/* * CBC Padding Methods * (C) 1999-2007,2013 Jack Lloyd * (C) 2016 René Korthaus, Rohde & Schwarz Cybersecurity * * Botan is released under the Simplified BSD License (see license.txt) */ #include #include #include namespace Botan { /** * Get a block cipher padding method by name */ BlockCipherModePaddingMethod* get_bc_pad(const std::string& algo_spec) { if(algo_spec == "NoPadding") return new Null_Padding; if(algo_spec == "PKCS7") return new PKCS7_Padding; if(algo_spec == "OneAndZeros") return new OneAndZeros_Padding; if(algo_spec == "X9.23") return new ANSI_X923_Padding; if(algo_spec == "ESP") return new ESP_Padding; return nullptr; } /* * Pad with PKCS #7 Method */ void PKCS7_Padding::add_padding(secure_vector& buffer, size_t last_byte_pos, size_t block_size) const { const uint8_t pad_value = static_cast(block_size - last_byte_pos); for(size_t i = 0; i != pad_value; ++i) buffer.push_back(pad_value); } /* * Unpad with PKCS #7 Method */ size_t PKCS7_Padding::unpad(const uint8_t block[], size_t size) const { CT::poison(block,size); size_t bad_input = 0; const uint8_t last_byte = block[size-1]; bad_input |= CT::expand_mask(last_byte > size); size_t pad_pos = size - last_byte; size_t i = size - 2; while(i) { bad_input |= ~CT::is_equal(block[i],last_byte) & CT::expand_mask(i >= pad_pos); --i; } CT::conditional_copy_mem(bad_input,&pad_pos,&size,&pad_pos,1); CT::unpoison(block,size); CT::unpoison(pad_pos); return pad_pos; } /* * Pad with ANSI X9.23 Method */ void ANSI_X923_Padding::add_padding(secure_vector& buffer, size_t last_byte_pos, size_t block_size) const { const uint8_t pad_value = static_cast(block_size - last_byte_pos); for(size_t i = last_byte_pos; i < block_size-1; ++i) { buffer.push_back(0); } buffer.push_back(pad_value); } /* * Unpad with ANSI X9.23 Method */ size_t ANSI_X923_Padding::unpad(const uint8_t block[], size_t size) const { CT::poison(block,size); size_t bad_input = 0; const size_t last_byte = block[size-1]; bad_input |= CT::expand_mask(last_byte > size); size_t pad_pos = size - last_byte; size_t i = size - 2; while(i) { bad_input |= ~CT::is_zero(block[i]) & CT::expand_mask(i >= pad_pos); --i; } CT::conditional_copy_mem(bad_input,&pad_pos,&size,&pad_pos,1); CT::unpoison(block,size); CT::unpoison(pad_pos); return pad_pos; } /* * Pad with One and Zeros Method */ void OneAndZeros_Padding::add_padding(secure_vector& buffer, size_t last_byte_pos, size_t block_size) const { buffer.push_back(0x80); for(size_t i = last_byte_pos + 1; i % block_size; ++i) buffer.push_back(0x00); } /* * Unpad with One and Zeros Method */ size_t OneAndZeros_Padding::unpad(const uint8_t block[], size_t size) const { CT::poison(block, size); uint8_t bad_input = 0; uint8_t seen_one = 0; size_t pad_pos = size - 1; size_t i = size; while(i) { seen_one |= CT::is_equal(block[i-1],0x80); pad_pos -= CT::select(~seen_one, 1, 0); bad_input |= ~CT::is_zero(block[i-1]) & ~seen_one; i--; } bad_input |= ~seen_one; CT::conditional_copy_mem(size_t(bad_input),&pad_pos,&size,&pad_pos,1); CT::unpoison(block, size); CT::unpoison(pad_pos); return pad_pos; } /* * Pad with ESP Padding Method */ void ESP_Padding::add_padding(secure_vector& buffer, size_t last_byte_pos, size_t block_size) const { uint8_t pad_value = 0x01; for(size_t i = last_byte_pos; i < block_size; ++i) { buffer.push_back(pad_value++); } } /* * Unpad with ESP Padding Method */ size_t ESP_Padding::unpad(const uint8_t block[], size_t size) const { CT::poison(block,size); const size_t last_byte = block[size-1]; size_t bad_input = 0; bad_input |= CT::expand_mask(last_byte > size); size_t pad_pos = size - last_byte; size_t i = size - 1; while(i) { bad_input |= ~CT::is_equal(size_t(block[i-1]),size_t(block[i])-1) & CT::expand_mask(i > pad_pos); --i; } CT::conditional_copy_mem(bad_input,&pad_pos,&size,&pad_pos,1); CT::unpoison(block, size); CT::unpoison(pad_pos); return pad_pos; } }