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authorErik Kundt <bitshift@posteo.org>2018-03-27 01:48:20 +0800
committerDaniel Kirchner <daniel@ekpyron.org>2018-04-16 17:45:55 +0800
commit33fbf88707e69362bd5b6336860827a7b4d74440 (patch)
treeebf17d15faaa23225ba3b4d6dd101be10ec0a25b /libsolidity/ast
parent2001cc6bdca87d715380b15f11c797666528e040 (diff)
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Limits rational numbers to 4096 bits.
Diffstat (limited to 'libsolidity/ast')
-rw-r--r--libsolidity/ast/Types.cpp180
1 files changed, 160 insertions, 20 deletions
diff --git a/libsolidity/ast/Types.cpp b/libsolidity/ast/Types.cpp
index 68b12777..51739cb0 100644
--- a/libsolidity/ast/Types.cpp
+++ b/libsolidity/ast/Types.cpp
@@ -44,6 +44,85 @@ using namespace std;
using namespace dev;
using namespace dev::solidity;
+namespace
+{
+
+unsigned int mostSignificantBit(bigint const& _number)
+{
+#if BOOST_VERSION < 105500
+ solAssert(_number > 0, "");
+ bigint number = _number;
+ unsigned int result = 0;
+ while (number != 0)
+ {
+ number >>= 1;
+ ++result;
+ }
+ return --result;
+#else
+ return boost::multiprecision::msb(_number);
+#endif
+}
+
+/// Check whether (_base ** _exp) fits into 4096 bits.
+bool fitsPrecisionExp(bigint const& _base, bigint const& _exp)
+{
+ if (_base == 0)
+ return true;
+
+ solAssert(_base > 0, "");
+
+ size_t const bitsMax = 4096;
+
+ unsigned mostSignificantBaseBit = mostSignificantBit(_base);
+ if (mostSignificantBaseBit == 0) // _base == 1
+ return true;
+ if (mostSignificantBaseBit > bitsMax) // _base >= 2 ^ 4096
+ return false;
+
+ bigint bitsNeeded = _exp * (mostSignificantBaseBit + 1);
+
+ return bitsNeeded <= bitsMax;
+}
+
+/// Checks whether _mantissa * (X ** _exp) fits into 4096 bits,
+/// where X is given indirectly via _log2OfBase = log2(X).
+bool fitsPrecisionBaseX(
+ bigint const& _mantissa,
+ double _log2OfBase,
+ uint32_t _exp
+)
+{
+ if (_mantissa == 0)
+ return true;
+
+ solAssert(_mantissa > 0, "");
+
+ size_t const bitsMax = 4096;
+
+ unsigned mostSignificantMantissaBit = mostSignificantBit(_mantissa);
+ if (mostSignificantMantissaBit > bitsMax) // _mantissa >= 2 ^ 4096
+ return false;
+
+ bigint bitsNeeded = mostSignificantMantissaBit + bigint(floor(double(_exp) * _log2OfBase)) + 1;
+ return bitsNeeded <= bitsMax;
+}
+
+/// Checks whether _mantissa * (10 ** _expBase10) fits into 4096 bits.
+bool fitsPrecisionBase10(bigint const& _mantissa, uint32_t _expBase10)
+{
+ double const log2Of10AwayFromZero = 3.3219280948873624;
+ return fitsPrecisionBaseX(_mantissa, log2Of10AwayFromZero, _expBase10);
+}
+
+/// Checks whether _mantissa * (2 ** _expBase10) fits into 4096 bits.
+bool fitsPrecisionBase2(bigint const& _mantissa, uint32_t _expBase2)
+{
+ return fitsPrecisionBaseX(_mantissa, 1.0, _expBase2);
+}
+
+}
+
void StorageOffsets::computeOffsets(TypePointers const& _types)
{
bigint slotOffset = 0;
@@ -689,31 +768,39 @@ tuple<bool, rational> RationalNumberType::isValidLiteral(Literal const& _literal
}
else if (expPoint != _literal.value().end())
{
- // parse the exponent
+ // Parse base and exponent. Checks numeric limit.
bigint exp = bigint(string(expPoint + 1, _literal.value().end()));
if (exp > numeric_limits<int32_t>::max() || exp < numeric_limits<int32_t>::min())
return make_tuple(false, rational(0));
- // parse the base
+ uint32_t expAbs = bigint(abs(exp)).convert_to<uint32_t>();
+
+
tuple<bool, rational> base = parseRational(string(_literal.value().begin(), expPoint));
+
if (!get<0>(base))
return make_tuple(false, rational(0));
value = get<1>(base);
if (exp < 0)
{
- exp *= -1;
+ if (!fitsPrecisionBase10(abs(value.denominator()), expAbs))
+ return make_tuple(false, rational(0));
value /= boost::multiprecision::pow(
bigint(10),
- exp.convert_to<int32_t>()
+ expAbs
);
}
- else
+ else if (exp > 0)
+ {
+ if (!fitsPrecisionBase10(abs(value.numerator()), expAbs))
+ return make_tuple(false, rational(0));
value *= boost::multiprecision::pow(
bigint(10),
- exp.convert_to<int32_t>()
+ expAbs
);
+ }
}
else
{
@@ -912,16 +999,49 @@ TypePointer RationalNumberType::binaryOperatorResult(Token::Value _operator, Typ
using boost::multiprecision::pow;
if (other.isFractional())
return TypePointer();
- else if (abs(other.m_value) > numeric_limits<uint32_t>::max())
- return TypePointer(); // This will need too much memory to represent.
- uint32_t exponent = abs(other.m_value).numerator().convert_to<uint32_t>();
- bigint numerator = pow(m_value.numerator(), exponent);
- bigint denominator = pow(m_value.denominator(), exponent);
- if (other.m_value >= 0)
- value = rational(numerator, denominator);
+ solAssert(other.m_value.denominator() == 1, "");
+ bigint const& exp = other.m_value.numerator();
+
+ // x ** 0 = 1
+ // for 0, 1 and -1 the size of the exponent doesn't have to be restricted
+ if (exp == 0)
+ value = 1;
+ else if (m_value.numerator() == 0 || m_value == 1)
+ value = m_value;
+ else if (m_value == -1)
+ {
+ bigint isOdd = abs(exp) & bigint(1);
+ value = 1 - 2 * isOdd.convert_to<int>();
+ }
else
- // invert
- value = rational(denominator, numerator);
+ {
+ if (abs(exp) > numeric_limits<uint32_t>::max())
+ return TypePointer(); // This will need too much memory to represent.
+
+ uint32_t absExp = bigint(abs(exp)).convert_to<uint32_t>();
+
+ // Limit size to 4096 bits
+ if (!fitsPrecisionExp(abs(m_value.numerator()), absExp) || !fitsPrecisionExp(abs(m_value.denominator()), absExp))
+ return TypePointer();
+
+ static auto const optimizedPow = [](bigint const& _base, uint32_t _exponent) -> bigint {
+ if (_base == 1)
+ return 1;
+ else if (_base == -1)
+ return 1 - 2 * int(_exponent & 1);
+ else
+ return pow(_base, _exponent);
+ };
+
+ bigint numerator = optimizedPow(m_value.numerator(), absExp);
+ bigint denominator = optimizedPow(m_value.denominator(), absExp);
+
+ if (exp >= 0)
+ value = rational(numerator, denominator);
+ else
+ // invert
+ value = rational(denominator, numerator);
+ }
break;
}
case Token::SHL:
@@ -933,28 +1053,48 @@ TypePointer RationalNumberType::binaryOperatorResult(Token::Value _operator, Typ
return TypePointer();
else if (other.m_value > numeric_limits<uint32_t>::max())
return TypePointer();
- uint32_t exponent = other.m_value.numerator().convert_to<uint32_t>();
- value = m_value.numerator() * pow(bigint(2), exponent);
+ if (m_value.numerator() == 0)
+ value = 0;
+ else
+ {
+ uint32_t exponent = other.m_value.numerator().convert_to<uint32_t>();
+ if (!fitsPrecisionBase2(abs(m_value.numerator()), exponent))
+ return TypePointer();
+ value = m_value.numerator() * pow(bigint(2), exponent);
+ }
break;
}
// NOTE: we're using >> (SAR) to denote right shifting. The type of the LValue
// determines the resulting type and the type of shift (SAR or SHR).
case Token::SAR:
{
- using boost::multiprecision::pow;
+ namespace mp = boost::multiprecision;
if (fractional)
return TypePointer();
else if (other.m_value < 0)
return TypePointer();
else if (other.m_value > numeric_limits<uint32_t>::max())
return TypePointer();
- uint32_t exponent = other.m_value.numerator().convert_to<uint32_t>();
- value = rational(m_value.numerator() / pow(bigint(2), exponent), 1);
+ if (m_value.numerator() == 0)
+ value = 0;
+ else
+ {
+ uint32_t exponent = other.m_value.numerator().convert_to<uint32_t>();
+ if (exponent > mostSignificantBit(mp::abs(m_value.numerator())))
+ value = 0;
+ else
+ value = rational(m_value.numerator() / mp::pow(bigint(2), exponent), 1);
+ }
break;
}
default:
return TypePointer();
}
+
+ // verify that numerator and denominator fit into 4096 bit after every operation
+ if (value.numerator() != 0 && max(mostSignificantBit(abs(value.numerator())), mostSignificantBit(abs(value.denominator()))) > 4096)
+ return TypePointer();
+
return make_shared<RationalNumberType>(value);
}
}