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llvm-project/lldb/source/Plugins/Process/Linux/NativeRegisterContextLinux_arm64.cpp
Omair Javaid 43507f573d Allow installing watchpoints at less than 8-byte alligned addresses for AArch64 targets 
This patch allows LLDB for AArch64 to watch all bytes, words or double words individually on non 8-byte alligned addresses.

This patch also adds tests to verify this functionality.

Differential revision: http://reviews.llvm.org/D21280

llvm-svn: 272916
2016-06-16 16:41:22 +00:00

1093 lines
32 KiB
C++
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//===-- NativeRegisterContextLinux_arm64.cpp --------------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#if defined (__arm64__) || defined (__aarch64__)
#include "NativeRegisterContextLinux_arm.h"
#include "NativeRegisterContextLinux_arm64.h"
// C Includes
// C++ Includes
// Other libraries and framework includes
#include "lldb/Core/DataBufferHeap.h"
#include "lldb/Core/Error.h"
#include "lldb/Core/Log.h"
#include "lldb/Core/RegisterValue.h"
#include "lldb/Host/common/NativeProcessProtocol.h"
#include "Plugins/Process/Linux/NativeProcessLinux.h"
#include "Plugins/Process/Linux/Procfs.h"
#include "Plugins/Process/POSIX/ProcessPOSIXLog.h"
#include "Plugins/Process/Utility/RegisterContextLinux_arm64.h"
// System includes - They have to be included after framework includes because they define some
// macros which collide with variable names in other modules
#include <sys/socket.h>
// NT_PRSTATUS and NT_FPREGSET definition
#include <elf.h>
// user_hwdebug_state definition
#include <asm/ptrace.h>
#define REG_CONTEXT_SIZE (GetGPRSize() + GetFPRSize())
using namespace lldb;
using namespace lldb_private;
using namespace lldb_private::process_linux;
// ARM64 general purpose registers.
static const uint32_t g_gpr_regnums_arm64[] =
{
gpr_x0_arm64,
gpr_x1_arm64,
gpr_x2_arm64,
gpr_x3_arm64,
gpr_x4_arm64,
gpr_x5_arm64,
gpr_x6_arm64,
gpr_x7_arm64,
gpr_x8_arm64,
gpr_x9_arm64,
gpr_x10_arm64,
gpr_x11_arm64,
gpr_x12_arm64,
gpr_x13_arm64,
gpr_x14_arm64,
gpr_x15_arm64,
gpr_x16_arm64,
gpr_x17_arm64,
gpr_x18_arm64,
gpr_x19_arm64,
gpr_x20_arm64,
gpr_x21_arm64,
gpr_x22_arm64,
gpr_x23_arm64,
gpr_x24_arm64,
gpr_x25_arm64,
gpr_x26_arm64,
gpr_x27_arm64,
gpr_x28_arm64,
gpr_fp_arm64,
gpr_lr_arm64,
gpr_sp_arm64,
gpr_pc_arm64,
gpr_cpsr_arm64,
LLDB_INVALID_REGNUM // register sets need to end with this flag
};
static_assert(((sizeof g_gpr_regnums_arm64 / sizeof g_gpr_regnums_arm64[0]) - 1) == k_num_gpr_registers_arm64, \
"g_gpr_regnums_arm64 has wrong number of register infos");
// ARM64 floating point registers.
static const uint32_t g_fpu_regnums_arm64[] =
{
fpu_v0_arm64,
fpu_v1_arm64,
fpu_v2_arm64,
fpu_v3_arm64,
fpu_v4_arm64,
fpu_v5_arm64,
fpu_v6_arm64,
fpu_v7_arm64,
fpu_v8_arm64,
fpu_v9_arm64,
fpu_v10_arm64,
fpu_v11_arm64,
fpu_v12_arm64,
fpu_v13_arm64,
fpu_v14_arm64,
fpu_v15_arm64,
fpu_v16_arm64,
fpu_v17_arm64,
fpu_v18_arm64,
fpu_v19_arm64,
fpu_v20_arm64,
fpu_v21_arm64,
fpu_v22_arm64,
fpu_v23_arm64,
fpu_v24_arm64,
fpu_v25_arm64,
fpu_v26_arm64,
fpu_v27_arm64,
fpu_v28_arm64,
fpu_v29_arm64,
fpu_v30_arm64,
fpu_v31_arm64,
fpu_fpsr_arm64,
fpu_fpcr_arm64,
LLDB_INVALID_REGNUM // register sets need to end with this flag
};
static_assert(((sizeof g_fpu_regnums_arm64 / sizeof g_fpu_regnums_arm64[0]) - 1) == k_num_fpr_registers_arm64, \
"g_fpu_regnums_arm64 has wrong number of register infos");
namespace {
// Number of register sets provided by this context.
enum
{
k_num_register_sets = 2
};
}
// Register sets for ARM64.
static const RegisterSet
g_reg_sets_arm64[k_num_register_sets] =
{
{ "General Purpose Registers", "gpr", k_num_gpr_registers_arm64, g_gpr_regnums_arm64 },
{ "Floating Point Registers", "fpu", k_num_fpr_registers_arm64, g_fpu_regnums_arm64 }
};
NativeRegisterContextLinux*
NativeRegisterContextLinux::CreateHostNativeRegisterContextLinux(const ArchSpec& target_arch,
NativeThreadProtocol &native_thread,
uint32_t concrete_frame_idx)
{
Log *log = ProcessPOSIXLog::GetLogIfAllCategoriesSet(POSIX_LOG_REGISTERS);
switch (target_arch.GetMachine())
{
case llvm::Triple::arm:
return new NativeRegisterContextLinux_arm(target_arch, native_thread, concrete_frame_idx);
case llvm::Triple::aarch64:
return new NativeRegisterContextLinux_arm64(target_arch, native_thread, concrete_frame_idx);
default:
if (log)
log->Printf("NativeRegisterContextLinux::%s() have no register context for architecture: %s\n", __FUNCTION__,
target_arch.GetTriple().getArchName().str().c_str());
return nullptr;
}
}
NativeRegisterContextLinux_arm64::NativeRegisterContextLinux_arm64 (const ArchSpec& target_arch,
NativeThreadProtocol &native_thread,
uint32_t concrete_frame_idx) :
NativeRegisterContextLinux (native_thread, concrete_frame_idx, new RegisterContextLinux_arm64(target_arch))
{
switch (target_arch.GetMachine())
{
case llvm::Triple::aarch64:
m_reg_info.num_registers = k_num_registers_arm64;
m_reg_info.num_gpr_registers = k_num_gpr_registers_arm64;
m_reg_info.num_fpr_registers = k_num_fpr_registers_arm64;
m_reg_info.last_gpr = k_last_gpr_arm64;
m_reg_info.first_fpr = k_first_fpr_arm64;
m_reg_info.last_fpr = k_last_fpr_arm64;
m_reg_info.first_fpr_v = fpu_v0_arm64;
m_reg_info.last_fpr_v = fpu_v31_arm64;
m_reg_info.gpr_flags = gpr_cpsr_arm64;
break;
default:
assert(false && "Unhandled target architecture.");
break;
}
::memset(&m_fpr, 0, sizeof (m_fpr));
::memset(&m_gpr_arm64, 0, sizeof (m_gpr_arm64));
::memset(&m_hwp_regs, 0, sizeof (m_hwp_regs));
// 16 is just a maximum value, query hardware for actual watchpoint count
m_max_hwp_supported = 16;
m_max_hbp_supported = 16;
m_refresh_hwdebug_info = true;
}
uint32_t
NativeRegisterContextLinux_arm64::GetRegisterSetCount () const
{
return k_num_register_sets;
}
const RegisterSet *
NativeRegisterContextLinux_arm64::GetRegisterSet (uint32_t set_index) const
{
if (set_index < k_num_register_sets)
return &g_reg_sets_arm64[set_index];
return nullptr;
}
uint32_t
NativeRegisterContextLinux_arm64::GetUserRegisterCount() const
{
uint32_t count = 0;
for (uint32_t set_index = 0; set_index < k_num_register_sets; ++set_index)
count += g_reg_sets_arm64[set_index].num_registers;
return count;
}
Error
NativeRegisterContextLinux_arm64::ReadRegister (const RegisterInfo *reg_info, RegisterValue &reg_value)
{
Error error;
if (!reg_info)
{
error.SetErrorString ("reg_info NULL");
return error;
}
const uint32_t reg = reg_info->kinds[lldb::eRegisterKindLLDB];
if (IsFPR(reg))
{
error = ReadFPR();
if (error.Fail())
return error;
}
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];
}
error = ReadRegisterRaw(full_reg, reg_value);
if (error.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))
reg_value.SetUInt64(reg_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 (reg_value.GetByteSize() > reg_info->byte_size)
reg_value.SetType(reg_info);
}
return error;
}
// Get pointer to m_fpr variable and set the data from it.
uint32_t fpr_offset = CalculateFprOffset(reg_info);
assert (fpr_offset < sizeof m_fpr);
uint8_t *src = (uint8_t *)&m_fpr + fpr_offset;
reg_value.SetFromMemoryData(reg_info, src, reg_info->byte_size, eByteOrderLittle, error);
return error;
}
Error
NativeRegisterContextLinux_arm64::WriteRegister (const RegisterInfo *reg_info, const RegisterValue &reg_value)
{
if (!reg_info)
return Error ("reg_info NULL");
const uint32_t reg_index = reg_info->kinds[lldb::eRegisterKindLLDB];
if (reg_index == LLDB_INVALID_REGNUM)
return Error ("no lldb regnum for %s", reg_info && reg_info->name ? reg_info->name : "<unknown register>");
if (IsGPR(reg_index))
return WriteRegisterRaw(reg_index, reg_value);
if (IsFPR(reg_index))
{
// Get pointer to m_fpr variable and set the data to it.
uint32_t fpr_offset = CalculateFprOffset(reg_info);
assert (fpr_offset < sizeof m_fpr);
uint8_t *dst = (uint8_t *)&m_fpr + fpr_offset;
switch (reg_info->byte_size)
{
case 2:
*(uint16_t *)dst = reg_value.GetAsUInt16();
break;
case 4:
*(uint32_t *)dst = reg_value.GetAsUInt32();
break;
case 8:
*(uint64_t *)dst = reg_value.GetAsUInt64();
break;
default:
assert(false && "Unhandled data size.");
return Error ("unhandled register data size %" PRIu32, reg_info->byte_size);
}
Error error = WriteFPR();
if (error.Fail())
return error;
return Error ();
}
return Error ("failed - register wasn't recognized to be a GPR or an FPR, write strategy unknown");
}
Error
NativeRegisterContextLinux_arm64::ReadAllRegisterValues (lldb::DataBufferSP &data_sp)
{
Error error;
data_sp.reset (new DataBufferHeap (REG_CONTEXT_SIZE, 0));
if (!data_sp)
return Error ("failed to allocate DataBufferHeap instance of size %" PRIu64, REG_CONTEXT_SIZE);
error = ReadGPR();
if (error.Fail())
return error;
error = ReadFPR();
if (error.Fail())
return error;
uint8_t *dst = data_sp->GetBytes ();
if (dst == nullptr)
{
error.SetErrorStringWithFormat ("DataBufferHeap instance of size %" PRIu64 " returned a null pointer", REG_CONTEXT_SIZE);
return error;
}
::memcpy (dst, &m_gpr_arm64, GetGPRSize());
dst += GetGPRSize();
::memcpy (dst, &m_fpr, sizeof(m_fpr));
return error;
}
Error
NativeRegisterContextLinux_arm64::WriteAllRegisterValues (const lldb::DataBufferSP &data_sp)
{
Error error;
if (!data_sp)
{
error.SetErrorStringWithFormat ("NativeRegisterContextLinux_x86_64::%s invalid data_sp provided", __FUNCTION__);
return error;
}
if (data_sp->GetByteSize () != REG_CONTEXT_SIZE)
{
error.SetErrorStringWithFormat ("NativeRegisterContextLinux_x86_64::%s data_sp contained mismatched data size, expected %" PRIu64 ", actual %" PRIu64, __FUNCTION__, REG_CONTEXT_SIZE, data_sp->GetByteSize ());
return error;
}
uint8_t *src = data_sp->GetBytes ();
if (src == nullptr)
{
error.SetErrorStringWithFormat ("NativeRegisterContextLinux_x86_64::%s DataBuffer::GetBytes() returned a null pointer", __FUNCTION__);
return error;
}
::memcpy (&m_gpr_arm64, src, GetRegisterInfoInterface ().GetGPRSize ());
error = WriteGPR();
if (error.Fail())
return error;
src += GetRegisterInfoInterface ().GetGPRSize ();
::memcpy (&m_fpr, src, sizeof(m_fpr));
error = WriteFPR();
if (error.Fail())
return error;
return error;
}
bool
NativeRegisterContextLinux_arm64::IsGPR(unsigned reg) const
{
return reg <= m_reg_info.last_gpr; // GPR's come first.
}
bool
NativeRegisterContextLinux_arm64::IsFPR(unsigned reg) const
{
return (m_reg_info.first_fpr <= reg && reg <= m_reg_info.last_fpr);
}
uint32_t
NativeRegisterContextLinux_arm64::SetHardwareBreakpoint (lldb::addr_t addr, size_t size)
{
Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_WATCHPOINTS));
if (log)
log->Printf ("NativeRegisterContextLinux_arm64::%s()", __FUNCTION__);
Error error;
// Read hardware breakpoint and watchpoint information.
error = ReadHardwareDebugInfo ();
if (error.Fail())
return LLDB_INVALID_INDEX32;
uint32_t control_value = 0, bp_index = 0;
// Check if size has a valid hardware breakpoint length.
if (size != 4)
return LLDB_INVALID_INDEX32; // Invalid size for a AArch64 hardware breakpoint
// Check 4-byte alignment for hardware breakpoint target address.
if (addr & 0x03)
return LLDB_INVALID_INDEX32; // Invalid address, should be 4-byte aligned.
// Setup control value
control_value = 0;
control_value |= ((1 << size) - 1) << 5;
control_value |= (2 << 1) | 1;
// Iterate over stored hardware breakpoints
// Find a free bp_index or update reference count if duplicate.
bp_index = LLDB_INVALID_INDEX32;
for (uint32_t i = 0; i < m_max_hbp_supported; i++)
{
if ((m_hbr_regs[i].control & 1) == 0)
{
bp_index = i; // Mark last free slot
}
else if (m_hbr_regs[i].address == addr && m_hbr_regs[i].control == control_value)
{
bp_index = i; // Mark duplicate index
break; // Stop searching here
}
}
if (bp_index == LLDB_INVALID_INDEX32)
return LLDB_INVALID_INDEX32;
// Add new or update existing breakpoint
if ((m_hbr_regs[bp_index].control & 1) == 0)
{
m_hbr_regs[bp_index].address = addr;
m_hbr_regs[bp_index].control = control_value;
m_hbr_regs[bp_index].refcount = 1;
// PTRACE call to set corresponding hardware breakpoint register.
error = WriteHardwareDebugRegs(eDREGTypeBREAK);
if (error.Fail())
{
m_hbr_regs[bp_index].address = 0;
m_hbr_regs[bp_index].control &= ~1;
m_hbr_regs[bp_index].refcount = 0;
return LLDB_INVALID_INDEX32;
}
}
else
m_hbr_regs[bp_index].refcount++;
return bp_index;
}
bool
NativeRegisterContextLinux_arm64::ClearHardwareBreakpoint (uint32_t hw_idx)
{
Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_WATCHPOINTS));
if (log)
log->Printf ("NativeRegisterContextLinux_arm64::%s()", __FUNCTION__);
Error error;
// Read hardware breakpoint and watchpoint information.
error = ReadHardwareDebugInfo ();
if (error.Fail())
return false;
if (hw_idx >= m_max_hbp_supported)
return false;
// Update reference count if multiple references.
if (m_hbr_regs[hw_idx].refcount > 1)
{
m_hbr_regs[hw_idx].refcount--;
return true;
}
else if (m_hbr_regs[hw_idx].refcount == 1)
{
// Create a backup we can revert to in case of failure.
lldb::addr_t tempAddr = m_hbr_regs[hw_idx].address;
uint32_t tempControl = m_hbr_regs[hw_idx].control;
uint32_t tempRefCount = m_hbr_regs[hw_idx].refcount;
m_hbr_regs[hw_idx].control &= ~1;
m_hbr_regs[hw_idx].address = 0;
m_hbr_regs[hw_idx].refcount = 0;
// PTRACE call to clear corresponding hardware breakpoint register.
WriteHardwareDebugRegs(eDREGTypeBREAK);
if (error.Fail())
{
m_hbr_regs[hw_idx].control = tempControl;
m_hbr_regs[hw_idx].address = tempAddr;
m_hbr_regs[hw_idx].refcount = tempRefCount;
return false;
}
return true;
}
return false;
}
uint32_t
NativeRegisterContextLinux_arm64::NumSupportedHardwareWatchpoints ()
{
Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_WATCHPOINTS));
if (log)
log->Printf ("NativeRegisterContextLinux_arm64::%s()", __FUNCTION__);
Error error;
// Read hardware breakpoint and watchpoint information.
error = ReadHardwareDebugInfo ();
if (error.Fail())
return LLDB_INVALID_INDEX32;
return m_max_hwp_supported;
}
uint32_t
NativeRegisterContextLinux_arm64::SetHardwareWatchpoint (lldb::addr_t addr, size_t size, uint32_t watch_flags)
{
Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_WATCHPOINTS));
if (log)
log->Printf ("NativeRegisterContextLinux_arm64::%s()", __FUNCTION__);
Error error;
// Read hardware breakpoint and watchpoint information.
error = ReadHardwareDebugInfo ();
if (error.Fail())
return LLDB_INVALID_INDEX32;
uint32_t control_value = 0, wp_index = 0;
lldb::addr_t real_addr = addr;
// Check if we are setting watchpoint other than read/write/access
// Also update watchpoint flag to match AArch64 write-read bit configuration.
switch (watch_flags)
{
case 1:
watch_flags = 2;
break;
case 2:
watch_flags = 1;
break;
case 3:
break;
default:
return LLDB_INVALID_INDEX32;
}
// Check if size has a valid hardware watchpoint length.
if (size != 1 && size != 2 && size != 4 && size != 8)
return LLDB_INVALID_INDEX32;
// Check 8-byte alignment for hardware watchpoint target address.
// Below is a hack to recalculate address and size in order to
// make sure we can watch non 8-byte alligned addresses as well.
if (addr & 0x07)
{
uint8_t watch_mask = (addr & 0x07) + size;
if (watch_mask > 0x08)
return LLDB_INVALID_INDEX32;
else if (watch_mask <= 0x02)
size = 2;
else if (watch_mask <= 0x04)
size = 4;
else
size = 8;
addr = addr & (~0x07);
}
// Setup control value
control_value = watch_flags << 3;
control_value |= ((1 << size) - 1) << 5;
control_value |= (2 << 1) | 1;
// Iterate over stored watchpoints
// Find a free wp_index or update reference count if duplicate.
wp_index = LLDB_INVALID_INDEX32;
for (uint32_t i = 0; i < m_max_hwp_supported; i++)
{
if ((m_hwp_regs[i].control & 1) == 0)
{
wp_index = i; // Mark last free slot
}
else if (m_hwp_regs[i].address == addr && m_hwp_regs[i].control == control_value)
{
wp_index = i; // Mark duplicate index
break; // Stop searching here
}
}
if (wp_index == LLDB_INVALID_INDEX32)
return LLDB_INVALID_INDEX32;
// Add new or update existing watchpoint
if ((m_hwp_regs[wp_index].control & 1) == 0)
{
// Update watchpoint in local cache
m_hwp_regs[wp_index].real_addr = real_addr;
m_hwp_regs[wp_index].address = addr;
m_hwp_regs[wp_index].control = control_value;
m_hwp_regs[wp_index].refcount = 1;
// PTRACE call to set corresponding watchpoint register.
error = WriteHardwareDebugRegs(eDREGTypeWATCH);
if (error.Fail())
{
m_hwp_regs[wp_index].address = 0;
m_hwp_regs[wp_index].control &= ~1;
m_hwp_regs[wp_index].refcount = 0;
return LLDB_INVALID_INDEX32;
}
}
else
m_hwp_regs[wp_index].refcount++;
return wp_index;
}
bool
NativeRegisterContextLinux_arm64::ClearHardwareWatchpoint (uint32_t wp_index)
{
Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_WATCHPOINTS));
if (log)
log->Printf ("NativeRegisterContextLinux_arm64::%s()", __FUNCTION__);
Error error;
// Read hardware breakpoint and watchpoint information.
error = ReadHardwareDebugInfo ();
if (error.Fail())
return false;
if (wp_index >= m_max_hwp_supported)
return false;
// Update reference count if multiple references.
if (m_hwp_regs[wp_index].refcount > 1)
{
m_hwp_regs[wp_index].refcount--;
return true;
}
else if (m_hwp_regs[wp_index].refcount == 1)
{
// Create a backup we can revert to in case of failure.
lldb::addr_t tempAddr = m_hwp_regs[wp_index].address;
uint32_t tempControl = m_hwp_regs[wp_index].control;
uint32_t tempRefCount = m_hwp_regs[wp_index].refcount;
// Update watchpoint in local cache
m_hwp_regs[wp_index].control &= ~1;
m_hwp_regs[wp_index].address = 0;
m_hwp_regs[wp_index].refcount = 0;
// Ptrace call to update hardware debug registers
error = WriteHardwareDebugRegs(eDREGTypeWATCH);
if (error.Fail())
{
m_hwp_regs[wp_index].control = tempControl;
m_hwp_regs[wp_index].address = tempAddr;
m_hwp_regs[wp_index].refcount = tempRefCount;
return false;
}
return true;
}
return false;
}
Error
NativeRegisterContextLinux_arm64::ClearAllHardwareWatchpoints ()
{
Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_WATCHPOINTS));
if (log)
log->Printf ("NativeRegisterContextLinux_arm64::%s()", __FUNCTION__);
Error error;
// Read hardware breakpoint and watchpoint information.
error = ReadHardwareDebugInfo ();
if (error.Fail())
return error;
lldb::addr_t tempAddr = 0;
uint32_t tempControl = 0, tempRefCount = 0;
for (uint32_t i = 0; i < m_max_hwp_supported; i++)
{
if (m_hwp_regs[i].control & 0x01)
{
// Create a backup we can revert to in case of failure.
tempAddr = m_hwp_regs[i].address;
tempControl = m_hwp_regs[i].control;
tempRefCount = m_hwp_regs[i].refcount;
// Clear watchpoints in local cache
m_hwp_regs[i].control &= ~1;
m_hwp_regs[i].address = 0;
m_hwp_regs[i].refcount = 0;
// Ptrace call to update hardware debug registers
error = WriteHardwareDebugRegs(eDREGTypeWATCH);
if (error.Fail())
{
m_hwp_regs[i].control = tempControl;
m_hwp_regs[i].address = tempAddr;
m_hwp_regs[i].refcount = tempRefCount;
return error;
}
}
}
return Error();
}
uint32_t
NativeRegisterContextLinux_arm64::GetWatchpointSize(uint32_t wp_index)
{
Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_WATCHPOINTS));
if (log)
log->Printf ("NativeRegisterContextLinux_arm64::%s()", __FUNCTION__);
switch ((m_hwp_regs[wp_index].control >> 5) & 0xff)
{
case 0x01:
return 1;
case 0x03:
return 2;
case 0x0f:
return 4;
case 0xff:
return 8;
default:
return 0;
}
}
bool
NativeRegisterContextLinux_arm64::WatchpointIsEnabled(uint32_t wp_index)
{
Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_WATCHPOINTS));
if (log)
log->Printf ("NativeRegisterContextLinux_arm64::%s()", __FUNCTION__);
if ((m_hwp_regs[wp_index].control & 0x1) == 0x1)
return true;
else
return false;
}
Error
NativeRegisterContextLinux_arm64::GetWatchpointHitIndex(uint32_t &wp_index, lldb::addr_t trap_addr)
{
Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_WATCHPOINTS));
if (log)
log->Printf ("NativeRegisterContextLinux_arm64::%s()", __FUNCTION__);
uint32_t watch_size;
lldb::addr_t watch_addr;
for (wp_index = 0; wp_index < m_max_hwp_supported; ++wp_index)
{
watch_size = GetWatchpointSize (wp_index);
watch_addr = m_hwp_regs[wp_index].address;
if (m_hwp_regs[wp_index].refcount >= 1 && WatchpointIsEnabled(wp_index)
&& trap_addr >= watch_addr && trap_addr < watch_addr + watch_size)
{
m_hwp_regs[wp_index].hit_addr = trap_addr;
return Error();
}
}
wp_index = LLDB_INVALID_INDEX32;
return Error();
}
lldb::addr_t
NativeRegisterContextLinux_arm64::GetWatchpointAddress (uint32_t wp_index)
{
Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_WATCHPOINTS));
if (log)
log->Printf ("NativeRegisterContextLinux_arm64::%s()", __FUNCTION__);
if (wp_index >= m_max_hwp_supported)
return LLDB_INVALID_ADDRESS;
if (WatchpointIsEnabled(wp_index))
return m_hwp_regs[wp_index].real_addr;
else
return LLDB_INVALID_ADDRESS;
}
lldb::addr_t
NativeRegisterContextLinux_arm64::GetWatchpointHitAddress (uint32_t wp_index)
{
Log *log(lldb_private::GetLogIfAllCategoriesSet (LIBLLDB_LOG_WATCHPOINTS));
if (log)
log->Printf ("NativeRegisterContextLinux_arm64::%s()", __FUNCTION__);
if (wp_index >= m_max_hwp_supported)
return LLDB_INVALID_ADDRESS;
if (WatchpointIsEnabled(wp_index))
return m_hwp_regs[wp_index].hit_addr;
else
return LLDB_INVALID_ADDRESS;
}
Error
NativeRegisterContextLinux_arm64::ReadHardwareDebugInfo()
{
if (!m_refresh_hwdebug_info)
{
return Error();
}
::pid_t tid = m_thread.GetID();
int regset = NT_ARM_HW_WATCH;
struct iovec ioVec;
struct user_hwdebug_state dreg_state;
Error error;
ioVec.iov_base = &dreg_state;
ioVec.iov_len = sizeof (dreg_state);
error = NativeProcessLinux::PtraceWrapper(PTRACE_GETREGSET, tid, &regset, &ioVec, ioVec.iov_len);
if (error.Fail())
return error;
m_max_hwp_supported = dreg_state.dbg_info & 0xff;
regset = NT_ARM_HW_BREAK;
error = NativeProcessLinux::PtraceWrapper(PTRACE_GETREGSET, tid, &regset, &ioVec, ioVec.iov_len);
if (error.Fail())
return error;
m_max_hbp_supported = dreg_state.dbg_info & 0xff;
m_refresh_hwdebug_info = false;
return error;
}
Error
NativeRegisterContextLinux_arm64::WriteHardwareDebugRegs(int hwbType)
{
struct iovec ioVec;
struct user_hwdebug_state dreg_state;
Error error;
memset (&dreg_state, 0, sizeof (dreg_state));
ioVec.iov_base = &dreg_state;
if (hwbType == eDREGTypeWATCH)
{
hwbType = NT_ARM_HW_WATCH;
ioVec.iov_len = sizeof (dreg_state.dbg_info) + sizeof (dreg_state.pad)
+ (sizeof (dreg_state.dbg_regs [0]) * m_max_hwp_supported);
for (uint32_t i = 0; i < m_max_hwp_supported; i++)
{
dreg_state.dbg_regs[i].addr = m_hwp_regs[i].address;
dreg_state.dbg_regs[i].ctrl = m_hwp_regs[i].control;
}
}
else
{
hwbType = NT_ARM_HW_BREAK;
ioVec.iov_len = sizeof (dreg_state.dbg_info) + sizeof (dreg_state.pad)
+ (sizeof (dreg_state.dbg_regs [0]) * m_max_hbp_supported);
for (uint32_t i = 0; i < m_max_hbp_supported; i++)
{
dreg_state.dbg_regs[i].addr = m_hbr_regs[i].address;
dreg_state.dbg_regs[i].ctrl = m_hbr_regs[i].control;
}
}
return NativeProcessLinux::PtraceWrapper(PTRACE_SETREGSET, m_thread.GetID(), &hwbType, &ioVec, ioVec.iov_len);
}
Error
NativeRegisterContextLinux_arm64::DoReadRegisterValue(uint32_t offset,
const char* reg_name,
uint32_t size,
RegisterValue &value)
{
Error error;
if (offset > sizeof(struct user_pt_regs))
{
uintptr_t offset = offset - sizeof(struct user_pt_regs);
if (offset > sizeof(struct user_fpsimd_state))
{
error.SetErrorString("invalid offset value");
return error;
}
elf_fpregset_t regs;
int regset = NT_FPREGSET;
struct iovec ioVec;
ioVec.iov_base = &regs;
ioVec.iov_len = sizeof regs;
error = NativeProcessLinux::PtraceWrapper(
PTRACE_GETREGSET, m_thread.GetID(), &regset, &ioVec, sizeof regs);
if (error.Success())
{
ArchSpec arch;
if (m_thread.GetProcess()->GetArchitecture(arch))
value.SetBytes((void *)(((unsigned char *)(&regs)) + offset), 16, arch.GetByteOrder());
else
error.SetErrorString("failed to get architecture");
}
}
else
{
elf_gregset_t regs;
int regset = NT_PRSTATUS;
struct iovec ioVec;
ioVec.iov_base = &regs;
ioVec.iov_len = sizeof regs;
error = NativeProcessLinux::PtraceWrapper(
PTRACE_GETREGSET, m_thread.GetID(), &regset, &ioVec, sizeof regs);
if (error.Success())
{
ArchSpec arch;
if (m_thread.GetProcess()->GetArchitecture(arch))
value.SetBytes((void *)(((unsigned char *)(regs)) + offset), 8, arch.GetByteOrder());
else
error.SetErrorString("failed to get architecture");
}
}
return error;
}
Error
NativeRegisterContextLinux_arm64::DoWriteRegisterValue(uint32_t offset,
const char* reg_name,
const RegisterValue &value)
{
Error error;
::pid_t tid = m_thread.GetID();
if (offset > sizeof(struct user_pt_regs))
{
uintptr_t offset = offset - sizeof(struct user_pt_regs);
if (offset > sizeof(struct user_fpsimd_state))
{
error.SetErrorString("invalid offset value");
return error;
}
elf_fpregset_t regs;
int regset = NT_FPREGSET;
struct iovec ioVec;
ioVec.iov_base = &regs;
ioVec.iov_len = sizeof regs;
error = NativeProcessLinux::PtraceWrapper( PTRACE_GETREGSET, tid, &regset, &ioVec, sizeof regs);
if (error.Success())
{
::memcpy((void *)(((unsigned char *)(&regs)) + offset), value.GetBytes(), 16);
error = NativeProcessLinux::PtraceWrapper(PTRACE_SETREGSET, tid, &regset, &ioVec, sizeof regs);
}
}
else
{
elf_gregset_t regs;
int regset = NT_PRSTATUS;
struct iovec ioVec;
ioVec.iov_base = &regs;
ioVec.iov_len = sizeof regs;
error = NativeProcessLinux::PtraceWrapper(PTRACE_GETREGSET, tid, &regset, &ioVec, sizeof regs);
if (error.Success())
{
::memcpy((void *)(((unsigned char *)(&regs)) + offset), value.GetBytes(), 8);
error = NativeProcessLinux::PtraceWrapper(PTRACE_SETREGSET, tid, &regset, &ioVec, sizeof regs);
}
}
return error;
}
Error
NativeRegisterContextLinux_arm64::DoReadGPR(void *buf, size_t buf_size)
{
int regset = NT_PRSTATUS;
struct iovec ioVec;
Error error;
ioVec.iov_base = buf;
ioVec.iov_len = buf_size;
return NativeProcessLinux::PtraceWrapper(PTRACE_GETREGSET, m_thread.GetID(), &regset, &ioVec, buf_size);
}
Error
NativeRegisterContextLinux_arm64::DoWriteGPR(void *buf, size_t buf_size)
{
int regset = NT_PRSTATUS;
struct iovec ioVec;
Error error;
ioVec.iov_base = buf;
ioVec.iov_len = buf_size;
return NativeProcessLinux::PtraceWrapper(PTRACE_SETREGSET, m_thread.GetID(), &regset, &ioVec, buf_size);
}
Error
NativeRegisterContextLinux_arm64::DoReadFPR(void *buf, size_t buf_size)
{
int regset = NT_FPREGSET;
struct iovec ioVec;
Error error;
ioVec.iov_base = buf;
ioVec.iov_len = buf_size;
return NativeProcessLinux::PtraceWrapper(PTRACE_GETREGSET, m_thread.GetID(), &regset, &ioVec, buf_size);
}
Error
NativeRegisterContextLinux_arm64::DoWriteFPR(void *buf, size_t buf_size)
{
int regset = NT_FPREGSET;
struct iovec ioVec;
Error error;
ioVec.iov_base = buf;
ioVec.iov_len = buf_size;
return NativeProcessLinux::PtraceWrapper(PTRACE_SETREGSET, m_thread.GetID(), &regset, &ioVec, buf_size);
}
uint32_t
NativeRegisterContextLinux_arm64::CalculateFprOffset(const RegisterInfo* reg_info) const
{
return reg_info->byte_offset - GetRegisterInfoAtIndex(m_reg_info.first_fpr)->byte_offset;
}
#endif // defined (__arm64__) || defined (__aarch64__)
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