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Simplify integer checks
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@ -864,26 +864,27 @@ inline uint64_t umul128_upper64(uint64_t x, uint64_t y) FMT_NOEXCEPT {
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#endif
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}
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// Computes upper 64 bits of multiplication of a 64-bit unsigned integer and a
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// Computes upper 128 bits of multiplication of a 64-bit unsigned integer and a
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// 128-bit unsigned integer.
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inline uint64_t umul192_upper64(uint64_t x, uint128_wrapper y) FMT_NOEXCEPT {
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uint128_wrapper g0 = umul128(x, y.high());
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g0 += umul128_upper64(x, y.low());
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return g0.high();
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inline uint128_wrapper umul192_upper128(uint64_t x,
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uint128_wrapper y) FMT_NOEXCEPT {
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uint128_wrapper r = umul128(x, y.high());
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r += umul128_upper64(x, y.low());
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return r;
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}
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// Computes upper 32 bits of multiplication of a 32-bit unsigned integer and a
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// Computes upper 64 bits of multiplication of a 32-bit unsigned integer and a
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// 64-bit unsigned integer.
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inline uint32_t umul96_upper32(uint32_t x, uint64_t y) FMT_NOEXCEPT {
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return static_cast<uint32_t>(umul128_upper64(x, y));
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inline uint64_t umul96_upper64(uint32_t x, uint64_t y) FMT_NOEXCEPT {
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return umul128_upper64(uint64_t(x) << 32, y);
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}
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// Computes middle 64 bits of multiplication of a 64-bit unsigned integer and a
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// Computes lower 128 bits of multiplication of a 64-bit unsigned integer and a
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// 128-bit unsigned integer.
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inline uint64_t umul192_middle64(uint64_t x, uint128_wrapper y) FMT_NOEXCEPT {
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uint64_t g01 = x * y.high();
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uint64_t g10 = umul128_upper64(x, y.low());
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return g01 + g10;
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inline uint64_t umul192_lower128(uint64_t x, uint128_wrapper y) FMT_NOEXCEPT {
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uint64_t high = x * y.high();
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uint128_wrapper high_low = umul128(x, y.low());
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return {high + high_low.high(), high_low.low()};
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}
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// Computes lower 64 bits of multiplication of a 32-bit unsigned integer and a
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@ -1071,9 +1072,20 @@ template <> struct cache_accessor<float> {
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return pow10_significands[k - float_info<float>::min_k];
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}
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static carrier_uint compute_mul(carrier_uint u,
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const cache_entry_type& cache) FMT_NOEXCEPT {
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return umul96_upper32(u, cache);
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struct compute_mul_result {
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carrier_uint result;
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bool is_integer;
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};
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struct compute_mul_parity_result {
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bool parity;
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bool is_integer;
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};
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static compute_mul_result compute_mul(
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carrier_uint u, const cache_entry_type& cache) FMT_NOEXCEPT {
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auto r = umul96_upper64(u, cache);
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return {static_cast<carrier_uint>(r >> 32),
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static_cast<carrier_uint>(r) == 0};
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}
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static uint32_t compute_delta(const cache_entry_type& cache,
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@ -1081,13 +1093,15 @@ template <> struct cache_accessor<float> {
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return static_cast<uint32_t>(cache >> (64 - 1 - beta_minus_1));
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}
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static bool compute_mul_parity(carrier_uint two_f,
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const cache_entry_type& cache,
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static compute_mul_parity_result compute_mul_parity(
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carrier_uint two_f, const cache_entry_type& cache,
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int beta_minus_1) FMT_NOEXCEPT {
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FMT_ASSERT(beta_minus_1 >= 1, "");
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FMT_ASSERT(beta_minus_1 < 64, "");
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return ((umul96_lower64(two_f, cache) >> (64 - beta_minus_1)) & 1) != 0;
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auto r = umul96_lower64(two_f, cache);
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return {((r >> (64 - beta_minus_1)) & 1) != 0,
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static_cast<uint32_t>(r >> (32 - beta_minus_1)) == 0};
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}
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static carrier_uint compute_left_endpoint_for_shorter_interval_case(
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@ -1838,9 +1852,19 @@ template <> struct cache_accessor<double> {
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#endif
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}
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static carrier_uint compute_mul(carrier_uint u,
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const cache_entry_type& cache) FMT_NOEXCEPT {
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return umul192_upper64(u, cache);
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struct compute_mul_result {
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carrier_uint result;
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bool is_integer;
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};
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struct compute_mul_parity_result {
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bool parity;
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bool is_integer;
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};
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static compute_mul_result compute_mul(
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carrier_uint u, const cache_entry_type& cache) FMT_NOEXCEPT {
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auto r = umul192_upper128(u, cache);
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return {r.high(), r.low() == 0};
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}
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static uint32_t compute_delta(cache_entry_type const& cache,
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@ -1848,13 +1872,16 @@ template <> struct cache_accessor<double> {
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return static_cast<uint32_t>(cache.high() >> (64 - 1 - beta_minus_1));
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}
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static bool compute_mul_parity(carrier_uint two_f,
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const cache_entry_type& cache,
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static compute_mul_parity_result compute_mul_parity(
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carrier_uint two_f, const cache_entry_type& cache,
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int beta_minus_1) FMT_NOEXCEPT {
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FMT_ASSERT(beta_minus_1 >= 1, "");
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FMT_ASSERT(beta_minus_1 < 64, "");
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return ((umul192_middle64(two_f, cache) >> (64 - beta_minus_1)) & 1) != 0;
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auto r = umul192_lower128(two_f, cache);
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return {
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((r.high() >> (64 - beta_minus_1)) & 1) != 0,
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((r.high() << beta_minus_1) | (r.low() >> (64 - beta_minus_1))) == 0};
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}
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static carrier_uint compute_left_endpoint_for_shorter_interval_case(
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@ -2114,39 +2141,50 @@ template <typename T> decimal_fp<T> to_decimal(T x) FMT_NOEXCEPT {
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// 10^kappa <= deltai < 10^(kappa + 1)
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const uint32_t deltai = cache_accessor<T>::compute_delta(cache, beta_minus_1);
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const carrier_uint two_fc = significand << 1;
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const carrier_uint two_fr = two_fc | 1;
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const carrier_uint zi =
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cache_accessor<T>::compute_mul(two_fr << beta_minus_1, cache);
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const typename cache_accessor<T>::compute_mul_result z_mul =
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cache_accessor<T>::compute_mul((two_fc | 1) << beta_minus_1, cache);
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// Step 2: Try larger divisor; remove trailing zeros if necessary.
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// Using an upper bound on zi, we might be able to optimize the division
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// better than the compiler; we are computing zi / big_divisor here.
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decimal_fp<T> ret_value;
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ret_value.significand = divide_by_10_to_kappa_plus_1(zi);
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uint32_t r = static_cast<uint32_t>(zi - float_info<T>::big_divisor *
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ret_value.significand);
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ret_value.significand = divide_by_10_to_kappa_plus_1(z_mul.result);
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const uint32_t r = static_cast<uint32_t>(
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z_mul.result - float_info<T>::big_divisor * ret_value.significand);
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if (r > deltai) {
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goto small_divisor_case_label;
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} else if (r < deltai) {
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// Exclude the right endpoint if necessary.
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if (r == 0 && !include_right_endpoint &&
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is_endpoint_integer<T>(two_fr, exponent, minus_k)) {
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if (r == 0 && z_mul.is_integer && !include_right_endpoint) {
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--ret_value.significand;
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r = float_info<T>::big_divisor;
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goto small_divisor_case_label;
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}
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} else {
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// r == deltai; compare fractional parts
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// Check conditions in the order different from the paper
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// to take advantage of short-circuiting.
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// r == deltai; compare fractional parts.
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const carrier_uint two_fl = two_fc - 1;
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if ((!include_left_endpoint ||
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!is_endpoint_integer<T>(two_fl, exponent, minus_k)) &&
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!cache_accessor<T>::compute_mul_parity(two_fl, cache, beta_minus_1)) {
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if (!include_left_endpoint ||
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exponent < float_info<T>::case_fc_pm_half_lower_threshold ||
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exponent > float_info<T>::divisibility_check_by_5_threshold) {
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// If the left endpoint is not included, the condition for
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// success is z^(f) < delta^(f) (odd parity).
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// Otherwise, the inequalities on exponent ensure that
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// x is not an integer, so if z^(f) >= delta^(f) (even parity), we in fact
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// have strict inequality.
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if (!cache_accessor<T>::compute_mul_parity(two_fl, cache, beta_minus_1)
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.parity) {
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goto small_divisor_case_label;
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}
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} else {
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const typename cache_accessor<T>::compute_mul_parity_result x_mul = =
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compute_mul_parity(two_fl, cache, beta_minus_1);
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if (!x_mul.parity && !x_mul.is_integer) {
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goto small_divisor_case_label;
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}
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}
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}
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ret_value.exponent = minus_k + float_info<T>::kappa + 1;
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@ -2160,37 +2198,40 @@ small_divisor_case_label:
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ret_value.significand *= 10;
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ret_value.exponent = minus_k + float_info<T>::kappa;
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auto dist = r - (deltai / 2) + (float_info<T>::small_divisor / 2);
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bool const approx_y_parity = ((dist ^ (small_divisor / 2)) & 1) != 0;
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uint32_t dist = r - (deltai / 2) + (float_info<T>::small_divisor / 2);
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const bool approx_y_parity =
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((dist ^ (float_info<T>::small_divisor / 2)) & 1) != 0;
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// Is dist divisible by 10^kappa?
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bool divisible_by_10_to_the_kappa =
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const bool divisible_by_small_divisor =
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check_divisibility_and_divide_by_pow10<float_info<T>::kappa>(dist);
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// Add dist / 10^kappa to the significand.
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ret_value.significand += dist;
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if (divisible_by_10_to_the_kappa) {
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if (divisible_by_small_divisor) {
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// Check z^(f) >= epsilon^(f).
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// We have either yi == zi - epsiloni or yi == (zi - epsiloni) - 1,
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// where yi == zi - epsiloni if and only if z^(f) >= epsilon^(f)
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// Since there are only 2 possibilities, we only need to care about the
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// parity. Also, zi and r should have the same parity since the divisor
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// is an even number.
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if (cache_accessor<T>::compute_mul_parity(two_fc, cache, beta_minus_1) !=
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approx_y_parity) {
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const typename cache_accessor<T>::compute_mul_parity_result y_mul = =
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compute_mul_parity(two_fc, cache, beta_minus_1);
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if (y_mul.parity != approx_y_parity) {
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--ret_value.significand;
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} else {
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// If z^(f) >= epsilon^(f), we might have a tie
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// when z^(f) == epsilon^(f), or equivalently, when y is an integer
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if (is_center_integer<T>(two_fc, exponent, minus_k)) {
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if (y_mul.is_integer) {
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ret_value.significand = ret_value.significand % 2 == 0
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? ret_value.significand
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: ret_value.significand - 1;
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}
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}
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return ret_value;
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}
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}
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} // namespace dragonbox
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// Formats a floating-point number using a variation of the Fixed-Precision
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