6 pkeyutl - public key algorithm utility
18 [B<-peerform PEM|DER>]
28 [B<-pkeyopt opt:value>]
35 The B<pkeyutl> command can be used to perform public key operations using
36 any supported algorithm.
38 =head1 COMMAND OPTIONS
44 This specifies the input filename to read data from or standard input
45 if this option is not specified.
47 =item B<-out filename>
49 specifies the output filename to write to or standard output by
54 the input key file, by default it should be a private key.
56 =item B<-keyform PEM|DER>
58 the key format PEM, DER or ENGINE.
62 the input key password source. For more information about the format of B<arg>
63 see the B<PASS PHRASE ARGUMENTS> section in L<openssl(1)|openssl(1)>.
66 =item B<-peerkey file>
68 the peer key file, used by key derivation (agreement) operations.
70 =item B<-peerform PEM|DER>
72 the peer key format PEM, DER or ENGINE.
76 specifying an engine (by its unique B<id> string) will cause B<pkeyutl>
77 to attempt to obtain a functional reference to the specified engine,
78 thus initialising it if needed. The engine will then be set as the default
79 for all available algorithms.
84 the input file is a public key.
88 the input is a certificate containing a public key.
92 reverse the order of the input buffer. This is useful for some libraries
93 (such as CryptoAPI) which represent the buffer in little endian format.
97 sign the input data and output the signed result. This requires
102 verify the input data against the signature file and indicate if the
103 verification succeeded or failed.
105 =item B<-verifyrecover>
107 verify the input data and output the recovered data.
111 encrypt the input data using a public key.
115 decrypt the input data using a private key.
119 derive a shared secret using the peer key.
123 hex dump the output data.
127 asn1parse the output data, this is useful when combined with the
128 B<-verifyrecover> option when an ASN1 structure is signed.
134 The operations and options supported vary according to the key algorithm
135 and its implementation. The OpenSSL operations and options are indicated below.
137 Unless otherwise mentioned all algorithms support the B<digest:alg> option
138 which specifies the digest in use for sign, verify and verifyrecover operations.
139 The value B<alg> should represent a digest name as used in the
140 EVP_get_digestbyname() function for example B<sha1>.
141 This value is used only for sanity-checking the lengths of data passed in to
142 the B<pkeyutl> and for creating the structures that make up the signature
143 (e.g. B<DigestInfo> in RSASSA PKCS#1 v1.5 signatures).
144 In case of RSA, ECDSA and DSA signatures, this utility
145 will not perform hashing on input data but rather use the data directly as
146 input of signature algorithm. Depending on key type, signature type and mode
147 of padding, the maximum acceptable lengths of input data differ. In general,
148 with RSA the signed data can't be longer than the key modulus, in case of ECDSA
149 and DSA the data shouldn't be longer than field size, otherwise it will be
150 silently truncated to field size.
152 In other words, if the value of digest is B<sha1> the input should be 20 bytes
153 long binary encoding of SHA-1 hash function output.
157 The RSA algorithm supports encrypt, decrypt, sign, verify and verifyrecover
158 operations in general. Some padding modes only support some of these
163 =item -B<rsa_padding_mode:mode>
165 This sets the RSA padding mode. Acceptable values for B<mode> are B<pkcs1> for
166 PKCS#1 padding, B<sslv23> for SSLv23 padding, B<none> for no padding, B<oaep>
167 for B<OAEP> mode, B<x931> for X9.31 mode and B<pss> for PSS.
169 In PKCS#1 padding if the message digest is not set then the supplied data is
170 signed or verified directly instead of using a B<DigestInfo> structure. If a
171 digest is set then the a B<DigestInfo> structure is used and its the length
172 must correspond to the digest type.
174 For B<oeap> mode only encryption and decryption is supported.
176 For B<x931> if the digest type is set it is used to format the block data
177 otherwise the first byte is used to specify the X9.31 digest ID. Sign,
178 verify and verifyrecover are can be performed in this mode.
180 For B<pss> mode only sign and verify are supported and the digest type must be
183 =item B<rsa_pss_saltlen:len>
185 For B<pss> mode only this option specifies the salt length. Two special values
186 are supported: -1 sets the salt length to the digest length. When signing -2
187 sets the salt length to the maximum permissible value. When verifying -2 causes
188 the salt length to be automatically determined based on the B<PSS> block
195 The DSA algorithm supports signing and verification operations only. Currently
196 there are no additional options other than B<digest>. Only the SHA1
197 digest can be used and this digest is assumed by default.
201 The DH algorithm only supports the derivation operation and no additional
206 The EC algorithm supports sign, verify and derive operations. The sign and
207 verify operations use ECDSA and derive uses ECDH. Currently there are no
208 additional options other than B<digest>. Only the SHA1 digest can be used and
209 this digest is assumed by default.
213 Sign some data using a private key:
215 openssl pkeyutl -sign -in file -inkey key.pem -out sig
217 Recover the signed data (e.g. if an RSA key is used):
219 openssl pkeyutl -verifyrecover -in sig -inkey key.pem
221 Verify the signature (e.g. a DSA key):
223 openssl pkeyutl -verify -in file -sigfile sig -inkey key.pem
225 Sign data using a message digest value (this is currently only valid for RSA):
227 openssl pkeyutl -sign -in file -inkey key.pem -out sig -pkeyopt digest:sha256
229 Derive a shared secret value:
231 openssl pkeyutl -derive -inkey key.pem -peerkey pubkey.pem -out secret
235 L<genpkey(1)|genpkey(1)>, L<pkey(1)|pkey(1)>, L<rsautl(1)|rsautl(1)>
236 L<dgst(1)|dgst(1)>, L<rsa(1)|rsa(1)>, L<genrsa(1)|genrsa(1)>