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cobalt / cobalt / 61a8495e1e0485bd40f613004bf29f8a925ab37c / . / src / third_party / llvm-project / lldb / source / Plugins / Process / FreeBSD / RegisterContextPOSIXProcessMonitor_x86.cpp
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//===-- RegisterContextPOSIXProcessMonitor_x86.cpp --------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "lldb/Core/RegisterValue.h"
#include "lldb/Target/Thread.h"
#include "lldb/Utility/DataBufferHeap.h"
#include "Plugins/Process/FreeBSD/ProcessFreeBSD.h"
#include "Plugins/Process/FreeBSD/ProcessMonitor.h"
#include "RegisterContextPOSIXProcessMonitor_x86.h"
using namespace lldb_private;
using namespace lldb;
// Support ptrace extensions even when compiled without required kernel support
#ifndef NT_X86_XSTATE
#define NT_X86_XSTATE 0x202
#endif
#define REG_CONTEXT_SIZE (GetGPRSize() + sizeof(FPR))
static uint32_t size_and_rw_bits(size_t size, bool read, bool write) {
uint32_t rw;
if (read)
rw = 0x3; // READ or READ/WRITE
else if (write)
rw = 0x1; // WRITE
else
assert(0 && "read and write cannot both be false");
switch (size) {
case 1:
return rw;
case 2:
return (0x1 << 2) | rw;
case 4:
return (0x3 << 2) | rw;
case 8:
return (0x2 << 2) | rw;
default:
assert(0 && "invalid size, must be one of 1, 2, 4, or 8");
return 0; // Unreachable. Just to silence compiler.
}
}
RegisterContextPOSIXProcessMonitor_x86_64::
RegisterContextPOSIXProcessMonitor_x86_64(
Thread &thread, uint32_t concrete_frame_idx,
lldb_private::RegisterInfoInterface *register_info)
: RegisterContextPOSIX_x86(thread, concrete_frame_idx, register_info) {
// Store byte offset of fctrl (i.e. first register of FPR) wrt 'UserArea'
const RegisterInfo *reg_info_fctrl = GetRegisterInfoByName("fctrl");
m_fctrl_offset_in_userarea = reg_info_fctrl->byte_offset;
m_iovec.iov_base = &m_fpr.xsave;
m_iovec.iov_len = sizeof(m_fpr.xsave);
}
ProcessMonitor &RegisterContextPOSIXProcessMonitor_x86_64::GetMonitor() {
ProcessSP base = CalculateProcess();
ProcessFreeBSD *process = static_cast<ProcessFreeBSD *>(base.get());
return process->GetMonitor();
}
bool RegisterContextPOSIXProcessMonitor_x86_64::ReadGPR() {
ProcessMonitor &monitor = GetMonitor();
return monitor.ReadGPR(m_thread.GetID(), &m_gpr_x86_64, GetGPRSize());
}
bool RegisterContextPOSIXProcessMonitor_x86_64::ReadFPR() {
ProcessMonitor &monitor = GetMonitor();
if (GetFPRType() == eFXSAVE)
return monitor.ReadFPR(m_thread.GetID(), &m_fpr.fxsave,
sizeof(m_fpr.fxsave));
if (GetFPRType() == eXSAVE)
return monitor.ReadRegisterSet(m_thread.GetID(), &m_iovec,
sizeof(m_fpr.xsave), NT_X86_XSTATE);
return false;
}
bool RegisterContextPOSIXProcessMonitor_x86_64::WriteGPR() {
ProcessMonitor &monitor = GetMonitor();
return monitor.WriteGPR(m_thread.GetID(), &m_gpr_x86_64, GetGPRSize());
}
bool RegisterContextPOSIXProcessMonitor_x86_64::WriteFPR() {
ProcessMonitor &monitor = GetMonitor();
if (GetFPRType() == eFXSAVE)
return monitor.WriteFPR(m_thread.GetID(), &m_fpr.fxsave,
sizeof(m_fpr.fxsave));
if (GetFPRType() == eXSAVE)
return monitor.WriteRegisterSet(m_thread.GetID(), &m_iovec,
sizeof(m_fpr.xsave), NT_X86_XSTATE);
return false;
}
bool RegisterContextPOSIXProcessMonitor_x86_64::ReadRegister(
const unsigned reg, RegisterValue &value) {
ProcessMonitor &monitor = GetMonitor();
#if defined(__FreeBSD__)
if (reg >= m_reg_info.first_dr)
return monitor.ReadDebugRegisterValue(
m_thread.GetID(), GetRegisterOffset(reg), GetRegisterName(reg),
GetRegisterSize(reg), value);
#endif
return monitor.ReadRegisterValue(m_thread.GetID(), GetRegisterOffset(reg),
GetRegisterName(reg), GetRegisterSize(reg),
value);
}
bool RegisterContextPOSIXProcessMonitor_x86_64::WriteRegister(
const unsigned reg, const RegisterValue &value) {
unsigned reg_to_write = reg;
RegisterValue value_to_write = value;
// Check if this is a subregister of a full register.
const RegisterInfo *reg_info = GetRegisterInfoAtIndex(reg);
if (reg_info->invalidate_regs &&
(reg_info->invalidate_regs[0] != LLDB_INVALID_REGNUM)) {
RegisterValue full_value;
uint32_t full_reg = reg_info->invalidate_regs[0];
const RegisterInfo *full_reg_info = GetRegisterInfoAtIndex(full_reg);
// Read the full register.
if (ReadRegister(full_reg_info, full_value)) {
Status error;
ByteOrder byte_order = GetByteOrder();
uint8_t dst[RegisterValue::kMaxRegisterByteSize];
// Get the bytes for the full register.
const uint32_t dest_size = full_value.GetAsMemoryData(
full_reg_info, dst, sizeof(dst), byte_order, error);
if (error.Success() && dest_size) {
uint8_t src[RegisterValue::kMaxRegisterByteSize];
// Get the bytes for the source data.
const uint32_t src_size = value.GetAsMemoryData(
reg_info, src, sizeof(src), byte_order, error);
if (error.Success() && src_size && (src_size < dest_size)) {
// Copy the src bytes to the destination.
memcpy(dst + (reg_info->byte_offset & 0x1), src, src_size);
// Set this full register as the value to write.
value_to_write.SetBytes(dst, full_value.GetByteSize(), byte_order);
value_to_write.SetType(full_reg_info);
reg_to_write = full_reg;
}
}
}
}
ProcessMonitor &monitor = GetMonitor();
#if defined(__FreeBSD__)
if (reg >= m_reg_info.first_dr)
return monitor.WriteDebugRegisterValue(
m_thread.GetID(), GetRegisterOffset(reg_to_write),
GetRegisterName(reg_to_write), value_to_write);
#endif
return monitor.WriteRegisterValue(
m_thread.GetID(), GetRegisterOffset(reg_to_write),
GetRegisterName(reg_to_write), value_to_write);
}
bool RegisterContextPOSIXProcessMonitor_x86_64::ReadRegister(
const RegisterInfo *reg_info, RegisterValue &value) {
if (!reg_info)
return false;
const uint32_t reg = reg_info->kinds[eRegisterKindLLDB];
if (IsFPR(reg, GetFPRType())) {
if (!ReadFPR())
return false;
} else {
uint32_t full_reg = reg;
bool is_subreg = reg_info->invalidate_regs &&
(reg_info->invalidate_regs[0] != LLDB_INVALID_REGNUM);
if (is_subreg) {
// Read the full aligned 64-bit register.
full_reg = reg_info->invalidate_regs[0];
}
bool success = ReadRegister(full_reg, value);
if (success) {
// If our read was not aligned (for ah,bh,ch,dh), shift our returned
// value one byte to the right.
if (is_subreg && (reg_info->byte_offset & 0x1))
value.SetUInt64(value.GetAsUInt64() >> 8);
// If our return byte size was greater than the return value reg size,
// then use the type specified by reg_info rather than the uint64_t
// default
if (value.GetByteSize() > reg_info->byte_size)
value.SetType(reg_info);
}
return success;
}
if (reg_info->encoding == eEncodingVector) {
ByteOrder byte_order = GetByteOrder();
if (byte_order != ByteOrder::eByteOrderInvalid) {
if (reg >= m_reg_info.first_st && reg <= m_reg_info.last_st)
value.SetBytes(m_fpr.fxsave.stmm[reg - m_reg_info.first_st].bytes,
reg_info->byte_size, byte_order);
if (reg >= m_reg_info.first_mm && reg <= m_reg_info.last_mm)
value.SetBytes(m_fpr.fxsave.stmm[reg - m_reg_info.first_mm].bytes,
reg_info->byte_size, byte_order);
if (reg >= m_reg_info.first_xmm && reg <= m_reg_info.last_xmm)
value.SetBytes(m_fpr.fxsave.xmm[reg - m_reg_info.first_xmm].bytes,
reg_info->byte_size, byte_order);
if (reg >= m_reg_info.first_ymm && reg <= m_reg_info.last_ymm) {
// Concatenate ymm using the register halves in xmm.bytes and
// ymmh.bytes
if (GetFPRType() == eXSAVE && CopyXSTATEtoYMM(reg, byte_order))
value.SetBytes(m_ymm_set.ymm[reg - m_reg_info.first_ymm].bytes,
reg_info->byte_size, byte_order);
else
return false;
}
return value.GetType() == RegisterValue::eTypeBytes;
}
return false;
}
// Get pointer to m_fpr.fxsave variable and set the data from it. Byte
// offsets of all registers are calculated wrt 'UserArea' structure. However,
// ReadFPR() reads fpu registers {using ptrace(PT_GETFPREGS,..)} and stores
// them in 'm_fpr' (of type FPR structure). To extract values of fpu
// registers, m_fpr should be read at byte offsets calculated wrt to FPR
// structure.
// Since, FPR structure is also one of the member of UserArea structure.
// byte_offset(fpu wrt FPR) = byte_offset(fpu wrt UserArea) -
// byte_offset(fctrl wrt UserArea)
assert((reg_info->byte_offset - m_fctrl_offset_in_userarea) < sizeof(m_fpr));
uint8_t *src =
(uint8_t *)&m_fpr + reg_info->byte_offset - m_fctrl_offset_in_userarea;
switch (reg_info->byte_size) {
case 1:
value.SetUInt8(*(uint8_t *)src);
return true;
case 2:
value.SetUInt16(*(uint16_t *)src);
return true;
case 4:
value.SetUInt32(*(uint32_t *)src);
return true;
case 8:
value.SetUInt64(*(uint64_t *)src);
return true;
default:
assert(false && "Unhandled data size.");
return false;
}
}
bool RegisterContextPOSIXProcessMonitor_x86_64::WriteRegister(
const RegisterInfo *reg_info, const RegisterValue &value) {
const uint32_t reg = reg_info->kinds[eRegisterKindLLDB];
if (IsGPR(reg))
return WriteRegister(reg, value);
if (IsFPR(reg, GetFPRType())) {
if (reg_info->encoding == eEncodingVector) {
if (reg >= m_reg_info.first_st && reg <= m_reg_info.last_st)
::memcpy(m_fpr.fxsave.stmm[reg - m_reg_info.first_st].bytes,
value.GetBytes(), value.GetByteSize());
if (reg >= m_reg_info.first_mm && reg <= m_reg_info.last_mm)
::memcpy(m_fpr.fxsave.stmm[reg - m_reg_info.first_mm].bytes,
value.GetBytes(), value.GetByteSize());
if (reg >= m_reg_info.first_xmm && reg <= m_reg_info.last_xmm)
::memcpy(m_fpr.fxsave.xmm[reg - m_reg_info.first_xmm].bytes,
value.GetBytes(), value.GetByteSize());
if (reg >= m_reg_info.first_ymm && reg <= m_reg_info.last_ymm) {
if (GetFPRType() != eXSAVE)
return false; // the target processor does not support AVX
// Store ymm register content, and split into the register halves in
// xmm.bytes and ymmh.bytes
::memcpy(m_ymm_set.ymm[reg - m_reg_info.first_ymm].bytes,
value.GetBytes(), value.GetByteSize());
if (false == CopyYMMtoXSTATE(reg, GetByteOrder()))
return false;
}
} else {
// Get pointer to m_fpr.fxsave variable and set the data to it. Byte
// offsets of all registers are calculated wrt 'UserArea' structure.
// However, WriteFPR() takes m_fpr (of type FPR structure) and writes
// only fpu registers using ptrace(PT_SETFPREGS,..) API. Hence fpu
// registers should be written in m_fpr at byte offsets calculated wrt
// FPR structure.
// Since, FPR structure is also one of the member of UserArea structure.
// byte_offset(fpu wrt FPR) = byte_offset(fpu wrt UserArea) -
// byte_offset(fctrl wrt UserArea)
assert((reg_info->byte_offset - m_fctrl_offset_in_userarea) <
sizeof(m_fpr));
uint8_t *dst = (uint8_t *)&m_fpr + reg_info->byte_offset -
m_fctrl_offset_in_userarea;
switch (reg_info->byte_size) {
case 1:
*(uint8_t *)dst = value.GetAsUInt8();
break;
case 2:
*(uint16_t *)dst = value.GetAsUInt16();
break;
case 4:
*(uint32_t *)dst = value.GetAsUInt32();
break;
case 8:
*(uint64_t *)dst = value.GetAsUInt64();
break;
default:
assert(false && "Unhandled data size.");
return false;
}
}
if (WriteFPR()) {
if (IsAVX(reg))
return CopyYMMtoXSTATE(reg, GetByteOrder());
return true;
}
}
return false;
}
bool RegisterContextPOSIXProcessMonitor_x86_64::ReadAllRegisterValues(
DataBufferSP &data_sp) {
bool success = false;
data_sp.reset(new DataBufferHeap(REG_CONTEXT_SIZE, 0));
if (data_sp && ReadGPR() && ReadFPR()) {
uint8_t *dst = data_sp->GetBytes();
success = dst != 0;
if (success) {
::memcpy(dst, &m_gpr_x86_64, GetGPRSize());
dst += GetGPRSize();
if (GetFPRType() == eFXSAVE)
::memcpy(dst, &m_fpr.fxsave, sizeof(m_fpr.fxsave));
}
if (GetFPRType() == eXSAVE) {
ByteOrder byte_order = GetByteOrder();
// Assemble the YMM register content from the register halves.
for (uint32_t reg = m_reg_info.first_ymm;
success && reg <= m_reg_info.last_ymm; ++reg)
success = CopyXSTATEtoYMM(reg, byte_order);
if (success) {
// Copy the extended register state including the assembled ymm
// registers.
::memcpy(dst, &m_fpr, sizeof(m_fpr));
}
}
}
return success;
}
bool RegisterContextPOSIXProcessMonitor_x86_64::WriteAllRegisterValues(
const DataBufferSP &data_sp) {
bool success = false;
if (data_sp && data_sp->GetByteSize() == REG_CONTEXT_SIZE) {
uint8_t *src = data_sp->GetBytes();
if (src) {
::memcpy(&m_gpr_x86_64, src, GetGPRSize());
if (WriteGPR()) {
src += GetGPRSize();
if (GetFPRType() == eFXSAVE)
::memcpy(&m_fpr.fxsave, src, sizeof(m_fpr.fxsave));
if (GetFPRType() == eXSAVE)
::memcpy(&m_fpr.xsave, src, sizeof(m_fpr.xsave));
success = WriteFPR();
if (success) {
if (GetFPRType() == eXSAVE) {
ByteOrder byte_order = GetByteOrder();
// Parse the YMM register content from the register halves.
for (uint32_t reg = m_reg_info.first_ymm;
success && reg <= m_reg_info.last_ymm; ++reg)
success = CopyYMMtoXSTATE(reg, byte_order);
}
}
}
}
}
return success;
}
uint32_t RegisterContextPOSIXProcessMonitor_x86_64::SetHardwareWatchpoint(
addr_t addr, size_t size, bool read, bool write) {
const uint32_t num_hw_watchpoints = NumSupportedHardwareWatchpoints();
uint32_t hw_index;
for (hw_index = 0; hw_index < num_hw_watchpoints; ++hw_index) {
if (IsWatchpointVacant(hw_index))
return SetHardwareWatchpointWithIndex(addr, size, read, write, hw_index);
}
return LLDB_INVALID_INDEX32;
}
bool RegisterContextPOSIXProcessMonitor_x86_64::ClearHardwareWatchpoint(
uint32_t hw_index) {
if (hw_index < NumSupportedHardwareWatchpoints()) {
RegisterValue current_dr7_bits;
if (ReadRegister(m_reg_info.first_dr + 7, current_dr7_bits)) {
uint64_t new_dr7_bits =
current_dr7_bits.GetAsUInt64() & ~(3 << (2 * hw_index));
if (WriteRegister(m_reg_info.first_dr + 7, RegisterValue(new_dr7_bits)))
return true;
}
}
return false;
}
bool RegisterContextPOSIXProcessMonitor_x86_64::HardwareSingleStep(
bool enable) {
enum { TRACE_BIT = 0x100 };
uint64_t rflags;
if ((rflags = ReadRegisterAsUnsigned(m_reg_info.gpr_flags, -1UL)) == -1UL)
return false;
if (enable) {
if (rflags & TRACE_BIT)
return true;
rflags |= TRACE_BIT;
} else {
if (!(rflags & TRACE_BIT))
return false;
rflags &= ~TRACE_BIT;
}
return WriteRegisterFromUnsigned(m_reg_info.gpr_flags, rflags);
}
bool RegisterContextPOSIXProcessMonitor_x86_64::UpdateAfterBreakpoint() {
// PC points one byte past the int3 responsible for the breakpoint.
lldb::addr_t pc;
if ((pc = GetPC()) == LLDB_INVALID_ADDRESS)
return false;
SetPC(pc - 1);
return true;
}
unsigned RegisterContextPOSIXProcessMonitor_x86_64::GetRegisterIndexFromOffset(
unsigned offset) {
unsigned reg;
for (reg = 0; reg < m_reg_info.num_registers; reg++) {
if (GetRegisterInfo()[reg].byte_offset == offset)
break;
}
assert(reg < m_reg_info.num_registers && "Invalid register offset.");
return reg;
}
bool RegisterContextPOSIXProcessMonitor_x86_64::IsWatchpointHit(
uint32_t hw_index) {
bool is_hit = false;
if (m_watchpoints_initialized == false) {
// Reset the debug status and debug control registers
RegisterValue zero_bits = RegisterValue(uint64_t(0));
if (!WriteRegister(m_reg_info.first_dr + 6, zero_bits) ||
!WriteRegister(m_reg_info.first_dr + 7, zero_bits))
assert(false && "Could not initialize watchpoint registers");
m_watchpoints_initialized = true;
}
if (hw_index < NumSupportedHardwareWatchpoints()) {
RegisterValue value;
if (ReadRegister(m_reg_info.first_dr + 6, value)) {
uint64_t val = value.GetAsUInt64();
is_hit = val & (1 << hw_index);
}
}
return is_hit;
}
bool RegisterContextPOSIXProcessMonitor_x86_64::ClearWatchpointHits() {
return WriteRegister(m_reg_info.first_dr + 6, RegisterValue((uint64_t)0));
}
addr_t RegisterContextPOSIXProcessMonitor_x86_64::GetWatchpointAddress(
uint32_t hw_index) {
addr_t wp_monitor_addr = LLDB_INVALID_ADDRESS;
if (hw_index < NumSupportedHardwareWatchpoints()) {
if (!IsWatchpointVacant(hw_index)) {
RegisterValue value;
if (ReadRegister(m_reg_info.first_dr + hw_index, value))
wp_monitor_addr = value.GetAsUInt64();
}
}
return wp_monitor_addr;
}
bool RegisterContextPOSIXProcessMonitor_x86_64::IsWatchpointVacant(
uint32_t hw_index) {
bool is_vacant = false;
RegisterValue value;
assert(hw_index < NumSupportedHardwareWatchpoints());
if (m_watchpoints_initialized == false) {
// Reset the debug status and debug control registers
RegisterValue zero_bits = RegisterValue(uint64_t(0));
if (!WriteRegister(m_reg_info.first_dr + 6, zero_bits) ||
!WriteRegister(m_reg_info.first_dr + 7, zero_bits))
assert(false && "Could not initialize watchpoint registers");
m_watchpoints_initialized = true;
}
if (ReadRegister(m_reg_info.first_dr + 7, value)) {
uint64_t val = value.GetAsUInt64();
is_vacant = (val & (3 << 2 * hw_index)) == 0;
}
return is_vacant;
}
bool RegisterContextPOSIXProcessMonitor_x86_64::SetHardwareWatchpointWithIndex(
addr_t addr, size_t size, bool read, bool write, uint32_t hw_index) {
const uint32_t num_hw_watchpoints = NumSupportedHardwareWatchpoints();
if (num_hw_watchpoints == 0 || hw_index >= num_hw_watchpoints)
return false;
if (!(size == 1 || size == 2 || size == 4 || size == 8))
return false;
if (read == false && write == false)
return false;
if (!IsWatchpointVacant(hw_index))
return false;
// Set both dr7 (debug control register) and dri (debug address register).
// dr7{7-0} encodes the local/global enable bits:
// global enable --. .-- local enable
// | |
// v v
// dr0 -> bits{1-0}
// dr1 -> bits{3-2}
// dr2 -> bits{5-4}
// dr3 -> bits{7-6}
//
// dr7{31-16} encodes the rw/len bits:
// b_x+3, b_x+2, b_x+1, b_x
// where bits{x+1, x} => rw
// 0b00: execute, 0b01: write, 0b11: read-or-write,
// 0b10: io read-or-write (unused)
// and bits{x+3, x+2} => len
// 0b00: 1-byte, 0b01: 2-byte, 0b11: 4-byte, 0b10: 8-byte
//
// dr0 -> bits{19-16}
// dr1 -> bits{23-20}
// dr2 -> bits{27-24}
// dr3 -> bits{31-28}
if (hw_index < num_hw_watchpoints) {
RegisterValue current_dr7_bits;
if (ReadRegister(m_reg_info.first_dr + 7, current_dr7_bits)) {
uint64_t new_dr7_bits =
current_dr7_bits.GetAsUInt64() |
(1 << (2 * hw_index) |
size_and_rw_bits(size, read, write) << (16 + 4 * hw_index));
if (WriteRegister(m_reg_info.first_dr + hw_index, RegisterValue(addr)) &&
WriteRegister(m_reg_info.first_dr + 7, RegisterValue(new_dr7_bits)))
return true;
}
}
return false;
}
uint32_t
RegisterContextPOSIXProcessMonitor_x86_64::NumSupportedHardwareWatchpoints() {
// Available debug address registers: dr0, dr1, dr2, dr3
return 4;
}