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// Copyright 2014 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#ifndef PDFIUM_THIRD_PARTY_BASE_SAFE_CONVERSIONS_IMPL_H_
#define PDFIUM_THIRD_PARTY_BASE_SAFE_CONVERSIONS_IMPL_H_
#include <assert.h>
#include <limits>
#include "../macros.h"
#include "../template_util.h"
namespace pdfium {
namespace base {
namespace internal {
// The std library doesn't provide a binary max_exponent for integers, however
// we can compute one by adding one to the number of non-sign bits. This allows
// for accurate range comparisons between floating point and integer types.
template <typename NumericType>
struct MaxExponent {
static const int value = std::numeric_limits<NumericType>::is_iec559
? std::numeric_limits<NumericType>::max_exponent
: (sizeof(NumericType) * 8 + 1 -
std::numeric_limits<NumericType>::is_signed);
};
enum IntegerRepresentation {
INTEGER_REPRESENTATION_UNSIGNED,
INTEGER_REPRESENTATION_SIGNED
};
// A range for a given nunmeric Src type is contained for a given numeric Dst
// type if both numeric_limits<Src>::max() <= numeric_limits<Dst>::max() and
// numeric_limits<Src>::min() >= numeric_limits<Dst>::min() are true.
// We implement this as template specializations rather than simple static
// comparisons to ensure type correctness in our comparisons.
enum NumericRangeRepresentation {
NUMERIC_RANGE_NOT_CONTAINED,
NUMERIC_RANGE_CONTAINED
};
// Helper templates to statically determine if our destination type can contain
// maximum and minimum values represented by the source type.
template <
typename Dst,
typename Src,
IntegerRepresentation DstSign = std::numeric_limits<Dst>::is_signed
? INTEGER_REPRESENTATION_SIGNED
: INTEGER_REPRESENTATION_UNSIGNED,
IntegerRepresentation SrcSign =
std::numeric_limits<Src>::is_signed
? INTEGER_REPRESENTATION_SIGNED
: INTEGER_REPRESENTATION_UNSIGNED >
struct StaticDstRangeRelationToSrcRange;
// Same sign: Dst is guaranteed to contain Src only if its range is equal or
// larger.
template <typename Dst, typename Src, IntegerRepresentation Sign>
struct StaticDstRangeRelationToSrcRange<Dst, Src, Sign, Sign> {
static const NumericRangeRepresentation value =
MaxExponent<Dst>::value >= MaxExponent<Src>::value
? NUMERIC_RANGE_CONTAINED
: NUMERIC_RANGE_NOT_CONTAINED;
};
// Unsigned to signed: Dst is guaranteed to contain source only if its range is
// larger.
template <typename Dst, typename Src>
struct StaticDstRangeRelationToSrcRange<Dst,
Src,
INTEGER_REPRESENTATION_SIGNED,
INTEGER_REPRESENTATION_UNSIGNED> {
static const NumericRangeRepresentation value =
MaxExponent<Dst>::value > MaxExponent<Src>::value
? NUMERIC_RANGE_CONTAINED
: NUMERIC_RANGE_NOT_CONTAINED;
};
// Signed to unsigned: Dst cannot be statically determined to contain Src.
template <typename Dst, typename Src>
struct StaticDstRangeRelationToSrcRange<Dst,
Src,
INTEGER_REPRESENTATION_UNSIGNED,
INTEGER_REPRESENTATION_SIGNED> {
static const NumericRangeRepresentation value = NUMERIC_RANGE_NOT_CONTAINED;
};
enum RangeConstraint {
RANGE_VALID = 0x0, // Value can be represented by the destination type.
RANGE_UNDERFLOW = 0x1, // Value would overflow.
RANGE_OVERFLOW = 0x2, // Value would underflow.
RANGE_INVALID = RANGE_UNDERFLOW | RANGE_OVERFLOW // Invalid (i.e. NaN).
};
// Helper function for coercing an int back to a RangeContraint.
inline RangeConstraint GetRangeConstraint(int integer_range_constraint) {
assert(integer_range_constraint >= RANGE_VALID &&
integer_range_constraint <= RANGE_INVALID);
return static_cast<RangeConstraint>(integer_range_constraint);
}
// This function creates a RangeConstraint from an upper and lower bound
// check by taking advantage of the fact that only NaN can be out of range in
// both directions at once.
inline RangeConstraint GetRangeConstraint(bool is_in_upper_bound,
bool is_in_lower_bound) {
return GetRangeConstraint((is_in_upper_bound ? 0 : RANGE_OVERFLOW) |
(is_in_lower_bound ? 0 : RANGE_UNDERFLOW));
}
template <
typename Dst,
typename Src,
IntegerRepresentation DstSign = std::numeric_limits<Dst>::is_signed
? INTEGER_REPRESENTATION_SIGNED
: INTEGER_REPRESENTATION_UNSIGNED,
IntegerRepresentation SrcSign = std::numeric_limits<Src>::is_signed
? INTEGER_REPRESENTATION_SIGNED
: INTEGER_REPRESENTATION_UNSIGNED,
NumericRangeRepresentation DstRange =
StaticDstRangeRelationToSrcRange<Dst, Src>::value >
struct DstRangeRelationToSrcRangeImpl;
// The following templates are for ranges that must be verified at runtime. We
// split it into checks based on signedness to avoid confusing casts and
// compiler warnings on signed an unsigned comparisons.
// Dst range is statically determined to contain Src: Nothing to check.
template <typename Dst,
typename Src,
IntegerRepresentation DstSign,
IntegerRepresentation SrcSign>
struct DstRangeRelationToSrcRangeImpl<Dst,
Src,
DstSign,
SrcSign,
NUMERIC_RANGE_CONTAINED> {
static RangeConstraint Check(Src value) { return RANGE_VALID; }
};
// Signed to signed narrowing: Both the upper and lower boundaries may be
// exceeded.
template <typename Dst, typename Src>
struct DstRangeRelationToSrcRangeImpl<Dst,
Src,
INTEGER_REPRESENTATION_SIGNED,
INTEGER_REPRESENTATION_SIGNED,
NUMERIC_RANGE_NOT_CONTAINED> {
static RangeConstraint Check(Src value) {
return std::numeric_limits<Dst>::is_iec559
? GetRangeConstraint(value <= std::numeric_limits<Dst>::max(),
value >= -std::numeric_limits<Dst>::max())
: GetRangeConstraint(value <= std::numeric_limits<Dst>::max(),
value >= std::numeric_limits<Dst>::min());
}
};
// Unsigned to unsigned narrowing: Only the upper boundary can be exceeded.
template <typename Dst, typename Src>
struct DstRangeRelationToSrcRangeImpl<Dst,
Src,
INTEGER_REPRESENTATION_UNSIGNED,
INTEGER_REPRESENTATION_UNSIGNED,
NUMERIC_RANGE_NOT_CONTAINED> {
static RangeConstraint Check(Src value) {
return GetRangeConstraint(value <= std::numeric_limits<Dst>::max(), true);
}
};
// Unsigned to signed: The upper boundary may be exceeded.
template <typename Dst, typename Src>
struct DstRangeRelationToSrcRangeImpl<Dst,
Src,
INTEGER_REPRESENTATION_SIGNED,
INTEGER_REPRESENTATION_UNSIGNED,
NUMERIC_RANGE_NOT_CONTAINED> {
static RangeConstraint Check(Src value) {
return sizeof(Dst) > sizeof(Src)
? RANGE_VALID
: GetRangeConstraint(
value <= static_cast<Src>(std::numeric_limits<Dst>::max()),
true);
}
};
// Signed to unsigned: The upper boundary may be exceeded for a narrower Dst,
// and any negative value exceeds the lower boundary.
template <typename Dst, typename Src>
struct DstRangeRelationToSrcRangeImpl<Dst,
Src,
INTEGER_REPRESENTATION_UNSIGNED,
INTEGER_REPRESENTATION_SIGNED,
NUMERIC_RANGE_NOT_CONTAINED> {
static RangeConstraint Check(Src value) {
return (MaxExponent<Dst>::value >= MaxExponent<Src>::value)
? GetRangeConstraint(true, value >= static_cast<Src>(0))
: GetRangeConstraint(
value <= static_cast<Src>(std::numeric_limits<Dst>::max()),
value >= static_cast<Src>(0));
}
};
template <typename Dst, typename Src>
inline RangeConstraint DstRangeRelationToSrcRange(Src value) {
COMPILE_ASSERT(std::numeric_limits<Src>::is_specialized,
argument_must_be_numeric);
COMPILE_ASSERT(std::numeric_limits<Dst>::is_specialized,
result_must_be_numeric);
return DstRangeRelationToSrcRangeImpl<Dst, Src>::Check(value);
}
} // namespace internal
} // namespace base
} // namespace pdfium
#endif // PDFIUM_THIRD_PARTY_BASE_SAFE_CONVERSIONS_IMPL_H_
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