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ASN1.cpp
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/*
* ASN1.cpp
*
* Created on: Oct 9, 2015
* Author: nissassin17
*/
#include "ASN1.hpp"
#include "BitUtil.hpp"
vector<uint8_t> ASN1::toData() {
vector<uint8_t> data;
return data;
}
size_t ASN1::size() {
return psize;
}
void ASN1::parseTagNumber(const vector<uint8_t>& data, size_t& offset) {
//define tag number
if (BitUtil::isAllOne(data[offset], 5)) {
//high tag number
offset++;
tagNumber = 0ll;
do {
tagNumber = BitUtil::append(tagNumber,
BitUtil::filter(data[offset], 7), 7);
offset++;
} while (BitUtil::isBitOn(data[offset - 1], 7));
offset++;
} else {
//low tag number
tagNumber = BitUtil::filter(data[offset], 5);
offset++;
}
}
long long ASN1::parseContentLength(const vector<uint8_t>& data,
size_t& offset) {
//define length
long long contentLength = 0ll;
if (BitUtil::isBitOff(data[offset], 7)) {
//short form definitive
definitive = true;
contentLength = BitUtil::filter(data[offset], 7);
offset++;
} else {
//long form: definitive or indefinitive
if (not BitUtil::isAllZero(data[offset], 7)) {
//definitive
definitive = false;
//number of octets for length octet
int nlengthOctets = (int) BitUtil::filter(data[offset], 7);
while (offset++, nlengthOctets--) {
contentLength = BitUtil::append(contentLength, data[offset], 8);
}
} else {
//indefinitive form
definitive = true;
contentLength = -1;
offset++;
}
}
return contentLength;
}
void ASN1::parseBoolContent(const vector<uint8_t>& data, size_t& offset) {
//primitive
boolVal = data[offset] == 0;
offset++;
}
void ASN1::parserIntegerContent(const vector<uint8_t>& data, size_t& offset,
long long contentLength) {
//primitive
intVal = vector<uint8_t>();
bool isNegative = BitUtil::isBitOn(data[offset], 7);
for (int i = 0; i < contentLength; i++) {
intVal.push_back(data[offset]);
// intVal = BitUtil::append(intVal, data[offset], 8);
offset++;
}
// BIG NOTE HERE: do 2-complement in case of negative
// if (isNegative) {
// intVal -= (1 << (contentLength - 1));
// }
}
void ASN1::parseRealContent(const vector<uint8_t>& data, size_t& offset,
long long contentLength) {
throw logic_error("ASN1 REAL type is unimplemented");
if (BitUtil::isBitOn(data[offset], 7)) {
//normal real number
//get sign bit
int sign = BitUtil::isBitOn(data[offset], 6);
//get base
int BASE;
switch (BitUtil::filter(data[offset], 2, 4)) {
case 00:
BASE = 2;
break;
case 01:
BASE = 8;
break;
case 10:
BASE = 16;
break;
default: //11 -> reserved
break;
}
//get scale factor
int scaleFactor = BitUtil::filter(data[offset], 2, 2);
//get encoding
switch (BitUtil::filter(data[offset], 2, 0)) {
case 00:
/**
*if bits 2 to 1 are 00, then the second contents octet encodes the value of
*if the exponent as a two's
* complement binary number;
*/
break;
case 01:
/**
* if bits 2 to 1 are 01, then the second and third contents octets encode the value of
* the exponent as a two's complement binary number;
*/
break;
case 10:
/**
* if bits 2 to 1 are 10, then the second, third and fourth contents octets encode the
* value of the exponent as a two's complement binary number;
*/
break;
default:
/**
* if bits 2 to 1 are 11, then the second contents octet encodes the number of octets,
* X say, (as an unsigned binary number) used to encode the value of the exponent,
* and the third up to the (X plus 3)th (inclusive) contents octets encode the value
* of the exponent as a two's complement binary number; the value of X shall be at least one;
* the first nine bits of the transmitted exponent shall not be all zeros or all ones.
*/
break;
}
offset++;
long long intVal = 0;
for (int i = 1; i < contentLength; i++) {
intVal = BitUtil::append(intVal, data[offset], 8);
offset++;
}
} else if (BitUtil::isBitOn(data[offset], 6)) {
//SpecialRealValue
} else {
}
}
void ASN1::parseSequence(const vector<uint8_t>& data, size_t& offset,
long long contentLength) {
size_t oldOffset(offset);
while ((contentLength >= 0 and contentLength + oldOffset > offset)
or (contentLength == -1 and offset < data.size())) {
sequenceVal.push_back(shared_ptr<ASN1>(new ASN1(data, offset)));
offset += (*sequenceVal.rbegin())->size();
}
}
void ASN1::parseSet(const vector<uint8_t>& data, size_t& offset,
long long contentLength) {
size_t oldOffset(offset);
while ((contentLength >= 0 and contentLength + oldOffset > offset)
or (contentLength == -1 and offset < data.size())) {
shared_ptr<ASN1> val(new ASN1(data, offset));
setVal.insert(val);
offset += val->size();
}
}
void ASN1::parseObjectIdentifier(const vector<uint8_t>& data, size_t& offset,
long long contentLength) {
size_t oldOffset(offset);
while ((contentLength >= 0 and contentLength + oldOffset > offset)
or (contentLength == -1 and offset < data.size())) {
long long subid(0ll);
do {
subid = BitUtil::append(subid, data[offset], 7);
offset++;
} while (BitUtil::isBitOn(data[offset - 1], 7));
objectIdentifierVal.push_back(subid);
}
}
void ASN1::parseBitString(const vector<uint8_t>& data, size_t& offset,
long long contentLength) {
int nUnused = data[offset];
offset++;
for (int i = 1; i < contentLength; i++) {
int t;
if (i == contentLength - 1)
t = nUnused;
else
t = 0;
//NOTE: take bitstring as array of bytes (not bool)
// for (int j = 0; j < 8 - t; j++)
// bitStringVal.push_back(BitUtil::isBitOn(data[offset], 7 - j));
bitStringVal.push_back(data[offset]);
offset++;
}
}
void ASN1::parseOctetString(const vector<uint8_t>& data, size_t& offset,
long long contentLength) {
for (int i = 0; i < contentLength; i++) {
octetStringVal.push_back(data[offset]);
offset++;
}
}
void ASN1::parseContent(const vector<uint8_t>& data, size_t& offset,
long long contentLength) {
switch (tagNumber) {
case BOOLEAN:
//primitive
parseBoolContent(data, offset);
break;
case INTEGER:
case ENUMERATED:
//primitive
parserIntegerContent(data, offset, contentLength);
break;
case REAL:
parseRealContent(data, offset, contentLength);
break;
case BIT_STRING:
parseBitString(data, offset, contentLength);
break;
case ASN1_NULL:
//do nothing
break;
case SEQUENCE: //constructed
parseSequence(data, offset, contentLength);
break;
case SET:
parseSet(data, offset, contentLength);
break;
case OBJECT_IDENTIFIER:
parseObjectIdentifier(data, offset, contentLength);
break;
case OCTET_STRING:
case UTF8_STRING:
// parseOctetString(data, offset, contentLength);
// break;
case IA5_STRING:
// parseOctetString(data, offset, contentLength);
// break;
case PRINTABLE_STRING:
// parseOctetString(data, offset, contentLength);
// break;
case UTC_TIME:
parseOctetString(data, offset, contentLength);
break;
default:
throw logic_error("unimplemented asn1 type");
break;
}
}
ASN1::ASN1(const vector<uint8_t> &data, size_t offset) :
typeTag(ASN1_NULL), tagClass(UNIVERSAL), primitive(false), tagNumber(0), definitive(
true), psize(0), wrappedData(NULL) {
size_t oldOffset(offset);
//find tag type
tagClass = (TagClass) BitUtil::filter(data[offset], 2, 6);
//primitive or constructed
primitive = BitUtil::isBitOff(data[offset], 5);
//define tag number
parseTagNumber(data, offset);
//define length
long long contentLength = parseContentLength(data, offset);
if (tagClass == CONTEXT_SPECIFIC) {
vector<uint8_t> wrapper(data.begin() + offset,
data.begin() + offset + contentLength);
offset += contentLength;
wrappedData.reset(new ASN1(wrapper, 0));
} else
//parse content
parseContent(data, offset, contentLength);
psize = offset - oldOffset;
}
const ASN1::BitStringType& ASN1::getBitStringVal() const {
return bitStringVal;
}
ASN1::BoolType ASN1::isBoolVal() const {
return boolVal;
}
bool ASN1::isDefinitive() const {
return definitive;
}
ASN1::IntType ASN1::getIntVal() const {
return intVal;
}
const ASN1::ObjectIdentifierType& ASN1::getObjectIdentifierVal() const {
return objectIdentifierVal;
}
const ASN1::OctetStringType& ASN1::getOctetStringVal() const {
return octetStringVal;
}
bool ASN1::isPrimitive() const {
return primitive;
}
size_t ASN1::getPsize() const {
return psize;
}
const ASN1::SequenceType& ASN1::getSequenceVal() const {
return sequenceVal;
}
const ASN1::SetType& ASN1::getSetVal() const {
return setVal;
}