numam-dpdk/lib/librte_cryptodev/rte_crypto_asym.h
Balakrishna Bhamidipati e98dc331e9 cryptodev: support ECPM
Asymmetric crypto library is extended to add ECPM (Elliptic Curve Point
Multiplication). The required xform type and op parameters are
introduced.

Signed-off-by: Anoob Joseph <anoobj@marvell.com>
Signed-off-by: Balakrishna Bhamidipati <bbhamidipati@marvell.com>
Signed-off-by: Sunila Sahu <ssahu@marvell.com>
Acked-by: Akhil Goyal <akhil.goyal@nxp.com>
2020-01-15 15:01:55 +01:00

649 lines
16 KiB
C

/* SPDX-License-Identifier: BSD-3-Clause
* Copyright(c) 2018 Cavium Networks
*/
#ifndef _RTE_CRYPTO_ASYM_H_
#define _RTE_CRYPTO_ASYM_H_
/**
* @file rte_crypto_asym.h
*
* RTE Definitions for Asymmetric Cryptography
*
* Defines asymmetric algorithms and modes, as well as supported
* asymmetric crypto operations.
*/
#ifdef __cplusplus
extern "C" {
#endif
#include <string.h>
#include <stdint.h>
#include <rte_memory.h>
#include <rte_mempool.h>
#include <rte_common.h>
#include "rte_crypto_sym.h"
/**
* Buffer to hold crypto params required for asym operations.
*
* These buffers can be used for both input to PMD and output from PMD. When
* used for output from PMD, application has to ensure the buffer is large
* enough to hold the target data.
*/
typedef struct rte_crypto_param_t {
uint8_t *data;
/**< pointer to buffer holding data */
rte_iova_t iova;
/**< IO address of data buffer */
size_t length;
/**< length of data in bytes */
} rte_crypto_param;
/** asym xform type name strings */
extern const char *
rte_crypto_asym_xform_strings[];
/** asym operations type name strings */
extern const char *
rte_crypto_asym_op_strings[];
/**
* Asymmetric crypto transformation types.
* Each xform type maps to one asymmetric algorithm
* performing specific operation
*
*/
enum rte_crypto_asym_xform_type {
RTE_CRYPTO_ASYM_XFORM_UNSPECIFIED = 0,
/**< Invalid xform. */
RTE_CRYPTO_ASYM_XFORM_NONE,
/**< Xform type None.
* May be supported by PMD to support
* passthrough op for debugging purpose.
* if xform_type none , op_type is disregarded.
*/
RTE_CRYPTO_ASYM_XFORM_RSA,
/**< RSA. Performs Encrypt, Decrypt, Sign and Verify.
* Refer to rte_crypto_asym_op_type
*/
RTE_CRYPTO_ASYM_XFORM_DH,
/**< Diffie-Hellman.
* Performs Key Generate and Shared Secret Compute.
* Refer to rte_crypto_asym_op_type
*/
RTE_CRYPTO_ASYM_XFORM_DSA,
/**< Digital Signature Algorithm
* Performs Signature Generation and Verification.
* Refer to rte_crypto_asym_op_type
*/
RTE_CRYPTO_ASYM_XFORM_MODINV,
/**< Modular Multiplicative Inverse
* Perform Modular Multiplicative Inverse b^(-1) mod n
*/
RTE_CRYPTO_ASYM_XFORM_MODEX,
/**< Modular Exponentiation
* Perform Modular Exponentiation b^e mod n
*/
RTE_CRYPTO_ASYM_XFORM_ECDSA,
/**< Elliptic Curve Digital Signature Algorithm
* Perform Signature Generation and Verification.
*/
RTE_CRYPTO_ASYM_XFORM_ECPM,
/**< Elliptic Curve Point Multiplication */
RTE_CRYPTO_ASYM_XFORM_TYPE_LIST_END
/**< End of list */
};
/**
* Asymmetric crypto operation type variants
*/
enum rte_crypto_asym_op_type {
RTE_CRYPTO_ASYM_OP_ENCRYPT,
/**< Asymmetric Encrypt operation */
RTE_CRYPTO_ASYM_OP_DECRYPT,
/**< Asymmetric Decrypt operation */
RTE_CRYPTO_ASYM_OP_SIGN,
/**< Signature Generation operation */
RTE_CRYPTO_ASYM_OP_VERIFY,
/**< Signature Verification operation */
RTE_CRYPTO_ASYM_OP_PRIVATE_KEY_GENERATE,
/**< DH Private Key generation operation */
RTE_CRYPTO_ASYM_OP_PUBLIC_KEY_GENERATE,
/**< DH Public Key generation operation */
RTE_CRYPTO_ASYM_OP_SHARED_SECRET_COMPUTE,
/**< DH Shared Secret compute operation */
RTE_CRYPTO_ASYM_OP_LIST_END
};
/**
* Padding types for RSA signature.
*/
enum rte_crypto_rsa_padding_type {
RTE_CRYPTO_RSA_PADDING_NONE = 0,
/**< RSA no padding scheme */
RTE_CRYPTO_RSA_PADDING_PKCS1_5,
/**< RSA PKCS#1 PKCS1-v1_5 padding scheme. For signatures block type 01,
* for encryption block type 02 are used.
*/
RTE_CRYPTO_RSA_PADDING_OAEP,
/**< RSA PKCS#1 OAEP padding scheme */
RTE_CRYPTO_RSA_PADDING_PSS,
/**< RSA PKCS#1 PSS padding scheme */
RTE_CRYPTO_RSA_PADDING_TYPE_LIST_END
};
/**
* RSA private key type enumeration
*
* enumerates private key format required to perform RSA crypto
* transform.
*
*/
enum rte_crypto_rsa_priv_key_type {
RTE_RSA_KEY_TYPE_EXP,
/**< RSA private key is an exponent */
RTE_RSA_KET_TYPE_QT,
/**< RSA private key is in quintuple format
* See rte_crypto_rsa_priv_key_qt
*/
};
/**
* Structure describing RSA private key in quintuple format.
* See PKCS V1.5 RSA Cryptography Standard.
*/
struct rte_crypto_rsa_priv_key_qt {
rte_crypto_param p;
/**< p - Private key component P
* Private key component of RSA parameter required for CRT method
* of private key operations in Octet-string network byte order
* format.
*/
rte_crypto_param q;
/**< q - Private key component Q
* Private key component of RSA parameter required for CRT method
* of private key operations in Octet-string network byte order
* format.
*/
rte_crypto_param dP;
/**< dP - Private CRT component
* Private CRT component of RSA parameter required for CRT method
* RSA private key operations in Octet-string network byte order
* format.
* dP = d mod ( p - 1 )
*/
rte_crypto_param dQ;
/**< dQ - Private CRT component
* Private CRT component of RSA parameter required for CRT method
* RSA private key operations in Octet-string network byte order
* format.
* dQ = d mod ( q - 1 )
*/
rte_crypto_param qInv;
/**< qInv - Private CRT component
* Private CRT component of RSA parameter required for CRT method
* RSA private key operations in Octet-string network byte order
* format.
* qInv = inv q mod p
*/
};
/**
* Asymmetric RSA transform data
*
* Structure describing RSA xform params
*
*/
struct rte_crypto_rsa_xform {
rte_crypto_param n;
/**< n - Modulus
* Modulus data of RSA operation in Octet-string network
* byte order format.
*/
rte_crypto_param e;
/**< e - Public key exponent
* Public key exponent used for RSA public key operations in Octet-
* string network byte order format.
*/
enum rte_crypto_rsa_priv_key_type key_type;
__extension__
union {
rte_crypto_param d;
/**< d - Private key exponent
* Private key exponent used for RSA
* private key operations in
* Octet-string network byte order format.
*/
struct rte_crypto_rsa_priv_key_qt qt;
/**< qt - Private key in quintuple format */
};
};
/**
* Asymmetric Modular exponentiation transform data
*
* Structure describing modular exponentiation xform param
*
*/
struct rte_crypto_modex_xform {
rte_crypto_param modulus;
/**< modulus
* Pointer to the modulus data for modexp transform operation
* in octet-string network byte order format
*
* In case this number is equal to zero the driver shall set
* the crypto op status field to RTE_CRYPTO_OP_STATUS_ERROR
*/
rte_crypto_param exponent;
/**< exponent
* Exponent of the modexp transform operation in
* octet-string network byte order format
*/
};
/**
* Asymmetric modular multiplicative inverse transform operation
*
* Structure describing modular multiplicative inverse transform
*
*/
struct rte_crypto_modinv_xform {
rte_crypto_param modulus;
/**<
* Pointer to the modulus data for modular multiplicative inverse
* operation in octet-string network byte order format
*
* In case this number is equal to zero the driver shall set
* the crypto op status field to RTE_CRYPTO_OP_STATUS_ERROR
*
* This number shall be relatively prime to base
* in corresponding Modular Multiplicative Inverse
* rte_crypto_mod_op_param
*/
};
/**
* Asymmetric DH transform data
*
* Structure describing deffie-hellman xform params
*
*/
struct rte_crypto_dh_xform {
enum rte_crypto_asym_op_type type;
/**< Setup xform for key generate or shared secret compute */
rte_crypto_param p;
/**< p : Prime modulus data
* DH prime modulus data in octet-string network byte order format.
*
*/
rte_crypto_param g;
/**< g : Generator
* DH group generator data in octet-string network byte order
* format.
*
*/
};
/**
* Asymmetric Digital Signature transform operation
*
* Structure describing DSA xform params
*
*/
struct rte_crypto_dsa_xform {
rte_crypto_param p;
/**< p - Prime modulus
* Prime modulus data for DSA operation in Octet-string network byte
* order format.
*/
rte_crypto_param q;
/**< q : Order of the subgroup.
* Order of the subgroup data in Octet-string network byte order
* format.
* (p-1) % q = 0
*/
rte_crypto_param g;
/**< g: Generator of the subgroup
* Generator data in Octet-string network byte order format.
*/
rte_crypto_param x;
/**< x: Private key of the signer in octet-string network
* byte order format.
* Used when app has pre-defined private key.
* Valid only when xform chain is DSA ONLY.
* if xform chain is DH private key generate + DSA, then DSA sign
* compute will use internally generated key.
*/
};
/**
* TLS named curves
* https://tools.ietf.org/html/rfc8422
*/
enum rte_crypto_ec_group {
RTE_CRYPTO_EC_GROUP_UNKNOWN = 0,
RTE_CRYPTO_EC_GROUP_SECP192R1 = 19,
RTE_CRYPTO_EC_GROUP_SECP224R1 = 21,
RTE_CRYPTO_EC_GROUP_SECP256R1 = 23,
RTE_CRYPTO_EC_GROUP_SECP384R1 = 24,
RTE_CRYPTO_EC_GROUP_SECP521R1 = 25,
};
/**
* Structure for elliptic curve point
*/
struct rte_crypto_ec_point {
rte_crypto_param x;
/**< X coordinate */
rte_crypto_param y;
/**< Y coordinate */
};
/**
* Asymmetric elliptic curve transform data
*
* Structure describing all EC based xform params
*
*/
struct rte_crypto_ec_xform {
enum rte_crypto_ec_group curve_id;
/**< Pre-defined ec groups */
};
/**
* Operations params for modular operations:
* exponentiation and multiplicative inverse
*
*/
struct rte_crypto_mod_op_param {
rte_crypto_param base;
/**<
* Pointer to base of modular exponentiation/multiplicative
* inverse data in octet-string network byte order format
*
* In case Multiplicative Inverse is used this number shall
* be relatively prime to modulus in corresponding Modular
* Multiplicative Inverse rte_crypto_modinv_xform
*/
rte_crypto_param result;
/**<
* Pointer to the result of modular exponentiation/multiplicative inverse
* data in octet-string network byte order format.
*
* This field shall be big enough to hold the result of Modular
* Exponentiation or Modular Multiplicative Inverse
* (bigger or equal to length of modulus)
*/
};
/**
* Asymmetric crypto transform data
*
* Structure describing asym xforms.
*/
struct rte_crypto_asym_xform {
struct rte_crypto_asym_xform *next;
/**< Pointer to next xform to set up xform chain.*/
enum rte_crypto_asym_xform_type xform_type;
/**< Asymmetric crypto transform */
__extension__
union {
struct rte_crypto_rsa_xform rsa;
/**< RSA xform parameters */
struct rte_crypto_modex_xform modex;
/**< Modular Exponentiation xform parameters */
struct rte_crypto_modinv_xform modinv;
/**< Modular Multiplicative Inverse xform parameters */
struct rte_crypto_dh_xform dh;
/**< DH xform parameters */
struct rte_crypto_dsa_xform dsa;
/**< DSA xform parameters */
struct rte_crypto_ec_xform ec;
/**< EC xform parameters, used by elliptic curve based
* operations.
*/
};
};
struct rte_cryptodev_asym_session;
/**
* RSA operation params
*
*/
struct rte_crypto_rsa_op_param {
enum rte_crypto_asym_op_type op_type;
/**< Type of RSA operation for transform */
rte_crypto_param message;
/**<
* Pointer to input data
* - to be encrypted for RSA public encrypt.
* - to be signed for RSA sign generation.
* - to be authenticated for RSA sign verification.
*
* Pointer to output data
* - for RSA private decrypt.
* In this case the underlying array should have been
* allocated with enough memory to hold plaintext output
* (i.e. must be at least RSA key size). The message.length
* field should be 0 and will be overwritten by the PMD
* with the decrypted length.
*
* All data is in Octet-string network byte order format.
*/
rte_crypto_param cipher;
/**<
* Pointer to input data
* - to be decrypted for RSA private decrypt.
*
* Pointer to output data
* - for RSA public encrypt.
* In this case the underlying array should have been allocated
* with enough memory to hold ciphertext output (i.e. must be
* at least RSA key size). The cipher.length field should
* be 0 and will be overwritten by the PMD with the encrypted length.
*
* All data is in Octet-string network byte order format.
*/
rte_crypto_param sign;
/**<
* Pointer to input data
* - to be verified for RSA public decrypt.
*
* Pointer to output data
* - for RSA private encrypt.
* In this case the underlying array should have been allocated
* with enough memory to hold signature output (i.e. must be
* at least RSA key size). The sign.length field should
* be 0 and will be overwritten by the PMD with the signature length.
*
* All data is in Octet-string network byte order format.
*/
enum rte_crypto_rsa_padding_type pad;
/**< RSA padding scheme to be used for transform */
enum rte_crypto_auth_algorithm md;
/**< Hash algorithm to be used for data hash if padding
* scheme is either OAEP or PSS. Valid hash algorithms
* are:
* MD5, SHA1, SHA224, SHA256, SHA384, SHA512
*/
enum rte_crypto_auth_algorithm mgf1md;
/**<
* Hash algorithm to be used for mask generation if
* padding scheme is either OAEP or PSS. If padding
* scheme is unspecified data hash algorithm is used
* for mask generation. Valid hash algorithms are:
* MD5, SHA1, SHA224, SHA256, SHA384, SHA512
*/
};
/**
* Diffie-Hellman Operations params.
* @note:
*/
struct rte_crypto_dh_op_param {
rte_crypto_param pub_key;
/**<
* Output generated public key when xform type is
* DH PUB_KEY_GENERATION.
* Input peer public key when xform type is DH
* SHARED_SECRET_COMPUTATION
* pub_key is in octet-string network byte order format.
*
*/
rte_crypto_param priv_key;
/**<
* Output generated private key if xform type is
* DH PRIVATE_KEY_GENERATION
* Input when xform type is DH SHARED_SECRET_COMPUTATION.
* priv_key is in octet-string network byte order format.
*
*/
rte_crypto_param shared_secret;
/**<
* Output with calculated shared secret
* when dh xform set up with op type = SHARED_SECRET_COMPUTATION.
* shared_secret is an octet-string network byte order format.
*
*/
};
/**
* DSA Operations params
*
*/
struct rte_crypto_dsa_op_param {
enum rte_crypto_asym_op_type op_type;
/**< Signature Generation or Verification */
rte_crypto_param message;
/**< input message to be signed or verified */
rte_crypto_param r;
/**< dsa sign component 'r' value
*
* output if op_type = sign generate,
* input if op_type = sign verify
*/
rte_crypto_param s;
/**< dsa sign component 's' value
*
* output if op_type = sign generate,
* input if op_type = sign verify
*/
rte_crypto_param y;
/**< y : Public key of the signer.
* Public key data of the signer in Octet-string network byte order
* format.
* y = g^x mod p
*/
};
/**
* ECDSA operation params
*/
struct rte_crypto_ecdsa_op_param {
enum rte_crypto_asym_op_type op_type;
/**< Signature generation or verification */
rte_crypto_param pkey;
/**< Private key of the signer for signature generation */
struct rte_crypto_ec_point q;
/**< Public key of the signer for verification */
rte_crypto_param message;
/**< Input message digest to be signed or verified */
rte_crypto_param k;
/**< The ECDSA per-message secret number, which is an integer
* in the interval (1, n-1)
*/
rte_crypto_param r;
/**< r component of elliptic curve signature
* output : for signature generation
* input : for signature verification
*/
rte_crypto_param s;
/**< s component of elliptic curve signature
* output : for signature generation
* input : for signature verification
*/
};
/**
* Structure for EC point multiplication operation param
*/
struct rte_crypto_ecpm_op_param {
struct rte_crypto_ec_point p;
/**< x and y coordinates of input point */
struct rte_crypto_ec_point r;
/**< x and y coordinates of resultant point */
rte_crypto_param scalar;
/**< Scalar to multiply the input point */
};
/**
* Asymmetric Cryptographic Operation.
*
* Structure describing asymmetric crypto operation params.
*
*/
struct rte_crypto_asym_op {
RTE_STD_C11
union {
struct rte_cryptodev_asym_session *session;
/**< Handle for the initialised session context */
struct rte_crypto_asym_xform *xform;
/**< Session-less API crypto operation parameters */
};
__extension__
union {
struct rte_crypto_rsa_op_param rsa;
struct rte_crypto_mod_op_param modex;
struct rte_crypto_mod_op_param modinv;
struct rte_crypto_dh_op_param dh;
struct rte_crypto_dsa_op_param dsa;
struct rte_crypto_ecdsa_op_param ecdsa;
struct rte_crypto_ecpm_op_param ecpm;
};
};
#ifdef __cplusplus
}
#endif
#endif /* _RTE_CRYPTO_ASYM_H_ */