/************************************************* * BigInt Encoding/Decoding Source File * * (C) 1999-2006 The Botan Project * *************************************************/ #include #include #include #include namespace Botan { /************************************************* * Encode a BigInt * *************************************************/ void BigInt::encode(byte output[], const BigInt& n, Base base) { if(base == Binary) n.binary_encode(output); else if(base == Hexadecimal) { SecureVector binary(n.encoded_size(Binary)); n.binary_encode(binary); for(u32bit j = 0; j != binary.size(); ++j) Hex_Encoder::encode(binary[j], output + 2*j); } else if(base == Octal) { BigInt copy = n; const u32bit output_size = n.encoded_size(Octal); for(u32bit j = 0; j != output_size; ++j) { output[output_size - 1 - j] = Charset::digit2char(copy % 8); copy /= 8; } } else if(base == Decimal) { BigInt copy = n; BigInt remainder; copy.set_sign(Positive); const u32bit output_size = n.encoded_size(Decimal); for(u32bit j = 0; j != output_size; ++j) { divide(copy, 10, copy, remainder); output[output_size - 1 - j] = Charset::digit2char(remainder.word_at(0)); if(copy.is_zero()) break; } } else throw Invalid_Argument("Unknown BigInt encoding method"); } /************************************************* * Encode a BigInt * *************************************************/ SecureVector BigInt::encode(const BigInt& n, Base base) { SecureVector output(n.encoded_size(base)); encode(output, n, base); if(base != Binary) for(u32bit j = 0; j != output.size(); ++j) if(output[j] == 0) output[j] = '0'; return output; } /************************************************* * Encode a BigInt, with leading 0s if needed * *************************************************/ SecureVector BigInt::encode_1363(const BigInt& n, u32bit bytes) { const u32bit n_bytes = n.bytes(); if(n_bytes > bytes) throw Encoding_Error("encode_1363: n is too large to encode properly"); const u32bit leading_0s = bytes - n_bytes; SecureVector output(bytes); encode(output + leading_0s, n, Binary); return output; } /************************************************* * Decode a BigInt * *************************************************/ BigInt BigInt::decode(const MemoryRegion& buf, Base base) { return BigInt::decode(buf, buf.size(), base); } /************************************************* * Decode a BigInt * *************************************************/ BigInt BigInt::decode(const byte buf[], u32bit length, Base base) { BigInt r; if(base == Binary) r.binary_decode(buf, length); else if(base == Hexadecimal) { SecureVector hex; for(u32bit j = 0; j != length; ++j) if(Hex_Decoder::is_valid(buf[j])) hex.append(buf[j]); u32bit offset = (hex.size() % 2); SecureVector binary(hex.size() / 2 + offset); if(offset) { byte temp[2] = { '0', hex[0] }; binary[0] = Hex_Decoder::decode(temp); } for(u32bit j = offset; j != binary.size(); ++j) binary[j] = Hex_Decoder::decode(hex+2*j-offset); r.binary_decode(binary, binary.size()); } else if(base == Decimal || base == Octal) { const u32bit RADIX = ((base == Decimal) ? 10 : 8); for(u32bit j = 0; j != length; ++j) { byte x = Charset::char2digit(buf[j]); if(x >= RADIX) { if(RADIX == 10) throw Invalid_Argument("BigInt: Invalid decimal string"); else throw Invalid_Argument("BigInt: Invalid octal string"); } r *= RADIX; r += x; } } else throw Invalid_Argument("Unknown BigInt decoding method"); return r; } }