// Copyright 2014 The Crashpad Authors. All rights reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include "snapshot/cpu_context.h" #include #include #include "base/cxx17_backports.h" #include "base/notreached.h" #include "util/misc/arraysize.h" #include "util/misc/implicit_cast.h" namespace crashpad { namespace { // Sanity-check complex structures to ensure interoperability. static_assert(sizeof(CPUContextX86::Fsave) == 108, "CPUContextX86::Fsave size"); static_assert(sizeof(CPUContextX86::Fxsave) == 512, "CPUContextX86::Fxsave size"); static_assert(sizeof(CPUContextX86_64::Fxsave) == 512, "CPUContextX86_64::Fxsave size"); enum { kX87TagValid = 0, kX87TagZero, kX87TagSpecial, kX87TagEmpty, }; } // namespace // static void CPUContextX86::FxsaveToFsave(const Fxsave& fxsave, Fsave* fsave) { fsave->fcw = fxsave.fcw; fsave->reserved_1 = 0; fsave->fsw = fxsave.fsw; fsave->reserved_2 = 0; fsave->ftw = FxsaveToFsaveTagWord(fxsave.fsw, fxsave.ftw, fxsave.st_mm); fsave->reserved_3 = 0; fsave->fpu_ip = fxsave.fpu_ip; fsave->fpu_cs = fxsave.fpu_cs; fsave->fop = fxsave.fop; fsave->fpu_dp = fxsave.fpu_dp; fsave->fpu_ds = fxsave.fpu_ds; fsave->reserved_4 = 0; static_assert(ArraySize(fsave->st) == ArraySize(fxsave.st_mm), "FPU stack registers must be equivalent"); for (size_t index = 0; index < base::size(fsave->st); ++index) { memcpy(fsave->st[index], fxsave.st_mm[index].st, sizeof(fsave->st[index])); } } // static void CPUContextX86::FsaveToFxsave(const Fsave& fsave, Fxsave* fxsave) { fxsave->fcw = fsave.fcw; fxsave->fsw = fsave.fsw; fxsave->ftw = FsaveToFxsaveTagWord(fsave.ftw); fxsave->reserved_1 = 0; fxsave->fop = fsave.fop; fxsave->fpu_ip = fsave.fpu_ip; fxsave->fpu_cs = fsave.fpu_cs; fxsave->reserved_2 = 0; fxsave->fpu_dp = fsave.fpu_dp; fxsave->fpu_ds = fsave.fpu_ds; fxsave->reserved_3 = 0; fxsave->mxcsr = 0; fxsave->mxcsr_mask = 0; static_assert(ArraySize(fxsave->st_mm) == ArraySize(fsave.st), "FPU stack registers must be equivalent"); for (size_t index = 0; index < base::size(fsave.st); ++index) { memcpy(fxsave->st_mm[index].st, fsave.st[index], sizeof(fsave.st[index])); memset(fxsave->st_mm[index].st_reserved, 0, sizeof(fxsave->st_mm[index].st_reserved)); } memset(fxsave->xmm, 0, sizeof(*fxsave) - offsetof(Fxsave, xmm)); } // static uint16_t CPUContextX86::FxsaveToFsaveTagWord( uint16_t fsw, uint8_t fxsave_tag, const CPUContextX86::X87OrMMXRegister st_mm[8]) { // The x87 tag word (in both abridged and full form) identifies physical // registers, but |st_mm| is arranged in logical stack order. In order to map // physical tag word bits to the logical stack registers they correspond to, // the “stack top” value from the x87 status word is necessary. int stack_top = (fsw >> 11) & 0x7; uint16_t fsave_tag = 0; for (int physical_index = 0; physical_index < 8; ++physical_index) { bool fxsave_bit = (fxsave_tag & (1 << physical_index)) != 0; uint8_t fsave_bits; if (fxsave_bit) { int st_index = (physical_index + 8 - stack_top) % 8; const CPUContextX86::X87Register& st = st_mm[st_index].st; uint32_t exponent = ((st[9] & 0x7f) << 8) | st[8]; if (exponent == 0x7fff) { // Infinity, NaN, pseudo-infinity, or pseudo-NaN. If it was important to // distinguish between these, the J bit and the M bit (the most // significant bit of |fraction|) could be consulted. fsave_bits = kX87TagSpecial; } else { // The integer bit the “J bit”. bool integer_bit = (st[7] & 0x80) != 0; if (exponent == 0) { uint64_t fraction = ((implicit_cast(st[7]) & 0x7f) << 56) | (implicit_cast(st[6]) << 48) | (implicit_cast(st[5]) << 40) | (implicit_cast(st[4]) << 32) | (implicit_cast(st[3]) << 24) | (st[2] << 16) | (st[1] << 8) | st[0]; if (!integer_bit && fraction == 0) { fsave_bits = kX87TagZero; } else { // Denormal (if the J bit is clear) or pseudo-denormal. fsave_bits = kX87TagSpecial; } } else if (integer_bit) { fsave_bits = kX87TagValid; } else { // Unnormal. fsave_bits = kX87TagSpecial; } } } else { fsave_bits = kX87TagEmpty; } fsave_tag |= (fsave_bits << (physical_index * 2)); } return fsave_tag; } // static uint8_t CPUContextX86::FsaveToFxsaveTagWord(uint16_t fsave_tag) { uint8_t fxsave_tag = 0; for (int physical_index = 0; physical_index < 8; ++physical_index) { const uint8_t fsave_bits = (fsave_tag >> (physical_index * 2)) & 0x3; const bool fxsave_bit = fsave_bits != kX87TagEmpty; fxsave_tag |= fxsave_bit << physical_index; } return fxsave_tag; } uint64_t CPUContext::InstructionPointer() const { switch (architecture) { case kCPUArchitectureX86: return x86->eip; case kCPUArchitectureX86_64: return x86_64->rip; case kCPUArchitectureARM: return arm->pc; case kCPUArchitectureARM64: return arm64->pc; default: NOTREACHED(); return ~0ull; } } uint64_t CPUContext::StackPointer() const { switch (architecture) { case kCPUArchitectureX86: return x86->esp; case kCPUArchitectureX86_64: return x86_64->rsp; case kCPUArchitectureARM: return arm->sp; case kCPUArchitectureARM64: return arm64->sp; default: NOTREACHED(); return ~0ull; } } bool CPUContext::Is64Bit() const { switch (architecture) { case kCPUArchitectureX86_64: case kCPUArchitectureARM64: case kCPUArchitectureMIPS64EL: return true; case kCPUArchitectureX86: case kCPUArchitectureARM: case kCPUArchitectureMIPSEL: return false; default: NOTREACHED(); return false; } } } // namespace crashpad