/* * BER Decoder * (C) 1999-2008,2015 Jack Lloyd * * Botan is released under the Simplified BSD License (see license.txt) */ #include #include #include #include namespace Botan { namespace { /* * BER decode an ASN.1 type tag */ size_t decode_tag(DataSource* ber, ASN1_Tag& type_tag, ASN1_Tag& class_tag) { uint8_t b; if(!ber->read_byte(b)) { class_tag = type_tag = NO_OBJECT; return 0; } if((b & 0x1F) != 0x1F) { type_tag = ASN1_Tag(b & 0x1F); class_tag = ASN1_Tag(b & 0xE0); return 1; } size_t tag_bytes = 1; class_tag = ASN1_Tag(b & 0xE0); size_t tag_buf = 0; while(true) { if(!ber->read_byte(b)) throw BER_Decoding_Error("Long-form tag truncated"); if(tag_buf & 0xFF000000) throw BER_Decoding_Error("Long-form tag overflowed 32 bits"); ++tag_bytes; tag_buf = (tag_buf << 7) | (b & 0x7F); if((b & 0x80) == 0) break; } type_tag = ASN1_Tag(tag_buf); return tag_bytes; } /* * Find the EOC marker */ size_t find_eoc(DataSource*); /* * BER decode an ASN.1 length field */ size_t decode_length(DataSource* ber, size_t& field_size) { uint8_t b; if(!ber->read_byte(b)) throw BER_Decoding_Error("Length field not found"); field_size = 1; if((b & 0x80) == 0) return b; field_size += (b & 0x7F); if(field_size == 1) return find_eoc(ber); if(field_size > 5) throw BER_Decoding_Error("Length field is too large"); size_t length = 0; for(size_t i = 0; i != field_size - 1; ++i) { if(get_byte(0, length) != 0) throw BER_Decoding_Error("Field length overflow"); if(!ber->read_byte(b)) throw BER_Decoding_Error("Corrupted length field"); length = (length << 8) | b; } return length; } /* * BER decode an ASN.1 length field */ size_t decode_length(DataSource* ber) { size_t dummy; return decode_length(ber, dummy); } /* * Find the EOC marker */ size_t find_eoc(DataSource* ber) { secure_vector buffer(DEFAULT_BUFFERSIZE), data; while(true) { const size_t got = ber->peek(buffer.data(), buffer.size(), data.size()); if(got == 0) break; data += std::make_pair(buffer.data(), got); } DataSource_Memory source(data); data.clear(); size_t length = 0; while(true) { ASN1_Tag type_tag, class_tag; size_t tag_size = decode_tag(&source, type_tag, class_tag); if(type_tag == NO_OBJECT) break; size_t length_size = 0; size_t item_size = decode_length(&source, length_size); source.discard_next(item_size); length = BOTAN_CHECKED_ADD(length, item_size); length = BOTAN_CHECKED_ADD(length, tag_size); length = BOTAN_CHECKED_ADD(length, length_size); if(type_tag == EOC && class_tag == UNIVERSAL) break; } return length; } } /* * Check a type invariant on BER data */ void BER_Object::assert_is_a(ASN1_Tag type_tag_, ASN1_Tag class_tag_) { if(type_tag != type_tag_ || class_tag != class_tag_) throw BER_Decoding_Error("Tag mismatch when decoding got " + std::to_string(type_tag) + "/" + std::to_string(class_tag) + " expected " + std::to_string(type_tag_) + "/" + std::to_string(class_tag_)); } /* * Check if more objects are there */ bool BER_Decoder::more_items() const { if(m_source->end_of_data() && (m_pushed.type_tag == NO_OBJECT)) return false; return true; } /* * Verify that no bytes remain in the source */ BER_Decoder& BER_Decoder::verify_end() { if(!m_source->end_of_data() || (m_pushed.type_tag != NO_OBJECT)) throw Invalid_State("BER_Decoder::verify_end called, but data remains"); return (*this); } /* * Save all the bytes remaining in the source */ BER_Decoder& BER_Decoder::raw_bytes(secure_vector& out) { out.clear(); uint8_t buf; while(m_source->read_byte(buf)) out.push_back(buf); return (*this); } BER_Decoder& BER_Decoder::raw_bytes(std::vector& out) { out.clear(); uint8_t buf; while(m_source->read_byte(buf)) out.push_back(buf); return (*this); } /* * Discard all the bytes remaining in the source */ BER_Decoder& BER_Decoder::discard_remaining() { uint8_t buf; while(m_source->read_byte(buf)) ; return (*this); } /* * Return the BER encoding of the next object */ BER_Object BER_Decoder::get_next_object() { BER_Object next; if(m_pushed.type_tag != NO_OBJECT) { next = m_pushed; m_pushed.class_tag = m_pushed.type_tag = NO_OBJECT; return next; } for(;;) { decode_tag(m_source, next.type_tag, next.class_tag); if(next.type_tag == NO_OBJECT) return next; const size_t length = decode_length(m_source); if(!m_source->check_available(length)) throw BER_Decoding_Error("Value truncated"); next.value.resize(length); if(m_source->read(next.value.data(), length) != length) throw BER_Decoding_Error("Value truncated"); if(next.type_tag == EOC && next.class_tag == UNIVERSAL) continue; else break; } return next; } BER_Decoder& BER_Decoder::get_next(BER_Object& ber) { ber = get_next_object(); return (*this); } /* * Push a object back into the stream */ void BER_Decoder::push_back(const BER_Object& obj) { if(m_pushed.type_tag != NO_OBJECT) throw Invalid_State("BER_Decoder: Only one push back is allowed"); m_pushed = obj; } /* * Begin decoding a CONSTRUCTED type */ BER_Decoder BER_Decoder::start_cons(ASN1_Tag type_tag, ASN1_Tag class_tag) { BER_Object obj = get_next_object(); obj.assert_is_a(type_tag, ASN1_Tag(class_tag | CONSTRUCTED)); BER_Decoder result(obj.value.data(), obj.value.size()); result.m_parent = this; return result; } /* * Finish decoding a CONSTRUCTED type */ BER_Decoder& BER_Decoder::end_cons() { if(!m_parent) throw Invalid_State("BER_Decoder::end_cons called with NULL parent"); if(!m_source->end_of_data()) throw Decoding_Error("BER_Decoder::end_cons called with data left"); return (*m_parent); } /* * BER_Decoder Constructor */ BER_Decoder::BER_Decoder(DataSource& src) { m_source = &src; m_owns = false; m_pushed.type_tag = m_pushed.class_tag = NO_OBJECT; m_parent = nullptr; } /* * BER_Decoder Constructor */ BER_Decoder::BER_Decoder(const uint8_t data[], size_t length) { m_source = new DataSource_Memory(data, length); m_owns = true; m_pushed.type_tag = m_pushed.class_tag = NO_OBJECT; m_parent = nullptr; } /* * BER_Decoder Constructor */ BER_Decoder::BER_Decoder(const secure_vector& data) { m_source = new DataSource_Memory(data); m_owns = true; m_pushed.type_tag = m_pushed.class_tag = NO_OBJECT; m_parent = nullptr; } /* * BER_Decoder Constructor */ BER_Decoder::BER_Decoder(const std::vector& data) { m_source = new DataSource_Memory(data.data(), data.size()); m_owns = true; m_pushed.type_tag = m_pushed.class_tag = NO_OBJECT; m_parent = nullptr; } /* * BER_Decoder Copy Constructor */ BER_Decoder::BER_Decoder(const BER_Decoder& other) { m_source = other.m_source; m_owns = false; if(other.m_owns) { other.m_owns = false; m_owns = true; } m_pushed.type_tag = m_pushed.class_tag = NO_OBJECT; m_parent = other.m_parent; } /* * BER_Decoder Destructor */ BER_Decoder::~BER_Decoder() { if(m_owns) delete m_source; m_source = nullptr; } /* * Request for an object to decode itself */ BER_Decoder& BER_Decoder::decode(ASN1_Object& obj, ASN1_Tag, ASN1_Tag) { obj.decode_from(*this); return (*this); } /* * Decode a BER encoded NULL */ BER_Decoder& BER_Decoder::decode_null() { BER_Object obj = get_next_object(); obj.assert_is_a(NULL_TAG, UNIVERSAL); if(obj.value.size()) throw BER_Decoding_Error("NULL object had nonzero size"); return (*this); } /* * Decode a BER encoded BOOLEAN */ BER_Decoder& BER_Decoder::decode(bool& out) { return decode(out, BOOLEAN, UNIVERSAL); } /* * Decode a small BER encoded INTEGER */ BER_Decoder& BER_Decoder::decode(size_t& out) { return decode(out, INTEGER, UNIVERSAL); } /* * Decode a BER encoded INTEGER */ BER_Decoder& BER_Decoder::decode(BigInt& out) { return decode(out, INTEGER, UNIVERSAL); } BER_Decoder& BER_Decoder::decode_octet_string_bigint(BigInt& out) { secure_vector out_vec; decode(out_vec, OCTET_STRING); out = BigInt::decode(out_vec.data(), out_vec.size()); return (*this); } std::vector BER_Decoder::get_next_octet_string() { std::vector out_vec; decode(out_vec, OCTET_STRING); return out_vec; } /* * Decode a BER encoded BOOLEAN */ BER_Decoder& BER_Decoder::decode(bool& out, ASN1_Tag type_tag, ASN1_Tag class_tag) { BER_Object obj = get_next_object(); obj.assert_is_a(type_tag, class_tag); if(obj.value.size() != 1) throw BER_Decoding_Error("BER boolean value had invalid size"); out = (obj.value[0]) ? true : false; return (*this); } /* * Decode a small BER encoded INTEGER */ BER_Decoder& BER_Decoder::decode(size_t& out, ASN1_Tag type_tag, ASN1_Tag class_tag) { BigInt integer; decode(integer, type_tag, class_tag); if(integer.bits() > 32) throw BER_Decoding_Error("Decoded integer value larger than expected"); out = 0; for(size_t i = 0; i != 4; ++i) out = (out << 8) | integer.byte_at(3-i); return (*this); } /* * Decode a small BER encoded INTEGER */ uint64_t BER_Decoder::decode_constrained_integer(ASN1_Tag type_tag, ASN1_Tag class_tag, size_t T_bytes) { if(T_bytes > 8) throw BER_Decoding_Error("Can't decode small integer over 8 bytes"); BigInt integer; decode(integer, type_tag, class_tag); if(integer.bits() > 8*T_bytes) throw BER_Decoding_Error("Decoded integer value larger than expected"); uint64_t out = 0; for(size_t i = 0; i != 8; ++i) out = (out << 8) | integer.byte_at(7-i); return out; } /* * Decode a BER encoded INTEGER */ BER_Decoder& BER_Decoder::decode(BigInt& out, ASN1_Tag type_tag, ASN1_Tag class_tag) { BER_Object obj = get_next_object(); obj.assert_is_a(type_tag, class_tag); if(obj.value.empty()) out = 0; else { const bool negative = (obj.value[0] & 0x80) ? true : false; if(negative) { for(size_t i = obj.value.size(); i > 0; --i) if(obj.value[i-1]--) break; for(size_t i = 0; i != obj.value.size(); ++i) obj.value[i] = ~obj.value[i]; } out = BigInt(&obj.value[0], obj.value.size()); if(negative) out.flip_sign(); } return (*this); } /* * BER decode a BIT STRING or OCTET STRING */ BER_Decoder& BER_Decoder::decode(secure_vector& out, ASN1_Tag real_type) { return decode(out, real_type, real_type, UNIVERSAL); } /* * BER decode a BIT STRING or OCTET STRING */ BER_Decoder& BER_Decoder::decode(std::vector& out, ASN1_Tag real_type) { return decode(out, real_type, real_type, UNIVERSAL); } /* * BER decode a BIT STRING or OCTET STRING */ BER_Decoder& BER_Decoder::decode(secure_vector& buffer, ASN1_Tag real_type, ASN1_Tag type_tag, ASN1_Tag class_tag) { if(real_type != OCTET_STRING && real_type != BIT_STRING) throw BER_Bad_Tag("Bad tag for {BIT,OCTET} STRING", real_type); BER_Object obj = get_next_object(); obj.assert_is_a(type_tag, class_tag); if(real_type == OCTET_STRING) buffer = obj.value; else { if(obj.value.empty()) throw BER_Decoding_Error("Invalid BIT STRING"); if(obj.value[0] >= 8) throw BER_Decoding_Error("Bad number of unused bits in BIT STRING"); buffer.resize(obj.value.size() - 1); if(obj.value.size() > 1) copy_mem(buffer.data(), &obj.value[1], obj.value.size() - 1); } return (*this); } BER_Decoder& BER_Decoder::decode(std::vector& buffer, ASN1_Tag real_type, ASN1_Tag type_tag, ASN1_Tag class_tag) { if(real_type != OCTET_STRING && real_type != BIT_STRING) throw BER_Bad_Tag("Bad tag for {BIT,OCTET} STRING", real_type); BER_Object obj = get_next_object(); obj.assert_is_a(type_tag, class_tag); if(real_type == OCTET_STRING) buffer = unlock(obj.value); else { if(obj.value.empty()) throw BER_Decoding_Error("Invalid BIT STRING"); if(obj.value[0] >= 8) throw BER_Decoding_Error("Bad number of unused bits in BIT STRING"); buffer.resize(obj.value.size() - 1); if(obj.value.size() > 1) copy_mem(buffer.data(), &obj.value[1], obj.value.size() - 1); } return (*this); } }