// Copyright 2017 The Chromium Authors
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#ifndef BASE_NUMERICS_SAFE_MATH_ARM_IMPL_H_
#define BASE_NUMERICS_SAFE_MATH_ARM_IMPL_H_
// IWYU pragma: private
#include <stdint.h>
#include <cassert>
#include "base/numerics/safe_conversions.h"
namespace base {
namespace internal {
template <typename T, typename U>
struct CheckedMulFastAsmOp {
static const bool is_supported =
kEnableAsmCode && FastIntegerArithmeticPromotion<T, U>::is_contained;
// The following is not an assembler routine and is thus constexpr safe, it
// just emits much more efficient code than the Clang and GCC builtins for
// performing overflow-checked multiplication when a twice wider type is
// available. The below compiles down to 2-3 instructions, depending on the
// width of the types in use.
// As an example, an int32_t multiply compiles to:
// smull r0, r1, r0, r1
// cmp r1, r1, asr #31
// And an int16_t multiply compiles to:
// smulbb r1, r1, r0
// asr r2, r1, #16
// cmp r2, r1, asr #15
template <typename V>
static constexpr bool Do(T x, U y, V* result) {
using Promotion = typename FastIntegerArithmeticPromotion<T, U>::type;
Promotion presult;
presult = static_cast<Promotion>(x) * static_cast<Promotion>(y);
if (!IsValueInRangeForNumericType<V>(presult))
return false;
*result = static_cast<V>(presult);
return true;
}
};
template <typename T, typename U>
struct ClampedAddFastAsmOp {
static const bool is_supported =
kEnableAsmCode && BigEnoughPromotion<T, U>::is_contained &&
IsTypeInRangeForNumericType<
int32_t,
typename BigEnoughPromotion<T, U>::type>::value;
template <typename V>
__attribute__((always_inline)) static V Do(T x, U y) {
// This will get promoted to an int, so let the compiler do whatever is
// clever and rely on the saturated cast to bounds check.
if (IsIntegerArithmeticSafe<int, T, U>::value)
return saturated_cast<V>(static_cast<int>(x) + static_cast<int>(y));
int32_t result;
int32_t x_i32 = checked_cast<int32_t>(x);
int32_t y_i32 = checked_cast<int32_t>(y);
asm("qadd %[result], %[first], %[second]"
: [result] "=r"(result)
: [first] "r"(x_i32), [second] "r"(y_i32));
return saturated_cast<V>(result);
}
};
template <typename T, typename U>
struct ClampedSubFastAsmOp {
static const bool is_supported =
kEnableAsmCode && BigEnoughPromotion<T, U>::is_contained &&
IsTypeInRangeForNumericType<
int32_t,
typename BigEnoughPromotion<T, U>::type>::value;
template <typename V>
__attribute__((always_inline)) static V Do(T x, U y) {
// This will get promoted to an int, so let the compiler do whatever is
// clever and rely on the saturated cast to bounds check.
if (IsIntegerArithmeticSafe<int, T, U>::value)
return saturated_cast<V>(static_cast<int>(x) - static_cast<int>(y));
int32_t result;
int32_t x_i32 = checked_cast<int32_t>(x);
int32_t y_i32 = checked_cast<int32_t>(y);
asm("qsub %[result], %[first], %[second]"
: [result] "=r"(result)
: [first] "r"(x_i32), [second] "r"(y_i32));
return saturated_cast<V>(result);
}
};
template <typename T, typename U>
struct ClampedMulFastAsmOp {
static const bool is_supported =
kEnableAsmCode && CheckedMulFastAsmOp<T, U>::is_supported;
template <typename V>
__attribute__((always_inline)) static V Do(T x, U y) {
// Use the CheckedMulFastAsmOp for full-width 32-bit values, because
// it's fewer instructions than promoting and then saturating.
if (!IsIntegerArithmeticSafe<int32_t, T, U>::value &&
!IsIntegerArithmeticSafe<uint32_t, T, U>::value) {
V result;
return CheckedMulFastAsmOp<T, U>::Do(x, y, &result)
? result
: CommonMaxOrMin<V>(IsValueNegative(x) ^ IsValueNegative(y));
}
assert((FastIntegerArithmeticPromotion<T, U>::is_contained));
using Promotion = typename FastIntegerArithmeticPromotion<T, U>::type;
return saturated_cast<V>(static_cast<Promotion>(x) *
static_cast<Promotion>(y));
}
};
} // namespace internal
} // namespace base
#endif // BASE_NUMERICS_SAFE_MATH_ARM_IMPL_H_
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