2023-05-02 20:38:16 +00:00
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/*-*- mode:c;indent-tabs-mode:nil;c-basic-offset:2;tab-width:8;coding:utf-8 -*-│
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2023-12-17 04:59:11 +00:00
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│ vi: set et ft=c ts=8 sts=2 sw=2 fenc=utf-8 :vi │
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2023-05-02 20:38:16 +00:00
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╚──────────────────────────────────────────────────────────────────────────────╝
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│ │
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│ Optimized Routines │
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│ Copyright (c) 1999-2022, Arm Limited. │
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│ │
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│ Permission is hereby granted, free of charge, to any person obtaining │
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│ a copy of this software and associated documentation files (the │
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│ "Software"), to deal in the Software without restriction, including │
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│ without limitation the rights to use, copy, modify, merge, publish, │
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│ distribute, sublicense, and/or sell copies of the Software, and to │
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│ permit persons to whom the Software is furnished to do so, subject to │
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│ the following conditions: │
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│ │
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│ The above copyright notice and this permission notice shall be │
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│ included in all copies or substantial portions of the Software. │
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│ │
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│ THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, │
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│ EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF │
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│ MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. │
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│ IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY │
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│ CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, │
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│ TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE │
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│ SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. │
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│ │
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╚─────────────────────────────────────────────────────────────────────────────*/
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#include "libc/intrin/likely.h"
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#include "libc/math.h"
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#include "libc/tinymath/internal.h"
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#include "libc/tinymath/log1pf_data.internal.h"
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Release Cosmopolitan v3.3
This change upgrades to GCC 12.3 and GNU binutils 2.42. The GNU linker
appears to have changed things so that only a single de-duplicated str
table is present in the binary, and it gets placed wherever the linker
wants, regardless of what the linker script says. To cope with that we
need to stop using .ident to embed licenses. As such, this change does
significant work to revamp how third party licenses are defined in the
codebase, using `.section .notice,"aR",@progbits`.
This new GCC 12.3 toolchain has support for GNU indirect functions. It
lets us support __target_clones__ for the first time. This is used for
optimizing the performance of libc string functions such as strlen and
friends so far on x86, by ensuring AVX systems favor a second codepath
that uses VEX encoding. It shaves some latency off certain operations.
It's a useful feature to have for scientific computing for the reasons
explained by the test/libcxx/openmp_test.cc example which compiles for
fifteen different microarchitectures. Thanks to the upgrades, it's now
also possible to use newer instruction sets, such as AVX512FP16, VNNI.
Cosmo now uses the %gs register on x86 by default for TLS. Doing it is
helpful for any program that links `cosmo_dlopen()`. Such programs had
to recompile their binaries at startup to change the TLS instructions.
That's not great, since it means every page in the executable needs to
be faulted. The work of rewriting TLS-related x86 opcodes, is moved to
fixupobj.com instead. This is great news for MacOS x86 users, since we
previously needed to morph the binary every time for that platform but
now that's no longer necessary. The only platforms where we need fixup
of TLS x86 opcodes at runtime are now Windows, OpenBSD, and NetBSD. On
Windows we morph TLS to point deeper into the TIB, based on a TlsAlloc
assignment, and on OpenBSD/NetBSD we morph %gs back into %fs since the
kernels do not allow us to specify a value for the %gs register.
OpenBSD users are now required to use APE Loader to run Cosmo binaries
and assimilation is no longer possible. OpenBSD kernel needs to change
to allow programs to specify a value for the %gs register, or it needs
to stop marking executable pages loaded by the kernel as mimmutable().
This release fixes __constructor__, .ctor, .init_array, and lastly the
.preinit_array so they behave the exact same way as glibc.
We no longer use hex constants to define math.h symbols like M_PI.
2024-02-20 19:12:09 +00:00
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__static_yoink("arm_optimized_routines_notice");
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2023-05-02 20:38:16 +00:00
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#define Ln2 (0x1.62e43p-1f)
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#define SignMask (0x80000000)
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/* Biased exponent of the largest float m for which m^8 underflows. */
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#define M8UFLOW_BOUND_BEXP 112
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/* Biased exponent of the largest float for which we just return x. */
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#define TINY_BOUND_BEXP 103
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#define C(i) __log1pf_data.coeffs[i]
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static inline float
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eval_poly (float m, uint32_t e)
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{
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#ifdef LOG1PF_2U5
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/* 2.5 ulp variant. Approximate log(1+m) on [-0.25, 0.5] using
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slightly modified Estrin scheme (no x^0 term, and x term is just x). */
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float p_12 = fmaf (m, C (1), C (0));
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float p_34 = fmaf (m, C (3), C (2));
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float p_56 = fmaf (m, C (5), C (4));
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float p_78 = fmaf (m, C (7), C (6));
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float m2 = m * m;
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float p_02 = fmaf (m2, p_12, m);
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float p_36 = fmaf (m2, p_56, p_34);
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float p_79 = fmaf (m2, C (8), p_78);
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float m4 = m2 * m2;
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float p_06 = fmaf (m4, p_36, p_02);
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if (UNLIKELY (e < M8UFLOW_BOUND_BEXP))
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return p_06;
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float m8 = m4 * m4;
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return fmaf (m8, p_79, p_06);
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#elif defined(LOG1PF_1U3)
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/* 1.3 ulp variant. Approximate log(1+m) on [-0.25, 0.5] using Horner
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scheme. Our polynomial approximation for log1p has the form
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x + C1 * x^2 + C2 * x^3 + C3 * x^4 + ...
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Hence approximation has the form m + m^2 * P(m)
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where P(x) = C1 + C2 * x + C3 * x^2 + ... . */
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return fmaf (m, m * HORNER_8 (m, C), m);
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#else
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#error No log1pf approximation exists with the requested precision. Options are 13 or 25.
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#endif
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}
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static inline uint32_t
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biased_exponent (uint32_t ix)
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{
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return (ix & 0x7f800000) >> 23;
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}
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/* log1pf approximation using polynomial on reduced interval. Worst-case error
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when using Estrin is roughly 2.02 ULP:
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log1pf(0x1.21e13ap-2) got 0x1.fe8028p-3 want 0x1.fe802cp-3. */
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float
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log1pf (float x)
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{
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uint32_t ix = asuint (x);
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uint32_t ia = ix & ~SignMask;
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uint32_t ia12 = ia >> 20;
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uint32_t e = biased_exponent (ix);
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/* Handle special cases first. */
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if (UNLIKELY (ia12 >= 0x7f8 || ix >= 0xbf800000 || ix == 0x80000000
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|| e <= TINY_BOUND_BEXP))
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{
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if (ix == 0xff800000)
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{
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/* x == -Inf => log1pf(x) = NaN. */
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return NAN;
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}
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if ((ix == 0x7f800000 || e <= TINY_BOUND_BEXP) && ia12 <= 0x7f8)
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{
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/* |x| < TinyBound => log1p(x) = x.
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x == Inf => log1pf(x) = Inf. */
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return x;
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}
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if (ix == 0xbf800000)
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{
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/* x == -1.0 => log1pf(x) = -Inf. */
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return __math_divzerof (-1);
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}
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if (ia12 >= 0x7f8)
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{
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/* x == +/-NaN => log1pf(x) = NaN. */
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return __math_invalidf (asfloat (ia));
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}
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/* x < -1.0 => log1pf(x) = NaN. */
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return __math_invalidf (x);
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}
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/* With x + 1 = t * 2^k (where t = m + 1 and k is chosen such that m
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is in [-0.25, 0.5]):
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log1p(x) = log(t) + log(2^k) = log1p(m) + k*log(2).
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We approximate log1p(m) with a polynomial, then scale by
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k*log(2). Instead of doing this directly, we use an intermediate
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scale factor s = 4*k*log(2) to ensure the scale is representable
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as a normalised fp32 number. */
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if (ix <= 0x3f000000 || ia <= 0x3e800000)
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{
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/* If x is in [-0.25, 0.5] then we can shortcut all the logic
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below, as k = 0 and m = x. All we need is to return the
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polynomial. */
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return eval_poly (x, e);
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}
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float m = x + 1.0f;
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/* k is used scale the input. 0x3f400000 is chosen as we are trying to
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reduce x to the range [-0.25, 0.5]. Inside this range, k is 0.
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Outside this range, if k is reinterpreted as (NOT CONVERTED TO) float:
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let k = sign * 2^p where sign = -1 if x < 0
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1 otherwise
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and p is a negative integer whose magnitude increases with the
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magnitude of x. */
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int k = (asuint (m) - 0x3f400000) & 0xff800000;
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/* By using integer arithmetic, we obtain the necessary scaling by
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subtracting the unbiased exponent of k from the exponent of x. */
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float m_scale = asfloat (asuint (x) - k);
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/* Scale up to ensure that the scale factor is representable as normalised
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fp32 number (s in [2**-126,2**26]), and scale m down accordingly. */
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float s = asfloat (asuint (4.0f) - k);
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m_scale = m_scale + fmaf (0.25f, s, -1.0f);
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float p = eval_poly (m_scale, biased_exponent (asuint (m_scale)));
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/* The scale factor to be applied back at the end - by multiplying float(k)
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by 2^-23 we get the unbiased exponent of k. */
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float scale_back = (float) k * 0x1.0p-23f;
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/* Apply the scaling back. */
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return fmaf (scale_back, Ln2, p);
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}
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