MODULE = CryptX PACKAGE = Crypt::Mode::CBC PROTOTYPES: DISABLE ### BEWARE - GENERATED FILE, DO NOT EDIT MANUALLY! Crypt::Mode::CBC new(Class, char * cipher_name, int padding=1, int rounds=0) CODE: { Newz(0, RETVAL, 1, struct cbc_struct); if (!RETVAL) croak("FATAL: Newz failed"); RETVAL->padding_mode = padding; RETVAL->padlen = 0; RETVAL->direction = 0; RETVAL->cipher_rounds = rounds; RETVAL->cipher_id = _find_cipher(cipher_name); if (RETVAL->cipher_id == -1) { Safefree(RETVAL); croak("FATAL: find_cipfer failed for '%s'", cipher_name); } } OUTPUT: RETVAL void DESTROY(Crypt::Mode::CBC self) CODE: Safefree(self); void start_decrypt(Crypt::Mode::CBC self, SV * key, SV * iv) ALIAS: start_encrypt = 1 PPCODE: { int rv; STRLEN k_len=0; unsigned char *k=NULL; STRLEN i_len=0; unsigned char *i=NULL; if (!SvPOK(key)) croak("FATAL: key must be string/buffer scalar"); k = (unsigned char *) SvPVbyte(key, k_len); if (!SvPOK(iv)) croak("FATAL: iv must be string/buffer scalar"); i = (unsigned char *) SvPVbyte(iv, i_len); if (i_len != (STRLEN)cipher_descriptor[self->cipher_id].block_length) { croak ("FATAL: sizeof(iv) should be equal to blocksize (%d)", cipher_descriptor[self->cipher_id].block_length); } rv = cbc_start(self->cipher_id, i, k, (unsigned long)k_len, self->cipher_rounds, &self->state); if (rv != CRYPT_OK) { croak("FATAL: cbc_start failed: %s", error_to_string(rv)); } self->direction = ix == 1 ? 1 : -1; self->padlen = 0; XPUSHs(ST(0)); /* return self */ } SV * add(Crypt::Mode::CBC self, ...) CODE: { int rv, has_tmp_block, blen, j; unsigned long i; STRLEN in_data_len, in_data_start, out_len = 0; unsigned char *in_data, *out_data, tmp_block[MAXBLOCKSIZE]; RETVAL = newSVpvn("", 0); for (j = 1; j < items; j++) { in_data = (unsigned char *)SvPVbyte(ST(j), in_data_len); blen = (&self->state)->blocklen; in_data_start = 0; has_tmp_block = 0; if (in_data_len > 0) { if (self->direction == 1) { /* handle non-empty self->pad buffer */ if (self->padlen > 0) { i = (blen - self->padlen); if (in_data_len >= i) { /* enough data to fill pad */ Copy(in_data, self->pad+self->padlen, i, unsigned char); in_data_len -= i; in_data_start = i; rv = cbc_encrypt(self->pad, tmp_block, blen, &self->state); if (rv != CRYPT_OK) { SvREFCNT_dec(RETVAL); croak("FATAL: cbc_encrypt failed: %s", error_to_string(rv)); } self->padlen = 0; has_tmp_block = 1; } else { /* not enough data to fill pad */ Copy(in_data, self->pad+self->padlen, in_data_len, unsigned char); self->padlen += (int)in_data_len; in_data_len = 0; } } i = (unsigned long)(in_data_len % blen); if (in_data_len > 0 && i > 0) { /* save tail of data into pad */ Copy(in_data + in_data_start + in_data_len - i, self->pad, i, unsigned char); self->padlen = i; in_data_len -= i; } if (in_data_len > 0) { i = (unsigned long)(has_tmp_block ? in_data_len + blen : in_data_len); out_data = (unsigned char*)SvGROW(RETVAL, out_len + i + 1) + out_len; out_len += i; if (has_tmp_block) { Copy(tmp_block, out_data, blen, unsigned char); out_data += blen; } rv = cbc_encrypt(in_data+in_data_start, out_data, (unsigned long)in_data_len, &self->state); if (rv != CRYPT_OK) { SvREFCNT_dec(RETVAL); croak("FATAL: cbc_encrypt failed: %s", error_to_string(rv)); } } /* in_data_len > 0 */ else if (has_tmp_block) { out_data = (unsigned char*)SvGROW(RETVAL, out_len + blen + 1) + out_len; out_len += blen; Copy(tmp_block, out_data, blen, unsigned char); } } else if (self->direction == -1) { if (self->padlen == blen) { rv = cbc_decrypt(self->pad, tmp_block, blen, &self->state); if (rv != CRYPT_OK) { SvREFCNT_dec(RETVAL); croak("FATAL: cbc_decrypt failed: %s", error_to_string(rv)); } self->padlen = 0; has_tmp_block = 1; } /* padlen == blen */ else if (self->padlen > 0) { i = (blen - self->padlen); /* remaining bytes in padding buffer */ if (in_data_len >= i) { /* enough data to fill pad */ Copy(in_data, self->pad+self->padlen, i, unsigned char); self->padlen += i; in_data_len -= i; in_data_start = i; if (in_data_len>0 || self->padding_mode == 0) { rv = cbc_decrypt(self->pad, tmp_block, blen, &self->state); if (rv != CRYPT_OK) { SvREFCNT_dec(RETVAL); croak("FATAL: cbc_decrypt failed: %s", error_to_string(rv)); } self->padlen = 0; has_tmp_block = 1; } } else { /* not enough data to fill pad */ Copy(in_data, self->pad+self->padlen, in_data_len, unsigned char); self->padlen += (int)in_data_len; in_data_len = 0; } } /* padlen > 0 */ /* here: a/ padlen == 1..16 && in_data_len == 0; b/ padlen == 0 && in_data_len > 0 */ if (in_data_len>0) { i = (unsigned long)(in_data_len % blen); if (i>0) { /* save tail of data into pad */ Copy(in_data+in_data_start+in_data_len-i, self->pad, i, unsigned char); self->padlen = i; in_data_len -= i; } } if (in_data_len>0) { if (self->padlen == 0 && self->padding_mode !=0) { /* in case of padding keep full pad if no more data */ Copy(in_data+in_data_start+in_data_len-blen, self->pad, blen, unsigned char); self->padlen = blen; in_data_len -= blen; } i = (unsigned long)(has_tmp_block ? in_data_len + blen : in_data_len); if (i > 0) { out_data = (unsigned char*)SvGROW(RETVAL, out_len + i + 1) + out_len; out_len += i; if (has_tmp_block) { Copy(tmp_block, out_data, blen, unsigned char); out_data += blen; } rv = cbc_decrypt(in_data+in_data_start, out_data, (unsigned long)in_data_len, &self->state); if (rv != CRYPT_OK) { SvREFCNT_dec(RETVAL); croak("FATAL: cbc_decrypt failed: %s", error_to_string(rv)); } } } /* in_data_len>0 */ else if (has_tmp_block) { out_data = (unsigned char*)SvGROW(RETVAL, out_len + blen + 1) + out_len; out_len += blen; Copy(tmp_block, out_data, blen, unsigned char); } } else { SvREFCNT_dec(RETVAL); croak("FATAL: call start_decryt or start_encrpyt first (%d)", self->direction); } } } if (out_len > 0) SvCUR_set(RETVAL, out_len); } OUTPUT: RETVAL SV * finish(Crypt::Mode::CBC self) CODE: { unsigned char tmp_block[MAXBLOCKSIZE], ch; int i, j, rv, blen = (&self->state)->blocklen; if (self->direction == 1) { if (self->padlen<0 || self->padlen>=blen) croak("FATAL: invalid padlen"); if (self->padding_mode == 1) { /* pkcs5|7 padding */ i = blen - self->padlen; if (i == 0) i = blen; for(j=self->padlen; jpad[j] = (unsigned char)i; rv = cbc_encrypt(self->pad, tmp_block, blen, &self->state); if (rv != CRYPT_OK) croak("FATAL: cbc_encrypt failed: %s", error_to_string(rv)); } else if (self->padding_mode == 2) { /* oneandzeroes padding */ self->pad[self->padlen] = 0x80; for(j=self->padlen+1; jpad[j] = 0; rv = cbc_encrypt(self->pad, tmp_block, blen, &self->state); if (rv != CRYPT_OK) croak("FATAL: cbc_encrypt failed: %s", error_to_string(rv)); } else { if (self->padlen>0) croak("FATAL: cbc_encrypt, input data length not multiple of %d", blen); blen = 0; } } else if (self->direction == -1) { if (self->padlen > 0) { if (self->padlen != blen) croak("FATAL: cipher text length has to be multiple of %d (%d)", blen, self->padlen); rv = cbc_decrypt(self->pad, tmp_block, blen, &self->state); if (rv != CRYPT_OK) croak("FATAL: cbc_decrypt failed: %s", error_to_string(rv)); if (self->padding_mode == 0) { /* no padding */ /* we already have blen */ } else if (self->padding_mode == 1) { /* pkcs5|7 padding */ ch = tmp_block[blen-1]; blen = blen - (ch > blen ? blen : ch); } else if (self->padding_mode == 2) { /* oneandzeroes padding */ while ((unsigned char)tmp_block[blen - 1] == 0x00) blen--; if ((unsigned char)tmp_block[blen - 1] == 0x80) blen--; if (blen < 0) blen = 0; } } else { blen = 0; } } else { XSRETURN_UNDEF; } self->direction = 0; RETVAL = newSVpvn((char*)tmp_block, blen); } OUTPUT: RETVAL