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Simplify Grisu implementation
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8877a67724
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@ -340,6 +340,14 @@ template <typename T> struct bits {
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class fp;
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template <int SHIFT = 0> fp normalize(fp value);
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// Lower (upper) boundary is a value half way between a floating-point value
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// and its predecessor (successor). Boundaries have the same exponent as the
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// value so only significands are stored.
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struct boundaries {
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uint64_t lower;
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uint64_t upper;
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};
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// A handmade floating-point number f * pow(2, e).
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class fp {
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private:
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@ -417,29 +425,28 @@ class fp {
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// where a boundary is a value half way between the number and its predecessor
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// (lower) or successor (upper). The upper boundary is normalized and lower
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// has the same exponent but may be not normalized.
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template <typename Double>
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void assign_with_boundaries(Double d, fp& lower, fp& upper) {
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template <typename Double> boundaries assign_with_boundaries(Double d) {
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bool is_lower_closer = assign(d);
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lower = is_lower_closer ? fp((f << 2) - 1, e - 2) : fp((f << 1) - 1, e - 1);
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fp lower =
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is_lower_closer ? fp((f << 2) - 1, e - 2) : fp((f << 1) - 1, e - 1);
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// 1 in normalize accounts for the exponent shift above.
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upper = normalize<1>(fp((f << 1) + 1, e - 1));
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fp upper = normalize<1>(fp((f << 1) + 1, e - 1));
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lower.f <<= lower.e - upper.e;
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lower.e = upper.e;
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return boundaries{lower.f, upper.f};
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}
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template <typename Double>
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void assign_float_with_boundaries(Double d, fp& lower, fp& upper) {
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template <typename Double> boundaries assign_float_with_boundaries(Double d) {
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assign(d);
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constexpr int min_normal_e = std::numeric_limits<float>::min_exponent -
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std::numeric_limits<double>::digits;
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significand_type half_ulp = 1 << (std::numeric_limits<double>::digits -
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std::numeric_limits<float>::digits - 1);
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if (min_normal_e > e) half_ulp <<= min_normal_e - e;
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upper = normalize<0>(fp(f + half_ulp, e));
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lower = fp(
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fp upper = normalize<0>(fp(f + half_ulp, e));
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fp lower = fp(
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f - (half_ulp >> ((f == implicit_bit && e > min_normal_e) ? 1 : 0)), e);
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lower.f <<= lower.e - upper.e;
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lower.e = upper.e;
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return boundaries{lower.f, upper.f};
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}
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};
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@ -451,28 +458,28 @@ inline fp operator-(fp x, fp y) {
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return {x.f - y.f, x.e};
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}
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// Computes an fp number r with r.f = x.f * y.f / pow(2, 64) rounded to nearest
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// with half-up tie breaking, r.e = x.e + y.e + 64. Result may not be
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// normalized.
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FMT_FUNC fp operator*(fp x, fp y) {
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int exp = x.e + y.e + 64;
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inline uint64_t multiply(uint64_t lhs, uint64_t rhs) {
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#if FMT_USE_INT128
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auto product = static_cast<__uint128_t>(x.f) * y.f;
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auto product = static_cast<__uint128_t>(lhs) * rhs;
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auto f = static_cast<uint64_t>(product >> 64);
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if ((static_cast<uint64_t>(product) & (1ULL << 63)) != 0) ++f;
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return {f, exp};
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return (static_cast<uint64_t>(product) & (1ULL << 63)) != 0 ? f + 1 : f;
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#else
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// Multiply 32-bit parts of significands.
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uint64_t mask = (1ULL << 32) - 1;
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uint64_t a = x.f >> 32, b = x.f & mask;
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uint64_t c = y.f >> 32, d = y.f & mask;
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uint64_t a = lhs >> 32, b = lhs & mask;
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uint64_t c = rhs >> 32, d = rhs & mask;
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uint64_t ac = a * c, bc = b * c, ad = a * d, bd = b * d;
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// Compute mid 64-bit of result and round.
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uint64_t mid = (bd >> 32) + (ad & mask) + (bc & mask) + (1U << 31);
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return fp(ac + (ad >> 32) + (bc >> 32) + (mid >> 32), exp);
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return ac + (ad >> 32) + (bc >> 32) + (mid >> 32);
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#endif
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}
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// Computes an fp number r with r.f = x.f * y.f / pow(2, 64) rounded to nearest
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// with half-up tie breaking, r.e = x.e + y.e + 64. Result may not be
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// normalized.
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inline fp operator*(fp x, fp y) { return {multiply(x.f, y.f), x.e + y.e + 64}; }
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// Returns a cached power of 10 `c_k = c_k.f * pow(2, c_k.e)` such that its
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// (binary) exponent satisfies `min_exponent <= c_k.e <= min_exponent + 28`.
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FMT_FUNC fp get_cached_power(int min_exponent, int& pow10_exponent) {
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@ -1062,8 +1069,7 @@ int format_float(T value, int precision, float_spec spec, buffer<char>& buf) {
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int cached_exp10 = 0; // K in Grisu.
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if (precision != -1) {
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if (precision > 17) return snprintf_float(value, precision, spec, buf);
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fp fp_value(value);
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fp normalized = normalize(fp_value);
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fp normalized = normalize(fp(value));
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const auto cached_pow = get_cached_power(
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min_exp - (normalized.e + fp::significand_size), cached_exp10);
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normalized = normalized * cached_pow;
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@ -1081,33 +1087,33 @@ int format_float(T value, int precision, float_spec spec, buffer<char>& buf) {
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buf.resize(to_unsigned(num_digits));
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} else {
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fp fp_value;
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fp lower, upper; // w^- and w^+ in the Grisu paper.
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if (spec.binary32)
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fp_value.assign_float_with_boundaries(value, lower, upper);
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else
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fp_value.assign_with_boundaries(value, lower, upper);
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// Find a cached power of 10 such that multiplying upper by it will bring
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auto boundaries = spec.binary32
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? fp_value.assign_float_with_boundaries(value)
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: fp_value.assign_with_boundaries(value);
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fp_value = normalize(fp_value);
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// Find a cached power of 10 such that multiplying value by it will bring
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// the exponent in the range [min_exp, -32].
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const auto cached_pow = get_cached_power( // \tilde{c}_{-k} in Grisu.
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min_exp - (upper.e + fp::significand_size), cached_exp10);
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fp normalized = normalize(fp_value);
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normalized = normalized * cached_pow;
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lower = lower * cached_pow; // \tilde{M}^- in Grisu.
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upper = upper * cached_pow; // \tilde{M}^+ in Grisu.
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assert(min_exp <= upper.e && upper.e <= -32);
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auto result = digits::result();
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--lower.f; // \tilde{M}^- - 1 ulp -> M^-_{\downarrow}.
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++upper.f; // \tilde{M}^+ + 1 ulp -> M^+_{\uparrow}.
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const fp cached_pow = get_cached_power(
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min_exp - (fp_value.e + fp::significand_size), cached_exp10);
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// Multiply value and boundaries by the cached power of 10.
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fp_value = fp_value * cached_pow;
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boundaries.lower = multiply(boundaries.lower, cached_pow.f);
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boundaries.upper = multiply(boundaries.upper, cached_pow.f);
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assert(min_exp <= fp_value.e && fp_value.e <= -32);
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--boundaries.lower; // \tilde{M}^- - 1 ulp -> M^-_{\downarrow}.
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++boundaries.upper; // \tilde{M}^+ + 1 ulp -> M^+_{\uparrow}.
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// Numbers outside of (lower, upper) definitely do not round to value.
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grisu_shortest_handler handler{buf.data(), 0, (upper - normalized).f};
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result = grisu_gen_digits(upper, upper.f - lower.f, exp, handler);
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int size = handler.size;
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grisu_shortest_handler handler{buf.data(), 0,
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boundaries.upper - fp_value.f};
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auto result =
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grisu_gen_digits(fp(boundaries.upper, fp_value.e),
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boundaries.upper - boundaries.lower, exp, handler);
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if (result == digits::error) {
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exp = exp + size - cached_exp10 - 1;
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exp += handler.size - cached_exp10 - 1;
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fallback_format(value, buf, exp);
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return exp;
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}
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buf.resize(to_unsigned(size));
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buf.resize(to_unsigned(handler.size));
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}
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return exp - cached_exp10;
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}
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@ -189,27 +189,27 @@ template <> void run_double_tests<true>() {
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EXPECT_EQ(fp(1.23), fp(0x13ae147ae147aeu, -52));
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// Compute boundaries:
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fp value, lower, upper;
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fp value;
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// Normalized & not power of 2 - equidistant boundaries:
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value.assign_with_boundaries(1.23, lower, upper);
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auto b = value.assign_with_boundaries(1.23);
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EXPECT_EQ(value, fp(0x0013ae147ae147ae, -52));
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EXPECT_EQ(lower, fp(0x9d70a3d70a3d6c00, -63));
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EXPECT_EQ(upper, fp(0x9d70a3d70a3d7400, -63));
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EXPECT_EQ(b.lower, 0x9d70a3d70a3d6c00);
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EXPECT_EQ(b.upper, 0x9d70a3d70a3d7400);
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// Normalized power of 2 - lower boundary is closer:
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value.assign_with_boundaries(1.9807040628566084e+28, lower, upper); // 2**94
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b = value.assign_with_boundaries(1.9807040628566084e+28); // 2**94
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EXPECT_EQ(value, fp(0x0010000000000000, 42));
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EXPECT_EQ(lower, fp(0x7ffffffffffffe00, 31));
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EXPECT_EQ(upper, fp(0x8000000000000400, 31));
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EXPECT_EQ(b.lower, 0x7ffffffffffffe00);
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EXPECT_EQ(b.upper, 0x8000000000000400);
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// Smallest normalized double - equidistant boundaries:
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value.assign_with_boundaries(2.2250738585072014e-308, lower, upper);
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b = value.assign_with_boundaries(2.2250738585072014e-308);
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EXPECT_EQ(value, fp(0x0010000000000000, -1074));
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EXPECT_EQ(lower, fp(0x7ffffffffffffc00, -1085));
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EXPECT_EQ(upper, fp(0x8000000000000400, -1085));
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EXPECT_EQ(b.lower, 0x7ffffffffffffc00);
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EXPECT_EQ(b.upper, 0x8000000000000400);
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// Subnormal - equidistant boundaries:
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value.assign_with_boundaries(4.9406564584124654e-324, lower, upper);
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b = value.assign_with_boundaries(4.9406564584124654e-324);
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EXPECT_EQ(value, fp(0x0000000000000001, -1074));
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EXPECT_EQ(lower, fp(0x4000000000000000, -1137));
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EXPECT_EQ(upper, fp(0xc000000000000000, -1137));
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EXPECT_EQ(b.lower, 0x4000000000000000);
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EXPECT_EQ(b.upper, 0xc000000000000000);
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}
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TEST(FPTest, DoubleTests) {
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@ -243,12 +243,10 @@ TEST(FPTest, ComputeFloatBoundaries) {
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fp vupper = normalize(fp(test.upper));
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vlower.f >>= vupper.e - vlower.e;
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vlower.e = vupper.e;
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fp value, lower, upper;
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value.assign_float_with_boundaries(test.x, lower, upper);
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EXPECT_EQ(vlower.f, lower.f);
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EXPECT_EQ(vlower.e, lower.e);
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EXPECT_EQ(vupper.f, upper.f);
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EXPECT_EQ(vupper.e, upper.e);
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fp value;
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auto b = value.assign_float_with_boundaries(test.x);
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EXPECT_EQ(vlower.f, b.lower);
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EXPECT_EQ(vupper.f, b.upper);
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}
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}
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