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llvm-project/lldb/source/Plugins/Process/Linux/NativeRegisterContextLinux_arm64.cpp
David Spickett d99d9d8b74 [lldb][AArch64] Add SME's Array Storage (ZA) register 
Note: This requires later commits for ZA to function properly,
it is split for ease of review. Testing is also in a later patch.

The "Matrix" part of the Scalable Matrix Extension is a new register
"ZA". You can think of this as a square matrix made up of scalable rows,
where each row is one scalable vector long. However it is not made
of the existing scalable vector registers, it is its own register.
Meaning that the size of ZA is the vector length in bytes * the vector
length in bytes.

https://developer.arm.com/documentation/ddi0616/latest/

It uses the streaming vector length, even when streaming mode itself
is not active. For this reason, it's register data header always
includes the streaming vector length.

Due to it's size I've changed kMaxRegisterByteSize to the maximum
possible ZA size and kTypicalRegisterByteSize will be the maximum
possible scalable vector size. Therefore ZA transactions will cause heap
allocations, and non ZA registers will perform exactly as before.

ZA can be enabled and disabled independently of streaming mode. The way
this works in ptrace is different to SVE versus streaming SVE. Writing
NT_ARM_ZA without register data disables ZA, writing NT_ARM_ZA with
register data enables ZA (LLDB will only support the latter, and only
because it's convenient for us to do so).

https://kernel.org/doc/html/v6.2/arm64/sme.html

LLDB does not handle registers that can appear and dissappear at
runtime. Rather than add complexity to implement that, LLDB will
show a block of 0s when ZA is disabled.

The alternative is not only updating the vector lengths every stop,
but every register definition. It's possible but I'm not sure it's worth
pursuing.

Users should refer to the SVCR register (added in later patches)
for the final word on whether ZA is active or not.

Writing to "VG" during streaming mode will change the size of the
streaming sve registers and ZA. LLDB will not attempt to preserve
register values in this case, we'll just read back the undefined
content the kernel shows. This is in line with, as stated, the
kernel ABIs and the prospective software ABIs look like.

ZA is defined as a vector of size SVL*SVL, so the display in lldb
is very basic. A giant block of values. This is no worse than SVE,
just larger. There is scope to improve this but that can wait
until we see some use cases.

Reviewed By: omjavaid

Differential Revision: https://reviews.llvm.org/D159502
2023-09-19 10:49:57 +00:00

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//===-- NativeRegisterContextLinux_arm64.cpp ------------------------------===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
#if defined(__arm64__) || defined(__aarch64__)
#include "NativeRegisterContextLinux_arm.h"
#include "NativeRegisterContextLinux_arm64.h"
#include "lldb/Host/HostInfo.h"
#include "lldb/Host/common/NativeProcessProtocol.h"
#include "lldb/Host/linux/Ptrace.h"
#include "lldb/Utility/DataBufferHeap.h"
#include "lldb/Utility/Log.h"
#include "lldb/Utility/RegisterValue.h"
#include "lldb/Utility/Status.h"
#include "Plugins/Process/Linux/NativeProcessLinux.h"
#include "Plugins/Process/Linux/Procfs.h"
#include "Plugins/Process/POSIX/ProcessPOSIXLog.h"
#include "Plugins/Process/Utility/MemoryTagManagerAArch64MTE.h"
#include "Plugins/Process/Utility/RegisterInfoPOSIX_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/uio.h>
// NT_PRSTATUS and NT_FPREGSET definition
#include <elf.h>
#include <optional>
#ifndef NT_ARM_SVE
#define NT_ARM_SVE 0x405 /* ARM Scalable Vector Extension */
#endif
#ifndef NT_ARM_SSVE
#define NT_ARM_SSVE \
0x40b /* ARM Scalable Matrix Extension, Streaming SVE mode */
#endif
#ifndef NT_ARM_ZA
#define NT_ARM_ZA 0x40c /* ARM Scalable Matrix Extension, Array Storage */
#endif
#ifndef NT_ARM_PAC_MASK
#define NT_ARM_PAC_MASK 0x406 /* Pointer authentication code masks */
#endif
#ifndef NT_ARM_TAGGED_ADDR_CTRL
#define NT_ARM_TAGGED_ADDR_CTRL 0x409 /* Tagged address control register */
#endif
#define HWCAP_PACA (1 << 30)
#define HWCAP2_MTE (1 << 18)
using namespace lldb;
using namespace lldb_private;
using namespace lldb_private::process_linux;
std::unique_ptr<NativeRegisterContextLinux>
NativeRegisterContextLinux::CreateHostNativeRegisterContextLinux(
const ArchSpec &target_arch, NativeThreadLinux &native_thread) {
switch (target_arch.GetMachine()) {
case llvm::Triple::arm:
return std::make_unique<NativeRegisterContextLinux_arm>(target_arch,
native_thread);
case llvm::Triple::aarch64: {
// Configure register sets supported by this AArch64 target.
// Read SVE header to check for SVE support.
struct sve::user_sve_header sve_header;
struct iovec ioVec;
ioVec.iov_base = &sve_header;
ioVec.iov_len = sizeof(sve_header);
unsigned int regset = NT_ARM_SVE;
Flags opt_regsets;
if (NativeProcessLinux::PtraceWrapper(PTRACE_GETREGSET,
native_thread.GetID(), &regset,
&ioVec, sizeof(sve_header))
.Success()) {
opt_regsets.Set(RegisterInfoPOSIX_arm64::eRegsetMaskSVE);
// We may also have the Scalable Matrix Extension (SME) which adds a
// streaming SVE mode.
ioVec.iov_len = sizeof(sve_header);
regset = NT_ARM_SSVE;
if (NativeProcessLinux::PtraceWrapper(PTRACE_GETREGSET,
native_thread.GetID(), &regset,
&ioVec, sizeof(sve_header))
.Success())
opt_regsets.Set(RegisterInfoPOSIX_arm64::eRegsetMaskSSVE);
}
sve::user_za_header za_header;
ioVec.iov_base = &za_header;
ioVec.iov_len = sizeof(za_header);
regset = NT_ARM_ZA;
if (NativeProcessLinux::PtraceWrapper(PTRACE_GETREGSET,
native_thread.GetID(), &regset,
&ioVec, sizeof(za_header))
.Success())
opt_regsets.Set(RegisterInfoPOSIX_arm64::eRegsetMaskZA);
NativeProcessLinux &process = native_thread.GetProcess();
std::optional<uint64_t> auxv_at_hwcap =
process.GetAuxValue(AuxVector::AUXV_AT_HWCAP);
if (auxv_at_hwcap && (*auxv_at_hwcap & HWCAP_PACA))
opt_regsets.Set(RegisterInfoPOSIX_arm64::eRegsetMaskPAuth);
std::optional<uint64_t> auxv_at_hwcap2 =
process.GetAuxValue(AuxVector::AUXV_AT_HWCAP2);
if (auxv_at_hwcap2 && (*auxv_at_hwcap2 & HWCAP2_MTE))
opt_regsets.Set(RegisterInfoPOSIX_arm64::eRegsetMaskMTE);
opt_regsets.Set(RegisterInfoPOSIX_arm64::eRegsetMaskTLS);
auto register_info_up =
std::make_unique<RegisterInfoPOSIX_arm64>(target_arch, opt_regsets);
return std::make_unique<NativeRegisterContextLinux_arm64>(
target_arch, native_thread, std::move(register_info_up));
}
default:
llvm_unreachable("have no register context for architecture");
}
}
llvm::Expected<ArchSpec>
NativeRegisterContextLinux::DetermineArchitecture(lldb::tid_t tid) {
return DetermineArchitectureViaGPR(
tid, RegisterInfoPOSIX_arm64::GetGPRSizeStatic());
}
NativeRegisterContextLinux_arm64::NativeRegisterContextLinux_arm64(
const ArchSpec &target_arch, NativeThreadProtocol &native_thread,
std::unique_ptr<RegisterInfoPOSIX_arm64> register_info_up)
: NativeRegisterContextRegisterInfo(native_thread,
register_info_up.release()),
NativeRegisterContextLinux(native_thread) {
::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));
::memset(&m_hbp_regs, 0, sizeof(m_hbp_regs));
::memset(&m_sve_header, 0, sizeof(m_sve_header));
::memset(&m_pac_mask, 0, sizeof(m_pac_mask));
::memset(&m_tls_regs, 0, sizeof(m_tls_regs));
m_mte_ctrl_reg = 0;
// 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;
m_gpr_is_valid = false;
m_fpu_is_valid = false;
m_sve_buffer_is_valid = false;
m_sve_header_is_valid = false;
m_pac_mask_is_valid = false;
m_mte_ctrl_is_valid = false;
m_tls_is_valid = false;
// SME adds the tpidr2 register
m_tls_size = GetRegisterInfo().IsSSVEEnabled() ? sizeof(m_tls_regs)
: sizeof(m_tls_regs.tpidr_reg);
if (GetRegisterInfo().IsSVEEnabled() || GetRegisterInfo().IsSSVEEnabled())
m_sve_state = SVEState::Unknown;
else
m_sve_state = SVEState::Disabled;
}
RegisterInfoPOSIX_arm64 &
NativeRegisterContextLinux_arm64::GetRegisterInfo() const {
return static_cast<RegisterInfoPOSIX_arm64 &>(*m_register_info_interface_up);
}
uint32_t NativeRegisterContextLinux_arm64::GetRegisterSetCount() const {
return GetRegisterInfo().GetRegisterSetCount();
}
const RegisterSet *
NativeRegisterContextLinux_arm64::GetRegisterSet(uint32_t set_index) const {
return GetRegisterInfo().GetRegisterSet(set_index);
}
uint32_t NativeRegisterContextLinux_arm64::GetUserRegisterCount() const {
uint32_t count = 0;
for (uint32_t set_index = 0; set_index < GetRegisterSetCount(); ++set_index)
count += GetRegisterSet(set_index)->num_registers;
return count;
}
Status
NativeRegisterContextLinux_arm64::ReadRegister(const RegisterInfo *reg_info,
RegisterValue &reg_value) {
Status error;
if (!reg_info) {
error.SetErrorString("reg_info NULL");
return error;
}
const uint32_t reg = reg_info->kinds[lldb::eRegisterKindLLDB];
if (reg == LLDB_INVALID_REGNUM)
return Status("no lldb regnum for %s", reg_info && reg_info->name
? reg_info->name
: "<unknown register>");
uint8_t *src;
uint32_t offset = LLDB_INVALID_INDEX32;
uint64_t sve_vg;
std::vector<uint8_t> sve_reg_non_live;
if (IsGPR(reg)) {
error = ReadGPR();
if (error.Fail())
return error;
offset = reg_info->byte_offset;
assert(offset < GetGPRSize());
src = (uint8_t *)GetGPRBuffer() + offset;
} else if (IsFPR(reg)) {
if (m_sve_state == SVEState::Disabled) {
// SVE is disabled take legacy route for FPU register access
error = ReadFPR();
if (error.Fail())
return error;
offset = CalculateFprOffset(reg_info);
assert(offset < GetFPRSize());
src = (uint8_t *)GetFPRBuffer() + offset;
} else {
// SVE or SSVE enabled, we will read and cache SVE ptrace data.
// In SIMD or Full mode, the data comes from the SVE regset. In streaming
// mode it comes from the streaming SVE regset.
error = ReadAllSVE();
if (error.Fail())
return error;
// FPSR and FPCR will be located right after Z registers in
// SVEState::FPSIMD while in SVEState::Full or SVEState::Streaming they
// will be located at the end of register data after an alignment
// correction based on currently selected vector length.
uint32_t sve_reg_num = LLDB_INVALID_REGNUM;
if (reg == GetRegisterInfo().GetRegNumFPSR()) {
sve_reg_num = reg;
if (m_sve_state == SVEState::Full || m_sve_state == SVEState::Streaming)
offset = sve::PTraceFPSROffset(sve::vq_from_vl(m_sve_header.vl));
else if (m_sve_state == SVEState::FPSIMD)
offset = sve::ptrace_fpsimd_offset + (32 * 16);
} else if (reg == GetRegisterInfo().GetRegNumFPCR()) {
sve_reg_num = reg;
if (m_sve_state == SVEState::Full || m_sve_state == SVEState::Streaming)
offset = sve::PTraceFPCROffset(sve::vq_from_vl(m_sve_header.vl));
else if (m_sve_state == SVEState::FPSIMD)
offset = sve::ptrace_fpsimd_offset + (32 * 16) + 4;
} else {
// Extract SVE Z register value register number for this reg_info
if (reg_info->value_regs &&
reg_info->value_regs[0] != LLDB_INVALID_REGNUM)
sve_reg_num = reg_info->value_regs[0];
offset = CalculateSVEOffset(GetRegisterInfoAtIndex(sve_reg_num));
}
assert(offset < GetSVEBufferSize());
src = (uint8_t *)GetSVEBuffer() + offset;
}
} else if (IsTLS(reg)) {
error = ReadTLS();
if (error.Fail())
return error;
offset = reg_info->byte_offset - GetRegisterInfo().GetTLSOffset();
assert(offset < GetTLSBufferSize());
src = (uint8_t *)GetTLSBuffer() + offset;
} else if (IsSVE(reg)) {
if (m_sve_state == SVEState::Disabled || m_sve_state == SVEState::Unknown)
return Status("SVE disabled or not supported");
if (GetRegisterInfo().IsSVERegVG(reg)) {
sve_vg = GetSVERegVG();
src = (uint8_t *)&sve_vg;
} else {
// SVE enabled, we will read and cache SVE ptrace data
error = ReadAllSVE();
if (error.Fail())
return error;
if (m_sve_state == SVEState::FPSIMD) {
// In FPSIMD state SVE payload mirrors legacy fpsimd struct and so
// just copy 16 bytes of v register to the start of z register. All
// other SVE register will be set to zero.
sve_reg_non_live.resize(reg_info->byte_size, 0);
src = sve_reg_non_live.data();
if (GetRegisterInfo().IsSVEZReg(reg)) {
offset = CalculateSVEOffset(reg_info);
assert(offset < GetSVEBufferSize());
::memcpy(sve_reg_non_live.data(), (uint8_t *)GetSVEBuffer() + offset,
16);
}
} else {
offset = CalculateSVEOffset(reg_info);
assert(offset < GetSVEBufferSize());
src = (uint8_t *)GetSVEBuffer() + offset;
}
}
} else if (IsPAuth(reg)) {
error = ReadPAuthMask();
if (error.Fail())
return error;
offset = reg_info->byte_offset - GetRegisterInfo().GetPAuthOffset();
assert(offset < GetPACMaskSize());
src = (uint8_t *)GetPACMask() + offset;
} else if (IsMTE(reg)) {
error = ReadMTEControl();
if (error.Fail())
return error;
offset = reg_info->byte_offset - GetRegisterInfo().GetMTEOffset();
assert(offset < GetMTEControlSize());
src = (uint8_t *)GetMTEControl() + offset;
} else if (IsSME(reg)) {
error = ReadZAHeader();
if (error.Fail())
return error;
// If there is only a header and no registers, ZA is inactive. Read as 0
// in this case.
if (m_za_header.size == sizeof(m_za_header)) {
// This will get reconfigured/reset later, so we are safe to use it.
// ZA is a square of VL * VL and the ptrace buffer also includes the
// header itself.
m_za_ptrace_payload.resize(((m_za_header.vl) * (m_za_header.vl)) +
GetZAHeaderSize());
std::fill(m_za_ptrace_payload.begin(), m_za_ptrace_payload.end(), 0);
} else {
// ZA is active, read the real register.
error = ReadZA();
if (error.Fail())
return error;
}
// ZA is part of the SME set but uses a seperate member buffer for storage.
// Therefore its effective byte offset is always 0 even if it isn't 0 within
// the SME register set.
src = (uint8_t *)GetZABuffer() + GetZAHeaderSize();
} else
return Status("failed - register wasn't recognized to be a GPR or an FPR, "
"write strategy unknown");
reg_value.SetFromMemoryData(*reg_info, src, reg_info->byte_size,
eByteOrderLittle, error);
return error;
}
Status NativeRegisterContextLinux_arm64::WriteRegister(
const RegisterInfo *reg_info, const RegisterValue &reg_value) {
Status error;
if (!reg_info)
return Status("reg_info NULL");
const uint32_t reg = reg_info->kinds[lldb::eRegisterKindLLDB];
if (reg == LLDB_INVALID_REGNUM)
return Status("no lldb regnum for %s", reg_info && reg_info->name
? reg_info->name
: "<unknown register>");
uint8_t *dst;
uint32_t offset = LLDB_INVALID_INDEX32;
std::vector<uint8_t> sve_reg_non_live;
if (IsGPR(reg)) {
error = ReadGPR();
if (error.Fail())
return error;
assert(reg_info->byte_offset < GetGPRSize());
dst = (uint8_t *)GetGPRBuffer() + reg_info->byte_offset;
::memcpy(dst, reg_value.GetBytes(), reg_info->byte_size);
return WriteGPR();
} else if (IsFPR(reg)) {
if (m_sve_state == SVEState::Disabled) {
// SVE is disabled take legacy route for FPU register access
error = ReadFPR();
if (error.Fail())
return error;
offset = CalculateFprOffset(reg_info);
assert(offset < GetFPRSize());
dst = (uint8_t *)GetFPRBuffer() + offset;
::memcpy(dst, reg_value.GetBytes(), reg_info->byte_size);
return WriteFPR();
} else {
// SVE enabled, we will read and cache SVE ptrace data.
error = ReadAllSVE();
if (error.Fail())
return error;
// FPSR and FPCR will be located right after Z registers in
// SVEState::FPSIMD while in SVEState::Full or SVEState::Streaming they
// will be located at the end of register data after an alignment
// correction based on currently selected vector length.
uint32_t sve_reg_num = LLDB_INVALID_REGNUM;
if (reg == GetRegisterInfo().GetRegNumFPSR()) {
sve_reg_num = reg;
if (m_sve_state == SVEState::Full || m_sve_state == SVEState::Streaming)
offset = sve::PTraceFPSROffset(sve::vq_from_vl(m_sve_header.vl));
else if (m_sve_state == SVEState::FPSIMD)
offset = sve::ptrace_fpsimd_offset + (32 * 16);
} else if (reg == GetRegisterInfo().GetRegNumFPCR()) {
sve_reg_num = reg;
if (m_sve_state == SVEState::Full || m_sve_state == SVEState::Streaming)
offset = sve::PTraceFPCROffset(sve::vq_from_vl(m_sve_header.vl));
else if (m_sve_state == SVEState::FPSIMD)
offset = sve::ptrace_fpsimd_offset + (32 * 16) + 4;
} else {
// Extract SVE Z register value register number for this reg_info
if (reg_info->value_regs &&
reg_info->value_regs[0] != LLDB_INVALID_REGNUM)
sve_reg_num = reg_info->value_regs[0];
offset = CalculateSVEOffset(GetRegisterInfoAtIndex(sve_reg_num));
}
assert(offset < GetSVEBufferSize());
dst = (uint8_t *)GetSVEBuffer() + offset;
::memcpy(dst, reg_value.GetBytes(), reg_info->byte_size);
return WriteAllSVE();
}
} else if (IsSVE(reg)) {
if (m_sve_state == SVEState::Disabled || m_sve_state == SVEState::Unknown)
return Status("SVE disabled or not supported");
else {
// Target has SVE enabled, we will read and cache SVE ptrace data
error = ReadAllSVE();
if (error.Fail())
return error;
if (GetRegisterInfo().IsSVERegVG(reg)) {
uint64_t vg_value = reg_value.GetAsUInt64();
if (sve::vl_valid(vg_value * 8)) {
if (m_sve_header_is_valid && vg_value == GetSVERegVG())
return error;
SetSVERegVG(vg_value);
error = WriteSVEHeader();
if (error.Success()) {
// Changing VG during streaming mode also changes the size of ZA.
if (m_sve_state == SVEState::Streaming)
m_za_header_is_valid = false;
ConfigureRegisterContext();
}
if (m_sve_header_is_valid && vg_value == GetSVERegVG())
return error;
}
return Status("SVE vector length update failed.");
}
// If target supports SVE but currently in FPSIMD mode.
if (m_sve_state == SVEState::FPSIMD) {
// Here we will check if writing this SVE register enables
// SVEState::Full
bool set_sve_state_full = false;
const uint8_t *reg_bytes = (const uint8_t *)reg_value.GetBytes();
if (GetRegisterInfo().IsSVEZReg(reg)) {
for (uint32_t i = 16; i < reg_info->byte_size; i++) {
if (reg_bytes[i]) {
set_sve_state_full = true;
break;
}
}
} else if (GetRegisterInfo().IsSVEPReg(reg) ||
reg == GetRegisterInfo().GetRegNumSVEFFR()) {
for (uint32_t i = 0; i < reg_info->byte_size; i++) {
if (reg_bytes[i]) {
set_sve_state_full = true;
break;
}
}
}
if (!set_sve_state_full && GetRegisterInfo().IsSVEZReg(reg)) {
// We are writing a Z register which is zero beyond 16 bytes so copy
// first 16 bytes only as SVE payload mirrors legacy fpsimd structure
offset = CalculateSVEOffset(reg_info);
assert(offset < GetSVEBufferSize());
dst = (uint8_t *)GetSVEBuffer() + offset;
::memcpy(dst, reg_value.GetBytes(), 16);
return WriteAllSVE();
} else
return Status("SVE state change operation not supported");
} else {
offset = CalculateSVEOffset(reg_info);
assert(offset < GetSVEBufferSize());
dst = (uint8_t *)GetSVEBuffer() + offset;
::memcpy(dst, reg_value.GetBytes(), reg_info->byte_size);
return WriteAllSVE();
}
}
} else if (IsMTE(reg)) {
error = ReadMTEControl();
if (error.Fail())
return error;
offset = reg_info->byte_offset - GetRegisterInfo().GetMTEOffset();
assert(offset < GetMTEControlSize());
dst = (uint8_t *)GetMTEControl() + offset;
::memcpy(dst, reg_value.GetBytes(), reg_info->byte_size);
return WriteMTEControl();
} else if (IsTLS(reg)) {
error = ReadTLS();
if (error.Fail())
return error;
offset = reg_info->byte_offset - GetRegisterInfo().GetTLSOffset();
assert(offset < GetTLSBufferSize());
dst = (uint8_t *)GetTLSBuffer() + offset;
::memcpy(dst, reg_value.GetBytes(), reg_info->byte_size);
return WriteTLS();
} else if (IsSME(reg)) {
error = ReadZA();
if (error.Fail())
return error;
// ZA is part of the SME set but not stored with the other SME registers.
// So its byte offset is effectively always 0.
dst = (uint8_t *)GetZABuffer() + GetZAHeaderSize();
::memcpy(dst, reg_value.GetBytes(), reg_info->byte_size);
// While this is writing a header that contains a vector length, the only
// way to change that is via the vg register. So here we assume the length
// will always be the current length and no reconfigure is needed.
return WriteZA();
}
return Status("Failed to write register value");
}
enum RegisterSetType : uint32_t {
GPR,
SVE, // Used for SVE and SSVE.
FPR, // When there is no SVE, or SVE in FPSIMD mode.
// Pointer authentication registers are read only, so not included here.
MTE,
TLS,
SME, // ZA only, SVCR and SVG are pseudo registers.
};
static uint8_t *AddRegisterSetType(uint8_t *dst,
RegisterSetType register_set_type) {
*(reinterpret_cast<uint32_t *>(dst)) = register_set_type;
return dst + sizeof(uint32_t);
}
static uint8_t *AddSavedRegistersData(uint8_t *dst, void *src, size_t size) {
::memcpy(dst, src, size);
return dst + size;
}
static uint8_t *AddSavedRegisters(uint8_t *dst,
enum RegisterSetType register_set_type,
void *src, size_t size) {
dst = AddRegisterSetType(dst, register_set_type);
return AddSavedRegistersData(dst, src, size);
}
Status
NativeRegisterContextLinux_arm64::CacheAllRegisters(uint32_t &cached_size) {
Status error;
cached_size = sizeof(RegisterSetType) + GetGPRBufferSize();
error = ReadGPR();
if (error.Fail())
return error;
// Here this means, does the system have ZA, not whether it is active.
if (GetRegisterInfo().IsZAEnabled()) {
error = ReadZAHeader();
if (error.Fail())
return error;
// Use header size here because the buffer may contain fake data when ZA is
// disabled. We do not want to write this fake data (all 0s) because this
// would tell the kernel that we want ZA to become active. Which is the
// opposite of what we want in the case where it is currently inactive.
cached_size += sizeof(RegisterSetType) + m_za_header.size;
// For the same reason, we need to force it to be re-read so that it will
// always contain the real header.
m_za_buffer_is_valid = false;
error = ReadZA();
if (error.Fail())
return error;
}
// If SVE is enabled we need not copy FPR separately.
if (GetRegisterInfo().IsSVEEnabled() || GetRegisterInfo().IsSSVEEnabled()) {
// Store mode and register data.
cached_size +=
sizeof(RegisterSetType) + sizeof(m_sve_state) + GetSVEBufferSize();
error = ReadAllSVE();
} else {
cached_size += sizeof(RegisterSetType) + GetFPRSize();
error = ReadFPR();
}
if (error.Fail())
return error;
if (GetRegisterInfo().IsMTEEnabled()) {
cached_size += sizeof(RegisterSetType) + GetMTEControlSize();
error = ReadMTEControl();
if (error.Fail())
return error;
}
// tpidr is always present but tpidr2 depends on SME.
cached_size += sizeof(RegisterSetType) + GetTLSBufferSize();
error = ReadTLS();
return error;
}
Status NativeRegisterContextLinux_arm64::ReadAllRegisterValues(
lldb::WritableDataBufferSP &data_sp) {
// AArch64 register data must contain GPRs and either FPR or SVE registers.
// SVE registers can be non-streaming (aka SVE) or streaming (aka SSVE).
// Finally an optional MTE register. Pointer Authentication (PAC) registers
// are read-only and will be skipped.
// In order to create register data checkpoint we first read all register
// values if not done already and calculate total size of register set data.
// We store all register values in data_sp by copying full PTrace data that
// corresponds to register sets enabled by current register context.
uint32_t reg_data_byte_size = 0;
Status error = CacheAllRegisters(reg_data_byte_size);
if (error.Fail())
return error;
data_sp.reset(new DataBufferHeap(reg_data_byte_size, 0));
uint8_t *dst = data_sp->GetBytes();
dst = AddSavedRegisters(dst, RegisterSetType::GPR, GetGPRBuffer(),
GetGPRBufferSize());
// Streaming SVE and the ZA register both use the streaming vector length.
// When you change this, the kernel will invalidate parts of the process
// state. Therefore we need a specific order of restoration for each mode, if
// we also have ZA to restore.
//
// Streaming mode enabled, ZA enabled:
// * Write streaming registers. This sets SVCR.SM and clears SVCR.ZA.
// * Write ZA, this set SVCR.ZA. The register data we provide is written to
// ZA.
// * Result is SVCR.SM and SVCR.ZA set, with the expected data in both
// register sets.
//
// Streaming mode disabled, ZA enabled:
// * Write ZA. This sets SVCR.ZA, and the ZA content. In the majority of cases
// the streaming vector length is changing, so the thread is converted into
// an FPSIMD thread if it is not already one. This also clears SVCR.SM.
// * Write SVE registers, which also clears SVCR.SM but most importantly, puts
// us into full SVE mode instead of FPSIMD mode (where the registers are
// actually the 128 bit Neon registers).
// * Result is we have SVCR.SM = 0, SVCR.ZA = 1 and the expected register
// state.
//
// Restoring in different orders leads to things like the SVE registers being
// truncated due to the FPSIMD mode and ZA being disabled or filled with 0s
// (disabled and 0s looks the same from inside lldb since we fake the value
// when it's disabled).
//
// For more information on this, look up the uses of the relevant NT_ARM_
// constants and the functions vec_set_vector_length, sve_set_common and
// za_set in the Linux Kernel.
if ((m_sve_state != SVEState::Streaming) && GetRegisterInfo().IsZAEnabled()) {
// Use the header size not the buffer size, as we may be using the buffer
// for fake data, which we do not want to write out.
assert(m_za_header.size <= GetZABufferSize());
dst = AddSavedRegisters(dst, RegisterSetType::SME, GetZABuffer(),
m_za_header.size);
}
if (GetRegisterInfo().IsSVEEnabled() || GetRegisterInfo().IsSSVEEnabled()) {
dst = AddRegisterSetType(dst, RegisterSetType::SVE);
*(reinterpret_cast<SVEState *>(dst)) = m_sve_state;
dst += sizeof(m_sve_state);
dst = AddSavedRegistersData(dst, GetSVEBuffer(), GetSVEBufferSize());
} else {
dst = AddSavedRegisters(dst, RegisterSetType::FPR, GetFPRBuffer(),
GetFPRSize());
}
if ((m_sve_state == SVEState::Streaming) && GetRegisterInfo().IsZAEnabled()) {
assert(m_za_header.size <= GetZABufferSize());
dst = AddSavedRegisters(dst, RegisterSetType::SME, GetZABuffer(),
m_za_header.size);
}
if (GetRegisterInfo().IsMTEEnabled()) {
dst = AddSavedRegisters(dst, RegisterSetType::MTE, GetMTEControl(),
GetMTEControlSize());
}
dst = AddSavedRegisters(dst, RegisterSetType::TLS, GetTLSBuffer(),
GetTLSBufferSize());
return error;
}
static Status RestoreRegisters(void *buffer, const uint8_t **src, size_t len,
bool &is_valid, std::function<Status()> writer) {
::memcpy(buffer, *src, len);
is_valid = true;
*src += len;
return writer();
}
Status NativeRegisterContextLinux_arm64::WriteAllRegisterValues(
const lldb::DataBufferSP &data_sp) {
// AArch64 register data must contain GPRs, either FPR or SVE registers
// (which can be streaming or non-streaming) and optional MTE register.
// Pointer Authentication (PAC) registers are read-only and will be skipped.
// We store all register values in data_sp by copying full PTrace data that
// corresponds to register sets enabled by current register context. In order
// to restore from register data checkpoint we will first restore GPRs, based
// on size of remaining register data either SVE or FPRs should be restored
// next. SVE is not enabled if we have register data size less than or equal
// to size of GPR + FPR + MTE.
Status error;
if (!data_sp) {
error.SetErrorStringWithFormat(
"NativeRegisterContextLinux_arm64::%s invalid data_sp provided",
__FUNCTION__);
return error;
}
const uint8_t *src = data_sp->GetBytes();
if (src == nullptr) {
error.SetErrorStringWithFormat("NativeRegisterContextLinux_arm64::%s "
"DataBuffer::GetBytes() returned a null "
"pointer",
__FUNCTION__);
return error;
}
uint64_t reg_data_min_size =
GetGPRBufferSize() + GetFPRSize() + 2 * (sizeof(RegisterSetType));
if (data_sp->GetByteSize() < reg_data_min_size) {
error.SetErrorStringWithFormat(
"NativeRegisterContextLinux_arm64::%s data_sp contained insufficient "
"register data bytes, expected at least %" PRIu64 ", actual %" PRIu64,
__FUNCTION__, reg_data_min_size, data_sp->GetByteSize());
return error;
}
const uint8_t *end = src + data_sp->GetByteSize();
while (src < end) {
const RegisterSetType kind =
*reinterpret_cast<const RegisterSetType *>(src);
src += sizeof(RegisterSetType);
switch (kind) {
case RegisterSetType::GPR:
error = RestoreRegisters(
GetGPRBuffer(), &src, GetGPRBufferSize(), m_gpr_is_valid,
std::bind(&NativeRegisterContextLinux_arm64::WriteGPR, this));
break;
case RegisterSetType::SVE:
// Restore to the correct mode, streaming or not.
m_sve_state = static_cast<SVEState>(*src);
src += sizeof(m_sve_state);
// First write SVE header. We do not use RestoreRegisters because we do
// not want src to be modified yet.
::memcpy(GetSVEHeader(), src, GetSVEHeaderSize());
if (!sve::vl_valid(m_sve_header.vl)) {
m_sve_header_is_valid = false;
error.SetErrorStringWithFormat("NativeRegisterContextLinux_arm64::%s "
"Invalid SVE header in data_sp",
__FUNCTION__);
return error;
}
m_sve_header_is_valid = true;
error = WriteSVEHeader();
if (error.Fail())
return error;
// SVE header has been written configure SVE vector length if needed.
// This could change ZA data too, but that will be restored again later
// anyway.
ConfigureRegisterContext();
// Write header and register data, incrementing src this time.
error = RestoreRegisters(
GetSVEBuffer(), &src, GetSVEBufferSize(), m_sve_buffer_is_valid,
std::bind(&NativeRegisterContextLinux_arm64::WriteAllSVE, this));
break;
case RegisterSetType::FPR:
error = RestoreRegisters(
GetFPRBuffer(), &src, GetFPRSize(), m_fpu_is_valid,
std::bind(&NativeRegisterContextLinux_arm64::WriteFPR, this));
break;
case RegisterSetType::MTE:
error = RestoreRegisters(
GetMTEControl(), &src, GetMTEControlSize(), m_mte_ctrl_is_valid,
std::bind(&NativeRegisterContextLinux_arm64::WriteMTEControl, this));
break;
case RegisterSetType::TLS:
error = RestoreRegisters(
GetTLSBuffer(), &src, GetTLSBufferSize(), m_tls_is_valid,
std::bind(&NativeRegisterContextLinux_arm64::WriteTLS, this));
break;
case RegisterSetType::SME:
// To enable or disable ZA you write the regset with or without register
// data. The kernel detects this by looking at the ioVec's length, not the
// ZA header size you pass in. Therefore we must write header and register
// data (if present) in one go every time. Read the header only first just
// to get the size.
::memcpy(GetZAHeader(), src, GetZAHeaderSize());
// Read the header and register data. Can't use the buffer size here, it
// may be incorrect due to being filled with dummy data previously. Resize
// this so WriteZA uses the correct size.
m_za_ptrace_payload.resize(m_za_header.size);
::memcpy(GetZABuffer(), src, GetZABufferSize());
m_za_buffer_is_valid = true;
error = WriteZA();
if (error.Fail())
return error;
// Update size of ZA, which resizes the ptrace payload potentially
// trashing our copy of the data we just wrote.
ConfigureRegisterContext();
// ZA buffer now has proper size, read back the data we wrote above, from
// ptrace.
error = ReadZA();
src += GetZABufferSize();
break;
}
if (error.Fail())
return error;
}
return error;
}
bool NativeRegisterContextLinux_arm64::IsGPR(unsigned reg) const {
if (GetRegisterInfo().GetRegisterSetFromRegisterIndex(reg) ==
RegisterInfoPOSIX_arm64::GPRegSet)
return true;
return false;
}
bool NativeRegisterContextLinux_arm64::IsFPR(unsigned reg) const {
if (GetRegisterInfo().GetRegisterSetFromRegisterIndex(reg) ==
RegisterInfoPOSIX_arm64::FPRegSet)
return true;
return false;
}
bool NativeRegisterContextLinux_arm64::IsSVE(unsigned reg) const {
return GetRegisterInfo().IsSVEReg(reg);
}
bool NativeRegisterContextLinux_arm64::IsSME(unsigned reg) const {
return GetRegisterInfo().IsSMEReg(reg);
}
bool NativeRegisterContextLinux_arm64::IsPAuth(unsigned reg) const {
return GetRegisterInfo().IsPAuthReg(reg);
}
bool NativeRegisterContextLinux_arm64::IsMTE(unsigned reg) const {
return GetRegisterInfo().IsMTEReg(reg);
}
bool NativeRegisterContextLinux_arm64::IsTLS(unsigned reg) const {
return GetRegisterInfo().IsTLSReg(reg);
}
llvm::Error NativeRegisterContextLinux_arm64::ReadHardwareDebugInfo() {
if (!m_refresh_hwdebug_info) {
return llvm::Error::success();
}
::pid_t tid = m_thread.GetID();
int regset = NT_ARM_HW_WATCH;
struct iovec ioVec;
struct user_hwdebug_state dreg_state;
Status 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.ToError();
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.ToError();
m_max_hbp_supported = dreg_state.dbg_info & 0xff;
m_refresh_hwdebug_info = false;
return llvm::Error::success();
}
llvm::Error
NativeRegisterContextLinux_arm64::WriteHardwareDebugRegs(DREGType hwbType) {
struct iovec ioVec;
struct user_hwdebug_state dreg_state;
int regset;
memset(&dreg_state, 0, sizeof(dreg_state));
ioVec.iov_base = &dreg_state;
switch (hwbType) {
case eDREGTypeWATCH:
regset = 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;
}
break;
case eDREGTypeBREAK:
regset = 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_hbp_regs[i].address;
dreg_state.dbg_regs[i].ctrl = m_hbp_regs[i].control;
}
break;
}
return NativeProcessLinux::PtraceWrapper(PTRACE_SETREGSET, m_thread.GetID(),
&regset, &ioVec, ioVec.iov_len)
.ToError();
}
Status NativeRegisterContextLinux_arm64::ReadGPR() {
Status error;
if (m_gpr_is_valid)
return error;
struct iovec ioVec;
ioVec.iov_base = GetGPRBuffer();
ioVec.iov_len = GetGPRBufferSize();
error = ReadRegisterSet(&ioVec, GetGPRBufferSize(), NT_PRSTATUS);
if (error.Success())
m_gpr_is_valid = true;
return error;
}
Status NativeRegisterContextLinux_arm64::WriteGPR() {
Status error = ReadGPR();
if (error.Fail())
return error;
struct iovec ioVec;
ioVec.iov_base = GetGPRBuffer();
ioVec.iov_len = GetGPRBufferSize();
m_gpr_is_valid = false;
return WriteRegisterSet(&ioVec, GetGPRBufferSize(), NT_PRSTATUS);
}
Status NativeRegisterContextLinux_arm64::ReadFPR() {
Status error;
if (m_fpu_is_valid)
return error;
struct iovec ioVec;
ioVec.iov_base = GetFPRBuffer();
ioVec.iov_len = GetFPRSize();
error = ReadRegisterSet(&ioVec, GetFPRSize(), NT_FPREGSET);
if (error.Success())
m_fpu_is_valid = true;
return error;
}
Status NativeRegisterContextLinux_arm64::WriteFPR() {
Status error = ReadFPR();
if (error.Fail())
return error;
struct iovec ioVec;
ioVec.iov_base = GetFPRBuffer();
ioVec.iov_len = GetFPRSize();
m_fpu_is_valid = false;
return WriteRegisterSet(&ioVec, GetFPRSize(), NT_FPREGSET);
}
void NativeRegisterContextLinux_arm64::InvalidateAllRegisters() {
m_gpr_is_valid = false;
m_fpu_is_valid = false;
m_sve_buffer_is_valid = false;
m_sve_header_is_valid = false;
m_za_buffer_is_valid = false;
m_za_header_is_valid = false;
m_pac_mask_is_valid = false;
m_mte_ctrl_is_valid = false;
m_tls_is_valid = false;
// Update SVE and ZA registers in case there is change in configuration.
ConfigureRegisterContext();
}
unsigned NativeRegisterContextLinux_arm64::GetSVERegSet() {
return m_sve_state == SVEState::Streaming ? NT_ARM_SSVE : NT_ARM_SVE;
}
Status NativeRegisterContextLinux_arm64::ReadSVEHeader() {
Status error;
if (m_sve_header_is_valid)
return error;
struct iovec ioVec;
ioVec.iov_base = GetSVEHeader();
ioVec.iov_len = GetSVEHeaderSize();
error = ReadRegisterSet(&ioVec, GetSVEHeaderSize(), GetSVERegSet());
if (error.Success())
m_sve_header_is_valid = true;
return error;
}
Status NativeRegisterContextLinux_arm64::ReadPAuthMask() {
Status error;
if (m_pac_mask_is_valid)
return error;
struct iovec ioVec;
ioVec.iov_base = GetPACMask();
ioVec.iov_len = GetPACMaskSize();
error = ReadRegisterSet(&ioVec, GetPACMaskSize(), NT_ARM_PAC_MASK);
if (error.Success())
m_pac_mask_is_valid = true;
return error;
}
Status NativeRegisterContextLinux_arm64::WriteSVEHeader() {
Status error;
error = ReadSVEHeader();
if (error.Fail())
return error;
struct iovec ioVec;
ioVec.iov_base = GetSVEHeader();
ioVec.iov_len = GetSVEHeaderSize();
m_sve_buffer_is_valid = false;
m_sve_header_is_valid = false;
m_fpu_is_valid = false;
return WriteRegisterSet(&ioVec, GetSVEHeaderSize(), GetSVERegSet());
}
Status NativeRegisterContextLinux_arm64::ReadAllSVE() {
Status error;
if (m_sve_buffer_is_valid)
return error;
struct iovec ioVec;
ioVec.iov_base = GetSVEBuffer();
ioVec.iov_len = GetSVEBufferSize();
error = ReadRegisterSet(&ioVec, GetSVEBufferSize(), GetSVERegSet());
if (error.Success())
m_sve_buffer_is_valid = true;
return error;
}
Status NativeRegisterContextLinux_arm64::WriteAllSVE() {
Status error;
error = ReadAllSVE();
if (error.Fail())
return error;
struct iovec ioVec;
ioVec.iov_base = GetSVEBuffer();
ioVec.iov_len = GetSVEBufferSize();
m_sve_buffer_is_valid = false;
m_sve_header_is_valid = false;
m_fpu_is_valid = false;
return WriteRegisterSet(&ioVec, GetSVEBufferSize(), GetSVERegSet());
}
Status NativeRegisterContextLinux_arm64::ReadMTEControl() {
Status error;
if (m_mte_ctrl_is_valid)
return error;
struct iovec ioVec;
ioVec.iov_base = GetMTEControl();
ioVec.iov_len = GetMTEControlSize();
error = ReadRegisterSet(&ioVec, GetMTEControlSize(), NT_ARM_TAGGED_ADDR_CTRL);
if (error.Success())
m_mte_ctrl_is_valid = true;
return error;
}
Status NativeRegisterContextLinux_arm64::WriteMTEControl() {
Status error;
error = ReadMTEControl();
if (error.Fail())
return error;
struct iovec ioVec;
ioVec.iov_base = GetMTEControl();
ioVec.iov_len = GetMTEControlSize();
m_mte_ctrl_is_valid = false;
return WriteRegisterSet(&ioVec, GetMTEControlSize(), NT_ARM_TAGGED_ADDR_CTRL);
}
Status NativeRegisterContextLinux_arm64::ReadTLS() {
Status error;
if (m_tls_is_valid)
return error;
struct iovec ioVec;
ioVec.iov_base = GetTLSBuffer();
ioVec.iov_len = GetTLSBufferSize();
error = ReadRegisterSet(&ioVec, GetTLSBufferSize(), NT_ARM_TLS);
if (error.Success())
m_tls_is_valid = true;
return error;
}
Status NativeRegisterContextLinux_arm64::WriteTLS() {
Status error;
error = ReadTLS();
if (error.Fail())
return error;
struct iovec ioVec;
ioVec.iov_base = GetTLSBuffer();
ioVec.iov_len = GetTLSBufferSize();
m_tls_is_valid = false;
return WriteRegisterSet(&ioVec, GetTLSBufferSize(), NT_ARM_TLS);
}
Status NativeRegisterContextLinux_arm64::ReadZAHeader() {
Status error;
if (m_za_header_is_valid)
return error;
struct iovec ioVec;
ioVec.iov_base = GetZAHeader();
ioVec.iov_len = GetZAHeaderSize();
error = ReadRegisterSet(&ioVec, GetZAHeaderSize(), NT_ARM_ZA);
if (error.Success())
m_za_header_is_valid = true;
return error;
}
Status NativeRegisterContextLinux_arm64::ReadZA() {
Status error;
if (m_za_buffer_is_valid)
return error;
struct iovec ioVec;
ioVec.iov_base = GetZABuffer();
ioVec.iov_len = GetZABufferSize();
error = ReadRegisterSet(&ioVec, GetZABufferSize(), NT_ARM_ZA);
if (error.Success())
m_za_buffer_is_valid = true;
return error;
}
Status NativeRegisterContextLinux_arm64::WriteZA() {
// Note that because the ZA ptrace payload contains the header also, this
// method will write both. This is done because writing only the header
// will disable ZA, even if .size in the header is correct for an enabled ZA.
Status error;
error = ReadZA();
if (error.Fail())
return error;
struct iovec ioVec;
ioVec.iov_base = GetZABuffer();
ioVec.iov_len = GetZABufferSize();
m_za_buffer_is_valid = false;
m_za_header_is_valid = false;
return WriteRegisterSet(&ioVec, GetZABufferSize(), NT_ARM_ZA);
}
void NativeRegisterContextLinux_arm64::ConfigureRegisterContext() {
// ConfigureRegisterContext gets called from InvalidateAllRegisters
// on every stop and configures SVE vector length and whether we are in
// streaming SVE mode.
// If m_sve_state is set to SVEState::Disabled on first stop, code below will
// be deemed non operational for the lifetime of current process.
if (!m_sve_header_is_valid && m_sve_state != SVEState::Disabled) {
// If we have SVE we may also have the SVE streaming mode that SME added.
// We can read the header of either mode, but only the active mode will
// have valid register data.
// Check whether SME is present and the streaming SVE mode is active.
m_sve_header_is_valid = false;
m_sve_buffer_is_valid = false;
m_sve_state = SVEState::Streaming;
Status error = ReadSVEHeader();
// Streaming mode is active if the header has the SVE active flag set.
if (!(error.Success() && ((m_sve_header.flags & sve::ptrace_regs_mask) ==
sve::ptrace_regs_sve))) {
// Non-streaming might be active instead.
m_sve_header_is_valid = false;
m_sve_buffer_is_valid = false;
m_sve_state = SVEState::Full;
error = ReadSVEHeader();
if (error.Success()) {
// If SVE is enabled thread can switch between SVEState::FPSIMD and
// SVEState::Full on every stop.
if ((m_sve_header.flags & sve::ptrace_regs_mask) ==
sve::ptrace_regs_fpsimd)
m_sve_state = SVEState::FPSIMD;
// Else we are in SVEState::Full.
} else {
m_sve_state = SVEState::Disabled;
}
}
if (m_sve_state == SVEState::Full || m_sve_state == SVEState::FPSIMD ||
m_sve_state == SVEState::Streaming) {
// On every stop we configure SVE vector length by calling
// ConfigureVectorLengthSVE regardless of current SVEState of this thread.
uint32_t vq = RegisterInfoPOSIX_arm64::eVectorQuadwordAArch64SVE;
if (sve::vl_valid(m_sve_header.vl))
vq = sve::vq_from_vl(m_sve_header.vl);
GetRegisterInfo().ConfigureVectorLengthSVE(vq);
m_sve_ptrace_payload.resize(sve::PTraceSize(vq, sve::ptrace_regs_sve));
}
}
if (!m_za_header_is_valid) {
Status error = ReadZAHeader();
if (error.Success()) {
uint32_t vq = RegisterInfoPOSIX_arm64::eVectorQuadwordAArch64SVE;
if (sve::vl_valid(m_za_header.vl))
vq = sve::vq_from_vl(m_za_header.vl);
GetRegisterInfo().ConfigureVectorLengthZA(vq);
m_za_ptrace_payload.resize(m_za_header.size);
m_za_buffer_is_valid = false;
}
}
}
uint32_t NativeRegisterContextLinux_arm64::CalculateFprOffset(
const RegisterInfo *reg_info) const {
return reg_info->byte_offset - GetGPRSize();
}
uint32_t NativeRegisterContextLinux_arm64::CalculateSVEOffset(
const RegisterInfo *reg_info) const {
// Start of Z0 data is after GPRs plus 8 bytes of vg register
uint32_t sve_reg_offset = LLDB_INVALID_INDEX32;
if (m_sve_state == SVEState::FPSIMD) {
const uint32_t reg = reg_info->kinds[lldb::eRegisterKindLLDB];
sve_reg_offset = sve::ptrace_fpsimd_offset +
(reg - GetRegisterInfo().GetRegNumSVEZ0()) * 16;
// Between non-streaming and streaming mode, the layout is identical.
} else if (m_sve_state == SVEState::Full ||
m_sve_state == SVEState::Streaming) {
uint32_t sve_z0_offset = GetGPRSize() + 16;
sve_reg_offset =
sve::SigRegsOffset() + reg_info->byte_offset - sve_z0_offset;
}
return sve_reg_offset;
}
std::vector<uint32_t> NativeRegisterContextLinux_arm64::GetExpeditedRegisters(
ExpeditedRegs expType) const {
std::vector<uint32_t> expedited_reg_nums =
NativeRegisterContext::GetExpeditedRegisters(expType);
// SVE, non-streaming vector length.
if (m_sve_state == SVEState::FPSIMD || m_sve_state == SVEState::Full)
expedited_reg_nums.push_back(GetRegisterInfo().GetRegNumSVEVG());
return expedited_reg_nums;
}
llvm::Expected<NativeRegisterContextLinux::MemoryTaggingDetails>
NativeRegisterContextLinux_arm64::GetMemoryTaggingDetails(int32_t type) {
if (type == MemoryTagManagerAArch64MTE::eMTE_allocation) {
return MemoryTaggingDetails{std::make_unique<MemoryTagManagerAArch64MTE>(),
PTRACE_PEEKMTETAGS, PTRACE_POKEMTETAGS};
}
return llvm::createStringError(llvm::inconvertibleErrorCode(),
"Unknown AArch64 memory tag type %d", type);
}
lldb::addr_t NativeRegisterContextLinux_arm64::FixWatchpointHitAddress(
lldb::addr_t hit_addr) {
// Linux configures user-space virtual addresses with top byte ignored.
// We set default value of mask such that top byte is masked out.
lldb::addr_t mask = ~((1ULL << 56) - 1);
// Try to read pointer authentication data_mask register and calculate a
// consolidated data address mask after ignoring the top byte.
if (ReadPAuthMask().Success())
mask |= m_pac_mask.data_mask;
return hit_addr & ~mask;
;
}
#endif // defined (__arm64__) || defined (__aarch64__)
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