/src/botan/src/lib/pk_pad/eme_oaep/oaep.cpp

Source (jump to first uncovered line)
/*
* OAEP
* (C) 1999-2010,2015,2018 Jack Lloyd
*
* Botan is released under the Simplified BSD License (see license.txt)
*/

#include <botan/internal/oaep.h>
#include <botan/internal/mgf1.h>
#include <botan/exceptn.h>
#include <botan/rng.h>
#include <botan/internal/ct_utils.h>

namespace Botan {

/*
* OAEP Pad Operation
*/
secure_vector<uint8_t> OAEP::pad(const uint8_t in[], size_t in_length,
                             size_t key_length,
                             RandomNumberGenerator& rng) const
   {
   key_length /= 8;

   if(in_length > maximum_input_size(key_length * 8))
      {
      throw Invalid_Argument("OAEP: Input is too large");
      }

   secure_vector<uint8_t> out(key_length);

   rng.randomize(out.data(), m_Phash.size());

   buffer_insert(out, m_Phash.size(), m_Phash.data(), m_Phash.size());
   out[out.size() - in_length - 1] = 0x01;
   buffer_insert(out, out.size() - in_length, in, in_length);

   mgf1_mask(*m_mgf1_hash,
             out.data(), m_Phash.size(),
             &out[m_Phash.size()], out.size() - m_Phash.size());

   mgf1_mask(*m_mgf1_hash,
             &out[m_Phash.size()], out.size() - m_Phash.size(),
             out.data(), m_Phash.size());

   return out;
   }

/*
* OAEP Unpad Operation
*/
secure_vector<uint8_t> OAEP::unpad(uint8_t& valid_mask,
                                   const uint8_t in[], size_t in_length) const
   {
   /*
   Must be careful about error messages here; if an attacker can
   distinguish them, it is easy to use the differences as an oracle to
   find the secret key, as described in "A Chosen Ciphertext Attack on
   RSA Optimal Asymmetric Encryption Padding (OAEP) as Standardized in
   PKCS #1 v2.0", James Manger, Crypto 2001

   Also have to be careful about timing attacks! Pointed out by Falko
   Strenzke.

   According to the standard (Section 7.1.1), the encryptor always
   creates a message as follows:
      i. Concatenate a single octet with hexadecimal value 0x00,
         maskedSeed, and maskedDB to form an encoded message EM of
         length k octets as
            EM = 0x00 || maskedSeed || maskedDB.
   where k is the length of the modulus N.
   Therefore, the first byte can always be skipped safely.
   */

   const uint8_t skip_first = CT::Mask<uint8_t>::is_zero(in[0]).if_set_return(1);

   secure_vector<uint8_t> input(in + skip_first, in + in_length);

   const size_t hlen = m_Phash.size();

   mgf1_mask(*m_mgf1_hash,
             &input[hlen], input.size() - hlen,
             input.data(), hlen);

   mgf1_mask(*m_mgf1_hash,
             input.data(), hlen,
             &input[hlen], input.size() - hlen);

   return oaep_find_delim(valid_mask, input.data(), input.size(), m_Phash);
   }

secure_vector<uint8_t>
oaep_find_delim(uint8_t& valid_mask,
                const uint8_t input[], size_t input_len,
                const secure_vector<uint8_t>& Phash)
   {
   const size_t hlen = Phash.size();

   // Too short to be valid, reject immediately
   if(input_len < 1 + 2*hlen)
      {
      return secure_vector<uint8_t>();
      }

   CT::poison(input, input_len);

   size_t delim_idx = 2 * hlen;
   CT::Mask<uint8_t> waiting_for_delim = CT::Mask<uint8_t>::set();
   CT::Mask<uint8_t> bad_input_m = CT::Mask<uint8_t>::cleared();

   for(size_t i = delim_idx; i < input_len; ++i)
      {
      const auto zero_m = CT::Mask<uint8_t>::is_zero(input[i]);
      const auto one_m = CT::Mask<uint8_t>::is_equal(input[i], 1);

      const auto add_m = waiting_for_delim & zero_m;

      bad_input_m |= waiting_for_delim & ~(zero_m | one_m);

      delim_idx += add_m.if_set_return(1);

      waiting_for_delim &= zero_m;
      }

   // If we never saw any non-zero byte, then it's not valid input
   bad_input_m |= waiting_for_delim;
   bad_input_m |= CT::Mask<uint8_t>::is_zero(ct_compare_u8(&input[hlen], Phash.data(), hlen));

   delim_idx += 1;

   valid_mask = (~bad_input_m).unpoisoned_value();
   const secure_vector<uint8_t> output = CT::copy_output(bad_input_m, input, input_len, delim_idx);

   CT::unpoison(input, input_len);

   return output;
   }

/*
* Return the max input size for a given key size
*/
size_t OAEP::maximum_input_size(size_t keybits) const
   {
   if(keybits / 8 > 2*m_Phash.size() + 1)
      return ((keybits / 8) - 2*m_Phash.size() - 1);
   else
      return 0;
   }

/*
* OAEP Constructor
*/
OAEP::OAEP(HashFunction* hash, const std::string& P) : m_mgf1_hash(hash)
   {
   m_Phash = m_mgf1_hash->process(P);
   }

OAEP::OAEP(HashFunction* hash,
           HashFunction* mgf1_hash,
           const std::string& P) : m_mgf1_hash(mgf1_hash)
   {
   std::unique_ptr<HashFunction> phash(hash); // takes ownership
   m_Phash = phash->process(P);
   }

}

Line	Count	Source (jump to first uncovered line)
1		/*
2		* OAEP
3		* (C) 1999-2010,2015,2018 Jack Lloyd
4		*
5		* Botan is released under the Simplified BSD License (see license.txt)
6		*/
7
8		#include <botan/internal/oaep.h>
9		#include <botan/internal/mgf1.h>
10		#include <botan/exceptn.h>
11		#include <botan/rng.h>
12		#include <botan/internal/ct_utils.h>
13
14		namespace Botan {
15
16		/*
17		* OAEP Pad Operation
18		*/
19		secure_vector<uint8_t> OAEP::pad(const uint8_t in[], size_t in_length,
20		size_t key_length,
21		RandomNumberGenerator& rng) const
22	0	{
23	0	key_length /= 8;
24
25	0	if(in_length > maximum_input_size(key_length * 8))
26	0	{
27	0	throw Invalid_Argument("OAEP: Input is too large");
28	0	}
29
30	0	secure_vector<uint8_t> out(key_length);
31
32	0	rng.randomize(out.data(), m_Phash.size());
33
34	0	buffer_insert(out, m_Phash.size(), m_Phash.data(), m_Phash.size());
35	0	out[out.size() - in_length - 1] = 0x01;
36	0	buffer_insert(out, out.size() - in_length, in, in_length);
37
38	0	mgf1_mask(*m_mgf1_hash,
39	0	out.data(), m_Phash.size(),
40	0	&out[m_Phash.size()], out.size() - m_Phash.size());
41
42	0	mgf1_mask(*m_mgf1_hash,
43	0	&out[m_Phash.size()], out.size() - m_Phash.size(),
44	0	out.data(), m_Phash.size());
45
46	0	return out;
47	0	}
48
49		/*
50		* OAEP Unpad Operation
51		*/
52		secure_vector<uint8_t> OAEP::unpad(uint8_t& valid_mask,
53		const uint8_t in[], size_t in_length) const
54	0	{
55		/*
56		Must be careful about error messages here; if an attacker can
57		distinguish them, it is easy to use the differences as an oracle to
58		find the secret key, as described in "A Chosen Ciphertext Attack on
59		RSA Optimal Asymmetric Encryption Padding (OAEP) as Standardized in
60		PKCS #1 v2.0", James Manger, Crypto 2001
61
62		Also have to be careful about timing attacks! Pointed out by Falko
63		Strenzke.
64
65		According to the standard (Section 7.1.1), the encryptor always
66		creates a message as follows:
67		i. Concatenate a single octet with hexadecimal value 0x00,
68		maskedSeed, and maskedDB to form an encoded message EM of
69		length k octets as
70		EM = 0x00 \|\| maskedSeed \|\| maskedDB.
71		where k is the length of the modulus N.
72		Therefore, the first byte can always be skipped safely.
73		*/
74
75	0	const uint8_t skip_first = CT::Mask<uint8_t>::is_zero(in[0]).if_set_return(1);
76
77	0	secure_vector<uint8_t> input(in + skip_first, in + in_length);
78
79	0	const size_t hlen = m_Phash.size();
80
81	0	mgf1_mask(*m_mgf1_hash,
82	0	&input[hlen], input.size() - hlen,
83	0	input.data(), hlen);
84
85	0	mgf1_mask(*m_mgf1_hash,
86	0	input.data(), hlen,
87	0	&input[hlen], input.size() - hlen);
88
89	0	return oaep_find_delim(valid_mask, input.data(), input.size(), m_Phash);
90	0	}
91
92		secure_vector<uint8_t>
93		oaep_find_delim(uint8_t& valid_mask,
94		const uint8_t input[], size_t input_len,
95		const secure_vector<uint8_t>& Phash)
96	224	{
97	224	const size_t hlen = Phash.size();
98
99		// Too short to be valid, reject immediately
100	224	if(input_len < 1 + 2*hlen)
101	6	{
102	6	return secure_vector<uint8_t>();
103	6	}
104
105	218	CT::poison(input, input_len);
106
107	218	size_t delim_idx = 2 * hlen;
108	218	CT::Mask<uint8_t> waiting_for_delim = CT::Mask<uint8_t>::set();
109	218	CT::Mask<uint8_t> bad_input_m = CT::Mask<uint8_t>::cleared();
110
111	204k	for(size_t i = delim_idx; i < input_len; ++i)
112	204k	{
113	204k	const auto zero_m = CT::Mask<uint8_t>::is_zero(input[i]);
114	204k	const auto one_m = CT::Mask<uint8_t>::is_equal(input[i], 1);
115
116	204k	const auto add_m = waiting_for_delim & zero_m;
117
118	204k	bad_input_m \|= waiting_for_delim & ~(zero_m \| one_m);
119
120	204k	delim_idx += add_m.if_set_return(1);
121
122	204k	waiting_for_delim &= zero_m;
123	204k	}
124
125		// If we never saw any non-zero byte, then it's not valid input
126	218	bad_input_m \|= waiting_for_delim;
127	218	bad_input_m \|= CT::Mask<uint8_t>::is_zero(ct_compare_u8(&input[hlen], Phash.data(), hlen));
128
129	218	delim_idx += 1;
130
131	218	valid_mask = (~bad_input_m).unpoisoned_value();
132	218	const secure_vector<uint8_t> output = CT::copy_output(bad_input_m, input, input_len, delim_idx);
133
134	218	CT::unpoison(input, input_len);
135
136	218	return output;
137	218	}
138
139		/*
140		* Return the max input size for a given key size
141		*/
142		size_t OAEP::maximum_input_size(size_t keybits) const
143	0	{
144	0	if(keybits / 8 > 2*m_Phash.size() + 1)
145	0	return ((keybits / 8) - 2*m_Phash.size() - 1);
146	0	else
147	0	return 0;
148	0	}
149
150		/*
151		* OAEP Constructor
152		*/
153		OAEP::OAEP(HashFunction* hash, const std::string& P) : m_mgf1_hash(hash)
154	0	{
155	0	m_Phash = m_mgf1_hash->process(P);
156	0	}
157
158		OAEP::OAEP(HashFunction* hash,
159		HashFunction* mgf1_hash,
160		const std::string& P) : m_mgf1_hash(mgf1_hash)
161	0	{
162	0	std::unique_ptr<HashFunction> phash(hash); // takes ownership
163	0	m_Phash = phash->process(P);
164	0	}
165
166		}

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Created: 2021-02-21 07:20