/* * (C) 2014,2015,2017 Jack Lloyd * * Botan is released under the Simplified BSD License (see license.txt) */ #include #include #include #include #include #include #include #include #include #include #include namespace Botan { namespace { bool all_printable_chars(const uint8_t bits[], size_t bits_len) { for(size_t i = 0; i != bits_len; ++i) { int c = bits[i]; if(c > 127) return false; if((std::isalnum(c) || c == '.' || c == ':' || c == '/' || c == '-') == false) return false; } return true; } /* * Special hack to handle GeneralName [2] and [6] (DNS name and URI) */ bool possibly_a_general_name(const uint8_t bits[], size_t bits_len) { if(bits_len <= 2) return false; if(bits[0] != 0x82 && bits[0] != 0x86) return false; if(bits[1] != bits_len - 2) return false; if(all_printable_chars(bits + 2, bits_len - 2) == false) return false; return true; } } std::string ASN1_Formatter::print(const uint8_t in[], size_t len) const { std::ostringstream output; print_to_stream(output, in, len); return output.str(); } void ASN1_Formatter::print_to_stream(std::ostream& output, const uint8_t in[], size_t len) const { BER_Decoder dec(in, len); decode(output, dec, 0); } void ASN1_Formatter::decode(std::ostream& output, BER_Decoder& decoder, size_t level) const { BER_Object obj = decoder.get_next_object(); const bool recurse_deeper = (m_max_depth == 0 || level < m_max_depth); while(obj.is_set()) { const ASN1_Tag type_tag = obj.type(); const ASN1_Tag class_tag = obj.get_class(); const size_t length = obj.length(); /* hack to insert the tag+length back in front of the stuff now that we've gotten the type info */ std::vector bits; DER_Encoder(bits).add_object(type_tag, class_tag, obj.bits(), obj.length()); BER_Decoder data(bits); if(class_tag & CONSTRUCTED) { BER_Decoder cons_info(obj.bits(), obj.length()); if(recurse_deeper) { output << format(type_tag, class_tag, level, length, ""); decode(output, cons_info, level + 1); // recurse } else { output << format(type_tag, class_tag, level, length, format_bin(type_tag, class_tag, bits)); } } else if((class_tag & APPLICATION) || (class_tag & CONTEXT_SPECIFIC)) { bool success_parsing_cs = false; if(m_print_context_specific) { try { if(possibly_a_general_name(bits.data(), bits.size())) { output << format(type_tag, class_tag, level, level, std::string(cast_uint8_ptr_to_char(&bits[2]), bits.size() - 2)); success_parsing_cs = true; } else if(recurse_deeper) { std::vector inner_bits; data.decode(inner_bits, type_tag); BER_Decoder inner(inner_bits); std::ostringstream inner_data; decode(inner_data, inner, level + 1); // recurse output << inner_data.str(); success_parsing_cs = true; } } catch(...) { } } if(success_parsing_cs == false) { output << format(type_tag, class_tag, level, length, format_bin(type_tag, class_tag, bits)); } } else if(type_tag == OBJECT_ID) { OID oid; data.decode(oid); std::string out = OIDS::oid2str_or_empty(oid); if(out.empty()) { out = oid.to_string(); } else { out += " [" + oid.to_string() + "]"; } output << format(type_tag, class_tag, level, length, out); } else if(type_tag == INTEGER || type_tag == ENUMERATED) { BigInt number; if(type_tag == INTEGER) { data.decode(number); } else if(type_tag == ENUMERATED) { data.decode(number, ENUMERATED, class_tag); } std::vector rep = BigInt::encode(number); if(rep.empty()) // if zero rep.resize(1); output << format(type_tag, class_tag, level, length, hex_encode(rep)); } else if(type_tag == BOOLEAN) { bool boolean; data.decode(boolean); output << format(type_tag, class_tag, level, length, (boolean ? "true" : "false")); } else if(type_tag == NULL_TAG) { output << format(type_tag, class_tag, level, length, ""); } else if(type_tag == OCTET_STRING || type_tag == BIT_STRING) { std::vector decoded_bits; data.decode(decoded_bits, type_tag); bool printing_octet_string_worked = false; if(recurse_deeper) { try { BER_Decoder inner(decoded_bits); std::ostringstream inner_data; decode(inner_data, inner, level + 1); // recurse output << format(type_tag, class_tag, level, length, ""); output << inner_data.str(); printing_octet_string_worked = true; } catch(...) { } } if(!printing_octet_string_worked) { output << format(type_tag, class_tag, level, length, format_bin(type_tag, class_tag, decoded_bits)); } } else if(ASN1_String::is_string_type(type_tag)) { ASN1_String str; data.decode(str); output << format(type_tag, class_tag, level, length, str.value()); } else if(type_tag == UTC_TIME || type_tag == GENERALIZED_TIME) { X509_Time time; data.decode(time); output << format(type_tag, class_tag, level, length, time.readable_string()); } else { output << "Unknown ASN.1 tag class=" << static_cast(class_tag) << " type=" << static_cast(type_tag) << "\n"; } obj = decoder.get_next_object(); } } namespace { std::string format_type(ASN1_Tag type_tag, ASN1_Tag class_tag) { if(class_tag == UNIVERSAL) return asn1_tag_to_string(type_tag); if(class_tag == CONSTRUCTED && (type_tag == SEQUENCE || type_tag == SET)) return asn1_tag_to_string(type_tag); std::string name; if(class_tag & CONSTRUCTED) name += "cons "; name += "[" + std::to_string(type_tag) + "]"; if(class_tag & APPLICATION) { name += " appl"; } if(class_tag & CONTEXT_SPECIFIC) { name += " context"; } return name; } } std::string ASN1_Pretty_Printer::format(ASN1_Tag type_tag, ASN1_Tag class_tag, size_t level, size_t length, const std::string& value) const { bool should_skip = false; if(value.length() > m_print_limit) { should_skip = true; } if((type_tag == OCTET_STRING || type_tag == BIT_STRING) && value.length() > m_print_binary_limit) { should_skip = true; } level += m_initial_level; std::ostringstream oss; oss << " d=" << std::setw(2) << level << ", l=" << std::setw(4) << length << ":" << std::string(level + 1, ' ') << format_type(type_tag, class_tag); if(value != "" && !should_skip) { const size_t current_pos = static_cast(oss.tellp()); const size_t spaces_to_align = (current_pos >= m_value_column) ? 1 : (m_value_column - current_pos); oss << std::string(spaces_to_align, ' ') << value; } oss << "\n"; return oss.str(); } std::string ASN1_Pretty_Printer::format_bin(ASN1_Tag /*type_tag*/, ASN1_Tag /*class_tag*/, const std::vector& vec) const { if(all_printable_chars(vec.data(), vec.size())) { return std::string(cast_uint8_ptr_to_char(vec.data()), vec.size()); } else return hex_encode(vec); } }