shimun/solo
1
0
Fork 0
Code Issues Pull Requests Releases 1 Wiki Activity

start replacing sf crypto with hw crypto

Browse Source
This commit is contained in:
Conor Patrick 2018-06-02 19:36:03 -04:00
parent 28b6305b4c
commit 6d778fa5e9
3 changed files with 388 additions and 4 deletions
Show Stats Download Patch File Download Diff File Expand all files Collapse all files

10
ctap.c
View File

@ -11,6 +11,7 @@
#include "crypto.h"
#include "util.h"
#include "log.h"
#include "device.h"
#define PIN_TOKEN_SIZE 16
@ -1084,10 +1085,11 @@ uint8_t ctap_request(uint8_t * pkt_raw, int length, CTAP_RESPONSE * resp)
CborEncoder encoder;
uint8_t status = 0;
uint8_t cmd = *pkt_raw;
uint64_t t1;
uint64_t t2;
pkt_raw++;
length--;
uint8_t * buf = resp->data;
cbor_encoder_init(&encoder, buf, resp->data_size, 0);
@ -1112,7 +1114,10 @@ uint8_t ctap_request(uint8_t * pkt_raw, int length, CTAP_RESPONSE * resp)
{
case CTAP_MAKE_CREDENTIAL:
printf1(TAG_CTAP,"CTAP_MAKE_CREDENTIAL\n");
t1 = millis();
status = ctap_make_credential(&encoder, pkt_raw, length);
t2 = millis();
printf1(TAG_TIME,"make_credential time: %d ms\n", t2-t1);
dump_hex1(TAG_DUMP, buf, cbor_encoder_get_buffer_size(&encoder, buf));
@ -1120,7 +1125,10 @@ uint8_t ctap_request(uint8_t * pkt_raw, int length, CTAP_RESPONSE * resp)
break;
case CTAP_GET_ASSERTION:
printf1(TAG_CTAP,"CTAP_GET_ASSERTION\n");
t1 = millis();
status = ctap_get_assertion(&encoder, pkt_raw, length);
t2 = millis();
printf1(TAG_TIME,"get_assertion time: %d ms\n", t2-t1);
resp->length = cbor_encoder_get_buffer_size(&encoder, buf);

9
nrf52840/Makefile
View File

@ -23,7 +23,7 @@ SRC_FILES += \
$(PROJ_DIR)/../ctap_parse.c \
$(PROJ_DIR)/../u2f.c \
\
$(PROJ_DIR)/../crypto.c \
$(PROJ_DIR)/crypto.c \
$(PROJ_DIR)/../crypto/sha256.c \
$(PROJ_DIR)/../crypto/tiny-AES-c/aes.c \
$(PROJ_DIR)/../crypto/micro-ecc/uECC.c \
@ -147,9 +147,12 @@ INC_FOLDERS += \
$(SDK_ROOT)/modules/nrfx/drivers/include \
$(SDK_ROOT)/modules/nrfx/hal \
$(SDK_ROOT)/external/fprintf \
$(SDK_ROOT)/external/nrf_cc310/include \
$(SDK_ROOT)/external/nrf_cc310/common \
# Libraries common to all targets
LIB_FILES += \
LIB_FILES += $(SDK_ROOT)/external/nrf_cc310/lib/libnrf_cc310_0.9.9.a \
$(PROJ_DIR)/../tinycbor/lib/libtinycbor.a
# Optimization flags
OPT = -O3 -g3
@ -207,7 +210,7 @@ nrf52840_xxaa: ASMFLAGS += -D__STACK_SIZE=8192
# Add standard libraries at the very end of the linker input, after all objects
# that may need symbols provided by these libraries.
LIB_FILES += -lc -lnosys -lm $(PROJ_DIR)/../tinycbor/lib/libtinycbor.a
LIB_FILES += -lc -lnosys -lm
.PHONY: default help

373
nrf52840/crypto.c Normal file
View File

@ -0,0 +1,373 @@
/*
* Wrapper for crypto implementation on device
*
* */
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include "util.h"
#include "crypto.h"
#include "sha256.h"
#include "uECC.h"
#include "aes.h"
#include "ctap.h"
#include "ssi_pal_types.h"
#include "ssi_pal_mem.h"
#include "sns_silib.h"
#include "crys_ecpki_build.h"
#include "crys_ecpki_ecdsa.h"
#include "crys_ecpki_dh.h"
#include "crys_ecpki_kg.h"
#include "crys_ecpki_domain.h"
#include "crys_rnd.h"
#include "nrf52840.h"
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;
const CRYS_ECPKI_Domain_t* _es256_curve;
CRYS_RND_State_t rndState_ptr;
CRYS_RND_WorkBuff_t rndWorkBuff_ptr;
static const uint8_t * _signing_key = NULL;
// Secrets for testing only
static uint8_t master_secret[32] = "\x00\x11\x22\x33\x44\x55\x66\x77\x88\x99\xaa\xbb\xcc\xdd\xee\xff"
"\xff\xee\xdd\xcc\xbb\xaa\x99\x88\x77\x66\x55\x44\x33\x22\x11\x00";
static uint8_t transport_secret[32] = "\x10\x01\x22\x33\x44\x55\x66\x77\x87\x90\x0a\xbb\x3c\xd8\xee\xff"
"\xff\xee\x8d\x1c\x3b\xfa\x99\x88\x77\x86\x55\x44\xd3\xff\x33\x00";
void crypto_sha256_init()
{
sha256_init(&sha256_ctx);
}
void crypto_reset_master_secret()
{
ctap_generate_rng(master_secret, 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)
{
printf("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)
{
printf("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()
{
int ret;
NVIC_EnableIRQ(CRYPTOCELL_IRQn);
NRF_CRYPTOCELL->ENABLE = 1;
ret = SaSi_LibInit();
if (ret != SA_SILIB_RET_OK) {
printf("Failed SaSi_LibInit - ret = 0x%x\n", ret);
switch(ret)
{
case SA_SILIB_RET_OK:
printf("SA_SILIB_RET_OK\n");
break;
case SA_SILIB_RET_EINVAL_CTX_PTR:
printf("SA_SILIB_RET_EINVAL_CTX_PTR\n");
break;
case SA_SILIB_RET_EINVAL_WORK_BUF_PTR:
printf("SA_SILIB_RET_EINVAL_WORK_BUF_PTR\n");
break;
case SA_SILIB_RET_HAL:
printf("SA_SILIB_RET_HAL\n");
break;
case SA_SILIB_RET_PAL:
printf("SA_SILIB_RET_PAL\n");
break;
case SA_SILIB_RET_EINVAL_HW_VERSION :
printf("SA_SILIB_RET_EINVAL_HW_VERSION \n");
break;
case SA_SILIB_RET_EINVAL_HW_SIGNATURE:
printf("SA_SILIB_RET_EINVAL_HW_SIGNATURE\n");
break;
case SA_SILIB_RESERVE32B:
printf("SA_SILIB_RESERVE32B\n");
break;
}
exit(1);
}
memset(&rndState_ptr, 0, sizeof(CRYS_RND_State_t));
memset(&rndWorkBuff_ptr, 0, sizeof(CRYS_RND_WorkBuff_t));
ret = CRYS_RndInit(&rndState_ptr, &rndWorkBuff_ptr);
if (ret != SA_SILIB_RET_OK) {
printf("Failed CRYS_RndInit - ret = 0x%x\n", ret);
while(1)
;
}
_es256_curve = CRYS_ECPKI_GetEcDomain(CRYS_ECPKI_DomainID_secp256r1);
//
uECC_set_rng((uECC_RNG_Function)ctap_generate_rng);
//
}
void crypto_ecc256_load_attestation_key()
{
_signing_key = attestation_key;
}
void crypto_ecc256_sign(uint8_t * data, int len, uint8_t * sig)
{
CRYS_ECPKI_UserPrivKey_t UserPrivKey;
CRYS_ECDSA_SignUserContext_t SignUserContext;
uint32_t sigsz = 64;
int ret = CRYS_ECPKI_BuildPrivKey(_es256_curve,
_signing_key,
32,
&UserPrivKey);
if (ret != SA_SILIB_RET_OK){
printf(" CRYS_ECPKI_BuildPrivKey failed with 0x%x \n",ret);
exit(1);
}
ret = CRYS_ECDSA_Sign(&rndState_ptr,
CRYS_RND_GenerateVector,
&SignUserContext,
&UserPrivKey,
CRYS_ECPKI_AFTER_HASH_SHA256_mode,
data,
len,
sig,
&sigsz);
if (ret != SA_SILIB_RET_OK){
printf(" CRYS_ECDSA_Sign failed with 0x%x \n",ret);
exit(1);
}
}
/*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, uECC_secp256r1());
memmove(x,pubkey,32);
memmove(y,pubkey+32,32);
}
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;
}
void crypto_ecc256_make_key_pair(uint8_t * pubkey, uint8_t * privkey)
{
if (uECC_make_key(pubkey, privkey, uECC_secp256r1()) != 1)
{
printf("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, uECC_secp256r1()) != 1)
{
printf("Error, uECC_shared_secret failed\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);
}
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;