int main()
{
int i,bytes,res;
unsigned long ran;
char m[RFS],ml[RFS],c[RFS],e[RFS],raw[100];
rsa_public_key pub;
rsa_private_key priv;
csprng RNG;
octet M={0,sizeof(m),m};
octet ML={0,sizeof(ml),ml};
octet C={0,sizeof(c),c};
octet E={0,sizeof(e),e};
octet RAW={0,sizeof(raw),raw};
time((time_t *)&ran);
RAW.len=100; /* fake random seed source */
RAW.val[0]=ran;
RAW.val[1]=ran>>8;
RAW.val[2]=ran>>16;
RAW.val[3]=ran>>24;
for (i=4;i<100;i++) RAW.val[i]=i;
CREATE_CSPRNG(&RNG,&RAW); /* initialise strong RNG */
printf("Generating public/private key pair\n");
RSA_KEY_PAIR(&RNG,65537,&priv,&pub);
printf("Encrypting test string\n");
OCT_jstring(&M,(char *)"Hello World\n");
OAEP_ENCODE(&M,&RNG,NULL,&E); /* OAEP encode message m to e */
RSA_ENCRYPT(&pub,&E,&C); /* encrypt encoded message */
printf("Ciphertext= "); OCT_output(&C);
printf("Decrypting test string\n");
RSA_DECRYPT(&priv,&C,&ML); /* ... and then decrypt it */
OAEP_DECODE(NULL,&ML); /* decode it */
OCT_output_string(&ML);
if (!OCT_comp(&M,&ML))
{
printf("FAILURE RSA Encryption failed");
return 1;
}
OCT_clear(&M); OCT_clear(&ML); /* clean up afterwards */
OCT_clear(&C); OCT_clear(&RAW); OCT_clear(&E);
KILL_CSPRNG(&RNG);
RSA_PRIVATE_KEY_KILL(&priv);
printf("SUCCESS\n");
return 0;
}
int main()
{
int i,PIN1,PIN2,rtn,err,iter;
char client_id[256];
octet CLIENT_ID = {0,sizeof(client_id),client_id};
char x[PGS],y[PGS];
octet X={sizeof(x), sizeof(x),x};
octet Y={sizeof(y),sizeof(y),y};
/* Master secret shares */
char ms1[PGS], ms2[PGS];
octet MS1={sizeof(ms1),sizeof(ms1),ms1};
octet MS2={sizeof(ms2),sizeof(ms2),ms2};
/* Hash values of CLIENT_ID */
char hcid[32];
octet HCID={sizeof(hcid),sizeof(hcid), hcid};
/* Client secret and shares */
char cs1[2*PFS+1], cs2[2*PFS+1], sec[2*PFS+1];
octet SEC={sizeof(sec),sizeof(sec),sec};
octet CS1={sizeof(cs1),sizeof(cs1), cs1};
octet CS2={sizeof(cs2),sizeof(cs2), cs2};
/* Server secret and shares */
char ss1[4*PFS], ss2[4*PFS], serverSecret[4*PFS];
octet ServerSecret={sizeof(serverSecret),sizeof(serverSecret),serverSecret};
octet SS1={sizeof(ss1),sizeof(ss1),ss1};
octet SS2={sizeof(ss2),sizeof(ss2),ss2};
/* Time Permit and shares */
char tp1[2*PFS+1], tp2[2*PFS+1], tp[2*PFS+1];
octet TP={sizeof(tp),sizeof(tp),tp};
octet TP1={sizeof(tp1),sizeof(tp1),tp1};
octet TP2={sizeof(tp2),sizeof(tp2),tp2};
/* Token stored on computer */
char token[2*PFS+1];
octet TOKEN={sizeof(token),sizeof(token),token};
char ut[2*PFS+1],u[2*PFS+1];
octet UT={sizeof(ut),sizeof(ut),ut};
octet U={sizeof(u),sizeof(u),u};
char hid[2*PFS+1],htid[2*PFS+1];
octet HID={0,sizeof(hid),hid};
octet HTID={0,sizeof(htid),htid};
char e[12*PFS], f[12*PFS];
octet E={sizeof(e),sizeof(e),e};
octet F={sizeof(f),sizeof(f),f};
PIN1 = 1234;
PIN2 = 1234;
/* Assign the End-User an ID */
char* user = "******";
OCT_jstring(&CLIENT_ID,user);
printf("CLIENT: ID %s\n", user);
int date = 0;
char seed[100] = {0};
octet SEED = {0,sizeof(seed),seed};
csprng RNG;
/* unrandom seed value! */
SEED.len=100;
for (i=0;i<100;i++) SEED.val[i]=i+1;
/* initialise random number generator */
CREATE_CSPRNG(&RNG,&SEED);
/* Hash CLIENT_ID */
MPIN_HASH_ID(&CLIENT_ID,&HCID);
OCT_output(&HCID);
/* Generate Client master secret for Certivox and Customer */
rtn = MPIN_RANDOM_GENERATE(&RNG,&MS1);
if (rtn != 0)
{
printf("MPIN_RANDOM_GENERATE(&RNG,&MS1) Error %d\n", rtn);
return 1;
}
rtn = MPIN_RANDOM_GENERATE(&RNG,&MS2);
if (rtn != 0)
{
printf("MPIN_RANDOM_GENERATE(&RNG,&MS2) Error %d\n", rtn);
return 1;
}
printf("MASTER SECRET CERTIVOX:= 0x");
OCT_output(&MS1);
printf("MASTER SECRET CUSTOMER:= 0x");
OCT_output(&MS2);
/* Generate server secret shares */
rtn = MPIN_GET_SERVER_SECRET(&MS1,&SS1);
if (rtn != 0)
{
printf("MPIN_GET_SERVER_SECRET(&MS1,&SS1) Error %d\n", rtn);
return 1;
}
rtn = MPIN_GET_SERVER_SECRET(&MS2,&SS2);
if (rtn != 0)
{
printf("MPIN_GET_SERVER_SECRET(&MS2,&SS2) Error %d\n", rtn);
return 1;
}
printf("SS1 = 0x");
OCT_output(&SS1);
printf("SS2 = 0x");
OCT_output(&SS2);
/* Combine server secret share */
rtn = MPIN_RECOMBINE_G2(&SS1, &SS2, &ServerSecret);
if (rtn != 0)
{
printf("MPIN_RECOMBINE_G2(&SS1, &SS2, &ServerSecret) Error %d\n", rtn);
return 1;
}
printf("ServerSecret = 0x");
OCT_output(&ServerSecret);
/* Generate client secret shares */
rtn = MPIN_GET_CLIENT_SECRET(&MS1,&HCID,&CS1);
if (rtn != 0)
{
printf("MPIN_GET_CLIENT_SECRET(&MS1,&HCID,&CS1) Error %d\n", rtn);
return 1;
}
rtn = MPIN_GET_CLIENT_SECRET(&MS2,&HCID,&CS2);
if (rtn != 0)
{
printf("MPIN_GET_CLIENT_SECRET(&MS2,&HCID,&CS2) Error %d\n", rtn);
return 1;
}
printf("CS1 = 0x");
OCT_output(&CS1);
printf("CS2 = 0x");
OCT_output(&CS2);
/* Combine client secret shares : TOKEN is the full client secret */
rtn = MPIN_RECOMBINE_G1(&CS1, &CS2, &TOKEN);
if (rtn != 0)
{
printf("MPIN_RECOMBINE_G1(&CS1, &CS2, &TOKEN) Error %d\n", rtn);
return 1;
}
printf("Client Secret = 0x");
OCT_output(&TOKEN);
/* Client extracts PIN1 from secret to create Token */
rtn = MPIN_EXTRACT_PIN(&CLIENT_ID, PIN1, &TOKEN);
if (rtn != 0)
{
printf("MPIN_EXTRACT_PIN( &CLIENT_ID, PIN, &TOKEN) Error %d\n", rtn);
return 1;
}
printf("Token = 0x");
OCT_output(&TOKEN);
/* Generate Time Permit shares */
date = today();
for(iter=1; iter<nTimePermitTests+1; iter++)
{
printf("Date %d \n", date);
rtn = MPIN_GET_CLIENT_PERMIT(date,&MS1,&HCID,&TP1);
if (rtn != 0)
{
printf("MPIN_GET_CLIENT_PERMIT(date,&MS1,&HCID,&TP1) Error %d\n", rtn);
return 1;
}
rtn = MPIN_GET_CLIENT_PERMIT(date,&MS2,&HCID,&TP2);
if (rtn != 0)
{
printf("MPIN_GET_CLIENT_PERMIT(date,&MS2,&HCID,&TP2) Error %d\n", rtn);
return 1;
}
printf("TP1 = 0x");
OCT_output(&TP1);
printf("TP2 = 0x");
OCT_output(&TP2);
/* Combine Time Permit shares */
rtn = MPIN_RECOMBINE_G1(&TP1, &TP2, &TP);
if (rtn != 0)
{
printf("MPIN_RECOMBINE_G1(&TP1, &TP2, &TP) Error %d\n", rtn);
return 1;
}
printf("Time Permit = 0x");
OCT_output(&TP);
/* This encoding makes Time permit look random */
if (MPIN_ENCODING(&RNG,&TP)!=0) printf("Encoding error\n");
printf("Encoded Time Permit= "); OCT_output(&TP);
if (MPIN_DECODING(&TP)!=0) printf("Decoding error\n");
printf("Decoded Time Permit= "); OCT_output(&TP);
/* Client first pass */
rtn = MPIN_CLIENT_1(date,&CLIENT_ID,&RNG,&X,PIN2,&TOKEN,&SEC,&U,&UT,&TP);
if (rtn != 0)
{
printf("MPIN_CLIENT_1 ERROR %d\n", rtn);
return 1;
}
/* Server calculates H(ID) and H(T|H(ID)) (if time permits enabled), and maps them to points on the curve HID and HTID resp. */
MPIN_SERVER_1(date,&CLIENT_ID,&HID,&HTID);
/* Server generates Random number Y and sends it to Client */
rtn = MPIN_RANDOM_GENERATE(&RNG,&Y);
if (rtn != 0)
{
printf("MPIN_RANDOM_GENERATE(&RNG,&Y) Error %d\n", rtn);
return 1;
}
printf("Y = 0x");
OCT_output(&Y);
/* Client second pass */
rtn = MPIN_CLIENT_2(&X,&Y,&SEC);
if (rtn != 0)
printf("MPIN_CLIENT_2(&X,&Y,&SEC) Error %d\n", rtn);
printf("V = 0x");
OCT_output(&SEC);
/* Server second pass */
rtn = MPIN_SERVER_2(date,&HID,&HTID,&Y,&ServerSecret,&U,&UT,&SEC,&E,&F);
if (rtn != 0)
{
err=MPIN_KANGAROO(&E,&F);
if (err==0)
{
printf("Iteration %d FAILURE Invalid Token Error Code %d\n", iter, rtn);
break;
}
else
{
printf("Iteration %d FAILURE PIN Error %d, Error Code %d\n", iter, err, rtn);
break;
}
}
else
{
printf("Iteration %d SUCCESS Error Code %d\n", iter, rtn);
}
date++;
}
return 0;
}
int main()
{
int res,len,sha;
int c,ic;
rsa_public_key_2048 PK;
pktype st,ca,pt;
printf("First check signature on self-signed cert and extract CA public key\n");
OCT_frombase64(&IO,ca_b64);
printf("CA Self-Signed Cert= \n");
OCT_output(&IO);
printf("\n");
st=X509_extract_cert_sig(&IO,&SIG); // returns signature type
if (st.type==0)
{
printf("Unable to extract cert signature\n");
return 0;
}
if (st.type==ECC)
{
OCT_chop(&SIG,&S,SIG.len/2);
OCT_copy(&R,&SIG);
printf("ECC SIG= \n");
OCT_output(&R);
OCT_output(&S);
printf("\n");
}
if (st.type==RSA)
{
printf("RSA SIG= \n");
OCT_output(&SIG);
printf("\n");
}
if (st.hash==H256) printf("Hashed with SHA256\n");
if (st.hash==H384) printf("Hashed with SHA384\n");
if (st.hash==H512) printf("Hashed with SHA512\n");
// Extract Cert from signed Cert
c=X509_extract_cert(&IO,&H);
printf("\nCert= \n");
OCT_output(&H);
printf("\n");
// show some details
printf("Issuer Details\n");
ic=X509_find_issuer(&H);
c=X509_find_entity_property(&H,&ON,ic,&len);
print_out("owner=",&H,c,len);
c=X509_find_entity_property(&H,&CN,ic,&len);
print_out("country=",&H,c,len);
c=X509_find_entity_property(&H,&EN,ic,&len);
print_out("email=",&H,c,len);
printf("\n");
ca=X509_extract_public_key(&H,&CAKEY);
if (ca.type==0)
{
printf("Not supported by library\n");
return 0;
}
if (ca.type!=st.type)
{
printf("Not self-signed\n");
}
if (ca.type==ECC)
{
printf("EXTRACTED ECC PUBLIC KEY= \n");
OCT_output(&CAKEY);
}
if (ca.type==RSA)
{
printf("EXTRACTED RSA PUBLIC KEY= \n");
OCT_output(&CAKEY);
}
printf("\n");
// Cert is self-signed - so check signature
printf("Checking Self-Signed Signature\n");
if (ca.type==ECC)
{
if (ca.curve!=CHOICE)
{
printf("Curve is not supported\n");
return 0;
}
res=ECP_NIST256_PUBLIC_KEY_VALIDATE(1,&CAKEY);
if (res!=0)
{
printf("ECP Public Key is invalid!\n");
return 0;
}
else printf("ECP Public Key is Valid\n");
sha=0;
if (st.hash==H256) sha=SHA256;
if (st.hash==H384) sha=SHA384;
if (st.hash==H512) sha=SHA512;
if (st.hash==0)
{
printf("Hash Function not supported\n");
return 0;
}
if (ECP_NIST256_VP_DSA(sha,&CAKEY,&H,&R,&S)!=0)
{
printf("***ECDSA Verification Failed\n");
return 0;
}
else
printf("ECDSA Signature/Verification succeeded \n");
}
if (ca.type==RSA)
{
if (ca.curve!=2048)
{
printf("RSA bit size is not supported\n");
return 0;
}
PK.e=65537; // assuming this!
RSA_2048_fromOctet(PK.n,&CAKEY);
sha=0;
if (st.hash==H256) sha=SHA256;
if (st.hash==H384) sha=SHA384;
if (st.hash==H512) sha=SHA512;
if (st.hash==0)
{
printf("Hash Function not supported\n");
return 0;
}
PKCS15(sha,&H,&HP);
RSA_2048_ENCRYPT(&PK,&SIG,&HH);
if (OCT_comp(&HP,&HH))
printf("RSA Signature/Verification succeeded \n");
else
{
printf("***RSA Verification Failed\n");
return 0;
}
}
printf("\nNext check CA signature on cert, and extract public key\n");
OCT_frombase64(&IO,cert_b64);
printf("Example Cert= \n");
OCT_output(&IO);
printf("\n");
st=X509_extract_cert_sig(&IO,&SIG);
if (st.type==0)
{
printf("Unable to check cert signature\n");
return 0;
}
if (st.type==ECC)
{
OCT_chop(&SIG,&S,SIG.len/2);
OCT_copy(&R,&SIG);
printf("SIG= \n");
OCT_output(&R);
OCT_output(&S);
printf("\n");
}
if (st.type==RSA)
{
printf("SIG= \n");
OCT_output(&SIG);
printf("\n");
}
c=X509_extract_cert(&IO,&H);
printf("Cert= \n");
OCT_output(&H);
printf("\n");
printf("Subject Details\n");
ic=X509_find_subject(&H);
c=X509_find_entity_property(&H,&ON,ic,&len);
print_out("owner=",&H,c,len);
c=X509_find_entity_property(&H,&CN,ic,&len);
print_out("country=",&H,c,len);
c=X509_find_entity_property(&H,&EN,ic,&len);
print_out("email=",&H,c,len);
printf("\n");
ic=X509_find_validity(&H);
c=X509_find_start_date(&H,ic);
print_date("start date= ",&H,c);
c=X509_find_expiry_date(&H,ic);
print_date("expiry date=",&H,c);
printf("\n");
pt=X509_extract_public_key(&H,&CERTKEY);
if (pt.type==0)
{
printf("Not supported by library\n");
return 0;
}
if (pt.type==ECC)
{
printf("EXTRACTED ECC PUBLIC KEY= \n");
OCT_output(&CERTKEY);
}
if (pt.type==RSA)
{
printf("EXTRACTED RSA PUBLIC KEY= \n");
OCT_output(&CERTKEY);
}
printf("\n");
/* Check CA signature */
if (ca.type==ECC)
{
printf("Checking CA's ECC Signature on Cert\n");
res=ECP_NIST256_PUBLIC_KEY_VALIDATE(1,&CAKEY);
if (res!=0)
printf("ECP Public Key is invalid!\n");
else printf("ECP Public Key is Valid\n");
sha=0;
if (st.hash==H256) sha=SHA256;
if (st.hash==H384) sha=SHA384;
if (st.hash==H512) sha=SHA512;
if (st.hash==0)
{
printf("Hash Function not supported\n");
return 0;
}
if (ECP_NIST256_VP_DSA(sha,&CAKEY,&H,&R,&S)!=0)
printf("***ECDSA Verification Failed\n");
else
printf("ECDSA Signature/Verification succeeded \n");
}
if (ca.type==RSA)
{
printf("Checking CA's RSA Signature on Cert\n");
PK.e=65537; // assuming this!
RSA_2048_fromOctet(PK.n,&CAKEY);
sha=0;
if (st.hash==H256) sha=SHA256;
if (st.hash==H384) sha=SHA384;
if (st.hash==H512) sha=SHA512;
if (st.hash==0)
{
printf("Hash Function not supported\n");
return 0;
}
PKCS15(sha,&H,&HP);
RSA_2048_ENCRYPT(&PK,&SIG,&HH);
if (OCT_comp(&HP,&HH))
printf("RSA Signature/Verification succeeded \n");
else
printf("***RSA Verification Failed\n");
}
return 0;
}
int main()
{
int i,j=0,res;
int result;
unsigned long ran;
char *pp="M0ng00se";
/* These octets are automatically protected against buffer overflow attacks */
/* Note salt must be big enough to include an appended word */
/* Note ECIES ciphertext C must be big enough to include at least 1 appended block */
/* Recall EFS is field size in bytes. So EFS=32 for 256-bit curve */
char s0[EGS],s1[EGS],w0[2*EFS+1],w1[2*EFS+1],z0[EFS],z1[EFS],raw[100],key[EAS],salt[32],pw[20],p1[30],p2[30],v[2*EFS+1],m[32],c[64],t[32],cs[EGS],ds[EGS];
octet S0={0,sizeof(s0),s0};
octet S1={0,sizeof(s1),s1};
octet W0={0,sizeof(w0),w0};
octet W1={0,sizeof(w1),w1};
octet Z0={0,sizeof(z0),z0};
octet Z1={0,sizeof(z1),z1};
octet RAW={0,sizeof(raw),raw};
octet KEY={0,sizeof(key),key};
octet SALT={0,sizeof(salt),salt};
octet PW={0,sizeof(pw),pw};
octet P1={0,sizeof(p1),p1};
octet P2={0,sizeof(p2),p2};
octet V={0,sizeof(v),v};
octet M={0,sizeof(m),m};
octet C={0,sizeof(c),c};
octet T={0,sizeof(t),t};
octet CS={0,sizeof(cs),cs};
octet DS={0,sizeof(ds),ds};
/* Crypto Strong RNG */
csprng RNG;
time((time_t *)&ran);
/* fake random seed source */
RAW.len=100;
RAW.val[0]=ran;
RAW.val[1]=ran>>8;
RAW.val[2]=ran>>16;
RAW.val[3]=ran>>24;
for (i=0;i<100;i++) RAW.val[i]=i;
/* initialise strong RNG */
CREATE_CSPRNG(&RNG,&RAW);
SALT.len=8;
for (i=0;i<8;i++) SALT.val[i]=i+1; // set Salt
printf("Alice's Passphrase= %s\n",pp);
OCT_empty(&PW);
OCT_jstring(&PW,pp); // set Password from string
/* private key S0 of size EGS bytes derived from Password and Salt */
PBKDF2(&PW,&SALT,1000,EGS,&S0);
printf("Alices private key= 0x"); OCT_output(&S0);
/* Generate Key pair S/W */
ECP_KEY_PAIR_GENERATE(NULL,&S0,&W0);
res=ECP_PUBLIC_KEY_VALIDATE(1,&W0);
if (res!=0)
{
printf("ECP Public Key is invalid!\n");
return 1;
}
printf("Alice's public key= 0x"); OCT_output(&W0);
/* Random private key for other party */
ECP_KEY_PAIR_GENERATE(&RNG,&S1,&W1);
res=ECP_PUBLIC_KEY_VALIDATE(1,&W1);
if (res!=0)
{
printf("ECP Public Key is invalid!\n");
return 1;
}
printf("Servers private key= 0x"); OCT_output(&S1);
printf("Servers public key= 0x"); OCT_output(&W1);
/* Calculate common key using DH - IEEE 1363 method */
ECPSVDP_DH(&S0,&W1,&Z0);
ECPSVDP_DH(&S1,&W0,&Z1);
if (!OCT_comp(&Z0,&Z1))
{
printf("*** ECPSVDP-DH Failed\n");
return 0;
}
KDF2(&Z0,NULL,EAS,&KEY);
printf("Alice's DH Key= 0x"); OCT_output(&KEY);
printf("Servers DH Key= 0x"); OCT_output(&KEY);
printf("Testing ECIES\n");
P1.len=3; P1.val[0]=0x0; P1.val[1]=0x1; P1.val[2]=0x2;
P2.len=4; P2.val[0]=0x0; P2.val[1]=0x1; P2.val[2]=0x2; P2.val[3]=0x3;
M.len=17;
for (i=0;i<=16;i++) M.val[i]=i;
ECP_ECIES_ENCRYPT(&P1,&P2,&RNG,&W1,&M,12,&V,&C,&T);
printf("Ciphertext= \n");
printf("V= 0x"); OCT_output(&V);
printf("C= 0x"); OCT_output(&C);
printf("T= 0x"); OCT_output(&T);
if (!ECP_ECIES_DECRYPT(&P1,&P2,&V,&C,&T,&S1,&M))
{
printf("*** ECIES Decryption Failed\n");
return 1;
}
else printf("Decryption succeeded\n");
printf("Message is 0x"); OCT_output(&M);
printf("Testing ECDSA\n");
if (ECPSP_DSA(&RNG,&S0,&M,&CS,&DS)!=0)
{
printf("***ECDSA Signature Failed\n");
return 1;
}
printf("Signature C = 0x"); OCT_output(&CS);
printf("Signature D = 0x"); OCT_output(&DS);
if (ECPVP_DSA(&W0,&M,&CS,&DS)!=0)
{
printf("***ECDSA Verification Failed\n");
return 1;
}
else printf("ECDSA Signature/Verification succeeded %d\n",j);
KILL_CSPRNG(&RNG);
printf("SUCCESS\n");
return 0;
}
int main(){
int rtn, i, PIN;
const char* user;
/* Master secret shares */
char ms1[PGS];
octet MS1={sizeof(ms1),sizeof(ms1),ms1};
/* Client Identity and its hash */
char client_id[100], hash_id[HASH_BYTES];
octet CLIENT_ID={0,sizeof(client_id),client_id};
octet HASH_ID={0,sizeof(hash_id),hash_id};
/* Server secret and shares */
char serverSecret[4*PFS];
octet ServerSecret={sizeof(serverSecret),sizeof(serverSecret),serverSecret};
#if defined(MBEDTLS_TLS_MILAGRO_CS_TIME_PERMITS)
/* Time Permit and shares */
char tp[2*PFS+1];
octet TP={sizeof(tp),sizeof(tp),tp};
int date = MPIN_today();
#endif
/* Token stored on computer */
char token[2*PFS+1];
octet TOKEN={sizeof(token),sizeof(token),token};
/* Random generator */
char seed[32] = {0};
octet SEED = {0,sizeof(seed),seed};
csprng RNG;
/* unrandom seed value! */
SEED.len=32;
for (i=0;i<32;i++) SEED.val[i]=i+1;
#ifdef DEBUG
printf("SEED: ");
OCT_output(&SEED);
printf("\n");
#endif
MPIN_CREATE_CSPRNG(&RNG,&SEED);
/* Assign the End-User an ID */
user = "******";
OCT_jstring(&CLIENT_ID, (char*)user);
/* Hash CLIENT_ID */
MPIN_HASH_ID(&CLIENT_ID,&HASH_ID);
/* master secret */
rtn = MPIN_RANDOM_GENERATE(&RNG,&MS1);
if (rtn != 0)
{
printf("MILAGRO_CS_RANDOM_GENERATE(&RNG,&MS1) Error %d\n", rtn);
return 1;
}
/* server secret */
rtn = MPIN_GET_SERVER_SECRET(&MS1,&ServerSecret);
if (rtn != 0)
{
printf("MILAGRO_CS_GET_SERVER_SECRET(&MS1,&SS1) Error %d\n", rtn);
return 1;
}
printf("Server Secret = 0x");
OCT_output(&ServerSecret);
/* client secret */
rtn = MPIN_GET_CLIENT_SECRET(&MS1,&HASH_ID,&TOKEN);
if (rtn != 0)
{
printf("MILAGRO_CS_GET_CLIENT_SECRET(&MS1,&HASH_ID,&CS1) Error %d\n", rtn);
return 1;
}
printf("Client Secret = 0x");
OCT_output(&TOKEN);
#if defined(MBEDTLS_TLS_MILAGRO_CS_TIME_PERMITS)
/* Generate Time Permits */
rtn = MPIN_GET_CLIENT_PERMIT(date,&MS1,&HASH_ID,&TP);
if (rtn != 0)
{
printf("MILAGRO_CS_GET_CLIENT_PERMIT(date,&MS1,&HASH_ID,&TP1) Error %d\n", rtn);
return 1;
}
printf("\nTime Permit = 0x");
OCT_output(&TP);
#endif
#if defined(MBEDTLS_TLS_MILAGRO_CS_ENABLE_PIN)
/* Client extracts PIN from secret to create Token */
PIN = 1234;
#else
PIN = 0;
#endif
rtn = MPIN_EXTRACT_PIN(&HASH_ID, PIN, &TOKEN);
if (rtn != 0)
{
printf("MILAGRO_CS_EXTRACT_PIN( &HASH_ID, PIN, &TOKEN) Error %d\n", rtn);
return 1;
}
printf("\nToken = 0x");
OCT_output(&TOKEN);
#if defined(MBEDTLS_TLS_MILAGRO_CS_TIME_PERMITS)
write_to_file("CSTimePermit", TP);
#endif
write_to_file("CSServerKey", ServerSecret);
write_to_file("CSClientKey", TOKEN);
return 0;
}
int test_ecdsa_keypair(int argc, char** argv)
{
if (argc != 2)
{
printf("usage: ./test_ecdsa_sign [path to test vector file]\n");
exit(EXIT_FAILURE);
}
int rc;
FILE * fp = NULL;
char line[LINE_LEN];
char * linePtr = NULL;
int l1=0;
int l2=0;
char * d = NULL;
const char* dStr = "d = ";
octet dOct;
char Qx[EGS];
const char* QxStr = "Qx = ";
octet QxOct = {EGS,EGS,Qx};
char Qy[EGS];
const char* QyStr = "Qy = ";
octet QyOct = {EGS,EGS,Qy};
char q2[2*EFS+1];
octet Q2Oct= {0,sizeof(q2),q2};
fp = fopen(argv[1], "r");
if (fp == NULL)
{
printf("ERROR opening test vector file\n");
exit(EXIT_FAILURE);
}
bool readLine = false;
int i=0;
while (fgets(line, LINE_LEN, fp) != NULL)
{
i++;
readLine = true;
if (!strncmp(line, dStr, strlen(dStr)))
{
#ifdef DEBUG
printf("line %d %s\n", i,line);
#endif
// Find hex value in string
linePtr = line + strlen(dStr);
// Allocate memory
l1 = strlen(linePtr)-1;
l2 = l1/2;
d = (char*) malloc (l2);
if (d==NULL)
exit(EXIT_FAILURE);
// d binary value
amcl_hex2bin(linePtr, d, l1);
dOct.len=l2;
dOct.max=l2;
dOct.val=d;
}
if (!strncmp(line, QxStr, strlen(QxStr)))
{
#ifdef DEBUG
printf("line %d %s\n", i,line);
#endif
// Find hex value in string
linePtr = line + strlen(QxStr);
// Allocate data
l1 = strlen(linePtr)-1;
// Qx binary value
amcl_hex2bin(linePtr, Qx, l1);
}
if (!strncmp(line, QyStr, strlen(QyStr)))
{
#ifdef DEBUG
printf("line %d %s\n", i,line);
#endif
// Find hex value in string
linePtr = line + strlen(QyStr);
// Allocate data
l1 = strlen(linePtr)-1;
// Qy binary value
amcl_hex2bin(linePtr, Qy, l1);
// Assign Public Key
BIG qx, qy;
char q[2*EFS+1];
BIG_fromBytes(qx,QxOct.val);
BIG_fromBytes(qy,QyOct.val);
octet QOct= {sizeof(q),sizeof(q),q};
QOct.val[0]=4;
BIG_toBytes(&(QOct.val[1]),qx);
BIG_toBytes(&(QOct.val[EFS+1]),qy);
// Generate Key pair
ECP_KEY_PAIR_GENERATE(NULL,&dOct,&Q2Oct);
#ifdef DEBUG
printf("QOct: ");
OCT_output(&QOct);
printf("\r\n");
printf("Q2Oct: ");
OCT_output(&Q2Oct);
printf("\r\n");
#endif
rc = OCT_comp(&QOct,&Q2Oct);
if (!rc)
{
printf("TEST ECDSA KEYPAIR FAILED LINE %d\n",i);
exit(EXIT_FAILURE);
}
free(d);
d = NULL;
}
}
fclose(fp);
if (!readLine)
{
printf("ERROR Empty test vector file\n");
exit(EXIT_FAILURE);
}
printf("SUCCESS TEST ECDSA KEYPAIR PASSED\n");
exit(EXIT_SUCCESS);
}
int main()
{
int i,PIN1,PIN2,rtn,err;
char client_id[256];
octet CLIENT_ID = {0,sizeof(client_id),client_id};
char x[PGS],y1[PGS],y2[PGS];
octet X={sizeof(x), sizeof(x),x};
octet Y1={sizeof(y1),sizeof(y1),y1};
octet Y2={sizeof(y2),sizeof(y2),y2};
/* Master secret shares */
char ms1[PGS], ms2[PGS];
octet MS1={sizeof(ms1),sizeof(ms1),ms1};
octet MS2={sizeof(ms2),sizeof(ms2),ms2};
/* Hash values of Client ID */
char hcid[32];
octet HCID={sizeof(hcid),sizeof(hcid), hcid};
/* Client secret and shares */
char cs1[2*PFS+1], cs2[2*PFS+1], sec[2*PFS+1];
octet SEC={sizeof(sec),sizeof(sec),sec};
octet CS1={sizeof(cs1),sizeof(cs1), cs1};
octet CS2={sizeof(cs2),sizeof(cs2), cs2};
/* Server secret and shares */
char ss1[4*PFS], ss2[4*PFS], serverSecret[4*PFS];
octet ServerSecret={sizeof(serverSecret),sizeof(serverSecret),serverSecret};
octet SS1={sizeof(ss1),sizeof(ss1),ss1};
octet SS2={sizeof(ss2),sizeof(ss2),ss2};
/* Time Permit and shares */
char tp1[2*PFS+1], tp2[2*PFS+1], tp[2*PFS+1];
octet TP={sizeof(tp),sizeof(tp),tp};
octet TP1={sizeof(tp1),sizeof(tp1),tp1};
octet TP2={sizeof(tp2),sizeof(tp2),tp2};
/* Token stored on computer */
char token[2*PFS+1];
octet TOKEN={sizeof(token),sizeof(token),token};
char ut[2*PFS+1],u[2*PFS+1];
octet UT={sizeof(ut),sizeof(ut),ut};
octet U={sizeof(u),sizeof(u),u};
char hid[2*PFS+1],htid[2*PFS+1];
octet HID={0,sizeof(hid),hid};
octet HTID={0,sizeof(htid),htid};
char e[12*PFS], f[12*PFS];
octet E={sizeof(e),sizeof(e),e};
octet F={sizeof(f),sizeof(f),f};
int TimeValue = 0;
PIN1 = 1234;
PIN2 = 1234;
/* Assign the End-User an ID */
char* user = "******";
OCT_jstring(&CLIENT_ID,user);
printf("CLIENT: ID %s\n", user);
int date = 0;
char seed[100] = {0};
octet SEED = {0,sizeof(seed),seed};
csprng RNG;
/* unrandom seed value! */
SEED.len=100;
for (i=0;i<100;i++) SEED.val[i]=i+1;
/* initialise random number generator */
CREATE_CSPRNG(&RNG,&SEED);
/* Hash CLIENT_ID */
MPIN_HASH_ID(&CLIENT_ID,&HCID);
OCT_output(&HCID);
/* Generate Client master secret for Certivox and Customer */
rtn = MPIN_RANDOM_GENERATE(&RNG,&MS1);
if (rtn != 0)
{
printf("MPIN_RANDOM_GENERATE(&RNG,&MS1) Error %d\n", rtn);
return 1;
}
rtn = MPIN_RANDOM_GENERATE(&RNG,&MS2);
if (rtn != 0)
{
printf("MPIN_RANDOM_GENERATE(&RNG,&MS2) Error %d\n", rtn);
return 1;
}
printf("MASTER SECRET CERTIVOX:= 0x");
OCT_output(&MS1);
printf("MASTER SECRET CUSTOMER:= 0x");
OCT_output(&MS2);
/* Generate server secret shares */
rtn = MPIN_GET_SERVER_SECRET(&MS1,&SS1);
if (rtn != 0)
{
printf("MPIN_GET_SERVER_SECRET(&MS1,&SS1) Error %d\n", rtn);
return 1;
}
rtn = MPIN_GET_SERVER_SECRET(&MS2,&SS2);
if (rtn != 0)
{
printf("MPIN_GET_SERVER_SECRET(&MS2,&SS2) Error %d\n", rtn);
return 1;
}
printf("SS1 = 0x");
OCT_output(&SS1);
printf("SS2 = 0x");
OCT_output(&SS2);
/* Combine server secret share */
rtn = MPIN_RECOMBINE_G2(&SS1, &SS2, &ServerSecret);
if (rtn != 0)
{
printf("MPIN_RECOMBINE_G2(&SS1, &SS2, &ServerSecret) Error %d\n", rtn);
return 1;
}
printf("ServerSecret = 0x");
OCT_output(&ServerSecret);
/* Generate client secret shares */
rtn = MPIN_GET_CLIENT_SECRET(&MS1,&HCID,&CS1);
if (rtn != 0)
{
printf("MPIN_GET_CLIENT_SECRET(&MS1,&HCID,&CS1) Error %d\n", rtn);
return 1;
}
rtn = MPIN_GET_CLIENT_SECRET(&MS2,&HCID,&CS2);
if (rtn != 0)
{
printf("MPIN_GET_CLIENT_SECRET(&MS2,&HCID,&CS2) Error %d\n", rtn);
return 1;
}
printf("CS1 = 0x");
OCT_output(&CS1);
printf("CS2 = 0x");
OCT_output(&CS2);
/* Combine client secret shares : TOKEN is the full client secret */
rtn = MPIN_RECOMBINE_G1(&CS1, &CS2, &TOKEN);
if (rtn != 0)
{
printf("MPIN_RECOMBINE_G1(&CS1, &CS2, &TOKEN) Error %d\n", rtn);
return 1;
}
printf("Client Secret = 0x");
OCT_output(&TOKEN);
/* Generate Time Permit shares */
date = today();
printf("Date %d \n", date);
rtn = MPIN_GET_CLIENT_PERMIT(date,&MS1,&HCID,&TP1);
if (rtn != 0)
{
printf("MPIN_GET_CLIENT_PERMIT(date,&MS1,&HCID,&TP1) Error %d\n", rtn);
return 1;
}
rtn = MPIN_GET_CLIENT_PERMIT(date,&MS2,&HCID,&TP2);
if (rtn != 0)
{
printf("MPIN_GET_CLIENT_PERMIT(date,&MS2,&HCID,&TP2) Error %d\n", rtn);
return 1;
}
printf("TP1 = 0x");
OCT_output(&TP1);
printf("TP2 = 0x");
OCT_output(&TP2);
/* Combine Time Permit shares */
rtn = MPIN_RECOMBINE_G1(&TP1, &TP2, &TP);
if (rtn != 0)
{
printf("MPIN_RECOMBINE_G1(&TP1, &TP2, &TP) Error %d\n", rtn);
return 1;
}
printf("Time Permit = 0x");
OCT_output(&TP);
/* This encoding makes Time permit look random */
if (MPIN_ENCODING(&RNG,&TP)!=0) printf("Encoding error\n");
printf("Encoded Time Permit= "); OCT_output(&TP);
if (MPIN_DECODING(&TP)!=0) printf("Decoding error\n");
printf("Decoded Time Permit= "); OCT_output(&TP);
/* Client extracts PIN1 from secret to create Token */
rtn = MPIN_EXTRACT_PIN(&CLIENT_ID, PIN1, &TOKEN);
if (rtn != 0)
{
printf("MPIN_EXTRACT_PIN( &CLIENT_ID, PIN, &TOKEN) Error %d\n", rtn);
return 1;
}
printf("Token = 0x");
OCT_output(&TOKEN);
/* One pass MPIN protocol */
/* Client */
TimeValue = MPIN_GET_TIME();
printf("TimeValue %d \n", TimeValue);
rtn = MPIN_CLIENT(date,&CLIENT_ID,&RNG,&X,PIN2,&TOKEN,&SEC,NULL,&UT,&TP,TimeValue,&Y1);
if (rtn != 0)
{
printf("MPIN_CLIENT ERROR %d\n", rtn);
return 1;
}
printf("Y1 = 0x");
OCT_output(&Y1);
printf("V = 0x");
OCT_output(&SEC);
/* Server */
rtn = MPIN_SERVER(date,NULL,&HTID,&Y2,&ServerSecret,NULL,&UT,&SEC,&E,&F,&CLIENT_ID,TimeValue);
printf("Y2 = 0x");
OCT_output(&Y2);
if (rtn != 0)
{
printf("FAILURE Invalid Token Error Code %d\n", rtn);
}
else
{
printf("SUCCESS Error Code %d\n", rtn);
}
return 0;
}
int main()
{
char* KT="feffe9928665731c6d6a8f9467308308";
char* MT="d9313225f88406e5a55909c5aff5269a86a7a9531534f7da2e4c303d8a318a721c3c0c95956809532fcf0e2449a6b525b16aedf5aa0de657ba637b39";
char* HT="feedfacedeadbeeffeedfacedeadbeefabaddad2";
char* NT="9313225df88406e555909c5aff5269aa6a7a9538534f7da1e4c303d2a318a728c3c0c95156809539fcf0e2429a6b525416aedbf5a0de6a57a637b39b";
// Tag should be 619cc5aefffe0bfa462af43c1699d050
int lenM=strlen(MT)/2;
int lenH=strlen(HT)/2;
int lenK=strlen(KT)/2;
int lenIV=strlen(NT)/2;
char t1[16]; // Tag
char t2[16]; // Tag
char k[16]; // AES Key
char h[64]; // Header - to be included in Authentication, but not encrypted
char iv[100]; // IV - Initialisation vector
char m[100]; // Plaintext to be encrypted/authenticated
char c[100]; // Ciphertext
char p[100]; // Recovered Plaintext
octet T1= {sizeof(t1),sizeof(t1),t1};
octet T2= {sizeof(t2),sizeof(t2),t2};
octet K= {0,sizeof(k),k};
octet H= {0,sizeof(h),h};
octet IV= {0,sizeof(iv),iv};
octet M= {0,sizeof(m),m};
octet C= {0,sizeof(c),c};
octet P= {0,sizeof(p),p};
M.len=lenM;
K.len=lenK;
H.len=lenH;
IV.len=lenIV;
hex2bytes(MT, m);
hex2bytes(HT, h);
hex2bytes(NT, iv);
hex2bytes(KT, k);
printf("Plaintext: ");
OCT_output(&M);
printf("\n");
AES_GCM_ENCRYPT(&K, &IV, &H, &M, &C, &T1);
printf("Ciphertext: ");
OCT_output(&C);
printf("\n");
printf("Encryption Tag: ");
OCT_output(&T1);
printf("\n");
AES_GCM_DECRYPT(&K, &IV, &H, &C, &P, &T2);
printf("Plaintext: ");
OCT_output(&P);
printf("\n");
printf("Decryption Tag: ");
OCT_output(&T2);
printf("\n");
if (!OCT_comp(&M,&P))
{
printf("FAILURE Decryption\n");
return 1;
}
if (!OCT_comp(&T1,&T2))
{
printf("FAILURE TAG mismatch\n");
return 1;
}
printf("SUCCESS\n");
return 0;
}
int main()
{
int i,j=0,res;
int result;
unsigned long ran;
char *pp="M0ng00se";
/* These octets are automatically protected against buffer overflow attacks */
/* Note salt must be big enough to include an appended word */
/* Note ECIES ciphertext C must be big enough to include at least 1 appended block */
/* Recall EFS is field size in bytes. So EFS=32 for 256-bit curve */
char s0[EGS],s1[EGS],w0[2*EFS+1],w1[2*EFS+1],z0[EFS],z1[EFS],raw[100],key[EAS],salt[32],pw[20];
octet S0={0,sizeof(s0),s0};
octet S1={0,sizeof(s1),s1};
octet W0={0,sizeof(w0),w0};
octet W1={0,sizeof(w1),w1};
octet Z0={0,sizeof(z0),z0};
octet Z1={0,sizeof(z1),z1};
octet RAW={0,sizeof(raw),raw};
octet KEY={0,sizeof(key),key};
octet SALT={0,sizeof(salt),salt};
octet PW={0,sizeof(pw),pw};
/* Crypto Strong RNG */
csprng RNG;
time((time_t *)&ran);
/* fake random seed source */
RAW.len=100;
RAW.val[0]=ran;
RAW.val[1]=ran>>8;
RAW.val[2]=ran>>16;
RAW.val[3]=ran>>24;
for (i=4;i<100;i++) RAW.val[i]=i;
CREATE_CSPRNG(&RNG,&RAW); /* initialise strong RNG */
SALT.len=8;
for (i=0;i<8;i++) SALT.val[i]=i+1; // set Salt
printf("Alice's Passphrase= %s\n",pp);
OCT_clear(&PW);
OCT_jstring(&PW,pp); // set Password from string
/* private key S0 of size EGS bytes derived from Password and Salt */
PBKDF2(&PW,&SALT,1000,EGS,&S0);
printf("Alices private key= 0x"); OCT_output(&S0);
/* Generate Key pair S/W */
ECP_KEY_PAIR_GENERATE(NULL,&S0,&W0);
res=ECP_PUBLIC_KEY_VALIDATE(1,&W0);
if (res!=0)
{
printf("Alice's ECP Public Key is invalid!\n");
return 1;
}
printf("Alice's public key= 0x"); OCT_output(&W0);
/* Random private key for other party */
ECP_KEY_PAIR_GENERATE(&RNG,&S1,&W1);
printf("Servers private key= 0x"); OCT_output(&S1);
printf("Servers public key= 0x"); OCT_output(&W1);
res=ECP_PUBLIC_KEY_VALIDATE(1,&W1);
if (res!=0)
{
printf("Server's ECP Public Key is invalid!\n");
return 1;
}
/* Calculate common key using DH - IEEE 1363 method */
ECPSVDP_DH(&S0,&W1,&Z0);
ECPSVDP_DH(&S1,&W0,&Z1);
if (!OCT_comp(&Z0,&Z1))
{
printf("*** ECPSVDP-DH Failed\n");
return 1;
}
KDF2(&Z0,NULL,EAS,&KEY);
printf("Alice's DH Key= 0x"); OCT_output(&KEY);
printf("Servers DH Key= 0x"); OCT_output(&KEY);
printf("SUCCESS\n");
return 0;
}
int main()
{
int i,PIN1,PIN2,rtn,err,iter;
char x[PGS],y[PGS];
octet X={sizeof(x), sizeof(x),x};
octet Y={sizeof(y),sizeof(y),y};
/* Master secret shares */
char ms1[PGS], ms2[PGS];
octet MS1={sizeof(ms1),sizeof(ms1),ms1};
octet MS2={sizeof(ms2),sizeof(ms2),ms2};
/* Hash values of CLIENT_ID */
char hcid[32];
octet HCID={sizeof(hcid),sizeof(hcid), hcid};
/* Client secret and shares */
char cs1[2*PFS+1], cs2[2*PFS+1], sec[2*PFS+1];
octet SEC={sizeof(sec),sizeof(sec),sec};
octet CS1={sizeof(cs1),sizeof(cs1), cs1};
octet CS2={sizeof(cs2),sizeof(cs2), cs2};
/* Server secret and shares */
char ss1[4*PFS], ss2[4*PFS], serverSecret[4*PFS];
octet ServerSecret={sizeof(serverSecret),sizeof(serverSecret),serverSecret};
octet SS1={sizeof(ss1),sizeof(ss1),ss1};
octet SS2={sizeof(ss2),sizeof(ss2),ss2};
/* Time Permit and shares */
char tp1[2*PFS+1], tp2[2*PFS+1], tp[2*PFS+1];
octet TP={sizeof(tp),sizeof(tp),tp};
octet TP1={sizeof(tp1),sizeof(tp1),tp1};
octet TP2={sizeof(tp2),sizeof(tp2),tp2};
/* Token stored on computer */
char token[2*PFS+1];
octet TOKEN={sizeof(token),sizeof(token),token};
char ut[2*PFS+1],u[2*PFS+1];
octet UT={sizeof(ut),sizeof(ut),ut};
octet U={sizeof(u),sizeof(u),u};
char hid[2*PFS+1],htid[2*PFS+1];
octet HID={0,sizeof(hid),hid};
octet HTID={0,sizeof(htid),htid};
char e[12*PFS], f[12*PFS];
octet E={sizeof(e),sizeof(e),e};
octet F={sizeof(f),sizeof(f),f};
int date = 0;
unsigned long ran;
int byte_count = 32;
FILE *fp;
char seed[32] = {0};
octet SEED = {sizeof(seed),sizeof(seed),seed};
csprng RNG;
#ifdef __linux__
size_t readSize;
fp = fopen("/dev/urandom", "r");
readSize = fread(&seed, 1, byte_count, fp);
fclose(fp);
#else
/* non random seed value! */
time((time_t *)&ran);
SEED.val[0]=ran;
SEED.val[1]=ran>>8;
SEED.val[2]=ran>>16;
SEED.val[3]=ran>>24;
for (i=4;i<byte_count;i++) SEED.val[i]=i+1;
#endif
printf("SEED 0x");
OCT_output(&SEED);
/* initialise random number generator */
CREATE_CSPRNG(&RNG,&SEED);
for(iter=1; iter<nRandomTests+1; iter++)
{
/* Generate Client master secret for MIRACL and Customer */
rtn = MPIN_RANDOM_GENERATE(&RNG,&MS1);
if (rtn != 0)
{
printf("MPIN_RANDOM_GENERATE(&RNG,&MS1) Error %d\n", rtn);
return 1;
}
rtn = MPIN_RANDOM_GENERATE(&RNG,&MS2);
if (rtn != 0)
{
printf("MPIN_RANDOM_GENERATE(&RNG,&MS2) Error %d\n", rtn);
return 1;
}
printf("MASTER SECRET MIRACL:= 0x");
OCT_output(&MS1);
printf("MASTER SECRET CUSTOMER:= 0x");
OCT_output(&MS2);
/* Generate server secret shares */
rtn = MPIN_GET_SERVER_SECRET(&MS1,&SS1);
if (rtn != 0)
{
printf("MPIN_GET_SERVER_SECRET(&MS1,&SS1) Error %d\n", rtn);
return 1;
}
rtn = MPIN_GET_SERVER_SECRET(&MS2,&SS2);
if (rtn != 0)
{
printf("MPIN_GET_SERVER_SECRET(&MS2,&SS2) Error %d\n", rtn);
return 1;
}
printf("SS1 = 0x");
OCT_output(&SS1);
printf("SS2 = 0x");
OCT_output(&SS2);
/* Combine server secret share */
rtn = MPIN_RECOMBINE_G2(&SS1, &SS2, &ServerSecret);
if (rtn != 0)
{
printf("MPIN_RECOMBINE_G2(&SS1, &SS2, &ServerSecret) Error %d\n", rtn);
return 1;
}
printf("ServerSecret = 0x");
OCT_output(&ServerSecret);
/* Assign the End-User an ID */
char client_id[256];
octet CLIENT_ID = {0,sizeof(client_id),client_id};
rand_str(client_id,256);
OCT_jstring(&CLIENT_ID,client_id);
printf("CLIENT: ID %s\n", client_id);
/* Hash CLIENT_ID */
MPIN_HASH_ID(&CLIENT_ID,&HCID);
OCT_output(&HCID);
srand ( time (NULL) );
PIN1 = rand()%MAX_RANGE; // Get random between 0 and MAX_RANGE
PIN2 = PIN1;
printf("PIN1 %d PIN2 %d\n", PIN1, PIN2);
/* Generate client secret shares */
rtn = MPIN_GET_CLIENT_SECRET(&MS1,&HCID,&CS1);
if (rtn != 0)
{
printf("MPIN_GET_CLIENT_SECRET(&MS1,&HCID,&CS1) Error %d\n", rtn);
return 1;
}
rtn = MPIN_GET_CLIENT_SECRET(&MS2,&HCID,&CS2);
if (rtn != 0)
{
printf("MPIN_GET_CLIENT_SECRET(&MS2,&HCID,&CS2) Error %d\n", rtn);
return 1;
}
printf("CS1 = 0x");
OCT_output(&CS1);
printf("CS2 = 0x");
OCT_output(&CS2);
/* Combine client secret shares : TOKEN is the full client secret */
rtn = MPIN_RECOMBINE_G1(&CS1, &CS2, &TOKEN);
if (rtn != 0)
{
printf("MPIN_RECOMBINE_G1(&CS1, &CS2, &TOKEN) Error %d\n", rtn);
return 1;
}
printf("Client Secret = 0x");
OCT_output(&TOKEN);
/* Client extracts PIN1 from secret to create Token */
rtn = MPIN_EXTRACT_PIN(&CLIENT_ID, PIN1, &TOKEN);
if (rtn != 0)
{
printf("MPIN_EXTRACT_PIN( &CLIENT_ID, PIN, &TOKEN) Error %d\n", rtn);
return 1;
}
printf("Token = 0x");
OCT_output(&TOKEN);
/* Generate Time Permit shares */
date = today();
printf("Date %d \n", date);
rtn = MPIN_GET_CLIENT_PERMIT(date,&MS1,&HCID,&TP1);
if (rtn != 0)
{
printf("MPIN_GET_CLIENT_PERMIT(date,&MS1,&HCID,&TP1) Error %d\n", rtn);
return 1;
}
rtn = MPIN_GET_CLIENT_PERMIT(date,&MS2,&HCID,&TP2);
if (rtn != 0)
{
printf("MPIN_GET_CLIENT_PERMIT(date,&MS2,&HCID,&TP2) Error %d\n", rtn);
return 1;
}
printf("TP1 = 0x");
OCT_output(&TP1);
printf("TP2 = 0x");
OCT_output(&TP2);
/* Combine Time Permit shares */
rtn = MPIN_RECOMBINE_G1(&TP1, &TP2, &TP);
if (rtn != 0)
{
printf("MPIN_RECOMBINE_G1(&TP1, &TP2, &TP) Error %d\n", rtn);
return 1;
}
printf("Time Permit = 0x");
OCT_output(&TP);
/* This encoding makes Time permit look random */
if (MPIN_ENCODING(&RNG,&TP)!=0) printf("Encoding error\n");
printf("Encoded Time Permit= "); OCT_output(&TP);
if (MPIN_DECODING(&TP)!=0) printf("Decoding error\n");
printf("Decoded Time Permit= "); OCT_output(&TP);
/* Client first pass */
rtn = MPIN_CLIENT_1(date,&CLIENT_ID,&RNG,&X,PIN2,&TOKEN,&SEC,&U,&UT,&TP);
if (rtn != 0)
{
printf("MPIN_CLIENT_1 ERROR %d\n", rtn);
return 1;
}
/* Server calculates H(ID) and H(T|H(ID)) (if time permits enabled), and maps them to points on the curve HID and HTID resp. */
MPIN_SERVER_1(date,&CLIENT_ID,&HID,&HTID);
/* Server generates Random number Y and sends it to Client */
rtn = MPIN_RANDOM_GENERATE(&RNG,&Y);
if (rtn != 0)
{
printf("MPIN_RANDOM_GENERATE(&RNG,&Y) Error %d\n", rtn);
return 1;
}
printf("Y = 0x");
OCT_output(&Y);
/* Client second pass */
rtn = MPIN_CLIENT_2(&X,&Y,&SEC);
if (rtn != 0)
printf("MPIN_CLIENT_2(&X,&Y,&SEC) Error %d\n", rtn);
printf("V = 0x");
OCT_output(&SEC);
/* Server second pass */
rtn = MPIN_SERVER_2(date,&HID,&HTID,&Y,&ServerSecret,&U,&UT,&SEC,&E,&F);
if (rtn != 0)
{
err=MPIN_KANGAROO(&E,&F);
if (err==0)
{
printf("Iteration %d FAILURE Invalid Token Error Code %d\n", iter, rtn);
return 1;
}
else
{
printf("Iteration %d FAILURE PIN Error %d, Error Code %d\n", iter, err, rtn);
return 1;
}
}
else
{
printf("Iteration %d SUCCESS Error Code %d\n\n", iter, rtn);
}
}
return 0;
}
