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/*
* EAC Time Types
* (C) 2007 FlexSecure GmbH
* 2008 Jack Lloyd
*
* Distributed under the terms of the Botan license
*/
#include <botan/eac_asn_obj.h>
#include <botan/der_enc.h>
#include <botan/ber_dec.h>
#include <botan/charset.h>
#include <botan/parsing.h>
#include <ctime>
#include <sstream>
namespace Botan {
namespace {
/*
* Convert a time_t to a struct tm
*/
std::tm get_tm(u64bit timer)
{
std::time_t time_val = static_cast<std::time_t>(timer);
std::tm* tm_p = std::gmtime(&time_val);
if (tm_p == 0)
throw Encoding_Error("EAC_Time: gmtime could not encode " +
to_string(timer));
return (*tm_p);
}
SecureVector<byte> enc_two_digit(u32bit in)
{
SecureVector<byte> result;
in %= 100;
if (in < 10)
{
result.append(0x00);
}
else
{
u32bit y_first_pos = (in - (in%10))/10;
result.append(static_cast<byte>(y_first_pos));
}
u32bit y_sec_pos = in%10;
result.append(static_cast<byte>(y_sec_pos));
return result;
}
u32bit dec_two_digit(byte b1, byte b2)
{
u32bit upper = (u32bit)b1;
u32bit lower = (u32bit)b2;
if (upper > 9 || lower > 9)
{
throw Invalid_Argument("u32bit dec_two_digit(byte b1, byte b2): value too large");
}
return upper*10 + lower;
}
}
/*
* Create an EAC_Time
*/
EAC_Time::EAC_Time(u64bit timer, ASN1_Tag t)
:tag(t)
{
std::tm time_info = get_tm(timer);
year = time_info.tm_year + 1900;
month = time_info.tm_mon + 1;
day = time_info.tm_mday;
}
/*
* Create an EAC_Time
*/
EAC_Time::EAC_Time(const std::string& t_spec, ASN1_Tag t)
:tag(t)
{
set_to(t_spec);
}
/*
* Create an EAC_Time
*/
EAC_Time::EAC_Time(u32bit y, u32bit m, u32bit d, ASN1_Tag t)
: year(y),
month(m),
day(d),
tag(t)
{
}
/*
* Set the time with a human readable string
*/
void EAC_Time::set_to(const std::string& time_str)
{
if (time_str == "")
{
year = month = day = 0;
return;
}
std::vector<std::string> params;
std::string current;
for (u32bit j = 0; j != time_str.size(); ++j)
{
if (Charset::is_digit(time_str[j]))
current += time_str[j];
else
{
if (current != "")
params.push_back(current);
current.clear();
}
}
if (current != "")
params.push_back(current);
if (params.size() != 3)
throw Invalid_Argument("Invalid time specification " + time_str);
year = to_u32bit(params[0]);
month = to_u32bit(params[1]);
day = to_u32bit(params[2]);
if (!passes_sanity_check())
throw Invalid_Argument("Invalid time specification " + time_str);
}
/*
* DER encode a EAC_Time
*/
void EAC_Time::encode_into(DER_Encoder& der) const
{
der.add_object(tag, APPLICATION,
encoded_eac_time());
}
/*
* Return a string representation of the time
*/
std::string EAC_Time::as_string() const
{
if (time_is_set() == false)
throw Invalid_State("EAC_Time::as_string: No time set");
std::string asn1rep;
asn1rep = to_string(year, 2);
asn1rep += to_string(month, 2) + to_string(day, 2);
return asn1rep;
}
/*
* Return if the time has been set somehow
*/
bool EAC_Time::time_is_set() const
{
return (year != 0);
}
/*
* Return a human readable string representation
*/
std::string EAC_Time::readable_string() const
{
if (time_is_set() == false)
throw Invalid_State("EAC_Time::readable_string: No time set");
std::string readable;
readable += to_string(year, 2) + "/";
readable += to_string(month, 2) + "/";
readable += to_string(day, 2) + " ";
return readable;
}
/*
* Do a general sanity check on the time
*/
bool EAC_Time::passes_sanity_check() const
{
if (year < 2000 || year > 2099)
return false;
if (month == 0 || month > 12)
return false;
if (day == 0 || day > 31)
return false;
return true;
}
/******************************************
* modification functions
******************************************/
void EAC_Time::add_years(u32bit years)
{
year += years;
}
void EAC_Time::add_months(u32bit months)
{
year += months/12;
month += months % 12;
if(month > 12)
{
year += 1;
month -= 12;
}
}
/*
* Compare this time against another
*/
s32bit EAC_Time::cmp(const EAC_Time& other) const
{
if (time_is_set() == false)
throw Invalid_State("EAC_Time::cmp: No time set");
const s32bit EARLIER = -1, LATER = 1, SAME_TIME = 0;
if (year < other.year) return EARLIER;
if (year > other.year) return LATER;
if (month < other.month) return EARLIER;
if (month > other.month) return LATER;
if (day < other.day) return EARLIER;
if (day > other.day) return LATER;
return SAME_TIME;
}
/*
* Compare two EAC_Times for in various ways
*/
bool operator==(const EAC_Time& t1, const EAC_Time& t2)
{
return (t1.cmp(t2) == 0);
}
bool operator!=(const EAC_Time& t1, const EAC_Time& t2)
{
return (t1.cmp(t2) != 0);
}
bool operator<=(const EAC_Time& t1, const EAC_Time& t2)
{
return (t1.cmp(t2) <= 0);
}
bool operator>=(const EAC_Time& t1, const EAC_Time& t2)
{
return (t1.cmp(t2) >= 0);
}
bool operator>(const EAC_Time& t1, const EAC_Time& t2)
{
return (t1.cmp(t2) > 0);
}
bool operator<(const EAC_Time& t1, const EAC_Time& t2)
{
return (t1.cmp(t2) < 0);
}
/*
* Decode a BER encoded EAC_Time
*/
void EAC_Time::decode_from(BER_Decoder& source)
{
BER_Object obj = source.get_next_object();
if (obj.type_tag != this->tag)
{
std::string message("decoding type mismatch for EAC_Time, tag is ");
std::stringstream ss;
std::string str_is;
ss << std::hex << obj.type_tag;
ss >> str_is;
message.append(str_is);
message.append(", while it should be ");
std::stringstream ss2;
std::string str_should;
ss2 << std::hex << this->tag;
ss2 >> str_should;
message.append(str_should);
throw Decoding_Error(message);
}
if (obj.value.size() != 6)
{
throw Decoding_Error("EAC_Time decoding failed");
}
try
{
u32bit tmp_year = dec_two_digit(obj.value[0], obj.value[1]);
u32bit tmp_mon = dec_two_digit(obj.value[2], obj.value[3]);
u32bit tmp_day = dec_two_digit(obj.value[4], obj.value[5]);
year = tmp_year + 2000;
month = tmp_mon;
day = tmp_day;
}
catch (Invalid_Argument)
{
throw Decoding_Error("EAC_Time decoding failed");
}
}
u32bit EAC_Time::get_year() const
{
return year;
}
u32bit EAC_Time::get_month() const
{
return month;
}
u32bit EAC_Time::get_day() const
{
return day;
}
/*
* make the value an octet string for encoding
*/
SecureVector<byte> EAC_Time::encoded_eac_time() const
{
SecureVector<byte> result;
result.append(enc_two_digit(year));
result.append(enc_two_digit(month));
result.append(enc_two_digit(day));
return result;
}
ASN1_Ced::ASN1_Ced(std::string const& str)
: EAC_Time(str, ASN1_Tag(37))
{}
ASN1_Ced::ASN1_Ced(u64bit val)
: EAC_Time(val, ASN1_Tag(37))
{}
ASN1_Ced::ASN1_Ced(EAC_Time const& other)
: EAC_Time(other.get_year(), other.get_month(), other.get_day(), ASN1_Tag(37))
{}
ASN1_Cex::ASN1_Cex(std::string const& str)
: EAC_Time(str, ASN1_Tag(36))
{}
ASN1_Cex::ASN1_Cex(u64bit val)
: EAC_Time(val, ASN1_Tag(36))
{}
ASN1_Cex::ASN1_Cex(EAC_Time const& other)
: EAC_Time(other.get_year(), other.get_month(), other.get_day(), ASN1_Tag(36))
{}
}
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