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cc166d71f4
This is a follow-up to c8a016b99d97, following the post-landing discussion at https://chromium-review.googlesource.com/c/crashpad/crashpad/+/1393921/5#message-2058541d8c4505d20a990ab7734cd758e437a5f7 base::size, and std::size that will eventually replace it when C++17 is assured, does not allow the size of non-static data members to be taken in constant expression context. The remaining uses of ArraySize are in: minidump/minidump_exception_writer.cc (×1) minidump/minidump_system_info_writer.cc (×2, also uses base::size) snapshot/cpu_context.cc (×4, also uses base::size) util/misc/arraysize_test.cc (×10, of course) The first of these occurs when initializing a constexpr variable. All others are in expressions used with static_assert. Includes: Update mini_chromium to 737433ebade4d446643c6c07daae02a67e8deccao f701716d9546 Add Windows ARM64 build target to mini_chromium 87a95a3d6ac2 Remove the arraysize macro 1f7255ead1f7 Placate MSVC in areas of base::size usage 737433ebade4 Add cast Bug: chromium:837308 Change-Id: I6a5162654461b1bdd9b7b6864d0d71a734bcde19 Reviewed-on: https://chromium-review.googlesource.com/c/1396108 Commit-Queue: Mark Mentovai <mark@chromium.org> Reviewed-by: Mark Mentovai <mark@chromium.org>
348 lines
14 KiB
C++
348 lines
14 KiB
C++
// Copyright 2014 The Crashpad Authors. All rights reserved.
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//
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// Licensed under the Apache License, Version 2.0 (the "License");
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// you may not use this file except in compliance with the License.
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// You may obtain a copy of the License at
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//
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// http://www.apache.org/licenses/LICENSE-2.0
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//
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// Unless required by applicable law or agreed to in writing, software
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// distributed under the License is distributed on an "AS IS" BASIS,
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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// See the License for the specific language governing permissions and
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// limitations under the License.
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#include "snapshot/cpu_context.h"
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#include <stddef.h>
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#include <string.h>
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#include <sys/types.h>
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#include "base/stl_util.h"
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#include "gtest/gtest.h"
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#include "test/hex_string.h"
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namespace crashpad {
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namespace test {
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namespace {
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enum ExponentValue {
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kExponentAllZero = 0,
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kExponentAllOne,
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kExponentNormal,
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};
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enum FractionValue {
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kFractionAllZero = 0,
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kFractionNormal,
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};
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//! \brief Initializes an x87 register to a known bit pattern.
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//!
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//! \param[out] st_mm The x87 register to initialize. The reserved portion of
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//! the register is always zeroed out.
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//! \param[in] exponent_value The bit pattern to use for the exponent. If this
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//! is kExponentAllZero, the sign bit will be set to `1`, and if this is
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//! kExponentAllOne, the sign bit will be set to `0`. This tests that the
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//! implementation doesn’t erroneously consider the sign bit to be part of
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//! the exponent. This may also be kExponentNormal, indicating that the
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//! exponent shall neither be all zeroes nor all ones.
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//! \param[in] j_bit The value to use for the “J bit” (“integer bit”).
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//! \param[in] fraction_value If kFractionAllZero, the fraction will be zeroed
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//! out. If kFractionNormal, the fraction will not be all zeroes.
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void SetX87Register(CPUContextX86::X87Register* st,
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ExponentValue exponent_value,
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bool j_bit,
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FractionValue fraction_value) {
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switch (exponent_value) {
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case kExponentAllZero:
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(*st)[9] = 0x80;
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(*st)[8] = 0;
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break;
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case kExponentAllOne:
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(*st)[9] = 0x7f;
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(*st)[8] = 0xff;
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break;
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case kExponentNormal:
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(*st)[9] = 0x55;
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(*st)[8] = 0x55;
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break;
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}
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uint8_t fraction_pattern = fraction_value == kFractionAllZero ? 0 : 0x55;
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memset(st, fraction_pattern, 8);
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if (j_bit) {
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(*st)[7] |= 0x80;
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} else {
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(*st)[7] &= ~0x80;
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}
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}
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//! \brief Initializes an x87 register to a known bit pattern.
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//!
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//! This behaves as SetX87Register() but also clears the reserved portion of the
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//! field as used in the `fxsave` format.
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void SetX87OrMMXRegister(CPUContextX86::X87OrMMXRegister* st_mm,
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ExponentValue exponent_value,
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bool j_bit,
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FractionValue fraction_value) {
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SetX87Register(&st_mm->st, exponent_value, j_bit, fraction_value);
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memset(st_mm->st_reserved, 0, sizeof(st_mm->st_reserved));
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}
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TEST(CPUContextX86, FxsaveToFsave) {
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// Establish a somewhat plausible fxsave state. Use nonzero values for
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// reserved fields and things that aren’t present in fsave.
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CPUContextX86::Fxsave fxsave;
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fxsave.fcw = 0x027f; // mask exceptions, 53-bit precision, round to nearest
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fxsave.fsw = 1 << 11; // top = 1: logical 0-7 maps to physical 1-7, 0
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fxsave.ftw = 0x1f; // physical 5-7 (logical 4-6) empty
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fxsave.reserved_1 = 0x5a;
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fxsave.fop = 0x1fe; // fsin
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fxsave.fpu_ip = 0x76543210;
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fxsave.fpu_cs = 0x0007;
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fxsave.reserved_2 = 0x5a5a;
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fxsave.fpu_dp = 0xfedcba98;
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fxsave.fpu_ds = 0x000f;
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fxsave.reserved_3 = 0x5a5a;
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fxsave.mxcsr = 0x1f80;
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fxsave.mxcsr_mask = 0xffff;
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SetX87Register(
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&fxsave.st_mm[0].st, kExponentNormal, true, kFractionAllZero); // valid
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SetX87Register(
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&fxsave.st_mm[1].st, kExponentAllZero, false, kFractionAllZero); // zero
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SetX87Register(
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&fxsave.st_mm[2].st, kExponentAllOne, true, kFractionAllZero); // spec.
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SetX87Register(
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&fxsave.st_mm[3].st, kExponentAllOne, true, kFractionNormal); // spec.
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SetX87Register(
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&fxsave.st_mm[4].st, kExponentAllZero, false, kFractionAllZero);
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SetX87Register(
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&fxsave.st_mm[5].st, kExponentAllZero, false, kFractionAllZero);
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SetX87Register(
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&fxsave.st_mm[6].st, kExponentAllZero, false, kFractionAllZero);
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SetX87Register(
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&fxsave.st_mm[7].st, kExponentNormal, true, kFractionNormal); // valid
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for (size_t index = 0; index < base::size(fxsave.st_mm); ++index) {
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memset(&fxsave.st_mm[index].st_reserved,
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0x5a,
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sizeof(fxsave.st_mm[index].st_reserved));
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}
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memset(&fxsave.xmm, 0x5a, sizeof(fxsave) - offsetof(decltype(fxsave), xmm));
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CPUContextX86::Fsave fsave;
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CPUContextX86::FxsaveToFsave(fxsave, &fsave);
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// Everything should have come over from fxsave. Reserved fields should be
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// zero.
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EXPECT_EQ(fsave.fcw, fxsave.fcw);
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EXPECT_EQ(fsave.reserved_1, 0);
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EXPECT_EQ(fsave.fsw, fxsave.fsw);
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EXPECT_EQ(fsave.reserved_2, 0);
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EXPECT_EQ(fsave.ftw, 0xfe90); // FxsaveToFsaveTagWord
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EXPECT_EQ(fsave.reserved_3, 0);
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EXPECT_EQ(fsave.fpu_ip, fxsave.fpu_ip);
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EXPECT_EQ(fsave.fpu_cs, fxsave.fpu_cs);
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EXPECT_EQ(fsave.fop, fxsave.fop);
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EXPECT_EQ(fsave.fpu_dp, fxsave.fpu_dp);
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EXPECT_EQ(fsave.fpu_ds, fxsave.fpu_ds);
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EXPECT_EQ(fsave.reserved_4, 0);
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for (size_t index = 0; index < base::size(fsave.st); ++index) {
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EXPECT_EQ(BytesToHexString(fsave.st[index], base::size(fsave.st[index])),
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BytesToHexString(fxsave.st_mm[index].st,
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base::size(fxsave.st_mm[index].st)))
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<< "index " << index;
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}
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}
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TEST(CPUContextX86, FsaveToFxsave) {
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// Establish a somewhat plausible fsave state. Use nonzero values for
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// reserved fields.
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CPUContextX86::Fsave fsave;
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fsave.fcw = 0x0300; // unmask exceptions, 64-bit precision, round to nearest
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fsave.reserved_1 = 0xa5a5;
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fsave.fsw = 2 << 11; // top = 2: logical 0-7 maps to physical 2-7, 0-1
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fsave.reserved_2 = 0xa5a5;
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fsave.ftw = 0xa9ff; // physical 0-3 (logical 6-7, 0-1) empty; physical 4
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// (logical 2) zero; physical 5-7 (logical 3-5) special
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fsave.reserved_3 = 0xa5a5;
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fsave.fpu_ip = 0x456789ab;
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fsave.fpu_cs = 0x1013;
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fsave.fop = 0x01ee; // fldz
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fsave.fpu_dp = 0x0123cdef;
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fsave.fpu_ds = 0x2017;
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fsave.reserved_4 = 0xa5a5;
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SetX87Register(&fsave.st[0], kExponentAllZero, false, kFractionNormal);
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SetX87Register(&fsave.st[1], kExponentAllZero, true, kFractionNormal);
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SetX87Register(
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&fsave.st[2], kExponentAllZero, false, kFractionAllZero); // zero
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SetX87Register(
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&fsave.st[3], kExponentAllZero, true, kFractionAllZero); // spec.
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SetX87Register(
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&fsave.st[4], kExponentAllZero, false, kFractionNormal); // spec.
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SetX87Register(
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&fsave.st[5], kExponentAllZero, true, kFractionNormal); // spec.
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SetX87Register(&fsave.st[6], kExponentAllZero, false, kFractionAllZero);
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SetX87Register(&fsave.st[7], kExponentAllZero, true, kFractionAllZero);
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CPUContextX86::Fxsave fxsave;
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CPUContextX86::FsaveToFxsave(fsave, &fxsave);
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// Everything in fsave should have come over from there. Fields not present in
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// fsave and reserved fields should be zero.
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EXPECT_EQ(fxsave.fcw, fsave.fcw);
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EXPECT_EQ(fxsave.fsw, fsave.fsw);
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EXPECT_EQ(fxsave.ftw, 0xf0); // FsaveToFxsaveTagWord
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EXPECT_EQ(fxsave.reserved_1, 0);
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EXPECT_EQ(fxsave.fop, fsave.fop);
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EXPECT_EQ(fxsave.fpu_ip, fsave.fpu_ip);
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EXPECT_EQ(fxsave.fpu_cs, fsave.fpu_cs);
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EXPECT_EQ(fxsave.reserved_2, 0);
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EXPECT_EQ(fxsave.fpu_dp, fsave.fpu_dp);
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EXPECT_EQ(fxsave.fpu_ds, fsave.fpu_ds);
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EXPECT_EQ(fxsave.reserved_3, 0);
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EXPECT_EQ(fxsave.mxcsr, 0u);
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EXPECT_EQ(fxsave.mxcsr_mask, 0u);
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for (size_t index = 0; index < base::size(fxsave.st_mm); ++index) {
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EXPECT_EQ(BytesToHexString(fxsave.st_mm[index].st,
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base::size(fxsave.st_mm[index].st)),
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BytesToHexString(fsave.st[index], base::size(fsave.st[index])))
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<< "index " << index;
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EXPECT_EQ(BytesToHexString(fxsave.st_mm[index].st_reserved,
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base::size(fxsave.st_mm[index].st_reserved)),
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std::string(base::size(fxsave.st_mm[index].st_reserved) * 2, '0'))
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<< "index " << index;
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}
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size_t unused_len = sizeof(fxsave) - offsetof(decltype(fxsave), xmm);
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EXPECT_EQ(BytesToHexString(fxsave.xmm, unused_len),
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std::string(unused_len * 2, '0'));
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// Since the fsave format is a subset of the fxsave format, fsave-fxsave-fsave
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// should round-trip cleanly.
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CPUContextX86::Fsave fsave_2;
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CPUContextX86::FxsaveToFsave(fxsave, &fsave_2);
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// Clear the reserved fields in the original fsave structure, since they’re
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// expected to be clear in the copy.
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fsave.reserved_1 = 0;
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fsave.reserved_2 = 0;
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fsave.reserved_3 = 0;
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fsave.reserved_4 = 0;
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EXPECT_EQ(memcmp(&fsave, &fsave_2, sizeof(fsave)), 0);
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}
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TEST(CPUContextX86, FxsaveToFsaveTagWord) {
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// The fsave tag word uses bit pattern 00 for valid, 01 for zero, 10 for
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// “special”, and 11 for empty. Like the fxsave tag word, it is arranged by
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// physical register. The fxsave tag word determines whether a register is
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// empty, and analysis of the x87 register content distinguishes between
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// valid, zero, and special. In the initializations below, comments show
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// whether a register is expected to be considered valid, zero, or special,
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// except where the tag word is expected to indicate that it is empty. Each
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// combination appears twice: once where the fxsave tag word indicates a
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// nonempty register, and once again where it indicates an empty register.
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uint16_t fsw = 0 << 11; // top = 0: logical 0-7 maps to physical 0-7
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uint8_t fxsave_tag = 0x0f; // physical 4-7 (logical 4-7) empty
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CPUContextX86::X87OrMMXRegister st_mm[8];
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SetX87OrMMXRegister(
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&st_mm[0], kExponentNormal, false, kFractionNormal); // spec.
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SetX87OrMMXRegister(
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&st_mm[1], kExponentNormal, true, kFractionNormal); // valid
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SetX87OrMMXRegister(
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&st_mm[2], kExponentNormal, false, kFractionAllZero); // spec.
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SetX87OrMMXRegister(
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&st_mm[3], kExponentNormal, true, kFractionAllZero); // valid
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SetX87OrMMXRegister(&st_mm[4], kExponentNormal, false, kFractionNormal);
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SetX87OrMMXRegister(&st_mm[5], kExponentNormal, true, kFractionNormal);
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SetX87OrMMXRegister(&st_mm[6], kExponentNormal, false, kFractionAllZero);
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SetX87OrMMXRegister(&st_mm[7], kExponentNormal, true, kFractionAllZero);
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EXPECT_EQ(CPUContextX86::FxsaveToFsaveTagWord(fsw, fxsave_tag, st_mm),
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0xff22);
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fsw = 2 << 11; // top = 2: logical 0-7 maps to physical 2-7, 0-1
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fxsave_tag = 0xf0; // physical 0-3 (logical 6-7, 0-1) empty
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SetX87OrMMXRegister(&st_mm[0], kExponentAllZero, false, kFractionNormal);
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SetX87OrMMXRegister(&st_mm[1], kExponentAllZero, true, kFractionNormal);
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SetX87OrMMXRegister(
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&st_mm[2], kExponentAllZero, false, kFractionAllZero); // zero
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SetX87OrMMXRegister(
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&st_mm[3], kExponentAllZero, true, kFractionAllZero); // spec.
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SetX87OrMMXRegister(
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&st_mm[4], kExponentAllZero, false, kFractionNormal); // spec.
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SetX87OrMMXRegister(
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&st_mm[5], kExponentAllZero, true, kFractionNormal); // spec.
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SetX87OrMMXRegister(&st_mm[6], kExponentAllZero, false, kFractionAllZero);
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SetX87OrMMXRegister(&st_mm[7], kExponentAllZero, true, kFractionAllZero);
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EXPECT_EQ(CPUContextX86::FxsaveToFsaveTagWord(fsw, fxsave_tag, st_mm),
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0xa9ff);
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fsw = 5 << 11; // top = 5: logical 0-7 maps to physical 5-7, 0-4
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fxsave_tag = 0x5a; // physical 0, 2, 5, and 7 (logical 5, 0, 2, and 3) empty
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SetX87OrMMXRegister(&st_mm[0], kExponentAllOne, false, kFractionNormal);
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SetX87OrMMXRegister(
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&st_mm[1], kExponentAllOne, true, kFractionNormal); // spec.
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SetX87OrMMXRegister(&st_mm[2], kExponentAllOne, false, kFractionAllZero);
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SetX87OrMMXRegister(&st_mm[3], kExponentAllOne, true, kFractionAllZero);
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SetX87OrMMXRegister(
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&st_mm[4], kExponentAllOne, false, kFractionNormal); // spec.
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SetX87OrMMXRegister(&st_mm[5], kExponentAllOne, true, kFractionNormal);
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SetX87OrMMXRegister(
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&st_mm[6], kExponentAllOne, false, kFractionAllZero); // spec.
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SetX87OrMMXRegister(
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&st_mm[7], kExponentAllOne, true, kFractionAllZero); // spec.
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EXPECT_EQ(CPUContextX86::FxsaveToFsaveTagWord(fsw, fxsave_tag, st_mm),
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0xeebb);
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// This set set is just a mix of all of the possible tag types in a single
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// register file.
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fsw = 1 << 11; // top = 1: logical 0-7 maps to physical 1-7, 0
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fxsave_tag = 0x1f; // physical 5-7 (logical 4-6) empty
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SetX87OrMMXRegister(
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&st_mm[0], kExponentNormal, true, kFractionAllZero); // valid
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SetX87OrMMXRegister(
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&st_mm[1], kExponentAllZero, false, kFractionAllZero); // zero
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SetX87OrMMXRegister(
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&st_mm[2], kExponentAllOne, true, kFractionAllZero); // spec.
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SetX87OrMMXRegister(
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&st_mm[3], kExponentAllOne, true, kFractionNormal); // spec.
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SetX87OrMMXRegister(&st_mm[4], kExponentAllZero, false, kFractionAllZero);
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SetX87OrMMXRegister(&st_mm[5], kExponentAllZero, false, kFractionAllZero);
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SetX87OrMMXRegister(&st_mm[6], kExponentAllZero, false, kFractionAllZero);
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SetX87OrMMXRegister(
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&st_mm[7], kExponentNormal, true, kFractionNormal); // valid
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EXPECT_EQ(CPUContextX86::FxsaveToFsaveTagWord(fsw, fxsave_tag, st_mm),
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0xfe90);
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// In this set, everything is valid.
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fsw = 0 << 11; // top = 0: logical 0-7 maps to physical 0-7
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fxsave_tag = 0xff; // nothing empty
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for (size_t index = 0; index < base::size(st_mm); ++index) {
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SetX87OrMMXRegister(&st_mm[index], kExponentNormal, true, kFractionAllZero);
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}
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EXPECT_EQ(CPUContextX86::FxsaveToFsaveTagWord(fsw, fxsave_tag, st_mm), 0);
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// In this set, everything is empty. The registers shouldn’t be consulted at
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// all, so they’re left alone from the previous set.
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fsw = 0 << 11; // top = 0: logical 0-7 maps to physical 0-7
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fxsave_tag = 0; // everything empty
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EXPECT_EQ(CPUContextX86::FxsaveToFsaveTagWord(fsw, fxsave_tag, st_mm),
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0xffff);
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}
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TEST(CPUContextX86, FsaveToFxsaveTagWord) {
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// The register sets that these x87 tag words might apply to are given in the
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// FxsaveToFsaveTagWord test above.
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EXPECT_EQ(CPUContextX86::FsaveToFxsaveTagWord(0xff22), 0x0f);
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EXPECT_EQ(CPUContextX86::FsaveToFxsaveTagWord(0xa9ff), 0xf0);
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EXPECT_EQ(CPUContextX86::FsaveToFxsaveTagWord(0xeebb), 0x5a);
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EXPECT_EQ(CPUContextX86::FsaveToFxsaveTagWord(0xfe90), 0x1f);
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EXPECT_EQ(CPUContextX86::FsaveToFxsaveTagWord(0x0000), 0xff);
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EXPECT_EQ(CPUContextX86::FsaveToFxsaveTagWord(0xffff), 0x00);
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}
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} // namespace
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} // namespace test
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} // namespace crashpad
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