solo1/fido2/crypto.c

// Copyright 2019 SoloKeys Developers
//
// Licensed under the Apache License, Version 2.0, <LICENSE-APACHE or
// http://apache.org/licenses/LICENSE-2.0> or the MIT license <LICENSE-MIT or
// http://opensource.org/licenses/MIT>, at your option. This file may not be
// copied, modified, or distributed except according to those terms.
/*
 *  Wrapper for crypto implementation on device
 *
 * */
#include <stdio.h>
#include <stdlib.h>
#include <string.h>



#include "util.h"
#include "crypto.h"

#ifdef USE_SOFTWARE_IMPLEMENTATION

#include "sha256.h"
#include "uECC.h"
#include "aes.h"
#include "ctap.h"
#include "device.h"
#include "log.h"
#include APP_CONFIG

#ifdef USING_PC
typedef enum
{
    MBEDTLS_ECP_DP_NONE = 0,
    MBEDTLS_ECP_DP_SECP192R1,      /*!< 192-bits NIST curve  */
    MBEDTLS_ECP_DP_SECP224R1,      /*!< 224-bits NIST curve  */
    MBEDTLS_ECP_DP_SECP256R1,      /*!< 256-bits NIST curve  */
    MBEDTLS_ECP_DP_SECP384R1,      /*!< 384-bits NIST curve  */
    MBEDTLS_ECP_DP_SECP521R1,      /*!< 521-bits NIST curve  */
    MBEDTLS_ECP_DP_BP256R1,        /*!< 256-bits Brainpool curve */
    MBEDTLS_ECP_DP_BP384R1,        /*!< 384-bits Brainpool curve */
    MBEDTLS_ECP_DP_BP512R1,        /*!< 512-bits Brainpool curve */
    MBEDTLS_ECP_DP_CURVE25519,           /*!< Curve25519               */
    MBEDTLS_ECP_DP_SECP192K1,      /*!< 192-bits "Koblitz" curve */
    MBEDTLS_ECP_DP_SECP224K1,      /*!< 224-bits "Koblitz" curve */
    MBEDTLS_ECP_DP_SECP256K1,      /*!< 256-bits "Koblitz" curve */
} mbedtls_ecp_group_id;
#endif


const uint8_t attestation_cert_der[];
const uint16_t attestation_cert_der_size;
const uint8_t attestation_key[];
const uint16_t attestation_key_size;



static SHA256_CTX sha256_ctx;
static const struct uECC_Curve_t * _es256_curve = NULL;
static const uint8_t * _signing_key = NULL;
static int _key_len = 0;

// Secrets for testing only
static uint8_t master_secret[32];

static uint8_t transport_secret[32];



void crypto_sha256_init()
{
    sha256_init(&sha256_ctx);
}

void crypto_reset_master_secret()
{
    ctap_generate_rng(master_secret, 32);
}

void crypto_load_master_secret(uint8_t * key)
{
    memmove(master_secret, key, 32);
    memmove(transport_secret, key+32, 32);
}

void crypto_sha256_update(uint8_t * data, size_t len)
{
    sha256_update(&sha256_ctx, data, len);
}

void crypto_sha256_update_secret()
{
    sha256_update(&sha256_ctx, master_secret, 32);
}

void crypto_sha256_final(uint8_t * hash)
{
    sha256_final(&sha256_ctx, hash);
}

void crypto_sha256_hmac_init(uint8_t * key, uint32_t klen, uint8_t * hmac)
{
    uint8_t buf[64];
    int i;
    memset(buf, 0, sizeof(buf));

    if (key == CRYPTO_MASTER_KEY)
    {
        key = master_secret;
        klen = sizeof(master_secret);
    }

    if(klen > 64)
    {
        printf2(TAG_ERR,"Error, key size must be <= 64\n");
        exit(1);
    }

    memmove(buf, key, klen);

    for (i = 0; i < sizeof(buf); i++)
    {
        buf[i] = buf[i] ^ 0x36;
    }

    crypto_sha256_init();
    crypto_sha256_update(buf, 64);
}

void crypto_sha256_hmac_final(uint8_t * key, uint32_t klen, uint8_t * hmac)
{
    uint8_t buf[64];
    int i;
    crypto_sha256_final(hmac);
    memset(buf, 0, sizeof(buf));
    if (key == CRYPTO_MASTER_KEY)
    {
        key = master_secret;
        klen = sizeof(master_secret);
    }


    if(klen > 64)
    {
        printf2(TAG_ERR,"Error, key size must be <= 64\n");
        exit(1);
    }
    memmove(buf, key, klen);

    for (i = 0; i < sizeof(buf); i++)
    {
        buf[i] = buf[i] ^ 0x5c;
    }

    crypto_sha256_init();
    crypto_sha256_update(buf, 64);
    crypto_sha256_update(hmac, 32);
    crypto_sha256_final(hmac);
}


void crypto_ecc256_init()
{
    uECC_set_rng((uECC_RNG_Function)ctap_generate_rng);
    _es256_curve = uECC_secp256r1();
}


void crypto_ecc256_load_attestation_key()
{
    _signing_key = attestation_key;
    _key_len = 32;
}

void crypto_ecc256_sign(uint8_t * data, int len, uint8_t * sig)
{
    if ( uECC_sign(_signing_key, data, len, sig, _es256_curve) == 0)
    {
        printf2(TAG_ERR,"error, uECC failed\n");
        exit(1);
    }
}

void crypto_ecc256_load_key(uint8_t * data, int len, uint8_t * data2, int len2)
{
    static uint8_t privkey[32];
    generate_private_key(data,len,data2,len2,privkey);
    _signing_key = privkey;
    _key_len = 32;
}

void crypto_ecdsa_sign(uint8_t * data, int len, uint8_t * sig, int MBEDTLS_ECP_ID)
{

    const struct uECC_Curve_t * curve = NULL;

    switch(MBEDTLS_ECP_ID)
    {
        case MBEDTLS_ECP_DP_SECP192R1:
            curve = uECC_secp192r1();
            if (_key_len != 24)  goto fail;
            break;
        case MBEDTLS_ECP_DP_SECP224R1:
            curve = uECC_secp224r1();
            if (_key_len != 28)  goto fail;
            break;
        case MBEDTLS_ECP_DP_SECP256R1:
            curve = uECC_secp256r1();
            if (_key_len != 32)  goto fail;
            break;
        case MBEDTLS_ECP_DP_SECP256K1:
            curve = uECC_secp256k1();
            if (_key_len != 32)  goto fail;
            break;
        default:
            printf2(TAG_ERR,"error, invalid ECDSA alg specifier\n");
            exit(1);
    }

    if ( uECC_sign(_signing_key, data, len, sig, curve) == 0)
    {
        printf2(TAG_ERR,"error, uECC failed\n");
        exit(1);
    }
    return;

fail:
    printf2(TAG_ERR,"error, invalid key length\n");
    exit(1);

}

void generate_private_key(uint8_t * data, int len, uint8_t * data2, int len2, uint8_t * privkey)
{
    crypto_sha256_hmac_init(CRYPTO_MASTER_KEY, 0, privkey);
    crypto_sha256_update(data, len);
    crypto_sha256_update(data2, len2);
    crypto_sha256_update(master_secret, 32);
    crypto_sha256_hmac_final(CRYPTO_MASTER_KEY, 0, privkey);
}


/*int uECC_compute_public_key(const uint8_t *private_key, uint8_t *public_key, uECC_Curve curve);*/
void crypto_ecc256_derive_public_key(uint8_t * data, int len, uint8_t * x, uint8_t * y)
{
    uint8_t privkey[32];
    uint8_t pubkey[64];

    generate_private_key(data,len,NULL,0,privkey);

    memset(pubkey,0,sizeof(pubkey));
    uECC_compute_public_key(privkey, pubkey, _es256_curve);
    memmove(x,pubkey,32);
    memmove(y,pubkey+32,32);
}

void crypto_load_external_key(uint8_t * key, int len)
{
    _signing_key = key;
    _key_len = len;
}


void crypto_ecc256_make_key_pair(uint8_t * pubkey, uint8_t * privkey)
{
    if (uECC_make_key(pubkey, privkey, _es256_curve) != 1)
    {
        printf2(TAG_ERR,"Error, uECC_make_key failed\n");
        exit(1);
    }
}

void crypto_ecc256_shared_secret(const uint8_t * pubkey, const uint8_t * privkey, uint8_t * shared_secret)
{
    if (uECC_shared_secret(pubkey, privkey, shared_secret, _es256_curve) != 1)
    {
        printf2(TAG_ERR,"Error, uECC_shared_secret failed\n");
        exit(1);
    }

}

struct AES_ctx aes_ctx;
void crypto_aes256_init(uint8_t * key, uint8_t * nonce)
{
    if (key == CRYPTO_TRANSPORT_KEY)
    {
        AES_init_ctx(&aes_ctx, transport_secret);
    }
    else
    {
        AES_init_ctx(&aes_ctx, key);
    }
    if (nonce == NULL)
    {
        memset(aes_ctx.Iv, 0, 16);
    }
    else
    {
        memmove(aes_ctx.Iv, nonce, 16);
    }
}

// prevent round key recomputation
void crypto_aes256_reset_iv(uint8_t * nonce)
{
    if (nonce == NULL)
    {
        memset(aes_ctx.Iv, 0, 16);
    }
    else
    {
        memmove(aes_ctx.Iv, nonce, 16);
    }
}

void crypto_aes256_decrypt(uint8_t * buf, int length)
{
    AES_CBC_decrypt_buffer(&aes_ctx, buf, length);
}

void crypto_aes256_encrypt(uint8_t * buf, int length)
{
    AES_CBC_encrypt_buffer(&aes_ctx, buf, length);
}


const uint8_t attestation_cert_der[] =
"\x30\x82\x01\xfb\x30\x82\x01\xa1\xa0\x03\x02\x01\x02\x02\x01\x00\x30\x0a\x06\x08"
"\x2a\x86\x48\xce\x3d\x04\x03\x02\x30\x2c\x31\x0b\x30\x09\x06\x03\x55\x04\x06\x13"
"\x02\x55\x53\x31\x0b\x30\x09\x06\x03\x55\x04\x08\x0c\x02\x4d\x44\x31\x10\x30\x0e"
"\x06\x03\x55\x04\x0a\x0c\x07\x54\x45\x53\x54\x20\x43\x41\x30\x20\x17\x0d\x31\x38"
"\x30\x35\x31\x30\x30\x33\x30\x36\x32\x30\x5a\x18\x0f\x32\x30\x36\x38\x30\x34\x32"
"\x37\x30\x33\x30\x36\x32\x30\x5a\x30\x7c\x31\x0b\x30\x09\x06\x03\x55\x04\x06\x13"
"\x02\x55\x53\x31\x0b\x30\x09\x06\x03\x55\x04\x08\x0c\x02\x4d\x44\x31\x0f\x30\x0d"
"\x06\x03\x55\x04\x07\x0c\x06\x4c\x61\x75\x72\x65\x6c\x31\x15\x30\x13\x06\x03\x55"
"\x04\x0a\x0c\x0c\x54\x45\x53\x54\x20\x43\x4f\x4d\x50\x41\x4e\x59\x31\x22\x30\x20"
"\x06\x03\x55\x04\x0b\x0c\x19\x41\x75\x74\x68\x65\x6e\x74\x69\x63\x61\x74\x6f\x72"
"\x20\x41\x74\x74\x65\x73\x74\x61\x74\x69\x6f\x6e\x31\x14\x30\x12\x06\x03\x55\x04"
"\x03\x0c\x0b\x63\x6f\x6e\x6f\x72\x70\x70\x2e\x63\x6f\x6d\x30\x59\x30\x13\x06\x07"
"\x2a\x86\x48\xce\x3d\x02\x01\x06\x08\x2a\x86\x48\xce\x3d\x03\x01\x07\x03\x42\x00"
"\x04\x45\xa9\x02\xc1\x2e\x9c\x0a\x33\xfa\x3e\x84\x50\x4a\xb8\x02\xdc\x4d\xb9\xaf"
"\x15\xb1\xb6\x3a\xea\x8d\x3f\x03\x03\x55\x65\x7d\x70\x3f\xb4\x02\xa4\x97\xf4\x83"
"\xb8\xa6\xf9\x3c\xd0\x18\xad\x92\x0c\xb7\x8a\x5a\x3e\x14\x48\x92\xef\x08\xf8\xca"
"\xea\xfb\x32\xab\x20\xa3\x62\x30\x60\x30\x46\x06\x03\x55\x1d\x23\x04\x3f\x30\x3d"
"\xa1\x30\xa4\x2e\x30\x2c\x31\x0b\x30\x09\x06\x03\x55\x04\x06\x13\x02\x55\x53\x31"
"\x0b\x30\x09\x06\x03\x55\x04\x08\x0c\x02\x4d\x44\x31\x10\x30\x0e\x06\x03\x55\x04"
"\x0a\x0c\x07\x54\x45\x53\x54\x20\x43\x41\x82\x09\x00\xf7\xc9\xec\x89\xf2\x63\x94"
"\xd9\x30\x09\x06\x03\x55\x1d\x13\x04\x02\x30\x00\x30\x0b\x06\x03\x55\x1d\x0f\x04"
"\x04\x03\x02\x04\xf0\x30\x0a\x06\x08\x2a\x86\x48\xce\x3d\x04\x03\x02\x03\x48\x00"
"\x30\x45\x02\x20\x18\x38\xb0\x45\x03\x69\xaa\xa7\xb7\x38\x62\x01\xaf\x24\x97\x5e"
"\x7e\x74\x64\x1b\xa3\x7b\xf7\xe6\xd3\xaf\x79\x28\xdb\xdc\xa5\x88\x02\x21\x00\xcd"
"\x06\xf1\xe3\xab\x16\x21\x8e\xd8\xc0\x14\xaf\x09\x4f\x5b\x73\xef\x5e\x9e\x4b\xe7"
"\x35\xeb\xdd\x9b\x6d\x8f\x7d\xf3\xc4\x3a\xd7";


const uint16_t attestation_cert_der_size = sizeof(attestation_cert_der)-1;


const uint8_t attestation_key[] = "\xcd\x67\xaa\x31\x0d\x09\x1e\xd1\x6e\x7e\x98\x92\xaa\x07\x0e\x19\x94\xfc\xd7\x14\xae\x7c\x40\x8f\xb9\x46\xb7\x2e\x5f\xe7\x5d\x30";
const uint16_t attestation_key_size = sizeof(attestation_key)-1;


#else
#error "No crypto implementation defined"
#endif