKey.



A PEM-encoded key will look like:



-----BEGIN RSA PRIVATE KEY-----
[...]
-----END RSA PRIVATE KEY-----


When the key contains private components, and cipher and password are given



Serializes it into a PKCS #1 RSAPrivateKey and encrypts it in OpenSSL’s traditional PEM encryption format. cipher must be a cipher name understood by OpenSSL::Cipher.new or an instance of OpenSSL::Cipher.



An encrypted PEM-encoded key will look like:



-----BEGIN RSA PRIVATE KEY-----
Proc-Type: 4,ENCRYPTED
DEK-Info: AES-128-CBC,733F5302505B34701FC41F5C0746E4C0

[...]
-----END RSA PRIVATE KEY-----



Note that this format uses MD5 to derive the encryption key, and hence will not be available on FIPS-compliant systems.





This method is kept for compatibility. This should only be used when the PKCS #1 RSAPrivateKey format is required.



Consider using #public_to_pem (X.509 SubjectPublicKeyInfo) or #private_to_pem (PKCS #8 PrivateKeyInfo or EncryptedPrivateKeyInfo) instead.


  



  [ GitHub ]


  

  


# File 'ext/openssl/ossl_pkey_rsa.c', line 276



static VALUE
ossl_rsa_export(int argc, VALUE *argv, VALUE self)
{
    if (can_export_rsaprivatekey(self))
        return ossl_pkey_export_traditional(argc, argv, self, 0);
    else
        return ossl_pkey_export_spki(self, 0);
}


  








  

    #translate_padding_mode(num)   (private)
  

  [ GitHub ]


  

  


# File 'ext/openssl/lib/openssl/pkey.rb', line 456



private def translate_padding_mode(num)
  case num
  when PKCS1_PADDING
    "pkcs1"
  when SSLV23_PADDING
    "sslv23"
  when NO_PADDING
    "none"
  when PKCS1_OAEP_PADDING
    "oaep"
  else
    raise OpenSSL::PKey::PKeyError, "unsupported padding mode"
  end
end


  








  

    #verify_pss(digest, signature, data, salt_length:, mgf1_hash:)  ⇒ Boolean   



  

    

Verifies data using the Probabilistic Signature Scheme (RSA-PSS).



The return value is true if the signature is valid, false otherwise. RSAError will be raised if an error occurs.



See #sign_pss for the signing operation and an example code.



Parameters


digest



A String containing the message digest algorithm name.


data



A String. The data to be signed.


salt_length



The length in octets of the salt. Two special values are reserved: :digest means the digest length, and :auto means automatically determining the length based on the signature.


mgf1_hash



The hash algorithm used in MGF1.




  



  [ GitHub ]


  

  


# File 'ext/openssl/ossl_pkey_rsa.c', line 427



static VALUE
ossl_rsa_verify_pss(int argc, VALUE *argv, VALUE self)
{
    VALUE digest, signature, data, options, kwargs[2];
    static ID kwargs_ids[2];
    EVP_PKEY *pkey;
    EVP_PKEY_CTX *pkey_ctx;
    const EVP_MD *md, *mgf1md;
    EVP_MD_CTX *md_ctx;
    int result, salt_len;

    if (!kwargs_ids[0]) {
	kwargs_ids[0] = rb_intern_const("salt_length");
	kwargs_ids[1] = rb_intern_const("mgf1_hash");
    }
    rb_scan_args(argc, argv, "3:", &digest, &signature, &data, &options);
    rb_get_kwargs(options, kwargs_ids, 2, 0, kwargs);
    if (kwargs[0] == ID2SYM(rb_intern("auto")))
	salt_len = -2; /* RSA_PSS_SALTLEN_AUTO */
    else if (kwargs[0] == ID2SYM(rb_intern("digest")))
	salt_len = -1; /* RSA_PSS_SALTLEN_DIGEST */
    else
	salt_len = NUM2INT(kwargs[0]);
    mgf1md = ossl_evp_get_digestbyname(kwargs[1]);

    GetPKey(self, pkey);
    md = ossl_evp_get_digestbyname(digest);
    StringValue(signature);
    StringValue(data);

    md_ctx = EVP_MD_CTX_new();
    if (!md_ctx)
	goto err;

    if (EVP_DigestVerifyInit(md_ctx, &pkey_ctx, md, NULL, pkey) != 1)
	goto err;

    if (EVP_PKEY_CTX_set_rsa_padding(pkey_ctx, RSA_PKCS1_PSS_PADDING) != 1)
	goto err;

    if (EVP_PKEY_CTX_set_rsa_pss_saltlen(pkey_ctx, salt_len) != 1)
	goto err;

    if (EVP_PKEY_CTX_set_rsa_mgf1_md(pkey_ctx, mgf1md) != 1)
	goto err;

    if (EVP_DigestVerifyUpdate(md_ctx, RSTRING_PTR(data), RSTRING_LEN(data)) != 1)
	goto err;

    result = EVP_DigestVerifyFinal(md_ctx,
				   (unsigned char *)RSTRING_PTR(signature),
				   RSTRING_LEN(signature));

    switch (result) {
      case 0:
	ossl_clear_error();
	EVP_MD_CTX_free(md_ctx);
	return Qfalse;
      case 1:
	EVP_MD_CTX_free(md_ctx);
	return Qtrue;
      default:
	goto err;
    }

  err:
    EVP_MD_CTX_free(md_ctx);
    ossl_raise(eRSAError, NULL);
}