sidh_torture/sidh/msr/include/P751_api.h

107 lines
6.3 KiB
C

/********************************************************************************************
* SIDH: an efficient supersingular isogeny cryptography library
*
* Abstract: API header file for P751
*********************************************************************************************/
#ifndef __P751_API_H__
#define __P751_API_H__
/*********************** Key encapsulation mechanism API ***********************/
#define CRYPTO_SECRETKEYBYTES 644 // MSG_BYTES + SECRETKEY_B_BYTES + CRYPTO_PUBLICKEYBYTES bytes
#define CRYPTO_PUBLICKEYBYTES 564
#define CRYPTO_BYTES 24
#define CRYPTO_CIPHERTEXTBYTES 596 // CRYPTO_PUBLICKEYBYTES + MSG_BYTES bytes
// Algorithm name
#define CRYPTO_ALGNAME "SIKEp751"
// SIKE's key generation
// It produces a private key sk and computes the public key pk.
// Outputs: secret key sk (CRYPTO_SECRETKEYBYTES = 644 bytes)
// public key pk (CRYPTO_PUBLICKEYBYTES = 564 bytes)
int crypto_kem_keypair_SIKEp751(unsigned char *pk, unsigned char *sk);
// SIKE's encapsulation
// Input: public key pk (CRYPTO_PUBLICKEYBYTES = 564 bytes)
// Outputs: shared secret ss (CRYPTO_BYTES = 24 bytes)
// ciphertext message ct (CRYPTO_CIPHERTEXTBYTES = 596 bytes)
int crypto_kem_enc_SIKEp751(unsigned char *ct, unsigned char *ss, const unsigned char *pk);
// SIKE's decapsulation
// Input: secret key sk (CRYPTO_SECRETKEYBYTES = 644 bytes)
// ciphertext message ct (CRYPTO_CIPHERTEXTBYTES = 596 bytes)
// Outputs: shared secret ss (CRYPTO_BYTES = 24 bytes)
int crypto_kem_dec_SIKEp751(unsigned char *ss, const unsigned char *ct, const unsigned char *sk);
// Encoding of keys for KEM-based isogeny system "SIKEp751" (wire format):
// ----------------------------------------------------------------------
// Elements over GF(p751) are encoded in 94 octets in little endian format (i.e., the least significant octet is located in the lowest memory address).
// Elements (a+b*i) over GF(p751^2), where a and b are defined over GF(p751), are encoded as {a, b}, with a in the lowest memory portion.
//
// Private keys sk consist of the concatenation of a 32-byte random value, a value in the range [0, 2^378-1] and the public key pk. In the SIKE API,
// private keys are encoded in 644 octets in little endian format.
// Public keys pk consist of 3 elements in GF(p751^2). In the SIKE API, pk is encoded in 564 octets.
// Ciphertexts ct consist of the concatenation of a public key value and a 32-byte value. In the SIKE API, ct is encoded in 564 + 32 = 596 octets.
// Shared keys ss consist of a value of 24 octets.
/*********************** Ephemeral key exchange API ***********************/
#define SIDH_SECRETKEYBYTES 48
#define SIDH_PUBLICKEYBYTES 564
#define SIDH_BYTES 188
// SECURITY NOTE: SIDH supports ephemeral Diffie-Hellman key exchange. It is NOT secure to use it with static keys.
// See "On the Security of Supersingular Isogeny Cryptosystems", S.D. Galbraith, C. Petit, B. Shani and Y.B. Ti, in ASIACRYPT 2016, 2016.
// Extended version available at: http://eprint.iacr.org/2016/859
// Generation of Alice's secret key
// Outputs random value in [0, 2^372 - 1] to be used as Alice's private key
void random_mod_order_A_SIDHp751(unsigned char* random_digits);
// Generation of Bob's secret key
// Outputs random value in [0, 2^Floor(Log(2,3^239)) - 1] to be used as Bob's private key
void random_mod_order_B_SIDHp751(unsigned char* random_digits);
// Alice's ephemeral public key generation
// Input: a private key PrivateKeyA in the range [0, 2^372 - 1], stored in 47 bytes.
// Output: the public key PublicKeyA consisting of 3 GF(p751^2) elements encoded in 564 bytes.
int EphemeralKeyGeneration_A_SIDHp751(const unsigned char* PrivateKeyA, unsigned char* PublicKeyA);
// Bob's ephemeral key-pair generation
// It produces a private key PrivateKeyB and computes the public key PublicKeyB.
// The private key is an integer in the range [0, 2^Floor(Log(2,3^239)) - 1], stored in 48 bytes.
// The public key consists of 3 GF(p751^2) elements encoded in 564 bytes.
int EphemeralKeyGeneration_B_SIDHp751(const unsigned char* PrivateKeyB, unsigned char* PublicKeyB);
// Alice's ephemeral shared secret computation
// It produces a shared secret key SharedSecretA using her secret key PrivateKeyA and Bob's public key PublicKeyB
// Inputs: Alice's PrivateKeyA is an integer in the range [0, 2^372 - 1], stored in 47 bytes.
// Bob's PublicKeyB consists of 3 GF(p751^2) elements encoded in 564 bytes.
// Output: a shared secret SharedSecretA that consists of one element in GF(p751^2) encoded in 188 bytes.
int EphemeralSecretAgreement_A_SIDHp751(const unsigned char* PrivateKeyA, const unsigned char* PublicKeyB, unsigned char* SharedSecretA);
// Bob's ephemeral shared secret computation
// It produces a shared secret key SharedSecretB using his secret key PrivateKeyB and Alice's public key PublicKeyA
// Inputs: Bob's PrivateKeyB is an integer in the range [0, 2^Floor(Log(2,3^239)) - 1], stored in 48 bytes.
// Alice's PublicKeyA consists of 3 GF(p751^2) elements encoded in 564 bytes.
// Output: a shared secret SharedSecretB that consists of one element in GF(p751^2) encoded in 188 bytes.
int EphemeralSecretAgreement_B_SIDHp751(const unsigned char* PrivateKeyB, const unsigned char* PublicKeyA, unsigned char* SharedSecretB);
// Encoding of keys for KEX-based isogeny system "SIDHp751" (wire format):
// ----------------------------------------------------------------------
// Elements over GF(p751) are encoded in 94 octets in little endian format (i.e., the least significant octet is located in the lowest memory address).
// Elements (a+b*i) over GF(p751^2), where a and b are defined over GF(p751), are encoded as {a, b}, with a in the lowest memory portion.
//
// Private keys PrivateKeyA and PrivateKeyB can have values in the range [0, 2^372-1] and [0, 2^378-1], resp. In the SIDH API, private keys are encoded
// in 48 octets in little endian format.
// Public keys PublicKeyA and PublicKeyB consist of 3 elements in GF(p751^2). In the SIDH API, they are encoded in 564 octets.
// Shared keys SharedSecretA and SharedSecretB consist of one element in GF(p751^2). In the SIDH API, they are encoded in 188 octets.
#endif