/************************************************* * BigInt Base Source File * * (C) 1999-2008 Jack Lloyd * *************************************************/ #include #include #include #include #include namespace Botan { /************************************************* * Construct a BigInt from a regular number * *************************************************/ BigInt::BigInt(u64bit n) { set_sign(Positive); if(n == 0) return; const u32bit limbs_needed = sizeof(u64bit) / sizeof(word); reg.create(4*limbs_needed); for(u32bit j = 0; j != limbs_needed; ++j) reg[j] = ((n >> (j*MP_WORD_BITS)) & MP_WORD_MASK); } /************************************************* * Construct a BigInt of the specified size * *************************************************/ BigInt::BigInt(Sign s, u32bit size) { reg.create(round_up(size, 8)); signedness = s; } /************************************************* * Construct a BigInt from a "raw" BigInt * *************************************************/ BigInt::BigInt(const BigInt& b) { const u32bit b_words = b.sig_words(); if(b_words) { reg.create(round_up(b_words, 8)); reg.copy(b.data(), b_words); set_sign(b.sign()); } else { reg.create(2); set_sign(Positive); } } /************************************************* * Construct a BigInt from a string * *************************************************/ BigInt::BigInt(const std::string& str) { Base base = Decimal; u32bit markers = 0; bool negative = false; if(str.length() > 0 && str[0] == '-') { markers += 1; negative = true; } if(str.length() > markers + 2 && str[markers ] == '0' && str[markers + 1] == 'x') { markers += 2; base = Hexadecimal; } else if(str.length() > markers + 1 && str[markers] == '0') { markers += 1; base = Octal; } *this = decode(reinterpret_cast(str.data()) + markers, str.length() - markers, base); if(negative) set_sign(Negative); else set_sign(Positive); } /************************************************* * Construct a BigInt from an encoded BigInt * *************************************************/ BigInt::BigInt(const byte input[], u32bit length, Base base) { set_sign(Positive); *this = decode(input, length, base); } /************************************************* * Construct a BigInt from an encoded BigInt * *************************************************/ BigInt::BigInt(RandomNumberGenerator& rng, u32bit bits) { set_sign(Positive); randomize(rng, bits); } /************************************************* * Swap this BigInt with another * *************************************************/ void BigInt::swap(BigInt& other) { reg.swap(other.reg); std::swap(signedness, other.signedness); } /************************************************* * Grow the internal storage * *************************************************/ void BigInt::grow_reg(u32bit n) { reg.grow_to(round_up(size() + n, 8)); } /************************************************* * Grow the internal storage * *************************************************/ void BigInt::grow_to(u32bit n) { if(n > size()) reg.grow_to(round_up(n, 8)); } /************************************************* * Comparison Function * *************************************************/ s32bit BigInt::cmp(const BigInt& n, bool check_signs) const { if(check_signs) { if(n.is_positive() && this->is_negative()) return -1; if(n.is_negative() && this->is_positive()) return 1; if(n.is_negative() && this->is_negative()) return (-bigint_cmp(data(), sig_words(), n.data(), n.sig_words())); } return bigint_cmp(data(), sig_words(), n.data(), n.sig_words()); } /************************************************* * Convert this number to a u32bit, if possible * *************************************************/ u32bit BigInt::to_u32bit() const { if(is_negative()) throw Encoding_Error("BigInt::to_u32bit: Number is negative"); if(bits() >= 32) throw Encoding_Error("BigInt::to_u32bit: Number is too big to convert"); u32bit out = 0; for(u32bit j = 0; j != 4; ++j) out = (out << 8) | byte_at(3-j); return out; } /************************************************* * Return byte n of this number * *************************************************/ byte BigInt::byte_at(u32bit n) const { const u32bit WORD_BYTES = sizeof(word); u32bit word_num = n / WORD_BYTES, byte_num = n % WORD_BYTES; if(word_num >= size()) return 0; else return get_byte(WORD_BYTES - byte_num - 1, reg[word_num]); } /************************************************* * Return bit n of this number * *************************************************/ bool BigInt::get_bit(u32bit n) const { return ((word_at(n / MP_WORD_BITS) >> (n % MP_WORD_BITS)) & 1); } /************************************************* * Return bits {offset...offset+length} * *************************************************/ u32bit BigInt::get_substring(u32bit offset, u32bit length) const { if(length > 32) throw Invalid_Argument("BigInt::get_substring: Substring size too big"); u64bit piece = 0; for(u32bit j = 0; j != 8; ++j) piece = (piece << 8) | byte_at((offset / 8) + (7-j)); u64bit mask = (1 << length) - 1; u32bit shift = (offset % 8); return static_cast((piece >> shift) & mask); } /************************************************* * Set bit number n * *************************************************/ void BigInt::set_bit(u32bit n) { const u32bit which = n / MP_WORD_BITS; const word mask = static_cast(1) << (n % MP_WORD_BITS); if(which >= size()) grow_to(which + 1); reg[which] |= mask; } /************************************************* * Clear bit number n * *************************************************/ void BigInt::clear_bit(u32bit n) { const u32bit which = n / MP_WORD_BITS; const word mask = static_cast(1) << (n % MP_WORD_BITS); if(which < size()) reg[which] &= ~mask; } /************************************************* * Clear all but the lowest n bits * *************************************************/ void BigInt::mask_bits(u32bit n) { if(n == 0) { clear(); return; } if(n >= bits()) return; const u32bit top_word = n / MP_WORD_BITS; const word mask = (static_cast(1) << (n % MP_WORD_BITS)) - 1; if(top_word < size()) for(u32bit j = top_word + 1; j != size(); ++j) reg[j] = 0; reg[top_word] &= mask; } /************************************************* * Count how many bytes are being used * *************************************************/ u32bit BigInt::bytes() const { return (bits() + 7) / 8; } /************************************************* * Count how many bits are being used * *************************************************/ u32bit BigInt::bits() const { if(sig_words() == 0) return 0; u32bit full_words = sig_words() - 1, top_bits = MP_WORD_BITS; word top_word = word_at(full_words), mask = MP_WORD_TOP_BIT; while(top_bits && ((top_word & mask) == 0)) { mask >>= 1; top_bits--; } return (full_words * MP_WORD_BITS + top_bits); } /************************************************* * Calcluate the size in a certain base * *************************************************/ u32bit BigInt::encoded_size(Base base) const { static const double LOG_2_BASE_10 = 0.30102999566; if(base == Binary) return bytes(); else if(base == Hexadecimal) return 2*bytes(); else if(base == Octal) return ((bits() + 2) / 3); else if(base == Decimal) return static_cast((bits() * LOG_2_BASE_10) + 1); else throw Invalid_Argument("Unknown base for BigInt encoding"); } /************************************************* * Set the sign * *************************************************/ void BigInt::set_sign(Sign s) { if(is_zero()) signedness = Positive; else signedness = s; } /************************************************* * Reverse the value of the sign flag * *************************************************/ void BigInt::flip_sign() { set_sign(reverse_sign()); } /************************************************* * Return the opposite value of the current sign * *************************************************/ BigInt::Sign BigInt::reverse_sign() const { if(sign() == Positive) return Negative; return Positive; } /************************************************* * Return the negation of this number * *************************************************/ BigInt BigInt::operator-() const { BigInt x = (*this); x.flip_sign(); return x; } /************************************************* * Return the absolute value of this number * *************************************************/ BigInt BigInt::abs() const { BigInt x = (*this); x.set_sign(Positive); return x; } /************************************************* * Encode this number into bytes * *************************************************/ void BigInt::binary_encode(byte output[]) const { const u32bit sig_bytes = bytes(); for(u32bit j = 0; j != sig_bytes; ++j) output[sig_bytes-j-1] = byte_at(j); } /************************************************* * Set this number to the value in buf * *************************************************/ void BigInt::binary_decode(const byte buf[], u32bit length) { const u32bit WORD_BYTES = sizeof(word); reg.create(round_up((length / WORD_BYTES) + 1, 8)); for(u32bit j = 0; j != length / WORD_BYTES; ++j) { u32bit top = length - WORD_BYTES*j; for(u32bit k = WORD_BYTES; k > 0; --k) reg[j] = (reg[j] << 8) | buf[top - k]; } for(u32bit j = 0; j != length % WORD_BYTES; ++j) reg[length / WORD_BYTES] = (reg[length / WORD_BYTES] << 8) | buf[j]; } /************************************************* * Set this number to the value in buf * *************************************************/ void BigInt::binary_decode(const MemoryRegion& buf) { binary_decode(buf, buf.size()); } }