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cobalt / cobalt / 61a8495e1e0485bd40f613004bf29f8a925ab37c / . / src / third_party / llvm-project / lldb / tools / debugserver / source / MacOSX / x86_64 / DNBArchImplX86_64.cpp
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//===-- DNBArchImplX86_64.cpp -----------------------------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// Created by Greg Clayton on 6/25/07.
//
//===----------------------------------------------------------------------===//
#if defined(__i386__) || defined(__x86_64__)
#include <sys/cdefs.h>
#include <sys/sysctl.h>
#include <sys/types.h>
#include "DNBLog.h"
#include "MacOSX/x86_64/DNBArchImplX86_64.h"
#include "MachProcess.h"
#include "MachThread.h"
#include <mach/mach.h>
#include <stdlib.h>
#if defined(LLDB_DEBUGSERVER_RELEASE) || defined(LLDB_DEBUGSERVER_DEBUG)
enum debugState { debugStateUnknown, debugStateOff, debugStateOn };
static debugState sFPUDebugState = debugStateUnknown;
static debugState sAVXForceState = debugStateUnknown;
static bool DebugFPURegs() {
if (sFPUDebugState == debugStateUnknown) {
if (getenv("DNB_DEBUG_FPU_REGS"))
sFPUDebugState = debugStateOn;
else
sFPUDebugState = debugStateOff;
}
return (sFPUDebugState == debugStateOn);
}
static bool ForceAVXRegs() {
if (sFPUDebugState == debugStateUnknown) {
if (getenv("DNB_DEBUG_X86_FORCE_AVX_REGS"))
sAVXForceState = debugStateOn;
else
sAVXForceState = debugStateOff;
}
return (sAVXForceState == debugStateOn);
}
#define DEBUG_FPU_REGS (DebugFPURegs())
#define FORCE_AVX_REGS (ForceAVXRegs())
#else
#define DEBUG_FPU_REGS (0)
#define FORCE_AVX_REGS (0)
#endif
bool DetectHardwareFeature(const char *feature) {
int answer = 0;
size_t answer_size = sizeof(answer);
int error = ::sysctlbyname(feature, &answer, &answer_size, NULL, 0);
return error == 0 && answer != 0;
}
enum AVXPresence { eAVXUnknown = -1, eAVXNotPresent = 0, eAVXPresent = 1 };
bool LogAVXAndReturn(AVXPresence has_avx, int err, const char * os_ver) {
DNBLogThreadedIf(LOG_THREAD,
"CPUHasAVX(): g_has_avx = %i (err = %i, os_ver = %s)",
has_avx, err, os_ver);
return (has_avx == eAVXPresent);
}
extern "C" bool CPUHasAVX() {
static AVXPresence g_has_avx = eAVXUnknown;
if (g_has_avx != eAVXUnknown)
return LogAVXAndReturn(g_has_avx, 0, "");
g_has_avx = eAVXNotPresent;
// OS X 10.7.3 and earlier have a bug in thread_get_state that truncated the
// size of the return. To work around this we have to disable AVX debugging
// on hosts prior to 10.7.3 (<rdar://problem/10122874>).
int mib[2];
char buffer[1024];
size_t length = sizeof(buffer);
mib[0] = CTL_KERN;
mib[1] = KERN_OSVERSION;
// KERN_OSVERSION returns the build number which is a number signifying the
// major version, a capitol letter signifying the minor version, and numbers
// signifying the build (ex: on 10.12.3, the returned value is 16D32).
int err = ::sysctl(mib, 2, &buffer, &length, NULL, 0);
if (err != 0)
return LogAVXAndReturn(g_has_avx, err, "");
size_t first_letter = 0;
for (; first_letter < length; ++first_letter) {
// This is looking for the first uppercase letter
if (isupper(buffer[first_letter]))
break;
}
char letter = buffer[first_letter];
buffer[first_letter] = '\0';
auto major_ver = strtoull(buffer, NULL, 0);
buffer[first_letter] = letter;
// In this check we're looking to see that our major and minor version numer
// was >= 11E, which is the 10.7.4 release.
if (major_ver < 11 || (major_ver == 11 && letter < 'E'))
return LogAVXAndReturn(g_has_avx, err, buffer);
if (DetectHardwareFeature("hw.optional.avx1_0"))
g_has_avx = eAVXPresent;
return LogAVXAndReturn(g_has_avx, err, buffer);
}
extern "C" bool CPUHasAVX512f() {
static AVXPresence g_has_avx512f = eAVXUnknown;
if (g_has_avx512f != eAVXUnknown)
return g_has_avx512f == eAVXPresent;
g_has_avx512f = DetectHardwareFeature("hw.optional.avx512f") ? eAVXPresent
: eAVXNotPresent;
return (g_has_avx512f == eAVXPresent);
}
uint64_t DNBArchImplX86_64::GetPC(uint64_t failValue) {
// Get program counter
if (GetGPRState(false) == KERN_SUCCESS)
return m_state.context.gpr.__rip;
return failValue;
}
kern_return_t DNBArchImplX86_64::SetPC(uint64_t value) {
// Get program counter
kern_return_t err = GetGPRState(false);
if (err == KERN_SUCCESS) {
m_state.context.gpr.__rip = value;
err = SetGPRState();
}
return err == KERN_SUCCESS;
}
uint64_t DNBArchImplX86_64::GetSP(uint64_t failValue) {
// Get stack pointer
if (GetGPRState(false) == KERN_SUCCESS)
return m_state.context.gpr.__rsp;
return failValue;
}
// Uncomment the value below to verify the values in the debugger.
//#define DEBUG_GPR_VALUES 1 // DO NOT CHECK IN WITH THIS DEFINE ENABLED
kern_return_t DNBArchImplX86_64::GetGPRState(bool force) {
if (force || m_state.GetError(e_regSetGPR, Read)) {
#if DEBUG_GPR_VALUES
m_state.context.gpr.__rax = ('a' << 8) + 'x';
m_state.context.gpr.__rbx = ('b' << 8) + 'x';
m_state.context.gpr.__rcx = ('c' << 8) + 'x';
m_state.context.gpr.__rdx = ('d' << 8) + 'x';
m_state.context.gpr.__rdi = ('d' << 8) + 'i';
m_state.context.gpr.__rsi = ('s' << 8) + 'i';
m_state.context.gpr.__rbp = ('b' << 8) + 'p';
m_state.context.gpr.__rsp = ('s' << 8) + 'p';
m_state.context.gpr.__r8 = ('r' << 8) + '8';
m_state.context.gpr.__r9 = ('r' << 8) + '9';
m_state.context.gpr.__r10 = ('r' << 8) + 'a';
m_state.context.gpr.__r11 = ('r' << 8) + 'b';
m_state.context.gpr.__r12 = ('r' << 8) + 'c';
m_state.context.gpr.__r13 = ('r' << 8) + 'd';
m_state.context.gpr.__r14 = ('r' << 8) + 'e';
m_state.context.gpr.__r15 = ('r' << 8) + 'f';
m_state.context.gpr.__rip = ('i' << 8) + 'p';
m_state.context.gpr.__rflags = ('f' << 8) + 'l';
m_state.context.gpr.__cs = ('c' << 8) + 's';
m_state.context.gpr.__fs = ('f' << 8) + 's';
m_state.context.gpr.__gs = ('g' << 8) + 's';
m_state.SetError(e_regSetGPR, Read, 0);
#else
mach_msg_type_number_t count = e_regSetWordSizeGPR;
m_state.SetError(
e_regSetGPR, Read,
::thread_get_state(m_thread->MachPortNumber(), __x86_64_THREAD_STATE,
(thread_state_t)&m_state.context.gpr, &count));
DNBLogThreadedIf(
LOG_THREAD,
"::thread_get_state (0x%4.4x, %u, &gpr, %u) => 0x%8.8x"
"\n\trax = %16.16llx rbx = %16.16llx rcx = %16.16llx rdx = %16.16llx"
"\n\trdi = %16.16llx rsi = %16.16llx rbp = %16.16llx rsp = %16.16llx"
"\n\t r8 = %16.16llx r9 = %16.16llx r10 = %16.16llx r11 = %16.16llx"
"\n\tr12 = %16.16llx r13 = %16.16llx r14 = %16.16llx r15 = %16.16llx"
"\n\trip = %16.16llx"
"\n\tflg = %16.16llx cs = %16.16llx fs = %16.16llx gs = %16.16llx",
m_thread->MachPortNumber(), x86_THREAD_STATE64,
x86_THREAD_STATE64_COUNT, m_state.GetError(e_regSetGPR, Read),
m_state.context.gpr.__rax, m_state.context.gpr.__rbx,
m_state.context.gpr.__rcx, m_state.context.gpr.__rdx,
m_state.context.gpr.__rdi, m_state.context.gpr.__rsi,
m_state.context.gpr.__rbp, m_state.context.gpr.__rsp,
m_state.context.gpr.__r8, m_state.context.gpr.__r9,
m_state.context.gpr.__r10, m_state.context.gpr.__r11,
m_state.context.gpr.__r12, m_state.context.gpr.__r13,
m_state.context.gpr.__r14, m_state.context.gpr.__r15,
m_state.context.gpr.__rip, m_state.context.gpr.__rflags,
m_state.context.gpr.__cs, m_state.context.gpr.__fs,
m_state.context.gpr.__gs);
// DNBLogThreadedIf (LOG_THREAD, "thread_get_state(0x%4.4x, %u, &gpr, %u)
// => 0x%8.8x"
// "\n\trax = %16.16llx"
// "\n\trbx = %16.16llx"
// "\n\trcx = %16.16llx"
// "\n\trdx = %16.16llx"
// "\n\trdi = %16.16llx"
// "\n\trsi = %16.16llx"
// "\n\trbp = %16.16llx"
// "\n\trsp = %16.16llx"
// "\n\t r8 = %16.16llx"
// "\n\t r9 = %16.16llx"
// "\n\tr10 = %16.16llx"
// "\n\tr11 = %16.16llx"
// "\n\tr12 = %16.16llx"
// "\n\tr13 = %16.16llx"
// "\n\tr14 = %16.16llx"
// "\n\tr15 = %16.16llx"
// "\n\trip = %16.16llx"
// "\n\tflg = %16.16llx"
// "\n\t cs = %16.16llx"
// "\n\t fs = %16.16llx"
// "\n\t gs = %16.16llx",
// m_thread->MachPortNumber(),
// x86_THREAD_STATE64,
// x86_THREAD_STATE64_COUNT,
// m_state.GetError(e_regSetGPR, Read),
// m_state.context.gpr.__rax,
// m_state.context.gpr.__rbx,
// m_state.context.gpr.__rcx,
// m_state.context.gpr.__rdx,
// m_state.context.gpr.__rdi,
// m_state.context.gpr.__rsi,
// m_state.context.gpr.__rbp,
// m_state.context.gpr.__rsp,
// m_state.context.gpr.__r8,
// m_state.context.gpr.__r9,
// m_state.context.gpr.__r10,
// m_state.context.gpr.__r11,
// m_state.context.gpr.__r12,
// m_state.context.gpr.__r13,
// m_state.context.gpr.__r14,
// m_state.context.gpr.__r15,
// m_state.context.gpr.__rip,
// m_state.context.gpr.__rflags,
// m_state.context.gpr.__cs,
// m_state.context.gpr.__fs,
// m_state.context.gpr.__gs);
#endif
}
return m_state.GetError(e_regSetGPR, Read);
}
// Uncomment the value below to verify the values in the debugger.
//#define DEBUG_FPU_REGS 1 // DO NOT CHECK IN WITH THIS DEFINE ENABLED
kern_return_t DNBArchImplX86_64::GetFPUState(bool force) {
if (force || m_state.GetError(e_regSetFPU, Read)) {
if (DEBUG_FPU_REGS) {
m_state.context.fpu.no_avx.__fpu_reserved[0] = -1;
m_state.context.fpu.no_avx.__fpu_reserved[1] = -1;
*(uint16_t *)&(m_state.context.fpu.no_avx.__fpu_fcw) = 0x1234;
*(uint16_t *)&(m_state.context.fpu.no_avx.__fpu_fsw) = 0x5678;
m_state.context.fpu.no_avx.__fpu_ftw = 1;
m_state.context.fpu.no_avx.__fpu_rsrv1 = UINT8_MAX;
m_state.context.fpu.no_avx.__fpu_fop = 2;
m_state.context.fpu.no_avx.__fpu_ip = 3;
m_state.context.fpu.no_avx.__fpu_cs = 4;
m_state.context.fpu.no_avx.__fpu_rsrv2 = 5;
m_state.context.fpu.no_avx.__fpu_dp = 6;
m_state.context.fpu.no_avx.__fpu_ds = 7;
m_state.context.fpu.no_avx.__fpu_rsrv3 = UINT16_MAX;
m_state.context.fpu.no_avx.__fpu_mxcsr = 8;
m_state.context.fpu.no_avx.__fpu_mxcsrmask = 9;
for (int i = 0; i < 16; ++i) {
if (i < 10) {
m_state.context.fpu.no_avx.__fpu_stmm0.__mmst_reg[i] = 'a';
m_state.context.fpu.no_avx.__fpu_stmm1.__mmst_reg[i] = 'b';
m_state.context.fpu.no_avx.__fpu_stmm2.__mmst_reg[i] = 'c';
m_state.context.fpu.no_avx.__fpu_stmm3.__mmst_reg[i] = 'd';
m_state.context.fpu.no_avx.__fpu_stmm4.__mmst_reg[i] = 'e';
m_state.context.fpu.no_avx.__fpu_stmm5.__mmst_reg[i] = 'f';
m_state.context.fpu.no_avx.__fpu_stmm6.__mmst_reg[i] = 'g';
m_state.context.fpu.no_avx.__fpu_stmm7.__mmst_reg[i] = 'h';
} else {
m_state.context.fpu.no_avx.__fpu_stmm0.__mmst_reg[i] = INT8_MIN;
m_state.context.fpu.no_avx.__fpu_stmm1.__mmst_reg[i] = INT8_MIN;
m_state.context.fpu.no_avx.__fpu_stmm2.__mmst_reg[i] = INT8_MIN;
m_state.context.fpu.no_avx.__fpu_stmm3.__mmst_reg[i] = INT8_MIN;
m_state.context.fpu.no_avx.__fpu_stmm4.__mmst_reg[i] = INT8_MIN;
m_state.context.fpu.no_avx.__fpu_stmm5.__mmst_reg[i] = INT8_MIN;
m_state.context.fpu.no_avx.__fpu_stmm6.__mmst_reg[i] = INT8_MIN;
m_state.context.fpu.no_avx.__fpu_stmm7.__mmst_reg[i] = INT8_MIN;
}
m_state.context.fpu.no_avx.__fpu_xmm0.__xmm_reg[i] = '0';
m_state.context.fpu.no_avx.__fpu_xmm1.__xmm_reg[i] = '1';
m_state.context.fpu.no_avx.__fpu_xmm2.__xmm_reg[i] = '2';
m_state.context.fpu.no_avx.__fpu_xmm3.__xmm_reg[i] = '3';
m_state.context.fpu.no_avx.__fpu_xmm4.__xmm_reg[i] = '4';
m_state.context.fpu.no_avx.__fpu_xmm5.__xmm_reg[i] = '5';
m_state.context.fpu.no_avx.__fpu_xmm6.__xmm_reg[i] = '6';
m_state.context.fpu.no_avx.__fpu_xmm7.__xmm_reg[i] = '7';
m_state.context.fpu.no_avx.__fpu_xmm8.__xmm_reg[i] = '8';
m_state.context.fpu.no_avx.__fpu_xmm9.__xmm_reg[i] = '9';
m_state.context.fpu.no_avx.__fpu_xmm10.__xmm_reg[i] = 'A';
m_state.context.fpu.no_avx.__fpu_xmm11.__xmm_reg[i] = 'B';
m_state.context.fpu.no_avx.__fpu_xmm12.__xmm_reg[i] = 'C';
m_state.context.fpu.no_avx.__fpu_xmm13.__xmm_reg[i] = 'D';
m_state.context.fpu.no_avx.__fpu_xmm14.__xmm_reg[i] = 'E';
m_state.context.fpu.no_avx.__fpu_xmm15.__xmm_reg[i] = 'F';
}
for (int i = 0; i < sizeof(m_state.context.fpu.no_avx.__fpu_rsrv4); ++i)
m_state.context.fpu.no_avx.__fpu_rsrv4[i] = INT8_MIN;
m_state.context.fpu.no_avx.__fpu_reserved1 = -1;
if (CPUHasAVX() || FORCE_AVX_REGS) {
for (int i = 0; i < 16; ++i) {
m_state.context.fpu.avx.__fpu_ymmh0.__xmm_reg[i] = '0' + i;
m_state.context.fpu.avx.__fpu_ymmh1.__xmm_reg[i] = '1' + i;
m_state.context.fpu.avx.__fpu_ymmh2.__xmm_reg[i] = '2' + i;
m_state.context.fpu.avx.__fpu_ymmh3.__xmm_reg[i] = '3' + i;
m_state.context.fpu.avx.__fpu_ymmh4.__xmm_reg[i] = '4' + i;
m_state.context.fpu.avx.__fpu_ymmh5.__xmm_reg[i] = '5' + i;
m_state.context.fpu.avx.__fpu_ymmh6.__xmm_reg[i] = '6' + i;
m_state.context.fpu.avx.__fpu_ymmh7.__xmm_reg[i] = '7' + i;
m_state.context.fpu.avx.__fpu_ymmh8.__xmm_reg[i] = '8' + i;
m_state.context.fpu.avx.__fpu_ymmh9.__xmm_reg[i] = '9' + i;
m_state.context.fpu.avx.__fpu_ymmh10.__xmm_reg[i] = 'A' + i;
m_state.context.fpu.avx.__fpu_ymmh11.__xmm_reg[i] = 'B' + i;
m_state.context.fpu.avx.__fpu_ymmh12.__xmm_reg[i] = 'C' + i;
m_state.context.fpu.avx.__fpu_ymmh13.__xmm_reg[i] = 'D' + i;
m_state.context.fpu.avx.__fpu_ymmh14.__xmm_reg[i] = 'E' + i;
m_state.context.fpu.avx.__fpu_ymmh15.__xmm_reg[i] = 'F' + i;
}
for (int i = 0; i < sizeof(m_state.context.fpu.avx.__avx_reserved1); ++i)
m_state.context.fpu.avx.__avx_reserved1[i] = INT8_MIN;
}
if (CPUHasAVX512f() || FORCE_AVX_REGS) {
for (int i = 0; i < 8; ++i) {
m_state.context.fpu.avx512f.__fpu_k0.__opmask_reg[i] = '0';
m_state.context.fpu.avx512f.__fpu_k1.__opmask_reg[i] = '1';
m_state.context.fpu.avx512f.__fpu_k2.__opmask_reg[i] = '2';
m_state.context.fpu.avx512f.__fpu_k3.__opmask_reg[i] = '3';
m_state.context.fpu.avx512f.__fpu_k4.__opmask_reg[i] = '4';
m_state.context.fpu.avx512f.__fpu_k5.__opmask_reg[i] = '5';
m_state.context.fpu.avx512f.__fpu_k6.__opmask_reg[i] = '6';
m_state.context.fpu.avx512f.__fpu_k7.__opmask_reg[i] = '7';
}
for (int i = 0; i < 32; ++i) {
m_state.context.fpu.avx512f.__fpu_zmmh0.__ymm_reg[i] = '0';
m_state.context.fpu.avx512f.__fpu_zmmh1.__ymm_reg[i] = '1';
m_state.context.fpu.avx512f.__fpu_zmmh2.__ymm_reg[i] = '2';
m_state.context.fpu.avx512f.__fpu_zmmh3.__ymm_reg[i] = '3';
m_state.context.fpu.avx512f.__fpu_zmmh4.__ymm_reg[i] = '4';
m_state.context.fpu.avx512f.__fpu_zmmh5.__ymm_reg[i] = '5';
m_state.context.fpu.avx512f.__fpu_zmmh6.__ymm_reg[i] = '6';
m_state.context.fpu.avx512f.__fpu_zmmh7.__ymm_reg[i] = '7';
m_state.context.fpu.avx512f.__fpu_zmmh8.__ymm_reg[i] = '8';
m_state.context.fpu.avx512f.__fpu_zmmh9.__ymm_reg[i] = '9';
m_state.context.fpu.avx512f.__fpu_zmmh10.__ymm_reg[i] = 'A';
m_state.context.fpu.avx512f.__fpu_zmmh11.__ymm_reg[i] = 'B';
m_state.context.fpu.avx512f.__fpu_zmmh12.__ymm_reg[i] = 'C';
m_state.context.fpu.avx512f.__fpu_zmmh13.__ymm_reg[i] = 'D';
m_state.context.fpu.avx512f.__fpu_zmmh14.__ymm_reg[i] = 'E';
m_state.context.fpu.avx512f.__fpu_zmmh15.__ymm_reg[i] = 'F';
}
for (int i = 0; i < 64; ++i) {
m_state.context.fpu.avx512f.__fpu_zmm16.__zmm_reg[i] = 'G';
m_state.context.fpu.avx512f.__fpu_zmm17.__zmm_reg[i] = 'H';
m_state.context.fpu.avx512f.__fpu_zmm18.__zmm_reg[i] = 'I';
m_state.context.fpu.avx512f.__fpu_zmm19.__zmm_reg[i] = 'J';
m_state.context.fpu.avx512f.__fpu_zmm20.__zmm_reg[i] = 'K';
m_state.context.fpu.avx512f.__fpu_zmm21.__zmm_reg[i] = 'L';
m_state.context.fpu.avx512f.__fpu_zmm22.__zmm_reg[i] = 'M';
m_state.context.fpu.avx512f.__fpu_zmm23.__zmm_reg[i] = 'N';
m_state.context.fpu.avx512f.__fpu_zmm24.__zmm_reg[i] = 'O';
m_state.context.fpu.avx512f.__fpu_zmm25.__zmm_reg[i] = 'P';
m_state.context.fpu.avx512f.__fpu_zmm26.__zmm_reg[i] = 'Q';
m_state.context.fpu.avx512f.__fpu_zmm27.__zmm_reg[i] = 'R';
m_state.context.fpu.avx512f.__fpu_zmm28.__zmm_reg[i] = 'S';
m_state.context.fpu.avx512f.__fpu_zmm29.__zmm_reg[i] = 'T';
m_state.context.fpu.avx512f.__fpu_zmm30.__zmm_reg[i] = 'U';
m_state.context.fpu.avx512f.__fpu_zmm31.__zmm_reg[i] = 'V';
}
}
m_state.SetError(e_regSetFPU, Read, 0);
} else {
mach_msg_type_number_t count = e_regSetWordSizeFPU;
int flavor = __x86_64_FLOAT_STATE;
// On a machine with the AVX512 register set, a process only gets a
// full AVX512 register context after it uses the AVX512 registers;
// if the process has not yet triggered this change, trying to fetch
// the AVX512 registers will fail. Fall through to fetching the AVX
// registers.
if (CPUHasAVX512f() || FORCE_AVX_REGS) {
count = e_regSetWordSizeAVX512f;
flavor = __x86_64_AVX512F_STATE;
m_state.SetError(e_regSetFPU, Read,
::thread_get_state(m_thread->MachPortNumber(), flavor,
(thread_state_t)&m_state.context.fpu,
&count));
DNBLogThreadedIf(LOG_THREAD,
"::thread_get_state (0x%4.4x, %u, &fpu, %u => 0x%8.8x",
m_thread->MachPortNumber(), flavor, (uint32_t)count,
m_state.GetError(e_regSetFPU, Read));
if (m_state.GetError(e_regSetFPU, Read) == KERN_SUCCESS)
return m_state.GetError(e_regSetFPU, Read);
else
DNBLogThreadedIf(LOG_THREAD,
"::thread_get_state attempted fetch of avx512 fpu regctx failed, will try fetching avx");
}
if (CPUHasAVX() || FORCE_AVX_REGS) {
count = e_regSetWordSizeAVX;
flavor = __x86_64_AVX_STATE;
}
m_state.SetError(e_regSetFPU, Read,
::thread_get_state(m_thread->MachPortNumber(), flavor,
(thread_state_t)&m_state.context.fpu,
&count));
DNBLogThreadedIf(LOG_THREAD,
"::thread_get_state (0x%4.4x, %u, &fpu, %u => 0x%8.8x",
m_thread->MachPortNumber(), flavor, (uint32_t)count,
m_state.GetError(e_regSetFPU, Read));
}
}
return m_state.GetError(e_regSetFPU, Read);
}
kern_return_t DNBArchImplX86_64::GetEXCState(bool force) {
if (force || m_state.GetError(e_regSetEXC, Read)) {
mach_msg_type_number_t count = e_regSetWordSizeEXC;
m_state.SetError(
e_regSetEXC, Read,
::thread_get_state(m_thread->MachPortNumber(), __x86_64_EXCEPTION_STATE,
(thread_state_t)&m_state.context.exc, &count));
}
return m_state.GetError(e_regSetEXC, Read);
}
kern_return_t DNBArchImplX86_64::SetGPRState() {
kern_return_t kret = ::thread_abort_safely(m_thread->MachPortNumber());
DNBLogThreadedIf(
LOG_THREAD, "thread = 0x%4.4x calling thread_abort_safely (tid) => %u "
"(SetGPRState() for stop_count = %u)",
m_thread->MachPortNumber(), kret, m_thread->Process()->StopCount());
m_state.SetError(e_regSetGPR, Write,
::thread_set_state(m_thread->MachPortNumber(),
__x86_64_THREAD_STATE,
(thread_state_t)&m_state.context.gpr,
e_regSetWordSizeGPR));
DNBLogThreadedIf(
LOG_THREAD,
"::thread_set_state (0x%4.4x, %u, &gpr, %u) => 0x%8.8x"
"\n\trax = %16.16llx rbx = %16.16llx rcx = %16.16llx rdx = %16.16llx"
"\n\trdi = %16.16llx rsi = %16.16llx rbp = %16.16llx rsp = %16.16llx"
"\n\t r8 = %16.16llx r9 = %16.16llx r10 = %16.16llx r11 = %16.16llx"
"\n\tr12 = %16.16llx r13 = %16.16llx r14 = %16.16llx r15 = %16.16llx"
"\n\trip = %16.16llx"
"\n\tflg = %16.16llx cs = %16.16llx fs = %16.16llx gs = %16.16llx",
m_thread->MachPortNumber(), __x86_64_THREAD_STATE, e_regSetWordSizeGPR,
m_state.GetError(e_regSetGPR, Write), m_state.context.gpr.__rax,
m_state.context.gpr.__rbx, m_state.context.gpr.__rcx,
m_state.context.gpr.__rdx, m_state.context.gpr.__rdi,
m_state.context.gpr.__rsi, m_state.context.gpr.__rbp,
m_state.context.gpr.__rsp, m_state.context.gpr.__r8,
m_state.context.gpr.__r9, m_state.context.gpr.__r10,
m_state.context.gpr.__r11, m_state.context.gpr.__r12,
m_state.context.gpr.__r13, m_state.context.gpr.__r14,
m_state.context.gpr.__r15, m_state.context.gpr.__rip,
m_state.context.gpr.__rflags, m_state.context.gpr.__cs,
m_state.context.gpr.__fs, m_state.context.gpr.__gs);
return m_state.GetError(e_regSetGPR, Write);
}
kern_return_t DNBArchImplX86_64::SetFPUState() {
if (DEBUG_FPU_REGS) {
m_state.SetError(e_regSetFPU, Write, 0);
return m_state.GetError(e_regSetFPU, Write);
} else {
int flavor = __x86_64_FLOAT_STATE;
mach_msg_type_number_t count = e_regSetWordSizeFPU;
if (CPUHasAVX512f() || FORCE_AVX_REGS) {
count = e_regSetWordSizeAVX512f;
flavor = __x86_64_AVX512F_STATE;
m_state.SetError(
e_regSetFPU, Write,
::thread_set_state(m_thread->MachPortNumber(), flavor,
(thread_state_t)&m_state.context.fpu, count));
if (m_state.GetError(e_regSetFPU, Write) == KERN_SUCCESS)
return m_state.GetError(e_regSetFPU, Write);
else
DNBLogThreadedIf(LOG_THREAD,
"::thread_get_state attempted save of avx512 fpu regctx failed, will try saving avx regctx");
}
if (CPUHasAVX() || FORCE_AVX_REGS) {
flavor = __x86_64_AVX_STATE;
count = e_regSetWordSizeAVX;
}
m_state.SetError(
e_regSetFPU, Write,
::thread_set_state(m_thread->MachPortNumber(), flavor,
(thread_state_t)&m_state.context.fpu, count));
return m_state.GetError(e_regSetFPU, Write);
}
}
kern_return_t DNBArchImplX86_64::SetEXCState() {
m_state.SetError(e_regSetEXC, Write,
::thread_set_state(m_thread->MachPortNumber(),
__x86_64_EXCEPTION_STATE,
(thread_state_t)&m_state.context.exc,
e_regSetWordSizeEXC));
return m_state.GetError(e_regSetEXC, Write);
}
kern_return_t DNBArchImplX86_64::GetDBGState(bool force) {
if (force || m_state.GetError(e_regSetDBG, Read)) {
mach_msg_type_number_t count = e_regSetWordSizeDBG;
m_state.SetError(
e_regSetDBG, Read,
::thread_get_state(m_thread->MachPortNumber(), __x86_64_DEBUG_STATE,
(thread_state_t)&m_state.context.dbg, &count));
}
return m_state.GetError(e_regSetDBG, Read);
}
kern_return_t DNBArchImplX86_64::SetDBGState(bool also_set_on_task) {
m_state.SetError(e_regSetDBG, Write,
::thread_set_state(m_thread->MachPortNumber(),
__x86_64_DEBUG_STATE,
(thread_state_t)&m_state.context.dbg,
e_regSetWordSizeDBG));
if (also_set_on_task) {
kern_return_t kret = ::task_set_state(
m_thread->Process()->Task().TaskPort(), __x86_64_DEBUG_STATE,
(thread_state_t)&m_state.context.dbg, e_regSetWordSizeDBG);
if (kret != KERN_SUCCESS)
DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchImplX86_64::SetDBGState failed "
"to set debug control register state: "
"0x%8.8x.",
kret);
}
return m_state.GetError(e_regSetDBG, Write);
}
void DNBArchImplX86_64::ThreadWillResume() {
// Do we need to step this thread? If so, let the mach thread tell us so.
if (m_thread->IsStepping()) {
// This is the primary thread, let the arch do anything it needs
EnableHardwareSingleStep(true);
}
// Reset the debug status register, if necessary, before we resume.
kern_return_t kret = GetDBGState(false);
DNBLogThreadedIf(
LOG_WATCHPOINTS,
"DNBArchImplX86_64::ThreadWillResume() GetDBGState() => 0x%8.8x.", kret);
if (kret != KERN_SUCCESS)
return;
DBG &debug_state = m_state.context.dbg;
bool need_reset = false;
uint32_t i, num = NumSupportedHardwareWatchpoints();
for (i = 0; i < num; ++i)
if (IsWatchpointHit(debug_state, i))
need_reset = true;
if (need_reset) {
ClearWatchpointHits(debug_state);
kret = SetDBGState(false);
DNBLogThreadedIf(
LOG_WATCHPOINTS,
"DNBArchImplX86_64::ThreadWillResume() SetDBGState() => 0x%8.8x.",
kret);
}
}
bool DNBArchImplX86_64::ThreadDidStop() {
bool success = true;
m_state.InvalidateAllRegisterStates();
// Are we stepping a single instruction?
if (GetGPRState(true) == KERN_SUCCESS) {
// We are single stepping, was this the primary thread?
if (m_thread->IsStepping()) {
// This was the primary thread, we need to clear the trace
// bit if so.
success = EnableHardwareSingleStep(false) == KERN_SUCCESS;
} else {
// The MachThread will automatically restore the suspend count
// in ThreadDidStop(), so we don't need to do anything here if
// we weren't the primary thread the last time
}
}
return success;
}
bool DNBArchImplX86_64::NotifyException(MachException::Data &exc) {
switch (exc.exc_type) {
case EXC_BAD_ACCESS:
break;
case EXC_BAD_INSTRUCTION:
break;
case EXC_ARITHMETIC:
break;
case EXC_EMULATION:
break;
case EXC_SOFTWARE:
break;
case EXC_BREAKPOINT:
if (exc.exc_data.size() >= 2 && exc.exc_data[0] == 2) {
// exc_code = EXC_I386_BPT
//
nub_addr_t pc = GetPC(INVALID_NUB_ADDRESS);
if (pc != INVALID_NUB_ADDRESS && pc > 0) {
pc -= 1;
// Check for a breakpoint at one byte prior to the current PC value
// since the PC will be just past the trap.
DNBBreakpoint *bp =
m_thread->Process()->Breakpoints().FindByAddress(pc);
if (bp) {
// Backup the PC for i386 since the trap was taken and the PC
// is at the address following the single byte trap instruction.
if (m_state.context.gpr.__rip > 0) {
m_state.context.gpr.__rip = pc;
// Write the new PC back out
SetGPRState();
}
}
return true;
}
} else if (exc.exc_data.size() >= 2 && exc.exc_data[0] == 1) {
// exc_code = EXC_I386_SGL
//
// Check whether this corresponds to a watchpoint hit event.
// If yes, set the exc_sub_code to the data break address.
nub_addr_t addr = 0;
uint32_t hw_index = GetHardwareWatchpointHit(addr);
if (hw_index != INVALID_NUB_HW_INDEX) {
exc.exc_data[1] = addr;
// Piggyback the hw_index in the exc.data.
exc.exc_data.push_back(hw_index);
}
return true;
}
break;
case EXC_SYSCALL:
break;
case EXC_MACH_SYSCALL:
break;
case EXC_RPC_ALERT:
break;
}
return false;
}
uint32_t DNBArchImplX86_64::NumSupportedHardwareWatchpoints() {
// Available debug address registers: dr0, dr1, dr2, dr3.
return 4;
}
static uint32_t size_and_rw_bits(nub_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;
}
assert(0 && "invalid size, must be one of 1, 2, 4, or 8");
return 0;
}
void DNBArchImplX86_64::SetWatchpoint(DBG &debug_state, uint32_t hw_index,
nub_addr_t addr, nub_size_t size,
bool read, bool write) {
// Set both dr7 (debug control register) and dri (debug address register).
// dr7{7-0} encodes the local/gloabl 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}
debug_state.__dr7 |=
(1 << (2 * hw_index) |
size_and_rw_bits(size, read, write) << (16 + 4 * hw_index));
switch (hw_index) {
case 0:
debug_state.__dr0 = addr;
break;
case 1:
debug_state.__dr1 = addr;
break;
case 2:
debug_state.__dr2 = addr;
break;
case 3:
debug_state.__dr3 = addr;
break;
default:
assert(0 &&
"invalid hardware register index, must be one of 0, 1, 2, or 3");
}
return;
}
void DNBArchImplX86_64::ClearWatchpoint(DBG &debug_state, uint32_t hw_index) {
debug_state.__dr7 &= ~(3 << (2 * hw_index));
switch (hw_index) {
case 0:
debug_state.__dr0 = 0;
break;
case 1:
debug_state.__dr1 = 0;
break;
case 2:
debug_state.__dr2 = 0;
break;
case 3:
debug_state.__dr3 = 0;
break;
default:
assert(0 &&
"invalid hardware register index, must be one of 0, 1, 2, or 3");
}
return;
}
bool DNBArchImplX86_64::IsWatchpointVacant(const DBG &debug_state,
uint32_t hw_index) {
// Check dr7 (debug control register) for 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}
return (debug_state.__dr7 & (3 << (2 * hw_index))) == 0;
}
// Resets local copy of debug status register to wait for the next debug
// exception.
void DNBArchImplX86_64::ClearWatchpointHits(DBG &debug_state) {
// See also IsWatchpointHit().
debug_state.__dr6 = 0;
return;
}
bool DNBArchImplX86_64::IsWatchpointHit(const DBG &debug_state,
uint32_t hw_index) {
// Check dr6 (debug status register) whether a watchpoint hits:
// is watchpoint hit?
// |
// v
// dr0 -> bits{0}
// dr1 -> bits{1}
// dr2 -> bits{2}
// dr3 -> bits{3}
return (debug_state.__dr6 & (1 << hw_index));
}
nub_addr_t DNBArchImplX86_64::GetWatchAddress(const DBG &debug_state,
uint32_t hw_index) {
switch (hw_index) {
case 0:
return debug_state.__dr0;
case 1:
return debug_state.__dr1;
case 2:
return debug_state.__dr2;
case 3:
return debug_state.__dr3;
}
assert(0 && "invalid hardware register index, must be one of 0, 1, 2, or 3");
return 0;
}
bool DNBArchImplX86_64::StartTransForHWP() {
if (m_2pc_trans_state != Trans_Done && m_2pc_trans_state != Trans_Rolled_Back)
DNBLogError("%s inconsistent state detected, expected %d or %d, got: %d",
__FUNCTION__, Trans_Done, Trans_Rolled_Back, m_2pc_trans_state);
m_2pc_dbg_checkpoint = m_state.context.dbg;
m_2pc_trans_state = Trans_Pending;
return true;
}
bool DNBArchImplX86_64::RollbackTransForHWP() {
m_state.context.dbg = m_2pc_dbg_checkpoint;
if (m_2pc_trans_state != Trans_Pending)
DNBLogError("%s inconsistent state detected, expected %d, got: %d",
__FUNCTION__, Trans_Pending, m_2pc_trans_state);
m_2pc_trans_state = Trans_Rolled_Back;
kern_return_t kret = SetDBGState(false);
DNBLogThreadedIf(
LOG_WATCHPOINTS,
"DNBArchImplX86_64::RollbackTransForHWP() SetDBGState() => 0x%8.8x.",
kret);
if (kret == KERN_SUCCESS)
return true;
else
return false;
}
bool DNBArchImplX86_64::FinishTransForHWP() {
m_2pc_trans_state = Trans_Done;
return true;
}
DNBArchImplX86_64::DBG DNBArchImplX86_64::GetDBGCheckpoint() {
return m_2pc_dbg_checkpoint;
}
uint32_t DNBArchImplX86_64::EnableHardwareWatchpoint(nub_addr_t addr,
nub_size_t size, bool read,
bool write,
bool also_set_on_task) {
DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchImplX86_64::"
"EnableHardwareWatchpoint(addr = 0x%llx, "
"size = %llu, read = %u, write = %u)",
(uint64_t)addr, (uint64_t)size, read, write);
const uint32_t num_hw_watchpoints = NumSupportedHardwareWatchpoints();
// Can only watch 1, 2, 4, or 8 bytes.
if (!(size == 1 || size == 2 || size == 4 || size == 8))
return INVALID_NUB_HW_INDEX;
// We must watch for either read or write
if (read == false && write == false)
return INVALID_NUB_HW_INDEX;
// Read the debug state
kern_return_t kret = GetDBGState(false);
if (kret == KERN_SUCCESS) {
// Check to make sure we have the needed hardware support
uint32_t i = 0;
DBG &debug_state = m_state.context.dbg;
for (i = 0; i < num_hw_watchpoints; ++i) {
if (IsWatchpointVacant(debug_state, i))
break;
}
// See if we found an available hw breakpoint slot above
if (i < num_hw_watchpoints) {
StartTransForHWP();
// Modify our local copy of the debug state, first.
SetWatchpoint(debug_state, i, addr, size, read, write);
// Now set the watch point in the inferior.
kret = SetDBGState(also_set_on_task);
DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchImplX86_64::"
"EnableHardwareWatchpoint() "
"SetDBGState() => 0x%8.8x.",
kret);
if (kret == KERN_SUCCESS)
return i;
else // Revert to the previous debug state voluntarily. The transaction
// coordinator knows that we have failed.
m_state.context.dbg = GetDBGCheckpoint();
} else {
DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchImplX86_64::"
"EnableHardwareWatchpoint(): All "
"hardware resources (%u) are in use.",
num_hw_watchpoints);
}
}
return INVALID_NUB_HW_INDEX;
}
bool DNBArchImplX86_64::DisableHardwareWatchpoint(uint32_t hw_index,
bool also_set_on_task) {
kern_return_t kret = GetDBGState(false);
const uint32_t num_hw_points = NumSupportedHardwareWatchpoints();
if (kret == KERN_SUCCESS) {
DBG &debug_state = m_state.context.dbg;
if (hw_index < num_hw_points &&
!IsWatchpointVacant(debug_state, hw_index)) {
StartTransForHWP();
// Modify our local copy of the debug state, first.
ClearWatchpoint(debug_state, hw_index);
// Now disable the watch point in the inferior.
kret = SetDBGState(also_set_on_task);
DNBLogThreadedIf(LOG_WATCHPOINTS,
"DNBArchImplX86_64::DisableHardwareWatchpoint( %u )",
hw_index);
if (kret == KERN_SUCCESS)
return true;
else // Revert to the previous debug state voluntarily. The transaction
// coordinator knows that we have failed.
m_state.context.dbg = GetDBGCheckpoint();
}
}
return false;
}
// Iterate through the debug status register; return the index of the first hit.
uint32_t DNBArchImplX86_64::GetHardwareWatchpointHit(nub_addr_t &addr) {
// Read the debug state
kern_return_t kret = GetDBGState(true);
DNBLogThreadedIf(
LOG_WATCHPOINTS,
"DNBArchImplX86_64::GetHardwareWatchpointHit() GetDBGState() => 0x%8.8x.",
kret);
if (kret == KERN_SUCCESS) {
DBG &debug_state = m_state.context.dbg;
uint32_t i, num = NumSupportedHardwareWatchpoints();
for (i = 0; i < num; ++i) {
if (IsWatchpointHit(debug_state, i)) {
addr = GetWatchAddress(debug_state, i);
DNBLogThreadedIf(LOG_WATCHPOINTS, "DNBArchImplX86_64::"
"GetHardwareWatchpointHit() found => "
"%u (addr = 0x%llx).",
i, (uint64_t)addr);
return i;
}
}
}
return INVALID_NUB_HW_INDEX;
}
// Set the single step bit in the processor status register.
kern_return_t DNBArchImplX86_64::EnableHardwareSingleStep(bool enable) {
if (GetGPRState(false) == KERN_SUCCESS) {
const uint32_t trace_bit = 0x100u;
if (enable)
m_state.context.gpr.__rflags |= trace_bit;
else
m_state.context.gpr.__rflags &= ~trace_bit;
return SetGPRState();
}
return m_state.GetError(e_regSetGPR, Read);
}
//----------------------------------------------------------------------
// Register information definitions
//----------------------------------------------------------------------
enum {
gpr_rax = 0,
gpr_rbx,
gpr_rcx,
gpr_rdx,
gpr_rdi,
gpr_rsi,
gpr_rbp,
gpr_rsp,
gpr_r8,
gpr_r9,
gpr_r10,
gpr_r11,
gpr_r12,
gpr_r13,
gpr_r14,
gpr_r15,
gpr_rip,
gpr_rflags,
gpr_cs,
gpr_fs,
gpr_gs,
gpr_eax,
gpr_ebx,
gpr_ecx,
gpr_edx,
gpr_edi,
gpr_esi,
gpr_ebp,
gpr_esp,
gpr_r8d, // Low 32 bits or r8
gpr_r9d, // Low 32 bits or r9
gpr_r10d, // Low 32 bits or r10
gpr_r11d, // Low 32 bits or r11
gpr_r12d, // Low 32 bits or r12
gpr_r13d, // Low 32 bits or r13
gpr_r14d, // Low 32 bits or r14
gpr_r15d, // Low 32 bits or r15
gpr_ax,
gpr_bx,
gpr_cx,
gpr_dx,
gpr_di,
gpr_si,
gpr_bp,
gpr_sp,
gpr_r8w, // Low 16 bits or r8
gpr_r9w, // Low 16 bits or r9
gpr_r10w, // Low 16 bits or r10
gpr_r11w, // Low 16 bits or r11
gpr_r12w, // Low 16 bits or r12
gpr_r13w, // Low 16 bits or r13
gpr_r14w, // Low 16 bits or r14
gpr_r15w, // Low 16 bits or r15
gpr_ah,
gpr_bh,
gpr_ch,
gpr_dh,
gpr_al,
gpr_bl,
gpr_cl,
gpr_dl,
gpr_dil,
gpr_sil,
gpr_bpl,
gpr_spl,
gpr_r8l, // Low 8 bits or r8
gpr_r9l, // Low 8 bits or r9
gpr_r10l, // Low 8 bits or r10
gpr_r11l, // Low 8 bits or r11
gpr_r12l, // Low 8 bits or r12
gpr_r13l, // Low 8 bits or r13
gpr_r14l, // Low 8 bits or r14
gpr_r15l, // Low 8 bits or r15
k_num_gpr_regs
};
enum {
fpu_fcw,
fpu_fsw,
fpu_ftw,
fpu_fop,
fpu_ip,
fpu_cs,
fpu_dp,
fpu_ds,
fpu_mxcsr,
fpu_mxcsrmask,
fpu_stmm0,
fpu_stmm1,
fpu_stmm2,
fpu_stmm3,
fpu_stmm4,
fpu_stmm5,
fpu_stmm6,
fpu_stmm7,
fpu_xmm0,
fpu_xmm1,
fpu_xmm2,
fpu_xmm3,
fpu_xmm4,
fpu_xmm5,
fpu_xmm6,
fpu_xmm7,
fpu_xmm8,
fpu_xmm9,
fpu_xmm10,
fpu_xmm11,
fpu_xmm12,
fpu_xmm13,
fpu_xmm14,
fpu_xmm15,
fpu_ymm0,
fpu_ymm1,
fpu_ymm2,
fpu_ymm3,
fpu_ymm4,
fpu_ymm5,
fpu_ymm6,
fpu_ymm7,
fpu_ymm8,
fpu_ymm9,
fpu_ymm10,
fpu_ymm11,
fpu_ymm12,
fpu_ymm13,
fpu_ymm14,
fpu_ymm15,
fpu_k0,
fpu_k1,
fpu_k2,
fpu_k3,
fpu_k4,
fpu_k5,
fpu_k6,
fpu_k7,
fpu_zmm0,
fpu_zmm1,
fpu_zmm2,
fpu_zmm3,
fpu_zmm4,
fpu_zmm5,
fpu_zmm6,
fpu_zmm7,
fpu_zmm8,
fpu_zmm9,
fpu_zmm10,
fpu_zmm11,
fpu_zmm12,
fpu_zmm13,
fpu_zmm14,
fpu_zmm15,
fpu_zmm16,
fpu_zmm17,
fpu_zmm18,
fpu_zmm19,
fpu_zmm20,
fpu_zmm21,
fpu_zmm22,
fpu_zmm23,
fpu_zmm24,
fpu_zmm25,
fpu_zmm26,
fpu_zmm27,
fpu_zmm28,
fpu_zmm29,
fpu_zmm30,
fpu_zmm31,
k_num_fpu_regs,
// Aliases
fpu_fctrl = fpu_fcw,
fpu_fstat = fpu_fsw,
fpu_ftag = fpu_ftw,
fpu_fiseg = fpu_cs,
fpu_fioff = fpu_ip,
fpu_foseg = fpu_ds,
fpu_fooff = fpu_dp
};
enum {
exc_trapno,
exc_err,
exc_faultvaddr,
k_num_exc_regs,
};
enum ehframe_dwarf_regnums {
ehframe_dwarf_rax = 0,
ehframe_dwarf_rdx = 1,
ehframe_dwarf_rcx = 2,
ehframe_dwarf_rbx = 3,
ehframe_dwarf_rsi = 4,
ehframe_dwarf_rdi = 5,
ehframe_dwarf_rbp = 6,
ehframe_dwarf_rsp = 7,
ehframe_dwarf_r8,
ehframe_dwarf_r9,
ehframe_dwarf_r10,
ehframe_dwarf_r11,
ehframe_dwarf_r12,
ehframe_dwarf_r13,
ehframe_dwarf_r14,
ehframe_dwarf_r15,
ehframe_dwarf_rip,
ehframe_dwarf_xmm0,
ehframe_dwarf_xmm1,
ehframe_dwarf_xmm2,
ehframe_dwarf_xmm3,
ehframe_dwarf_xmm4,
ehframe_dwarf_xmm5,
ehframe_dwarf_xmm6,
ehframe_dwarf_xmm7,
ehframe_dwarf_xmm8,
ehframe_dwarf_xmm9,
ehframe_dwarf_xmm10,
ehframe_dwarf_xmm11,
ehframe_dwarf_xmm12,
ehframe_dwarf_xmm13,
ehframe_dwarf_xmm14,
ehframe_dwarf_xmm15,
ehframe_dwarf_stmm0,
ehframe_dwarf_stmm1,
ehframe_dwarf_stmm2,
ehframe_dwarf_stmm3,
ehframe_dwarf_stmm4,
ehframe_dwarf_stmm5,
ehframe_dwarf_stmm6,
ehframe_dwarf_stmm7,
ehframe_dwarf_ymm0 = ehframe_dwarf_xmm0,
ehframe_dwarf_ymm1 = ehframe_dwarf_xmm1,
ehframe_dwarf_ymm2 = ehframe_dwarf_xmm2,
ehframe_dwarf_ymm3 = ehframe_dwarf_xmm3,
ehframe_dwarf_ymm4 = ehframe_dwarf_xmm4,
ehframe_dwarf_ymm5 = ehframe_dwarf_xmm5,
ehframe_dwarf_ymm6 = ehframe_dwarf_xmm6,
ehframe_dwarf_ymm7 = ehframe_dwarf_xmm7,
ehframe_dwarf_ymm8 = ehframe_dwarf_xmm8,
ehframe_dwarf_ymm9 = ehframe_dwarf_xmm9,
ehframe_dwarf_ymm10 = ehframe_dwarf_xmm10,
ehframe_dwarf_ymm11 = ehframe_dwarf_xmm11,
ehframe_dwarf_ymm12 = ehframe_dwarf_xmm12,
ehframe_dwarf_ymm13 = ehframe_dwarf_xmm13,
ehframe_dwarf_ymm14 = ehframe_dwarf_xmm14,
ehframe_dwarf_ymm15 = ehframe_dwarf_xmm15,
ehframe_dwarf_zmm0 = ehframe_dwarf_xmm0,
ehframe_dwarf_zmm1 = ehframe_dwarf_xmm1,
ehframe_dwarf_zmm2 = ehframe_dwarf_xmm2,
ehframe_dwarf_zmm3 = ehframe_dwarf_xmm3,
ehframe_dwarf_zmm4 = ehframe_dwarf_xmm4,
ehframe_dwarf_zmm5 = ehframe_dwarf_xmm5,
ehframe_dwarf_zmm6 = ehframe_dwarf_xmm6,
ehframe_dwarf_zmm7 = ehframe_dwarf_xmm7,
ehframe_dwarf_zmm8 = ehframe_dwarf_xmm8,
ehframe_dwarf_zmm9 = ehframe_dwarf_xmm9,
ehframe_dwarf_zmm10 = ehframe_dwarf_xmm10,
ehframe_dwarf_zmm11 = ehframe_dwarf_xmm11,
ehframe_dwarf_zmm12 = ehframe_dwarf_xmm12,
ehframe_dwarf_zmm13 = ehframe_dwarf_xmm13,
ehframe_dwarf_zmm14 = ehframe_dwarf_xmm14,
ehframe_dwarf_zmm15 = ehframe_dwarf_xmm15,
ehframe_dwarf_zmm16 = 67,
ehframe_dwarf_zmm17,
ehframe_dwarf_zmm18,
ehframe_dwarf_zmm19,
ehframe_dwarf_zmm20,
ehframe_dwarf_zmm21,
ehframe_dwarf_zmm22,
ehframe_dwarf_zmm23,
ehframe_dwarf_zmm24,
ehframe_dwarf_zmm25,
ehframe_dwarf_zmm26,
ehframe_dwarf_zmm27,
ehframe_dwarf_zmm28,
ehframe_dwarf_zmm29,
ehframe_dwarf_zmm30,
ehframe_dwarf_zmm31,
ehframe_dwarf_k0 = 118,
ehframe_dwarf_k1,
ehframe_dwarf_k2,
ehframe_dwarf_k3,
ehframe_dwarf_k4,
ehframe_dwarf_k5,
ehframe_dwarf_k6,
ehframe_dwarf_k7,
};
enum debugserver_regnums {
debugserver_rax = 0,
debugserver_rbx = 1,
debugserver_rcx = 2,
debugserver_rdx = 3,
debugserver_rsi = 4,
debugserver_rdi = 5,
debugserver_rbp = 6,
debugserver_rsp = 7,
debugserver_r8 = 8,
debugserver_r9 = 9,
debugserver_r10 = 10,
debugserver_r11 = 11,
debugserver_r12 = 12,
debugserver_r13 = 13,
debugserver_r14 = 14,
debugserver_r15 = 15,
debugserver_rip = 16,
debugserver_rflags = 17,
debugserver_cs = 18,
debugserver_ss = 19,
debugserver_ds = 20,
debugserver_es = 21,
debugserver_fs = 22,
debugserver_gs = 23,
debugserver_stmm0 = 24,
debugserver_stmm1 = 25,
debugserver_stmm2 = 26,
debugserver_stmm3 = 27,
debugserver_stmm4 = 28,
debugserver_stmm5 = 29,
debugserver_stmm6 = 30,
debugserver_stmm7 = 31,
debugserver_fctrl = 32,
debugserver_fcw = debugserver_fctrl,
debugserver_fstat = 33,
debugserver_fsw = debugserver_fstat,
debugserver_ftag = 34,
debugserver_ftw = debugserver_ftag,
debugserver_fiseg = 35,
debugserver_fpu_cs = debugserver_fiseg,
debugserver_fioff = 36,
debugserver_ip = debugserver_fioff,
debugserver_foseg = 37,
debugserver_fpu_ds = debugserver_foseg,
debugserver_fooff = 38,
debugserver_dp = debugserver_fooff,
debugserver_fop = 39,
debugserver_xmm0 = 40,
debugserver_xmm1 = 41,
debugserver_xmm2 = 42,
debugserver_xmm3 = 43,
debugserver_xmm4 = 44,
debugserver_xmm5 = 45,
debugserver_xmm6 = 46,
debugserver_xmm7 = 47,
debugserver_xmm8 = 48,
debugserver_xmm9 = 49,
debugserver_xmm10 = 50,
debugserver_xmm11 = 51,
debugserver_xmm12 = 52,
debugserver_xmm13 = 53,
debugserver_xmm14 = 54,
debugserver_xmm15 = 55,
debugserver_mxcsr = 56,
debugserver_ymm0 = debugserver_xmm0,
debugserver_ymm1 = debugserver_xmm1,
debugserver_ymm2 = debugserver_xmm2,
debugserver_ymm3 = debugserver_xmm3,
debugserver_ymm4 = debugserver_xmm4,
debugserver_ymm5 = debugserver_xmm5,
debugserver_ymm6 = debugserver_xmm6,
debugserver_ymm7 = debugserver_xmm7,
debugserver_ymm8 = debugserver_xmm8,
debugserver_ymm9 = debugserver_xmm9,
debugserver_ymm10 = debugserver_xmm10,
debugserver_ymm11 = debugserver_xmm11,
debugserver_ymm12 = debugserver_xmm12,
debugserver_ymm13 = debugserver_xmm13,
debugserver_ymm14 = debugserver_xmm14,
debugserver_ymm15 = debugserver_xmm15,
debugserver_zmm0 = debugserver_xmm0,
debugserver_zmm1 = debugserver_xmm1,
debugserver_zmm2 = debugserver_xmm2,
debugserver_zmm3 = debugserver_xmm3,
debugserver_zmm4 = debugserver_xmm4,
debugserver_zmm5 = debugserver_xmm5,
debugserver_zmm6 = debugserver_xmm6,
debugserver_zmm7 = debugserver_xmm7,
debugserver_zmm8 = debugserver_xmm8,
debugserver_zmm9 = debugserver_xmm9,
debugserver_zmm10 = debugserver_xmm10,
debugserver_zmm11 = debugserver_xmm11,
debugserver_zmm12 = debugserver_xmm12,
debugserver_zmm13 = debugserver_xmm13,
debugserver_zmm14 = debugserver_xmm14,
debugserver_zmm15 = debugserver_xmm15,
debugserver_zmm16 = 67,
debugserver_zmm17 = 68,
debugserver_zmm18 = 69,
debugserver_zmm19 = 70,
debugserver_zmm20 = 71,
debugserver_zmm21 = 72,
debugserver_zmm22 = 73,
debugserver_zmm23 = 74,
debugserver_zmm24 = 75,
debugserver_zmm25 = 76,
debugserver_zmm26 = 77,
debugserver_zmm27 = 78,
debugserver_zmm28 = 79,
debugserver_zmm29 = 80,
debugserver_zmm30 = 81,
debugserver_zmm31 = 82,
debugserver_k0 = 118,
debugserver_k1 = 119,
debugserver_k2 = 120,
debugserver_k3 = 121,
debugserver_k4 = 122,
debugserver_k5 = 123,
debugserver_k6 = 124,
debugserver_k7 = 125,
};
#define GPR_OFFSET(reg) (offsetof(DNBArchImplX86_64::GPR, __##reg))
#define FPU_OFFSET(reg) \
(offsetof(DNBArchImplX86_64::FPU, __fpu_##reg) + \
offsetof(DNBArchImplX86_64::Context, fpu.no_avx))
#define AVX_OFFSET(reg) \
(offsetof(DNBArchImplX86_64::AVX, __fpu_##reg) + \
offsetof(DNBArchImplX86_64::Context, fpu.avx))
#define AVX512F_OFFSET(reg) \
(offsetof(DNBArchImplX86_64::AVX512F, __fpu_##reg) + \
offsetof(DNBArchImplX86_64::Context, fpu.avx512f))
#define EXC_OFFSET(reg) \
(offsetof(DNBArchImplX86_64::EXC, __##reg) + \
offsetof(DNBArchImplX86_64::Context, exc))
#define AVX_OFFSET_YMM(n) (AVX_OFFSET(ymmh0) + (32 * n))
#define AVX512F_OFFSET_ZMM(n) (AVX512F_OFFSET(zmmh0) + (64 * n))
#define GPR_SIZE(reg) (sizeof(((DNBArchImplX86_64::GPR *)NULL)->__##reg))
#define FPU_SIZE_UINT(reg) \
(sizeof(((DNBArchImplX86_64::FPU *)NULL)->__fpu_##reg))
#define FPU_SIZE_MMST(reg) \
(sizeof(((DNBArchImplX86_64::FPU *)NULL)->__fpu_##reg.__mmst_reg))
#define FPU_SIZE_XMM(reg) \
(sizeof(((DNBArchImplX86_64::FPU *)NULL)->__fpu_##reg.__xmm_reg))
#define FPU_SIZE_YMM(reg) (32)
#define FPU_SIZE_ZMM(reg) (64)
#define EXC_SIZE(reg) (sizeof(((DNBArchImplX86_64::EXC *)NULL)->__##reg))
// These macros will auto define the register name, alt name, register size,
// register offset, encoding, format and native register. This ensures that
// the register state structures are defined correctly and have the correct
// sizes and offsets.
#define DEFINE_GPR(reg) \
{ \
e_regSetGPR, gpr_##reg, #reg, NULL, Uint, Hex, GPR_SIZE(reg), \
GPR_OFFSET(reg), ehframe_dwarf_##reg, ehframe_dwarf_##reg, \
INVALID_NUB_REGNUM, debugserver_##reg, NULL, g_invalidate_##reg \
}
#define DEFINE_GPR_ALT(reg, alt, gen) \
{ \
e_regSetGPR, gpr_##reg, #reg, alt, Uint, Hex, GPR_SIZE(reg), \
GPR_OFFSET(reg), ehframe_dwarf_##reg, ehframe_dwarf_##reg, gen, \
debugserver_##reg, NULL, g_invalidate_##reg \
}
#define DEFINE_GPR_ALT2(reg, alt) \
{ \
e_regSetGPR, gpr_##reg, #reg, alt, Uint, Hex, GPR_SIZE(reg), \
GPR_OFFSET(reg), INVALID_NUB_REGNUM, INVALID_NUB_REGNUM, \
INVALID_NUB_REGNUM, debugserver_##reg, NULL, NULL \
}
#define DEFINE_GPR_ALT3(reg, alt, gen) \
{ \
e_regSetGPR, gpr_##reg, #reg, alt, Uint, Hex, GPR_SIZE(reg), \
GPR_OFFSET(reg), INVALID_NUB_REGNUM, INVALID_NUB_REGNUM, gen, \
debugserver_##reg, NULL, NULL \
}
#define DEFINE_GPR_ALT4(reg, alt, gen) \
{ \
e_regSetGPR, gpr_##reg, #reg, alt, Uint, Hex, GPR_SIZE(reg), \
GPR_OFFSET(reg), ehframe_dwarf_##reg, ehframe_dwarf_##reg, gen, \
debugserver_##reg, NULL, NULL \
}
#define DEFINE_GPR_PSEUDO_32(reg32, reg64) \
{ \
e_regSetGPR, gpr_##reg32, #reg32, NULL, Uint, Hex, 4, 0, \
INVALID_NUB_REGNUM, INVALID_NUB_REGNUM, INVALID_NUB_REGNUM, \
INVALID_NUB_REGNUM, g_contained_##reg64, g_invalidate_##reg64 \
}
#define DEFINE_GPR_PSEUDO_16(reg16, reg64) \
{ \
e_regSetGPR, gpr_##reg16, #reg16, NULL, Uint, Hex, 2, 0, \
INVALID_NUB_REGNUM, INVALID_NUB_REGNUM, INVALID_NUB_REGNUM, \
INVALID_NUB_REGNUM, g_contained_##reg64, g_invalidate_##reg64 \
}
#define DEFINE_GPR_PSEUDO_8H(reg8, reg64) \
{ \
e_regSetGPR, gpr_##reg8, #reg8, NULL, Uint, Hex, 1, 1, INVALID_NUB_REGNUM, \
INVALID_NUB_REGNUM, INVALID_NUB_REGNUM, INVALID_NUB_REGNUM, \
g_contained_##reg64, g_invalidate_##reg64 \
}
#define DEFINE_GPR_PSEUDO_8L(reg8, reg64) \
{ \
e_regSetGPR, gpr_##reg8, #reg8, NULL, Uint, Hex, 1, 0, INVALID_NUB_REGNUM, \
INVALID_NUB_REGNUM, INVALID_NUB_REGNUM, INVALID_NUB_REGNUM, \
g_contained_##reg64, g_invalidate_##reg64 \
}
// General purpose registers for 64 bit
const char *g_contained_rax[] = {"rax", NULL};
const char *g_contained_rbx[] = {"rbx", NULL};
const char *g_contained_rcx[] = {"rcx", NULL};
const char *g_contained_rdx[] = {"rdx", NULL};
const char *g_contained_rdi[] = {"rdi", NULL};
const char *g_contained_rsi[] = {"rsi", NULL};
const char *g_contained_rbp[] = {"rbp", NULL};
const char *g_contained_rsp[] = {"rsp", NULL};
const char *g_contained_r8[] = {"r8", NULL};
const char *g_contained_r9[] = {"r9", NULL};
const char *g_contained_r10[] = {"r10", NULL};
const char *g_contained_r11[] = {"r11", NULL};
const char *g_contained_r12[] = {"r12", NULL};
const char *g_contained_r13[] = {"r13", NULL};
const char *g_contained_r14[] = {"r14", NULL};
const char *g_contained_r15[] = {"r15", NULL};
const char *g_invalidate_rax[] = {"rax", "eax", "ax", "ah", "al", NULL};
const char *g_invalidate_rbx[] = {"rbx", "ebx", "bx", "bh", "bl", NULL};
const char *g_invalidate_rcx[] = {"rcx", "ecx", "cx", "ch", "cl", NULL};
const char *g_invalidate_rdx[] = {"rdx", "edx", "dx", "dh", "dl", NULL};
const char *g_invalidate_rdi[] = {"rdi", "edi", "di", "dil", NULL};
const char *g_invalidate_rsi[] = {"rsi", "esi", "si", "sil", NULL};
const char *g_invalidate_rbp[] = {"rbp", "ebp", "bp", "bpl", NULL};
const char *g_invalidate_rsp[] = {"rsp", "esp", "sp", "spl", NULL};
const char *g_invalidate_r8[] = {"r8", "r8d", "r8w", "r8l", NULL};
const char *g_invalidate_r9[] = {"r9", "r9d", "r9w", "r9l", NULL};
const char *g_invalidate_r10[] = {"r10", "r10d", "r10w", "r10l", NULL};
const char *g_invalidate_r11[] = {"r11", "r11d", "r11w", "r11l", NULL};
const char *g_invalidate_r12[] = {"r12", "r12d", "r12w", "r12l", NULL};
const char *g_invalidate_r13[] = {"r13", "r13d", "r13w", "r13l", NULL};
const char *g_invalidate_r14[] = {"r14", "r14d", "r14w", "r14l", NULL};
const char *g_invalidate_r15[] = {"r15", "r15d", "r15w", "r15l", NULL};
const DNBRegisterInfo DNBArchImplX86_64::g_gpr_registers[] = {
DEFINE_GPR(rax),
DEFINE_GPR(rbx),
DEFINE_GPR_ALT(rcx, "arg4", GENERIC_REGNUM_ARG4),
DEFINE_GPR_ALT(rdx, "arg3", GENERIC_REGNUM_ARG3),
DEFINE_GPR_ALT(rdi, "arg1", GENERIC_REGNUM_ARG1),
DEFINE_GPR_ALT(rsi, "arg2", GENERIC_REGNUM_ARG2),
DEFINE_GPR_ALT(rbp, "fp", GENERIC_REGNUM_FP),
DEFINE_GPR_ALT(rsp, "sp", GENERIC_REGNUM_SP),
DEFINE_GPR_ALT(r8, "arg5", GENERIC_REGNUM_ARG5),
DEFINE_GPR_ALT(r9, "arg6", GENERIC_REGNUM_ARG6),
DEFINE_GPR(r10),
DEFINE_GPR(r11),
DEFINE_GPR(r12),
DEFINE_GPR(r13),
DEFINE_GPR(r14),
DEFINE_GPR(r15),
DEFINE_GPR_ALT4(rip, "pc", GENERIC_REGNUM_PC),
DEFINE_GPR_ALT3(rflags, "flags", GENERIC_REGNUM_FLAGS),
DEFINE_GPR_ALT2(cs, NULL),
DEFINE_GPR_ALT2(fs, NULL),
DEFINE_GPR_ALT2(gs, NULL),
DEFINE_GPR_PSEUDO_32(eax, rax),
DEFINE_GPR_PSEUDO_32(ebx, rbx),
DEFINE_GPR_PSEUDO_32(ecx, rcx),
DEFINE_GPR_PSEUDO_32(edx, rdx),
DEFINE_GPR_PSEUDO_32(edi, rdi),
DEFINE_GPR_PSEUDO_32(esi, rsi),
DEFINE_GPR_PSEUDO_32(ebp, rbp),
DEFINE_GPR_PSEUDO_32(esp, rsp),
DEFINE_GPR_PSEUDO_32(r8d, r8),
DEFINE_GPR_PSEUDO_32(r9d, r9),
DEFINE_GPR_PSEUDO_32(r10d, r10),
DEFINE_GPR_PSEUDO_32(r11d, r11),
DEFINE_GPR_PSEUDO_32(r12d, r12),
DEFINE_GPR_PSEUDO_32(r13d, r13),
DEFINE_GPR_PSEUDO_32(r14d, r14),
DEFINE_GPR_PSEUDO_32(r15d, r15),
DEFINE_GPR_PSEUDO_16(ax, rax),
DEFINE_GPR_PSEUDO_16(bx, rbx),
DEFINE_GPR_PSEUDO_16(cx, rcx),
DEFINE_GPR_PSEUDO_16(dx, rdx),
DEFINE_GPR_PSEUDO_16(di, rdi),
DEFINE_GPR_PSEUDO_16(si, rsi),
DEFINE_GPR_PSEUDO_16(bp, rbp),
DEFINE_GPR_PSEUDO_16(sp, rsp),
DEFINE_GPR_PSEUDO_16(r8w, r8),
DEFINE_GPR_PSEUDO_16(r9w, r9),
DEFINE_GPR_PSEUDO_16(r10w, r10),
DEFINE_GPR_PSEUDO_16(r11w, r11),
DEFINE_GPR_PSEUDO_16(r12w, r12),
DEFINE_GPR_PSEUDO_16(r13w, r13),
DEFINE_GPR_PSEUDO_16(r14w, r14),
DEFINE_GPR_PSEUDO_16(r15w, r15),
DEFINE_GPR_PSEUDO_8H(ah, rax),
DEFINE_GPR_PSEUDO_8H(bh, rbx),
DEFINE_GPR_PSEUDO_8H(ch, rcx),
DEFINE_GPR_PSEUDO_8H(dh, rdx),
DEFINE_GPR_PSEUDO_8L(al, rax),
DEFINE_GPR_PSEUDO_8L(bl, rbx),
DEFINE_GPR_PSEUDO_8L(cl, rcx),
DEFINE_GPR_PSEUDO_8L(dl, rdx),
DEFINE_GPR_PSEUDO_8L(dil, rdi),
DEFINE_GPR_PSEUDO_8L(sil, rsi),
DEFINE_GPR_PSEUDO_8L(bpl, rbp),
DEFINE_GPR_PSEUDO_8L(spl, rsp),
DEFINE_GPR_PSEUDO_8L(r8l, r8),
DEFINE_GPR_PSEUDO_8L(r9l, r9),
DEFINE_GPR_PSEUDO_8L(r10l, r10),
DEFINE_GPR_PSEUDO_8L(r11l, r11),
DEFINE_GPR_PSEUDO_8L(r12l, r12),
DEFINE_GPR_PSEUDO_8L(r13l, r13),
DEFINE_GPR_PSEUDO_8L(r14l, r14),
DEFINE_GPR_PSEUDO_8L(r15l, r15)};
// Floating point registers 64 bit
const DNBRegisterInfo DNBArchImplX86_64::g_fpu_registers_no_avx[] = {
{e_regSetFPU, fpu_fcw, "fctrl", NULL, Uint, Hex, FPU_SIZE_UINT(fcw),
FPU_OFFSET(fcw), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_fsw, "fstat", NULL, Uint, Hex, FPU_SIZE_UINT(fsw),
FPU_OFFSET(fsw), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_ftw, "ftag", NULL, Uint, Hex, 2 /* sizeof __fpu_ftw + sizeof __fpu_rsrv1 */,
FPU_OFFSET(ftw), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_fop, "fop", NULL, Uint, Hex, FPU_SIZE_UINT(fop),
FPU_OFFSET(fop), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_ip, "fioff", NULL, Uint, Hex, FPU_SIZE_UINT(ip),
FPU_OFFSET(ip), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_cs, "fiseg", NULL, Uint, Hex, FPU_SIZE_UINT(cs),
FPU_OFFSET(cs), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_dp, "fooff", NULL, Uint, Hex, FPU_SIZE_UINT(dp),
FPU_OFFSET(dp), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_ds, "foseg", NULL, Uint, Hex, FPU_SIZE_UINT(ds),
FPU_OFFSET(ds), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_mxcsr, "mxcsr", NULL, Uint, Hex, FPU_SIZE_UINT(mxcsr),
FPU_OFFSET(mxcsr), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_mxcsrmask, "mxcsrmask", NULL, Uint, Hex,
FPU_SIZE_UINT(mxcsrmask), FPU_OFFSET(mxcsrmask), -1U, -1U, -1U, -1U, NULL,
NULL},
{e_regSetFPU, fpu_stmm0, "stmm0", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm0), FPU_OFFSET(stmm0), ehframe_dwarf_stmm0,
ehframe_dwarf_stmm0, -1U, debugserver_stmm0, NULL, NULL},
{e_regSetFPU, fpu_stmm1, "stmm1", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm1), FPU_OFFSET(stmm1), ehframe_dwarf_stmm1,
ehframe_dwarf_stmm1, -1U, debugserver_stmm1, NULL, NULL},
{e_regSetFPU, fpu_stmm2, "stmm2", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm2), FPU_OFFSET(stmm2), ehframe_dwarf_stmm2,
ehframe_dwarf_stmm2, -1U, debugserver_stmm2, NULL, NULL},
{e_regSetFPU, fpu_stmm3, "stmm3", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm3), FPU_OFFSET(stmm3), ehframe_dwarf_stmm3,
ehframe_dwarf_stmm3, -1U, debugserver_stmm3, NULL, NULL},
{e_regSetFPU, fpu_stmm4, "stmm4", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm4), FPU_OFFSET(stmm4), ehframe_dwarf_stmm4,
ehframe_dwarf_stmm4, -1U, debugserver_stmm4, NULL, NULL},
{e_regSetFPU, fpu_stmm5, "stmm5", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm5), FPU_OFFSET(stmm5), ehframe_dwarf_stmm5,
ehframe_dwarf_stmm5, -1U, debugserver_stmm5, NULL, NULL},
{e_regSetFPU, fpu_stmm6, "stmm6", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm6), FPU_OFFSET(stmm6), ehframe_dwarf_stmm6,
ehframe_dwarf_stmm6, -1U, debugserver_stmm6, NULL, NULL},
{e_regSetFPU, fpu_stmm7, "stmm7", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm7), FPU_OFFSET(stmm7), ehframe_dwarf_stmm7,
ehframe_dwarf_stmm7, -1U, debugserver_stmm7, NULL, NULL},
{e_regSetFPU, fpu_xmm0, "xmm0", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm0), FPU_OFFSET(xmm0), ehframe_dwarf_xmm0,
ehframe_dwarf_xmm0, -1U, debugserver_xmm0, NULL, NULL},
{e_regSetFPU, fpu_xmm1, "xmm1", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm1), FPU_OFFSET(xmm1), ehframe_dwarf_xmm1,
ehframe_dwarf_xmm1, -1U, debugserver_xmm1, NULL, NULL},
{e_regSetFPU, fpu_xmm2, "xmm2", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm2), FPU_OFFSET(xmm2), ehframe_dwarf_xmm2,
ehframe_dwarf_xmm2, -1U, debugserver_xmm2, NULL, NULL},
{e_regSetFPU, fpu_xmm3, "xmm3", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm3), FPU_OFFSET(xmm3), ehframe_dwarf_xmm3,
ehframe_dwarf_xmm3, -1U, debugserver_xmm3, NULL, NULL},
{e_regSetFPU, fpu_xmm4, "xmm4", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm4), FPU_OFFSET(xmm4), ehframe_dwarf_xmm4,
ehframe_dwarf_xmm4, -1U, debugserver_xmm4, NULL, NULL},
{e_regSetFPU, fpu_xmm5, "xmm5", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm5), FPU_OFFSET(xmm5), ehframe_dwarf_xmm5,
ehframe_dwarf_xmm5, -1U, debugserver_xmm5, NULL, NULL},
{e_regSetFPU, fpu_xmm6, "xmm6", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm6), FPU_OFFSET(xmm6), ehframe_dwarf_xmm6,
ehframe_dwarf_xmm6, -1U, debugserver_xmm6, NULL, NULL},
{e_regSetFPU, fpu_xmm7, "xmm7", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm7), FPU_OFFSET(xmm7), ehframe_dwarf_xmm7,
ehframe_dwarf_xmm7, -1U, debugserver_xmm7, NULL, NULL},
{e_regSetFPU, fpu_xmm8, "xmm8", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm8), FPU_OFFSET(xmm8), ehframe_dwarf_xmm8,
ehframe_dwarf_xmm8, -1U, debugserver_xmm8, NULL, NULL},
{e_regSetFPU, fpu_xmm9, "xmm9", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm9), FPU_OFFSET(xmm9), ehframe_dwarf_xmm9,
ehframe_dwarf_xmm9, -1U, debugserver_xmm9, NULL, NULL},
{e_regSetFPU, fpu_xmm10, "xmm10", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm10), FPU_OFFSET(xmm10), ehframe_dwarf_xmm10,
ehframe_dwarf_xmm10, -1U, debugserver_xmm10, NULL, NULL},
{e_regSetFPU, fpu_xmm11, "xmm11", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm11), FPU_OFFSET(xmm11), ehframe_dwarf_xmm11,
ehframe_dwarf_xmm11, -1U, debugserver_xmm11, NULL, NULL},
{e_regSetFPU, fpu_xmm12, "xmm12", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm12), FPU_OFFSET(xmm12), ehframe_dwarf_xmm12,
ehframe_dwarf_xmm12, -1U, debugserver_xmm12, NULL, NULL},
{e_regSetFPU, fpu_xmm13, "xmm13", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm13), FPU_OFFSET(xmm13), ehframe_dwarf_xmm13,
ehframe_dwarf_xmm13, -1U, debugserver_xmm13, NULL, NULL},
{e_regSetFPU, fpu_xmm14, "xmm14", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm14), FPU_OFFSET(xmm14), ehframe_dwarf_xmm14,
ehframe_dwarf_xmm14, -1U, debugserver_xmm14, NULL, NULL},
{e_regSetFPU, fpu_xmm15, "xmm15", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm15), FPU_OFFSET(xmm15), ehframe_dwarf_xmm15,
ehframe_dwarf_xmm15, -1U, debugserver_xmm15, NULL, NULL},
};
static const char *g_contained_ymm0[] = {"ymm0", NULL};
static const char *g_contained_ymm1[] = {"ymm1", NULL};
static const char *g_contained_ymm2[] = {"ymm2", NULL};
static const char *g_contained_ymm3[] = {"ymm3", NULL};
static const char *g_contained_ymm4[] = {"ymm4", NULL};
static const char *g_contained_ymm5[] = {"ymm5", NULL};
static const char *g_contained_ymm6[] = {"ymm6", NULL};
static const char *g_contained_ymm7[] = {"ymm7", NULL};
static const char *g_contained_ymm8[] = {"ymm8", NULL};
static const char *g_contained_ymm9[] = {"ymm9", NULL};
static const char *g_contained_ymm10[] = {"ymm10", NULL};
static const char *g_contained_ymm11[] = {"ymm11", NULL};
static const char *g_contained_ymm12[] = {"ymm12", NULL};
static const char *g_contained_ymm13[] = {"ymm13", NULL};
static const char *g_contained_ymm14[] = {"ymm14", NULL};
static const char *g_contained_ymm15[] = {"ymm15", NULL};
const DNBRegisterInfo DNBArchImplX86_64::g_fpu_registers_avx[] = {
{e_regSetFPU, fpu_fcw, "fctrl", NULL, Uint, Hex, FPU_SIZE_UINT(fcw),
AVX_OFFSET(fcw), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_fsw, "fstat", NULL, Uint, Hex, FPU_SIZE_UINT(fsw),
AVX_OFFSET(fsw), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_ftw, "ftag", NULL, Uint, Hex, 2 /* sizeof __fpu_ftw + sizeof __fpu_rsrv1 */,
AVX_OFFSET(ftw), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_fop, "fop", NULL, Uint, Hex, FPU_SIZE_UINT(fop),
AVX_OFFSET(fop), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_ip, "fioff", NULL, Uint, Hex, FPU_SIZE_UINT(ip),
AVX_OFFSET(ip), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_cs, "fiseg", NULL, Uint, Hex, FPU_SIZE_UINT(cs),
AVX_OFFSET(cs), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_dp, "fooff", NULL, Uint, Hex, FPU_SIZE_UINT(dp),
AVX_OFFSET(dp), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_ds, "foseg", NULL, Uint, Hex, FPU_SIZE_UINT(ds),
AVX_OFFSET(ds), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_mxcsr, "mxcsr", NULL, Uint, Hex, FPU_SIZE_UINT(mxcsr),
AVX_OFFSET(mxcsr), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_mxcsrmask, "mxcsrmask", NULL, Uint, Hex,
FPU_SIZE_UINT(mxcsrmask), AVX_OFFSET(mxcsrmask), -1U, -1U, -1U, -1U, NULL,
NULL},
{e_regSetFPU, fpu_stmm0, "stmm0", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm0), AVX_OFFSET(stmm0), ehframe_dwarf_stmm0,
ehframe_dwarf_stmm0, -1U, debugserver_stmm0, NULL, NULL},
{e_regSetFPU, fpu_stmm1, "stmm1", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm1), AVX_OFFSET(stmm1), ehframe_dwarf_stmm1,
ehframe_dwarf_stmm1, -1U, debugserver_stmm1, NULL, NULL},
{e_regSetFPU, fpu_stmm2, "stmm2", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm2), AVX_OFFSET(stmm2), ehframe_dwarf_stmm2,
ehframe_dwarf_stmm2, -1U, debugserver_stmm2, NULL, NULL},
{e_regSetFPU, fpu_stmm3, "stmm3", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm3), AVX_OFFSET(stmm3), ehframe_dwarf_stmm3,
ehframe_dwarf_stmm3, -1U, debugserver_stmm3, NULL, NULL},
{e_regSetFPU, fpu_stmm4, "stmm4", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm4), AVX_OFFSET(stmm4), ehframe_dwarf_stmm4,
ehframe_dwarf_stmm4, -1U, debugserver_stmm4, NULL, NULL},
{e_regSetFPU, fpu_stmm5, "stmm5", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm5), AVX_OFFSET(stmm5), ehframe_dwarf_stmm5,
ehframe_dwarf_stmm5, -1U, debugserver_stmm5, NULL, NULL},
{e_regSetFPU, fpu_stmm6, "stmm6", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm6), AVX_OFFSET(stmm6), ehframe_dwarf_stmm6,
ehframe_dwarf_stmm6, -1U, debugserver_stmm6, NULL, NULL},
{e_regSetFPU, fpu_stmm7, "stmm7", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm7), AVX_OFFSET(stmm7), ehframe_dwarf_stmm7,
ehframe_dwarf_stmm7, -1U, debugserver_stmm7, NULL, NULL},
{e_regSetFPU, fpu_ymm0, "ymm0", NULL, Vector, VectorOfUInt8,
FPU_SIZE_YMM(ymm0), AVX_OFFSET_YMM(0), ehframe_dwarf_ymm0,
ehframe_dwarf_ymm0, -1U, debugserver_ymm0, NULL, NULL},
{e_regSetFPU, fpu_ymm1, "ymm1", NULL, Vector, VectorOfUInt8,
FPU_SIZE_YMM(ymm1), AVX_OFFSET_YMM(1), ehframe_dwarf_ymm1,
ehframe_dwarf_ymm1, -1U, debugserver_ymm1, NULL, NULL},
{e_regSetFPU, fpu_ymm2, "ymm2", NULL, Vector, VectorOfUInt8,
FPU_SIZE_YMM(ymm2), AVX_OFFSET_YMM(2), ehframe_dwarf_ymm2,
ehframe_dwarf_ymm2, -1U, debugserver_ymm2, NULL, NULL},
{e_regSetFPU, fpu_ymm3, "ymm3", NULL, Vector, VectorOfUInt8,
FPU_SIZE_YMM(ymm3), AVX_OFFSET_YMM(3), ehframe_dwarf_ymm3,
ehframe_dwarf_ymm3, -1U, debugserver_ymm3, NULL, NULL},
{e_regSetFPU, fpu_ymm4, "ymm4", NULL, Vector, VectorOfUInt8,
FPU_SIZE_YMM(ymm4), AVX_OFFSET_YMM(4), ehframe_dwarf_ymm4,
ehframe_dwarf_ymm4, -1U, debugserver_ymm4, NULL, NULL},
{e_regSetFPU, fpu_ymm5, "ymm5", NULL, Vector, VectorOfUInt8,
FPU_SIZE_YMM(ymm5), AVX_OFFSET_YMM(5), ehframe_dwarf_ymm5,
ehframe_dwarf_ymm5, -1U, debugserver_ymm5, NULL, NULL},
{e_regSetFPU, fpu_ymm6, "ymm6", NULL, Vector, VectorOfUInt8,
FPU_SIZE_YMM(ymm6), AVX_OFFSET_YMM(6), ehframe_dwarf_ymm6,
ehframe_dwarf_ymm6, -1U, debugserver_ymm6, NULL, NULL},
{e_regSetFPU, fpu_ymm7, "ymm7", NULL, Vector, VectorOfUInt8,
FPU_SIZE_YMM(ymm7), AVX_OFFSET_YMM(7), ehframe_dwarf_ymm7,
ehframe_dwarf_ymm7, -1U, debugserver_ymm7, NULL, NULL},
{e_regSetFPU, fpu_ymm8, "ymm8", NULL, Vector, VectorOfUInt8,
FPU_SIZE_YMM(ymm8), AVX_OFFSET_YMM(8), ehframe_dwarf_ymm8,
ehframe_dwarf_ymm8, -1U, debugserver_ymm8, NULL, NULL},
{e_regSetFPU, fpu_ymm9, "ymm9", NULL, Vector, VectorOfUInt8,
FPU_SIZE_YMM(ymm9), AVX_OFFSET_YMM(9), ehframe_dwarf_ymm9,
ehframe_dwarf_ymm9, -1U, debugserver_ymm9, NULL, NULL},
{e_regSetFPU, fpu_ymm10, "ymm10", NULL, Vector, VectorOfUInt8,
FPU_SIZE_YMM(ymm10), AVX_OFFSET_YMM(10), ehframe_dwarf_ymm10,
ehframe_dwarf_ymm10, -1U, debugserver_ymm10, NULL, NULL},
{e_regSetFPU, fpu_ymm11, "ymm11", NULL, Vector, VectorOfUInt8,
FPU_SIZE_YMM(ymm11), AVX_OFFSET_YMM(11), ehframe_dwarf_ymm11,
ehframe_dwarf_ymm11, -1U, debugserver_ymm11, NULL, NULL},
{e_regSetFPU, fpu_ymm12, "ymm12", NULL, Vector, VectorOfUInt8,
FPU_SIZE_YMM(ymm12), AVX_OFFSET_YMM(12), ehframe_dwarf_ymm12,
ehframe_dwarf_ymm12, -1U, debugserver_ymm12, NULL, NULL},
{e_regSetFPU, fpu_ymm13, "ymm13", NULL, Vector, VectorOfUInt8,
FPU_SIZE_YMM(ymm13), AVX_OFFSET_YMM(13), ehframe_dwarf_ymm13,
ehframe_dwarf_ymm13, -1U, debugserver_ymm13, NULL, NULL},
{e_regSetFPU, fpu_ymm14, "ymm14", NULL, Vector, VectorOfUInt8,
FPU_SIZE_YMM(ymm14), AVX_OFFSET_YMM(14), ehframe_dwarf_ymm14,
ehframe_dwarf_ymm14, -1U, debugserver_ymm14, NULL, NULL},
{e_regSetFPU, fpu_ymm15, "ymm15", NULL, Vector, VectorOfUInt8,
FPU_SIZE_YMM(ymm15), AVX_OFFSET_YMM(15), ehframe_dwarf_ymm15,
ehframe_dwarf_ymm15, -1U, debugserver_ymm15, NULL, NULL},
{e_regSetFPU, fpu_xmm0, "xmm0", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm0), 0, ehframe_dwarf_xmm0, ehframe_dwarf_xmm0, -1U,
debugserver_xmm0, g_contained_ymm0, NULL},
{e_regSetFPU, fpu_xmm1, "xmm1", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm1), 0, ehframe_dwarf_xmm1, ehframe_dwarf_xmm1, -1U,
debugserver_xmm1, g_contained_ymm1, NULL},
{e_regSetFPU, fpu_xmm2, "xmm2", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm2), 0, ehframe_dwarf_xmm2, ehframe_dwarf_xmm2, -1U,
debugserver_xmm2, g_contained_ymm2, NULL},
{e_regSetFPU, fpu_xmm3, "xmm3", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm3), 0, ehframe_dwarf_xmm3, ehframe_dwarf_xmm3, -1U,
debugserver_xmm3, g_contained_ymm3, NULL},
{e_regSetFPU, fpu_xmm4, "xmm4", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm4), 0, ehframe_dwarf_xmm4, ehframe_dwarf_xmm4, -1U,
debugserver_xmm4, g_contained_ymm4, NULL},
{e_regSetFPU, fpu_xmm5, "xmm5", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm5), 0, ehframe_dwarf_xmm5, ehframe_dwarf_xmm5, -1U,
debugserver_xmm5, g_contained_ymm5, NULL},
{e_regSetFPU, fpu_xmm6, "xmm6", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm6), 0, ehframe_dwarf_xmm6, ehframe_dwarf_xmm6, -1U,
debugserver_xmm6, g_contained_ymm6, NULL},
{e_regSetFPU, fpu_xmm7, "xmm7", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm7), 0, ehframe_dwarf_xmm7, ehframe_dwarf_xmm7, -1U,
debugserver_xmm7, g_contained_ymm7, NULL},
{e_regSetFPU, fpu_xmm8, "xmm8", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm8), 0, ehframe_dwarf_xmm8, ehframe_dwarf_xmm8, -1U,
debugserver_xmm8, g_contained_ymm8, NULL},
{e_regSetFPU, fpu_xmm9, "xmm9", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm9), 0, ehframe_dwarf_xmm9, ehframe_dwarf_xmm9, -1U,
debugserver_xmm9, g_contained_ymm9, NULL},
{e_regSetFPU, fpu_xmm10, "xmm10", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm10), 0, ehframe_dwarf_xmm10, ehframe_dwarf_xmm10, -1U,
debugserver_xmm10, g_contained_ymm10, NULL},
{e_regSetFPU, fpu_xmm11, "xmm11", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm11), 0, ehframe_dwarf_xmm11, ehframe_dwarf_xmm11, -1U,
debugserver_xmm11, g_contained_ymm11, NULL},
{e_regSetFPU, fpu_xmm12, "xmm12", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm12), 0, ehframe_dwarf_xmm12, ehframe_dwarf_xmm12, -1U,
debugserver_xmm12, g_contained_ymm12, NULL},
{e_regSetFPU, fpu_xmm13, "xmm13", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm13), 0, ehframe_dwarf_xmm13, ehframe_dwarf_xmm13, -1U,
debugserver_xmm13, g_contained_ymm13, NULL},
{e_regSetFPU, fpu_xmm14, "xmm14", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm14), 0, ehframe_dwarf_xmm14, ehframe_dwarf_xmm14, -1U,
debugserver_xmm14, g_contained_ymm14, NULL},
{e_regSetFPU, fpu_xmm15, "xmm15", NULL, Vector, VectorOfUInt8,
FPU_SIZE_XMM(xmm15), 0, ehframe_dwarf_xmm15, ehframe_dwarf_xmm15, -1U,
debugserver_xmm15, g_contained_ymm15, NULL}
};
static const char *g_contained_zmm0[] = {"zmm0", NULL};
static const char *g_contained_zmm1[] = {"zmm1", NULL};
static const char *g_contained_zmm2[] = {"zmm2", NULL};
static const char *g_contained_zmm3[] = {"zmm3", NULL};
static const char *g_contained_zmm4[] = {"zmm4", NULL};
static const char *g_contained_zmm5[] = {"zmm5", NULL};
static const char *g_contained_zmm6[] = {"zmm6", NULL};
static const char *g_contained_zmm7[] = {"zmm7", NULL};
static const char *g_contained_zmm8[] = {"zmm8", NULL};
static const char *g_contained_zmm9[] = {"zmm9", NULL};
static const char *g_contained_zmm10[] = {"zmm10", NULL};
static const char *g_contained_zmm11[] = {"zmm11", NULL};
static const char *g_contained_zmm12[] = {"zmm12", NULL};
static const char *g_contained_zmm13[] = {"zmm13", NULL};
static const char *g_contained_zmm14[] = {"zmm14", NULL};
static const char *g_contained_zmm15[] = {"zmm15", NULL};
#define STR(s) #s
#define ZMM_REG_DEF(reg) \
{ \
e_regSetFPU, fpu_zmm##reg, STR(zmm##reg), NULL, Vector, VectorOfUInt8, \
FPU_SIZE_ZMM(zmm##reg), AVX512F_OFFSET_ZMM(reg), \
ehframe_dwarf_zmm##reg, ehframe_dwarf_zmm##reg, -1U, \
debugserver_zmm##reg, NULL, NULL \
}
#define YMM_REG_ALIAS(reg) \
{ \
e_regSetFPU, fpu_ymm##reg, STR(ymm##reg), NULL, Vector, VectorOfUInt8, \
FPU_SIZE_YMM(ymm##reg), 0, ehframe_dwarf_ymm##reg, \
ehframe_dwarf_ymm##reg, -1U, debugserver_ymm##reg, \
g_contained_zmm##reg, NULL \
}
#define XMM_REG_ALIAS(reg) \
{ \
e_regSetFPU, fpu_xmm##reg, STR(xmm##reg), NULL, Vector, VectorOfUInt8, \
FPU_SIZE_XMM(xmm##reg), 0, ehframe_dwarf_xmm##reg, \
ehframe_dwarf_xmm##reg, -1U, debugserver_xmm##reg, \
g_contained_zmm##reg, NULL \
}
#define AVX512_K_REG_DEF(reg) \
{ \
e_regSetFPU, fpu_k##reg, STR(k##reg), NULL, Vector, VectorOfUInt8, 8, \
AVX512F_OFFSET(k##reg), ehframe_dwarf_k##reg, ehframe_dwarf_k##reg, \
-1U, debugserver_k##reg, NULL, NULL \
}
const DNBRegisterInfo DNBArchImplX86_64::g_fpu_registers_avx512f[] = {
{e_regSetFPU, fpu_fcw, "fctrl", NULL, Uint, Hex, FPU_SIZE_UINT(fcw),
AVX_OFFSET(fcw), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_fsw, "fstat", NULL, Uint, Hex, FPU_SIZE_UINT(fsw),
AVX_OFFSET(fsw), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_ftw, "ftag", NULL, Uint, Hex, 2 /* sizeof __fpu_ftw + sizeof __fpu_rsrv1 */,
AVX_OFFSET(ftw), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_fop, "fop", NULL, Uint, Hex, FPU_SIZE_UINT(fop),
AVX_OFFSET(fop), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_ip, "fioff", NULL, Uint, Hex, FPU_SIZE_UINT(ip),
AVX_OFFSET(ip), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_cs, "fiseg", NULL, Uint, Hex, FPU_SIZE_UINT(cs),
AVX_OFFSET(cs), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_dp, "fooff", NULL, Uint, Hex, FPU_SIZE_UINT(dp),
AVX_OFFSET(dp), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_ds, "foseg", NULL, Uint, Hex, FPU_SIZE_UINT(ds),
AVX_OFFSET(ds), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_mxcsr, "mxcsr", NULL, Uint, Hex, FPU_SIZE_UINT(mxcsr),
AVX_OFFSET(mxcsr), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetFPU, fpu_mxcsrmask, "mxcsrmask", NULL, Uint, Hex,
FPU_SIZE_UINT(mxcsrmask), AVX_OFFSET(mxcsrmask), -1U, -1U, -1U, -1U, NULL,
NULL},
{e_regSetFPU, fpu_stmm0, "stmm0", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm0), AVX_OFFSET(stmm0), ehframe_dwarf_stmm0,
ehframe_dwarf_stmm0, -1U, debugserver_stmm0, NULL, NULL},
{e_regSetFPU, fpu_stmm1, "stmm1", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm1), AVX_OFFSET(stmm1), ehframe_dwarf_stmm1,
ehframe_dwarf_stmm1, -1U, debugserver_stmm1, NULL, NULL},
{e_regSetFPU, fpu_stmm2, "stmm2", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm2), AVX_OFFSET(stmm2), ehframe_dwarf_stmm2,
ehframe_dwarf_stmm2, -1U, debugserver_stmm2, NULL, NULL},
{e_regSetFPU, fpu_stmm3, "stmm3", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm3), AVX_OFFSET(stmm3), ehframe_dwarf_stmm3,
ehframe_dwarf_stmm3, -1U, debugserver_stmm3, NULL, NULL},
{e_regSetFPU, fpu_stmm4, "stmm4", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm4), AVX_OFFSET(stmm4), ehframe_dwarf_stmm4,
ehframe_dwarf_stmm4, -1U, debugserver_stmm4, NULL, NULL},
{e_regSetFPU, fpu_stmm5, "stmm5", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm5), AVX_OFFSET(stmm5), ehframe_dwarf_stmm5,
ehframe_dwarf_stmm5, -1U, debugserver_stmm5, NULL, NULL},
{e_regSetFPU, fpu_stmm6, "stmm6", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm6), AVX_OFFSET(stmm6), ehframe_dwarf_stmm6,
ehframe_dwarf_stmm6, -1U, debugserver_stmm6, NULL, NULL},
{e_regSetFPU, fpu_stmm7, "stmm7", NULL, Vector, VectorOfUInt8,
FPU_SIZE_MMST(stmm7), AVX_OFFSET(stmm7), ehframe_dwarf_stmm7,
ehframe_dwarf_stmm7, -1U, debugserver_stmm7, NULL, NULL},
AVX512_K_REG_DEF(0),
AVX512_K_REG_DEF(1),
AVX512_K_REG_DEF(2),
AVX512_K_REG_DEF(3),
AVX512_K_REG_DEF(4),
AVX512_K_REG_DEF(5),
AVX512_K_REG_DEF(6),
AVX512_K_REG_DEF(7),
ZMM_REG_DEF(0),
ZMM_REG_DEF(1),
ZMM_REG_DEF(2),
ZMM_REG_DEF(3),
ZMM_REG_DEF(4),
ZMM_REG_DEF(5),
ZMM_REG_DEF(6),
ZMM_REG_DEF(7),
ZMM_REG_DEF(8),
ZMM_REG_DEF(9),
ZMM_REG_DEF(10),
ZMM_REG_DEF(11),
ZMM_REG_DEF(12),
ZMM_REG_DEF(13),
ZMM_REG_DEF(14),
ZMM_REG_DEF(15),
ZMM_REG_DEF(16),
ZMM_REG_DEF(17),
ZMM_REG_DEF(18),
ZMM_REG_DEF(19),
ZMM_REG_DEF(20),
ZMM_REG_DEF(21),
ZMM_REG_DEF(22),
ZMM_REG_DEF(23),
ZMM_REG_DEF(24),
ZMM_REG_DEF(25),
ZMM_REG_DEF(26),
ZMM_REG_DEF(27),
ZMM_REG_DEF(28),
ZMM_REG_DEF(29),
ZMM_REG_DEF(30),
ZMM_REG_DEF(31),
YMM_REG_ALIAS(0),
YMM_REG_ALIAS(1),
YMM_REG_ALIAS(2),
YMM_REG_ALIAS(3),
YMM_REG_ALIAS(4),
YMM_REG_ALIAS(5),
YMM_REG_ALIAS(6),
YMM_REG_ALIAS(7),
YMM_REG_ALIAS(8),
YMM_REG_ALIAS(9),
YMM_REG_ALIAS(10),
YMM_REG_ALIAS(11),
YMM_REG_ALIAS(12),
YMM_REG_ALIAS(13),
YMM_REG_ALIAS(14),
YMM_REG_ALIAS(15),
XMM_REG_ALIAS(0),
XMM_REG_ALIAS(1),
XMM_REG_ALIAS(2),
XMM_REG_ALIAS(3),
XMM_REG_ALIAS(4),
XMM_REG_ALIAS(5),
XMM_REG_ALIAS(6),
XMM_REG_ALIAS(7),
XMM_REG_ALIAS(8),
XMM_REG_ALIAS(9),
XMM_REG_ALIAS(10),
XMM_REG_ALIAS(11),
XMM_REG_ALIAS(12),
XMM_REG_ALIAS(13),
XMM_REG_ALIAS(14),
XMM_REG_ALIAS(15),
};
// Exception registers
const DNBRegisterInfo DNBArchImplX86_64::g_exc_registers[] = {
{e_regSetEXC, exc_trapno, "trapno", NULL, Uint, Hex, EXC_SIZE(trapno),
EXC_OFFSET(trapno), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetEXC, exc_err, "err", NULL, Uint, Hex, EXC_SIZE(err),
EXC_OFFSET(err), -1U, -1U, -1U, -1U, NULL, NULL},
{e_regSetEXC, exc_faultvaddr, "faultvaddr", NULL, Uint, Hex,
EXC_SIZE(faultvaddr), EXC_OFFSET(faultvaddr), -1U, -1U, -1U, -1U, NULL,
NULL}};
// Number of registers in each register set
const size_t DNBArchImplX86_64::k_num_gpr_registers =
sizeof(g_gpr_registers) / sizeof(DNBRegisterInfo);
const size_t DNBArchImplX86_64::k_num_fpu_registers_no_avx =
sizeof(g_fpu_registers_no_avx) / sizeof(DNBRegisterInfo);
const size_t DNBArchImplX86_64::k_num_fpu_registers_avx =
sizeof(g_fpu_registers_avx) / sizeof(DNBRegisterInfo);
const size_t DNBArchImplX86_64::k_num_exc_registers =
sizeof(g_exc_registers) / sizeof(DNBRegisterInfo);
const size_t DNBArchImplX86_64::k_num_all_registers_no_avx =
k_num_gpr_registers + k_num_fpu_registers_no_avx + k_num_exc_registers;
const size_t DNBArchImplX86_64::k_num_all_registers_avx =
k_num_gpr_registers + k_num_fpu_registers_avx + k_num_exc_registers;
const size_t DNBArchImplX86_64::k_num_fpu_registers_avx512f =
sizeof(g_fpu_registers_avx512f) / sizeof(DNBRegisterInfo);
const size_t DNBArchImplX86_64::k_num_all_registers_avx512f =
k_num_gpr_registers + k_num_fpu_registers_avx512f + k_num_exc_registers;
//----------------------------------------------------------------------
// Register set definitions. The first definitions at register set index
// of zero is for all registers, followed by other registers sets. The
// register information for the all register set need not be filled in.
//----------------------------------------------------------------------
const DNBRegisterSetInfo DNBArchImplX86_64::g_reg_sets_no_avx[] = {
{"x86_64 Registers", NULL, k_num_all_registers_no_avx},
{"General Purpose Registers", g_gpr_registers, k_num_gpr_registers},
{"Floating Point Registers", g_fpu_registers_no_avx,
k_num_fpu_registers_no_avx},
{"Exception State Registers", g_exc_registers, k_num_exc_registers}};
const DNBRegisterSetInfo DNBArchImplX86_64::g_reg_sets_avx[] = {
{"x86_64 Registers", NULL, k_num_all_registers_avx},
{"General Purpose Registers", g_gpr_registers, k_num_gpr_registers},
{"Floating Point Registers", g_fpu_registers_avx, k_num_fpu_registers_avx},
{"Exception State Registers", g_exc_registers, k_num_exc_registers}};
const DNBRegisterSetInfo DNBArchImplX86_64::g_reg_sets_avx512f[] = {
{"x86_64 Registers", NULL, k_num_all_registers_avx},
{"General Purpose Registers", g_gpr_registers, k_num_gpr_registers},
{"Floating Point Registers", g_fpu_registers_avx512f,
k_num_fpu_registers_avx512f},
{"Exception State Registers", g_exc_registers, k_num_exc_registers}};
// Total number of register sets for this architecture
const size_t DNBArchImplX86_64::k_num_register_sets =
sizeof(g_reg_sets_avx) / sizeof(DNBRegisterSetInfo);
DNBArchProtocol *DNBArchImplX86_64::Create(MachThread *thread) {
DNBArchImplX86_64 *obj = new DNBArchImplX86_64(thread);
return obj;
}
const uint8_t *
DNBArchImplX86_64::SoftwareBreakpointOpcode(nub_size_t byte_size) {
static const uint8_t g_breakpoint_opcode[] = {0xCC};
if (byte_size == 1)
return g_breakpoint_opcode;
return NULL;
}
const DNBRegisterSetInfo *
DNBArchImplX86_64::GetRegisterSetInfo(nub_size_t *num_reg_sets) {
*num_reg_sets = k_num_register_sets;
if (CPUHasAVX512f() || FORCE_AVX_REGS)
return g_reg_sets_avx512f;
if (CPUHasAVX() || FORCE_AVX_REGS)
return g_reg_sets_avx;
else
return g_reg_sets_no_avx;
}
void DNBArchImplX86_64::Initialize() {
DNBArchPluginInfo arch_plugin_info = {
CPU_TYPE_X86_64, DNBArchImplX86_64::Create,
DNBArchImplX86_64::GetRegisterSetInfo,
DNBArchImplX86_64::SoftwareBreakpointOpcode};
// Register this arch plug-in with the main protocol class
DNBArchProtocol::RegisterArchPlugin(arch_plugin_info);
}
bool DNBArchImplX86_64::GetRegisterValue(uint32_t set, uint32_t reg,
DNBRegisterValue *value) {
if (set == REGISTER_SET_GENERIC) {
switch (reg) {
case GENERIC_REGNUM_PC: // Program Counter
set = e_regSetGPR;
reg = gpr_rip;
break;
case GENERIC_REGNUM_SP: // Stack Pointer
set = e_regSetGPR;
reg = gpr_rsp;
break;
case GENERIC_REGNUM_FP: // Frame Pointer
set = e_regSetGPR;
reg = gpr_rbp;
break;
case GENERIC_REGNUM_FLAGS: // Processor flags register
set = e_regSetGPR;
reg = gpr_rflags;
break;
case GENERIC_REGNUM_RA: // Return Address
default:
return false;
}
}
if (GetRegisterState(set, false) != KERN_SUCCESS)
return false;
const DNBRegisterInfo *regInfo = m_thread->GetRegisterInfo(set, reg);
if (regInfo) {
value->info = *regInfo;
switch (set) {
case e_regSetGPR:
if (reg < k_num_gpr_registers) {
value->value.uint64 = ((uint64_t *)(&m_state.context.gpr))[reg];
return true;
}
break;
case e_regSetFPU:
if (reg > fpu_xmm15 && !(CPUHasAVX() || FORCE_AVX_REGS))
return false;
if (reg > fpu_ymm15 && !(CPUHasAVX512f() || FORCE_AVX_REGS))
return false;
switch (reg) {
case fpu_fcw:
value->value.uint16 =
*((uint16_t *)(&m_state.context.fpu.no_avx.__fpu_fcw));
return true;
case fpu_fsw:
value->value.uint16 =
*((uint16_t *)(&m_state.context.fpu.no_avx.__fpu_fsw));
return true;
case fpu_ftw:
memcpy (&value->value.uint16, &m_state.context.fpu.no_avx.__fpu_ftw, 2);
return true;
case fpu_fop:
value->value.uint16 = m_state.context.fpu.no_avx.__fpu_fop;
return true;
case fpu_ip:
value->value.uint32 = m_state.context.fpu.no_avx.__fpu_ip;
return true;
case fpu_cs:
value->value.uint16 = m_state.context.fpu.no_avx.__fpu_cs;
return true;
case fpu_dp:
value->value.uint32 = m_state.context.fpu.no_avx.__fpu_dp;
return true;
case fpu_ds:
value->value.uint16 = m_state.context.fpu.no_avx.__fpu_ds;
return true;
case fpu_mxcsr:
value->value.uint32 = m_state.context.fpu.no_avx.__fpu_mxcsr;
return true;
case fpu_mxcsrmask:
value->value.uint32 = m_state.context.fpu.no_avx.__fpu_mxcsrmask;
return true;
case fpu_stmm0:
case fpu_stmm1:
case fpu_stmm2:
case fpu_stmm3:
case fpu_stmm4:
case fpu_stmm5:
case fpu_stmm6:
case fpu_stmm7:
memcpy(&value->value.uint8,
&m_state.context.fpu.no_avx.__fpu_stmm0 + (reg - fpu_stmm0), 10);
return true;
case fpu_xmm0:
case fpu_xmm1:
case fpu_xmm2:
case fpu_xmm3:
case fpu_xmm4:
case fpu_xmm5:
case fpu_xmm6:
case fpu_xmm7:
case fpu_xmm8:
case fpu_xmm9:
case fpu_xmm10:
case fpu_xmm11:
case fpu_xmm12:
case fpu_xmm13:
case fpu_xmm14:
case fpu_xmm15:
memcpy(&value->value.uint8,
&m_state.context.fpu.no_avx.__fpu_xmm0 + (reg - fpu_xmm0), 16);
return true;
case fpu_ymm0:
case fpu_ymm1:
case fpu_ymm2:
case fpu_ymm3:
case fpu_ymm4:
case fpu_ymm5:
case fpu_ymm6:
case fpu_ymm7:
case fpu_ymm8:
case fpu_ymm9:
case fpu_ymm10:
case fpu_ymm11:
case fpu_ymm12:
case fpu_ymm13:
case fpu_ymm14:
case fpu_ymm15:
memcpy(&value->value.uint8,
&m_state.context.fpu.avx.__fpu_xmm0 + (reg - fpu_ymm0), 16);
memcpy((&value->value.uint8) + 16,
&m_state.context.fpu.avx.__fpu_ymmh0 + (reg - fpu_ymm0), 16);
return true;
case fpu_k0:
case fpu_k1:
case fpu_k2:
case fpu_k3:
case fpu_k4:
case fpu_k5:
case fpu_k6:
case fpu_k7:
memcpy((&value->value.uint8),
&m_state.context.fpu.avx512f.__fpu_k0 + (reg - fpu_k0), 8);
return true;
case fpu_zmm0:
case fpu_zmm1:
case fpu_zmm2:
case fpu_zmm3:
case fpu_zmm4:
case fpu_zmm5:
case fpu_zmm6:
case fpu_zmm7:
case fpu_zmm8:
case fpu_zmm9:
case fpu_zmm10:
case fpu_zmm11:
case fpu_zmm12:
case fpu_zmm13:
case fpu_zmm14:
case fpu_zmm15:
memcpy(&value->value.uint8,
&m_state.context.fpu.avx512f.__fpu_xmm0 + (reg - fpu_zmm0), 16);
memcpy((&value->value.uint8) + 16,
&m_state.context.fpu.avx512f.__fpu_ymmh0 + (reg - fpu_zmm0), 16);
memcpy((&value->value.uint8) + 32,
&m_state.context.fpu.avx512f.__fpu_zmmh0 + (reg - fpu_zmm0), 32);
return true;
case fpu_zmm16:
case fpu_zmm17:
case fpu_zmm18:
case fpu_zmm19:
case fpu_zmm20:
case fpu_zmm21:
case fpu_zmm22:
case fpu_zmm23:
case fpu_zmm24:
case fpu_zmm25:
case fpu_zmm26:
case fpu_zmm27:
case fpu_zmm28:
case fpu_zmm29:
case fpu_zmm30:
case fpu_zmm31:
memcpy(&value->value.uint8,
&m_state.context.fpu.avx512f.__fpu_zmm16 + (reg - fpu_zmm16), 64);
return true;
}
break;
case e_regSetEXC:
switch (reg) {
case exc_trapno:
value->value.uint32 = m_state.context.exc.__trapno;
return true;
case exc_err:
value->value.uint32 = m_state.context.exc.__err;
return true;
case exc_faultvaddr:
value->value.uint64 = m_state.context.exc.__faultvaddr;
return true;
}
break;
}
}
return false;
}
bool DNBArchImplX86_64::SetRegisterValue(uint32_t set, uint32_t reg,
const DNBRegisterValue *value) {
if (set == REGISTER_SET_GENERIC) {
switch (reg) {
case GENERIC_REGNUM_PC: // Program Counter
set = e_regSetGPR;
reg = gpr_rip;
break;
case GENERIC_REGNUM_SP: // Stack Pointer
set = e_regSetGPR;
reg = gpr_rsp;
break;
case GENERIC_REGNUM_FP: // Frame Pointer
set = e_regSetGPR;
reg = gpr_rbp;
break;
case GENERIC_REGNUM_FLAGS: // Processor flags register
set = e_regSetGPR;
reg = gpr_rflags;
break;
case GENERIC_REGNUM_RA: // Return Address
default:
return false;
}
}
if (GetRegisterState(set, false) != KERN_SUCCESS)
return false;
bool success = false;
const DNBRegisterInfo *regInfo = m_thread->GetRegisterInfo(set, reg);
if (regInfo) {
switch (set) {
case e_regSetGPR:
if (reg < k_num_gpr_registers) {
((uint64_t *)(&m_state.context.gpr))[reg] = value->value.uint64;
success = true;
}
break;
if (reg > fpu_xmm15 && !(CPUHasAVX() || FORCE_AVX_REGS))
return false;
if (reg > fpu_ymm15 && !(CPUHasAVX512f() || FORCE_AVX_REGS))
return false;
case e_regSetFPU:
switch (reg) {
case fpu_fcw:
*((uint16_t *)(&m_state.context.fpu.no_avx.__fpu_fcw)) =
value->value.uint16;
success = true;
break;
case fpu_fsw:
*((uint16_t *)(&m_state.context.fpu.no_avx.__fpu_fsw)) =
value->value.uint16;
success = true;
break;
case fpu_ftw:
memcpy (&m_state.context.fpu.no_avx.__fpu_ftw, &value->value.uint8, 2);
success = true;
break;
case fpu_fop:
m_state.context.fpu.no_avx.__fpu_fop = value->value.uint16;
success = true;
break;
case fpu_ip:
m_state.context.fpu.no_avx.__fpu_ip = value->value.uint32;
success = true;
break;
case fpu_cs:
m_state.context.fpu.no_avx.__fpu_cs = value->value.uint16;
success = true;
break;
case fpu_dp:
m_state.context.fpu.no_avx.__fpu_dp = value->value.uint32;
success = true;
break;
case fpu_ds:
m_state.context.fpu.no_avx.__fpu_ds = value->value.uint16;
success = true;
break;
case fpu_mxcsr:
m_state.context.fpu.no_avx.__fpu_mxcsr = value->value.uint32;
success = true;
break;
case fpu_mxcsrmask:
m_state.context.fpu.no_avx.__fpu_mxcsrmask = value->value.uint32;
success = true;
break;
case fpu_stmm0:
case fpu_stmm1:
case fpu_stmm2:
case fpu_stmm3:
case fpu_stmm4:
case fpu_stmm5:
case fpu_stmm6:
case fpu_stmm7:
memcpy(&m_state.context.fpu.no_avx.__fpu_stmm0 + (reg - fpu_stmm0),
&value->value.uint8, 10);
success = true;
break;
case fpu_xmm0:
case fpu_xmm1:
case fpu_xmm2:
case fpu_xmm3:
case fpu_xmm4:
case fpu_xmm5:
case fpu_xmm6:
case fpu_xmm7:
case fpu_xmm8:
case fpu_xmm9:
case fpu_xmm10:
case fpu_xmm11:
case fpu_xmm12:
case fpu_xmm13:
case fpu_xmm14:
case fpu_xmm15:
memcpy(&m_state.context.fpu.no_avx.__fpu_xmm0 + (reg - fpu_xmm0),
&value->value.uint8, 16);
success = true;
break;
case fpu_ymm0:
case fpu_ymm1:
case fpu_ymm2:
case fpu_ymm3:
case fpu_ymm4:
case fpu_ymm5:
case fpu_ymm6:
case fpu_ymm7:
case fpu_ymm8:
case fpu_ymm9:
case fpu_ymm10:
case fpu_ymm11:
case fpu_ymm12:
case fpu_ymm13:
case fpu_ymm14:
case fpu_ymm15:
memcpy(&m_state.context.fpu.avx.__fpu_xmm0 + (reg - fpu_ymm0),
&value->value.uint8, 16);
memcpy(&m_state.context.fpu.avx.__fpu_ymmh0 + (reg - fpu_ymm0),
(&value->value.uint8) + 16, 16);
return true;
case fpu_k0:
case fpu_k1:
case fpu_k2:
case fpu_k3:
case fpu_k4:
case fpu_k5:
case fpu_k6:
case fpu_k7:
memcpy(&m_state.context.fpu.avx512f.__fpu_k0 + (reg - fpu_k0),
&value->value.uint8, 8);
return true;
case fpu_zmm0:
case fpu_zmm1:
case fpu_zmm2:
case fpu_zmm3:
case fpu_zmm4:
case fpu_zmm5:
case fpu_zmm6:
case fpu_zmm7:
case fpu_zmm8:
case fpu_zmm9:
case fpu_zmm10:
case fpu_zmm11:
case fpu_zmm12:
case fpu_zmm13:
case fpu_zmm14:
case fpu_zmm15:
memcpy(&m_state.context.fpu.avx512f.__fpu_xmm0 + (reg - fpu_zmm0),
&value->value.uint8, 16);
memcpy(&m_state.context.fpu.avx512f.__fpu_ymmh0 + (reg - fpu_zmm0),
&value->value.uint8 + 16, 16);
memcpy(&m_state.context.fpu.avx512f.__fpu_zmmh0 + (reg - fpu_zmm0),
&value->value.uint8 + 32, 32);
return true;
case fpu_zmm16:
case fpu_zmm17:
case fpu_zmm18:
case fpu_zmm19:
case fpu_zmm20:
case fpu_zmm21:
case fpu_zmm22:
case fpu_zmm23:
case fpu_zmm24:
case fpu_zmm25:
case fpu_zmm26:
case fpu_zmm27:
case fpu_zmm28:
case fpu_zmm29:
case fpu_zmm30:
case fpu_zmm31:
memcpy(&m_state.context.fpu.avx512f.__fpu_zmm16 + (reg - fpu_zmm16),
&value->value.uint8, 64);
return true;
}
break;
case e_regSetEXC:
switch (reg) {
case exc_trapno:
m_state.context.exc.__trapno = value->value.uint32;
success = true;
break;
case exc_err:
m_state.context.exc.__err = value->value.uint32;
success = true;
break;
case exc_faultvaddr:
m_state.context.exc.__faultvaddr = value->value.uint64;
success = true;
break;
}
break;
}
}
if (success)
return SetRegisterState(set) == KERN_SUCCESS;
return false;
}
uint32_t DNBArchImplX86_64::GetRegisterContextSize() {
static uint32_t g_cached_size = 0;
if (g_cached_size == 0) {
if (CPUHasAVX512f() || FORCE_AVX_REGS) {
for (size_t i = 0; i < k_num_fpu_registers_avx512f; ++i) {
if (g_fpu_registers_avx512f[i].value_regs == NULL)
g_cached_size += g_fpu_registers_avx512f[i].size;
}
} else if (CPUHasAVX() || FORCE_AVX_REGS) {
for (size_t i = 0; i < k_num_fpu_registers_avx; ++i) {
if (g_fpu_registers_avx[i].value_regs == NULL)
g_cached_size += g_fpu_registers_avx[i].size;
}
} else {
for (size_t i = 0; i < k_num_fpu_registers_no_avx; ++i) {
if (g_fpu_registers_no_avx[i].value_regs == NULL)
g_cached_size += g_fpu_registers_no_avx[i].size;
}
}
DNBLogThreaded("DNBArchImplX86_64::GetRegisterContextSize() - GPR = %zu, "
"FPU = %u, EXC = %zu",
sizeof(GPR), g_cached_size, sizeof(EXC));
g_cached_size += sizeof(GPR);
g_cached_size += sizeof(EXC);
DNBLogThreaded(
"DNBArchImplX86_64::GetRegisterContextSize() - GPR + FPU + EXC = %u",
g_cached_size);
}
return g_cached_size;
}
nub_size_t DNBArchImplX86_64::GetRegisterContext(void *buf,
nub_size_t buf_len) {
uint32_t size = GetRegisterContextSize();
if (buf && buf_len) {
bool force = false;
kern_return_t kret;
if ((kret = GetGPRState(force)) != KERN_SUCCESS) {
DNBLogThreadedIf(LOG_THREAD, "DNBArchImplX86_64::GetRegisterContext (buf "
"= %p, len = %llu) error: GPR regs failed "
"to read: %u ",
buf, (uint64_t)buf_len, kret);
size = 0;
} else if ((kret = GetFPUState(force)) != KERN_SUCCESS) {
DNBLogThreadedIf(
LOG_THREAD, "DNBArchImplX86_64::GetRegisterContext (buf = %p, len = "
"%llu) error: %s regs failed to read: %u",
buf, (uint64_t)buf_len, CPUHasAVX() ? "AVX" : "FPU", kret);
size = 0;
} else if ((kret = GetEXCState(force)) != KERN_SUCCESS) {
DNBLogThreadedIf(LOG_THREAD, "DNBArchImplX86_64::GetRegisterContext (buf "
"= %p, len = %llu) error: EXC regs failed "
"to read: %u",
buf, (uint64_t)buf_len, kret);
size = 0;
} else {
uint8_t *p = (uint8_t *)buf;
// Copy the GPR registers
memcpy(p, &m_state.context.gpr, sizeof(GPR));
p += sizeof(GPR);
// Walk around the gaps in the FPU regs
memcpy(p, &m_state.context.fpu.no_avx.__fpu_fcw, 5);
// We read 5 bytes, but we skip 6 to account for __fpu_rsrv1
// to match the g_fpu_registers_* tables.
p += 6;
memcpy(p, &m_state.context.fpu.no_avx.__fpu_fop, 8);
p += 8;
memcpy(p, &m_state.context.fpu.no_avx.__fpu_dp, 6);
p += 6;
memcpy(p, &m_state.context.fpu.no_avx.__fpu_mxcsr, 8);
p += 8;
// Work around the padding between the stmm registers as they are 16
// byte structs with 10 bytes of the value in each
for (size_t i = 0; i < 8; ++i) {
memcpy(p, &m_state.context.fpu.no_avx.__fpu_stmm0 + i, 10);
p += 10;
}
if(CPUHasAVX512f() || FORCE_AVX_REGS) {
for (size_t i = 0; i < 8; ++i) {
memcpy(p, &m_state.context.fpu.avx512f.__fpu_k0 + i, 8);
p += 8;
}
}
if (CPUHasAVX() || FORCE_AVX_REGS) {
// Interleave the XMM and YMMH registers to make the YMM registers
for (size_t i = 0; i < 16; ++i) {
memcpy(p, &m_state.context.fpu.avx.__fpu_xmm0 + i, 16);
p += 16;
memcpy(p, &m_state.context.fpu.avx.__fpu_ymmh0 + i, 16);
p += 16;
}
if(CPUHasAVX512f() || FORCE_AVX_REGS) {
for (size_t i = 0; i < 16; ++i) {
memcpy(p, &m_state.context.fpu.avx512f.__fpu_zmmh0 + i, 32);
p += 32;
}
for (size_t i = 0; i < 16; ++i) {
memcpy(p, &m_state.context.fpu.avx512f.__fpu_zmm16 + i, 64);
p += 64;
}
}
} else {
// Copy the XMM registers in a single block
memcpy(p, &m_state.context.fpu.no_avx.__fpu_xmm0, 16 * 16);
p += 16 * 16;
}
// Copy the exception registers
memcpy(p, &m_state.context.exc, sizeof(EXC));
p += sizeof(EXC);
// make sure we end up with exactly what we think we should have
size_t bytes_written = p - (uint8_t *)buf;
UNUSED_IF_ASSERT_DISABLED(bytes_written);
assert(bytes_written == size);
}
}
DNBLogThreadedIf(
LOG_THREAD,
"DNBArchImplX86_64::GetRegisterContext (buf = %p, len = %llu) => %u", buf,
(uint64_t)buf_len, size);
// Return the size of the register context even if NULL was passed in
return size;
}
nub_size_t DNBArchImplX86_64::SetRegisterContext(const void *buf,
nub_size_t buf_len) {
uint32_t size = GetRegisterContextSize();
if (buf == NULL || buf_len == 0)
size = 0;
if (size) {
if (size > buf_len)
size = static_cast<uint32_t>(buf_len);
const uint8_t *p = (const uint8_t *)buf;
// Copy the GPR registers
memcpy(&m_state.context.gpr, p, sizeof(GPR));
p += sizeof(GPR);
// Copy fcw through mxcsrmask as there is no padding
memcpy(&m_state.context.fpu.no_avx.__fpu_fcw, p, 5);
// We wrote 5 bytes, but we skip 6 to account for __fpu_rsrv1
// to match the g_fpu_registers_* tables.
p += 6;
memcpy(&m_state.context.fpu.no_avx.__fpu_fop, p, 8);
p += 8;
memcpy(&m_state.context.fpu.no_avx.__fpu_dp, p, 6);
p += 6;
memcpy(&m_state.context.fpu.no_avx.__fpu_mxcsr, p, 8);
p += 8;
// Work around the padding between the stmm registers as they are 16
// byte structs with 10 bytes of the value in each
for (size_t i = 0; i < 8; ++i) {
memcpy(&m_state.context.fpu.no_avx.__fpu_stmm0 + i, p, 10);
p += 10;
}
if(CPUHasAVX512f() || FORCE_AVX_REGS) {
for (size_t i = 0; i < 8; ++i) {
memcpy(&m_state.context.fpu.avx512f.__fpu_k0 + i, p, 8);
p += 8;
}
}
if (CPUHasAVX() || FORCE_AVX_REGS) {
// Interleave the XMM and YMMH registers to make the YMM registers
for (size_t i = 0; i < 16; ++i) {
memcpy(&m_state.context.fpu.avx.__fpu_xmm0 + i, p, 16);
p += 16;
memcpy(&m_state.context.fpu.avx.__fpu_ymmh0 + i, p, 16);
p += 16;
}
if(CPUHasAVX512f() || FORCE_AVX_REGS) {
for (size_t i = 0; i < 16; ++i) {
memcpy(&m_state.context.fpu.avx512f.__fpu_zmmh0 + i, p, 32);
p += 32;
}
for (size_t i = 0; i < 16; ++i) {
memcpy(&m_state.context.fpu.avx512f.__fpu_zmm16 + i, p, 64);
p += 64;
}
}
} else {
// Copy the XMM registers in a single block
memcpy(&m_state.context.fpu.no_avx.__fpu_xmm0, p, 16 * 16);
p += 16 * 16;
}
// Copy the exception registers
memcpy(&m_state.context.exc, p, sizeof(EXC));
p += sizeof(EXC);
// make sure we end up with exactly what we think we should have
size_t bytes_written = p - (const uint8_t *)buf;
UNUSED_IF_ASSERT_DISABLED(bytes_written);
assert(bytes_written == size);
kern_return_t kret;
if ((kret = SetGPRState()) != KERN_SUCCESS)
DNBLogThreadedIf(LOG_THREAD, "DNBArchImplX86_64::SetRegisterContext (buf "
"= %p, len = %llu) error: GPR regs failed "
"to write: %u",
buf, (uint64_t)buf_len, kret);
if ((kret = SetFPUState()) != KERN_SUCCESS)
DNBLogThreadedIf(
LOG_THREAD, "DNBArchImplX86_64::SetRegisterContext (buf = %p, len = "
"%llu) error: %s regs failed to write: %u",
buf, (uint64_t)buf_len, CPUHasAVX() ? "AVX" : "FPU", kret);
if ((kret = SetEXCState()) != KERN_SUCCESS)
DNBLogThreadedIf(LOG_THREAD, "DNBArchImplX86_64::SetRegisterContext (buf "
"= %p, len = %llu) error: EXP regs failed "
"to write: %u",
buf, (uint64_t)buf_len, kret);
}
DNBLogThreadedIf(
LOG_THREAD,
"DNBArchImplX86_64::SetRegisterContext (buf = %p, len = %llu) => %llu",
buf, (uint64_t)buf_len, (uint64_t)size);
return size;
}
uint32_t DNBArchImplX86_64::SaveRegisterState() {
kern_return_t kret = ::thread_abort_safely(m_thread->MachPortNumber());
DNBLogThreadedIf(
LOG_THREAD, "thread = 0x%4.4x calling thread_abort_safely (tid) => %u "
"(SetGPRState() for stop_count = %u)",
m_thread->MachPortNumber(), kret, m_thread->Process()->StopCount());
// Always re-read the registers because above we call thread_abort_safely();
bool force = true;
if ((kret = GetGPRState(force)) != KERN_SUCCESS) {
DNBLogThreadedIf(LOG_THREAD, "DNBArchImplX86_64::SaveRegisterState () "
"error: GPR regs failed to read: %u ",
kret);
} else if ((kret = GetFPUState(force)) != KERN_SUCCESS) {
DNBLogThreadedIf(LOG_THREAD, "DNBArchImplX86_64::SaveRegisterState () "
"error: %s regs failed to read: %u",
CPUHasAVX() ? "AVX" : "FPU", kret);
} else {
const uint32_t save_id = GetNextRegisterStateSaveID();
m_saved_register_states[save_id] = m_state.context;
return save_id;
}
return 0;
}
bool DNBArchImplX86_64::RestoreRegisterState(uint32_t save_id) {
SaveRegisterStates::iterator pos = m_saved_register_states.find(save_id);
if (pos != m_saved_register_states.end()) {
m_state.context.gpr = pos->second.gpr;
m_state.context.fpu = pos->second.fpu;
m_state.SetError(e_regSetGPR, Read, 0);
m_state.SetError(e_regSetFPU, Read, 0);
kern_return_t kret;
bool success = true;
if ((kret = SetGPRState()) != KERN_SUCCESS) {
DNBLogThreadedIf(LOG_THREAD, "DNBArchImplX86_64::RestoreRegisterState "
"(save_id = %u) error: GPR regs failed to "
"write: %u",
save_id, kret);
success = false;
} else if ((kret = SetFPUState()) != KERN_SUCCESS) {
DNBLogThreadedIf(LOG_THREAD, "DNBArchImplX86_64::RestoreRegisterState "
"(save_id = %u) error: %s regs failed to "
"write: %u",
save_id, CPUHasAVX() ? "AVX" : "FPU", kret);
success = false;
}
m_saved_register_states.erase(pos);
return success;
}
return false;
}
kern_return_t DNBArchImplX86_64::GetRegisterState(int set, bool force) {
switch (set) {
case e_regSetALL:
return GetGPRState(force) | GetFPUState(force) | GetEXCState(force);
case e_regSetGPR:
return GetGPRState(force);
case e_regSetFPU:
return GetFPUState(force);
case e_regSetEXC:
return GetEXCState(force);
default:
break;
}
return KERN_INVALID_ARGUMENT;
}
kern_return_t DNBArchImplX86_64::SetRegisterState(int set) {
// Make sure we have a valid context to set.
if (RegisterSetStateIsValid(set)) {
switch (set) {
case e_regSetALL:
return SetGPRState() | SetFPUState() | SetEXCState();
case e_regSetGPR:
return SetGPRState();
case e_regSetFPU:
return SetFPUState();
case e_regSetEXC:
return SetEXCState();
default:
break;
}
}
return KERN_INVALID_ARGUMENT;
}
bool DNBArchImplX86_64::RegisterSetStateIsValid(int set) const {
return m_state.RegsAreValid(set);
}
#endif // #if defined (__i386__) || defined (__x86_64__)