MODULE = CryptX PACKAGE = Crypt::PK::DSA Crypt::PK::DSA _new() CODE: { int rv; Newz(0, RETVAL, 1, struct dsa_struct); if (!RETVAL) croak("FATAL: Newz failed"); RETVAL->key.type = -1; RETVAL->pindex = find_prng("chacha20"); if(RETVAL->pindex==-1) croak("FATAL: find_prng('chacha20') failed"); rv = rng_make_prng(320, RETVAL->pindex, &RETVAL->pstate, NULL); /* 320bits = 40bytes */ if (rv != CRYPT_OK) croak("FATAL: rng_make_prng failed: %s", error_to_string(rv)); } OUTPUT: RETVAL void generate_key(Crypt::PK::DSA self, int group_size=30, int modulus_size=256) PPCODE: { int rv; /* gen the key */ rv = dsa_make_key(&self->pstate, self->pindex, group_size, modulus_size, &self->key); if (rv != CRYPT_OK) croak("FATAL: dsa_make_key failed: %s", error_to_string(rv)); XPUSHs(ST(0)); /* return self */ } void _import(Crypt::PK::DSA self, SV * key_data) PPCODE: { int rv; unsigned char *data=NULL; STRLEN data_len=0; data = (unsigned char *)SvPVbyte(key_data, data_len); if (self->key.type != -1) { dsa_free(&self->key); self->key.type = -1; } rv = dsa_import(data, (unsigned long)data_len, &self->key); if (rv != CRYPT_OK) croak("FATAL: dsa_import failed: %s", error_to_string(rv)); XPUSHs(ST(0)); /* return self */ } void _import_hex(Crypt::PK::DSA self, char *p, char *q, char *g, char *x, char *y) PPCODE: { int rv; if (self->key.type != -1) { dsa_free(&self->key); self->key.type = -1; } rv = dsa_import_radix(16, p, q, g, x, y, &self->key); if (rv != CRYPT_OK) croak("FATAL: dsa_import_radix failed: %s", error_to_string(rv)); XPUSHs(ST(0)); /* return self */ } int is_private(Crypt::PK::DSA self) CODE: if (self->key.type == -1 || self->key.qord <= 0) XSRETURN_UNDEF; RETVAL = (self->key.type == PK_PRIVATE) ? 1 : 0; OUTPUT: RETVAL int size(Crypt::PK::DSA self) CODE: if (self->key.type == -1 || self->key.qord <= 0) XSRETURN_UNDEF; RETVAL = mp_unsigned_bin_size(self->key.g); OUTPUT: RETVAL int size_q(Crypt::PK::DSA self) CODE: if (self->key.type == -1 || self->key.qord <= 0) XSRETURN_UNDEF; RETVAL = self->key.qord; OUTPUT: RETVAL SV* key2hash(Crypt::PK::DSA self) PREINIT: HV *rv_hash; long siz, qsize, psize; char buf[20001]; SV **not_used; CODE: if (self->key.type == -1 || self->key.qord <= 0) XSRETURN_UNDEF; qsize = mp_unsigned_bin_size(self->key.q); psize = mp_unsigned_bin_size(self->key.p); rv_hash = newHV(); /* =====> g */ siz = (self->key.g) ? mp_unsigned_bin_size(self->key.g) : 0; if (siz>10000) { croak("FATAL: key2hash failed - 'g' too big number"); } if (siz>0) { mp_tohex_with_leading_zero(self->key.g, buf, 20000, 0); not_used = hv_store(rv_hash, "g", 1, newSVpv(buf, strlen(buf)), 0); } else{ not_used = hv_store(rv_hash, "g", 1, newSVpv("", 0), 0); } /* =====> q */ siz = (self->key.q) ? mp_unsigned_bin_size(self->key.q) : 0; if (siz>10000) { croak("FATAL: key2hash failed - 'q' too big number"); } if (siz>0) { mp_tohex_with_leading_zero(self->key.q, buf, 20000, 0); not_used = hv_store(rv_hash, "q", 1, newSVpv(buf, strlen(buf)), 0); } else{ not_used = hv_store(rv_hash, "q", 1, newSVpv("", 0), 0); } /* =====> p */ siz = (self->key.p) ? mp_unsigned_bin_size(self->key.p) : 0; if (siz>10000) { croak("FATAL: key2hash failed - 'p' too big number"); } if (siz>0) { mp_tohex_with_leading_zero(self->key.p, buf, 20000, 0); not_used = hv_store(rv_hash, "p", 1, newSVpv(buf, strlen(buf)), 0); } else{ not_used = hv_store(rv_hash, "p", 1, newSVpv("", 0), 0); } /* =====> x */ siz = (self->key.x) ? mp_unsigned_bin_size(self->key.x) : 0; if (siz>10000) { croak("FATAL: key2hash failed - 'x' too big number"); } if (siz>0) { mp_tohex_with_leading_zero(self->key.x, buf, 20000, qsize*2); not_used = hv_store(rv_hash, "x", 1, newSVpv(buf, strlen(buf)), 0); } else{ not_used = hv_store(rv_hash, "x", 1, newSVpv("", 0), 0); } /* =====> y */ siz = (self->key.y) ? mp_unsigned_bin_size(self->key.y) : 0; if (siz>10000) { croak("FATAL: key2hash failed - 'y' too big number"); } if (siz>0) { mp_tohex_with_leading_zero(self->key.y, buf, 20000, psize*2); not_used = hv_store(rv_hash, "y", 1, newSVpv(buf, strlen(buf)), 0); } else{ not_used = hv_store(rv_hash, "y", 1, newSVpv("", 0), 0); } /* =====> size */ not_used = hv_store(rv_hash, "size", 4, newSViv(qsize), 0); /* =====> type */ not_used = hv_store(rv_hash, "type", 4, newSViv(self->key.type), 0); if (not_used) not_used = NULL; /* just silence the warning: variable 'not_used' set but not used */ RETVAL = newRV_noinc((SV*)rv_hash); OUTPUT: RETVAL SV * export_key_der(Crypt::PK::DSA self, char * type) CODE: { int rv; unsigned char out[4096]; unsigned long int out_len = 4096; RETVAL = newSVpvn(NULL, 0); /* undef */ if (strnEQ(type, "private", 7)) { rv = dsa_export(out, &out_len, PK_PRIVATE|PK_STD, &self->key); if (rv != CRYPT_OK) croak("FATAL: dsa_export(PK_PRIVATE|PK_STD) failed: %s", error_to_string(rv)); RETVAL = newSVpvn((char*)out, out_len); } else if (strnEQ(type, "public", 6)) { rv = dsa_export(out, &out_len, PK_PUBLIC|PK_STD, &self->key); if (rv != CRYPT_OK) croak("FATAL: dsa_export(PK_PUBLIC|PK_STD) failed: %s", error_to_string(rv)); RETVAL = newSVpvn((char*)out, out_len); } else { croak("FATAL: export_key_der invalid type '%s'", type); } } OUTPUT: RETVAL SV * _encrypt(Crypt::PK::DSA self, SV * data, char * hash_name) CODE: { int rv, hash_id; unsigned char *data_ptr=NULL; STRLEN data_len=0; unsigned char buffer[1024]; unsigned long buffer_len = 1024; data_ptr = (unsigned char *)SvPVbyte(data, data_len); hash_id = find_hash(hash_name); if(hash_id==-1) croak("FATAL: find_hash failed for '%s'", hash_name); rv = dsa_encrypt_key(data_ptr, (unsigned long)data_len, buffer, &buffer_len, &self->pstate, self->pindex, hash_id, &self->key); if (rv != CRYPT_OK) croak("FATAL: dsa_encrypt_key failed: %s", error_to_string(rv)); RETVAL = newSVpvn((char*)buffer, buffer_len); } OUTPUT: RETVAL SV * _decrypt(Crypt::PK::DSA self, SV * data) CODE: { int rv; unsigned char *data_ptr=NULL; STRLEN data_len=0; unsigned char buffer[1024]; unsigned long buffer_len = 1024; data_ptr = (unsigned char *)SvPVbyte(data, data_len); rv = dsa_decrypt_key(data_ptr, (unsigned long)data_len, buffer, &buffer_len, &self->key); if (rv != CRYPT_OK) croak("FATAL: dsa_decrypt_key_ex failed: %s", error_to_string(rv)); RETVAL = newSVpvn((char*)buffer, buffer_len); } OUTPUT: RETVAL SV * _sign(Crypt::PK::DSA self, SV * data) CODE: { int rv; unsigned char *data_ptr=NULL; STRLEN data_len=0; unsigned char buffer[1024]; unsigned long buffer_len = 1024; data_ptr = (unsigned char *)SvPVbyte(data, data_len); rv = dsa_sign_hash(data_ptr, (unsigned long)data_len, buffer, &buffer_len, &self->pstate, self->pindex, &self->key); if (rv != CRYPT_OK) croak("FATAL: dsa_sign_hash_ex failed: %s", error_to_string(rv)); RETVAL = newSVpvn((char*)buffer, buffer_len); } OUTPUT: RETVAL int _verify(Crypt::PK::DSA self, SV * sig, SV * data) CODE: { int rv, stat; unsigned char *data_ptr=NULL; STRLEN data_len=0; unsigned char *sig_ptr=NULL; STRLEN sig_len=0; data_ptr = (unsigned char *)SvPVbyte(data, data_len); sig_ptr = (unsigned char *)SvPVbyte(sig, sig_len); RETVAL = 1; rv = dsa_verify_hash(sig_ptr, (unsigned long)sig_len, data_ptr, (unsigned long)data_len, &stat, &self->key); if (rv != CRYPT_OK || stat != 1) RETVAL = 0; } OUTPUT: RETVAL void DESTROY(Crypt::PK::DSA self) CODE: if (self->key.type != -1) { dsa_free(&self->key); self->key.type = -1; } Safefree(self);