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webkit / WebKit / 3ee83bd7079b5d32a56631e7e3c8cee2e6830703 / . / Source / JavaScriptCore / assembler / MacroAssemblerARM64.cpp
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/*
* Copyright (C) 2013-2019 Apple Inc. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY APPLE INC. ``AS IS'' AND ANY
* EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR
* CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY
* OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "config.h"
#if ENABLE(ASSEMBLER) && CPU(ARM64)
#include "MacroAssembler.h"
#include "ProbeContext.h"
#include <wtf/InlineASM.h>
#if OS(LINUX)
#include <asm/hwcap.h>
#include <sys/auxv.h>
#endif
namespace JSC {
#if ENABLE(MASM_PROBE)
extern "C" void ctiMasmProbeTrampoline();
using namespace ARM64Registers;
#if COMPILER(GCC_COMPATIBLE)
// The following are offsets for Probe::State fields accessed
// by the ctiMasmProbeTrampoline stub.
#if CPU(ADDRESS64)
#define PTR_SIZE 8
#else
#define PTR_SIZE 4
#endif
#define PROBE_PROBE_FUNCTION_OFFSET (0 * PTR_SIZE)
#define PROBE_ARG_OFFSET (1 * PTR_SIZE)
#define PROBE_INIT_STACK_FUNCTION_OFFSET (2 * PTR_SIZE)
#define PROBE_INIT_STACK_ARG_OFFSET (3 * PTR_SIZE)
#define PROBE_FIRST_GPREG_OFFSET (4 * PTR_SIZE)
#define GPREG_SIZE 8
#define PROBE_CPU_X0_OFFSET (PROBE_FIRST_GPREG_OFFSET + (0 * GPREG_SIZE))
#define PROBE_CPU_X1_OFFSET (PROBE_FIRST_GPREG_OFFSET + (1 * GPREG_SIZE))
#define PROBE_CPU_X2_OFFSET (PROBE_FIRST_GPREG_OFFSET + (2 * GPREG_SIZE))
#define PROBE_CPU_X3_OFFSET (PROBE_FIRST_GPREG_OFFSET + (3 * GPREG_SIZE))
#define PROBE_CPU_X4_OFFSET (PROBE_FIRST_GPREG_OFFSET + (4 * GPREG_SIZE))
#define PROBE_CPU_X5_OFFSET (PROBE_FIRST_GPREG_OFFSET + (5 * GPREG_SIZE))
#define PROBE_CPU_X6_OFFSET (PROBE_FIRST_GPREG_OFFSET + (6 * GPREG_SIZE))
#define PROBE_CPU_X7_OFFSET (PROBE_FIRST_GPREG_OFFSET + (7 * GPREG_SIZE))
#define PROBE_CPU_X8_OFFSET (PROBE_FIRST_GPREG_OFFSET + (8 * GPREG_SIZE))
#define PROBE_CPU_X9_OFFSET (PROBE_FIRST_GPREG_OFFSET + (9 * GPREG_SIZE))
#define PROBE_CPU_X10_OFFSET (PROBE_FIRST_GPREG_OFFSET + (10 * GPREG_SIZE))
#define PROBE_CPU_X11_OFFSET (PROBE_FIRST_GPREG_OFFSET + (11 * GPREG_SIZE))
#define PROBE_CPU_X12_OFFSET (PROBE_FIRST_GPREG_OFFSET + (12 * GPREG_SIZE))
#define PROBE_CPU_X13_OFFSET (PROBE_FIRST_GPREG_OFFSET + (13 * GPREG_SIZE))
#define PROBE_CPU_X14_OFFSET (PROBE_FIRST_GPREG_OFFSET + (14 * GPREG_SIZE))
#define PROBE_CPU_X15_OFFSET (PROBE_FIRST_GPREG_OFFSET + (15 * GPREG_SIZE))
#define PROBE_CPU_X16_OFFSET (PROBE_FIRST_GPREG_OFFSET + (16 * GPREG_SIZE))
#define PROBE_CPU_X17_OFFSET (PROBE_FIRST_GPREG_OFFSET + (17 * GPREG_SIZE))
#define PROBE_CPU_X18_OFFSET (PROBE_FIRST_GPREG_OFFSET + (18 * GPREG_SIZE))
#define PROBE_CPU_X19_OFFSET (PROBE_FIRST_GPREG_OFFSET + (19 * GPREG_SIZE))
#define PROBE_CPU_X20_OFFSET (PROBE_FIRST_GPREG_OFFSET + (20 * GPREG_SIZE))
#define PROBE_CPU_X21_OFFSET (PROBE_FIRST_GPREG_OFFSET + (21 * GPREG_SIZE))
#define PROBE_CPU_X22_OFFSET (PROBE_FIRST_GPREG_OFFSET + (22 * GPREG_SIZE))
#define PROBE_CPU_X23_OFFSET (PROBE_FIRST_GPREG_OFFSET + (23 * GPREG_SIZE))
#define PROBE_CPU_X24_OFFSET (PROBE_FIRST_GPREG_OFFSET + (24 * GPREG_SIZE))
#define PROBE_CPU_X25_OFFSET (PROBE_FIRST_GPREG_OFFSET + (25 * GPREG_SIZE))
#define PROBE_CPU_X26_OFFSET (PROBE_FIRST_GPREG_OFFSET + (26 * GPREG_SIZE))
#define PROBE_CPU_X27_OFFSET (PROBE_FIRST_GPREG_OFFSET + (27 * GPREG_SIZE))
#define PROBE_CPU_X28_OFFSET (PROBE_FIRST_GPREG_OFFSET + (28 * GPREG_SIZE))
#define PROBE_CPU_FP_OFFSET (PROBE_FIRST_GPREG_OFFSET + (29 * GPREG_SIZE))
#define PROBE_CPU_LR_OFFSET (PROBE_FIRST_GPREG_OFFSET + (30 * GPREG_SIZE))
#define PROBE_CPU_SP_OFFSET (PROBE_FIRST_GPREG_OFFSET + (31 * GPREG_SIZE))
#define PROBE_CPU_PC_OFFSET (PROBE_FIRST_GPREG_OFFSET + (32 * GPREG_SIZE))
#define PROBE_CPU_NZCV_OFFSET (PROBE_FIRST_GPREG_OFFSET + (33 * GPREG_SIZE))
#define PROBE_CPU_FPSR_OFFSET (PROBE_FIRST_GPREG_OFFSET + (34 * GPREG_SIZE))
#define PROBE_FIRST_FPREG_OFFSET (PROBE_FIRST_GPREG_OFFSET + (35 * GPREG_SIZE))
#define FPREG_SIZE 8
#define PROBE_CPU_Q0_OFFSET (PROBE_FIRST_FPREG_OFFSET + (0 * FPREG_SIZE))
#define PROBE_CPU_Q1_OFFSET (PROBE_FIRST_FPREG_OFFSET + (1 * FPREG_SIZE))
#define PROBE_CPU_Q2_OFFSET (PROBE_FIRST_FPREG_OFFSET + (2 * FPREG_SIZE))
#define PROBE_CPU_Q3_OFFSET (PROBE_FIRST_FPREG_OFFSET + (3 * FPREG_SIZE))
#define PROBE_CPU_Q4_OFFSET (PROBE_FIRST_FPREG_OFFSET + (4 * FPREG_SIZE))
#define PROBE_CPU_Q5_OFFSET (PROBE_FIRST_FPREG_OFFSET + (5 * FPREG_SIZE))
#define PROBE_CPU_Q6_OFFSET (PROBE_FIRST_FPREG_OFFSET + (6 * FPREG_SIZE))
#define PROBE_CPU_Q7_OFFSET (PROBE_FIRST_FPREG_OFFSET + (7 * FPREG_SIZE))
#define PROBE_CPU_Q8_OFFSET (PROBE_FIRST_FPREG_OFFSET + (8 * FPREG_SIZE))
#define PROBE_CPU_Q9_OFFSET (PROBE_FIRST_FPREG_OFFSET + (9 * FPREG_SIZE))
#define PROBE_CPU_Q10_OFFSET (PROBE_FIRST_FPREG_OFFSET + (10 * FPREG_SIZE))
#define PROBE_CPU_Q11_OFFSET (PROBE_FIRST_FPREG_OFFSET + (11 * FPREG_SIZE))
#define PROBE_CPU_Q12_OFFSET (PROBE_FIRST_FPREG_OFFSET + (12 * FPREG_SIZE))
#define PROBE_CPU_Q13_OFFSET (PROBE_FIRST_FPREG_OFFSET + (13 * FPREG_SIZE))
#define PROBE_CPU_Q14_OFFSET (PROBE_FIRST_FPREG_OFFSET + (14 * FPREG_SIZE))
#define PROBE_CPU_Q15_OFFSET (PROBE_FIRST_FPREG_OFFSET + (15 * FPREG_SIZE))
#define PROBE_CPU_Q16_OFFSET (PROBE_FIRST_FPREG_OFFSET + (16 * FPREG_SIZE))
#define PROBE_CPU_Q17_OFFSET (PROBE_FIRST_FPREG_OFFSET + (17 * FPREG_SIZE))
#define PROBE_CPU_Q18_OFFSET (PROBE_FIRST_FPREG_OFFSET + (18 * FPREG_SIZE))
#define PROBE_CPU_Q19_OFFSET (PROBE_FIRST_FPREG_OFFSET + (19 * FPREG_SIZE))
#define PROBE_CPU_Q20_OFFSET (PROBE_FIRST_FPREG_OFFSET + (20 * FPREG_SIZE))
#define PROBE_CPU_Q21_OFFSET (PROBE_FIRST_FPREG_OFFSET + (21 * FPREG_SIZE))
#define PROBE_CPU_Q22_OFFSET (PROBE_FIRST_FPREG_OFFSET + (22 * FPREG_SIZE))
#define PROBE_CPU_Q23_OFFSET (PROBE_FIRST_FPREG_OFFSET + (23 * FPREG_SIZE))
#define PROBE_CPU_Q24_OFFSET (PROBE_FIRST_FPREG_OFFSET + (24 * FPREG_SIZE))
#define PROBE_CPU_Q25_OFFSET (PROBE_FIRST_FPREG_OFFSET + (25 * FPREG_SIZE))
#define PROBE_CPU_Q26_OFFSET (PROBE_FIRST_FPREG_OFFSET + (26 * FPREG_SIZE))
#define PROBE_CPU_Q27_OFFSET (PROBE_FIRST_FPREG_OFFSET + (27 * FPREG_SIZE))
#define PROBE_CPU_Q28_OFFSET (PROBE_FIRST_FPREG_OFFSET + (28 * FPREG_SIZE))
#define PROBE_CPU_Q29_OFFSET (PROBE_FIRST_FPREG_OFFSET + (29 * FPREG_SIZE))
#define PROBE_CPU_Q30_OFFSET (PROBE_FIRST_FPREG_OFFSET + (30 * FPREG_SIZE))
#define PROBE_CPU_Q31_OFFSET (PROBE_FIRST_FPREG_OFFSET + (31 * FPREG_SIZE))
#define PROBE_SIZE (PROBE_FIRST_FPREG_OFFSET + (32 * FPREG_SIZE))
#define SAVED_PROBE_RETURN_PC_OFFSET (PROBE_SIZE + (0 * GPREG_SIZE))
#define PROBE_SIZE_PLUS_EXTRAS (PROBE_SIZE + (3 * GPREG_SIZE))
// These ASSERTs remind you that if you change the layout of Probe::State,
// you need to change ctiMasmProbeTrampoline offsets above to match.
#define PROBE_OFFSETOF(x) offsetof(struct Probe::State, x)
static_assert(PROBE_OFFSETOF(probeFunction) == PROBE_PROBE_FUNCTION_OFFSET, "Probe::State::probeFunction's offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(arg) == PROBE_ARG_OFFSET, "Probe::State::arg's offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(initializeStackFunction) == PROBE_INIT_STACK_FUNCTION_OFFSET, "Probe::State::initializeStackFunction's offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(initializeStackArg) == PROBE_INIT_STACK_ARG_OFFSET, "Probe::State::initializeStackArg's offset matches ctiMasmProbeTrampoline");
static_assert(!(PROBE_CPU_X0_OFFSET & 0x7), "Probe::State::cpu.gprs[x0]'s offset should be 8 byte aligned");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x0]) == PROBE_CPU_X0_OFFSET, "Probe::State::cpu.gprs[x0]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x1]) == PROBE_CPU_X1_OFFSET, "Probe::State::cpu.gprs[x1]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x2]) == PROBE_CPU_X2_OFFSET, "Probe::State::cpu.gprs[x2]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x3]) == PROBE_CPU_X3_OFFSET, "Probe::State::cpu.gprs[x3]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x4]) == PROBE_CPU_X4_OFFSET, "Probe::State::cpu.gprs[x4]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x5]) == PROBE_CPU_X5_OFFSET, "Probe::State::cpu.gprs[x5]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x6]) == PROBE_CPU_X6_OFFSET, "Probe::State::cpu.gprs[x6]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x7]) == PROBE_CPU_X7_OFFSET, "Probe::State::cpu.gprs[x7]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x8]) == PROBE_CPU_X8_OFFSET, "Probe::State::cpu.gprs[x8]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x9]) == PROBE_CPU_X9_OFFSET, "Probe::State::cpu.gprs[x9]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x10]) == PROBE_CPU_X10_OFFSET, "Probe::State::cpu.gprs[x10]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x11]) == PROBE_CPU_X11_OFFSET, "Probe::State::cpu.gprs[x11]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x12]) == PROBE_CPU_X12_OFFSET, "Probe::State::cpu.gprs[x12]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x13]) == PROBE_CPU_X13_OFFSET, "Probe::State::cpu.gprs[x13]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x14]) == PROBE_CPU_X14_OFFSET, "Probe::State::cpu.gprs[x14]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x15]) == PROBE_CPU_X15_OFFSET, "Probe::State::cpu.gprs[x15]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x16]) == PROBE_CPU_X16_OFFSET, "Probe::State::cpu.gprs[x16]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x17]) == PROBE_CPU_X17_OFFSET, "Probe::State::cpu.gprs[x17]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x18]) == PROBE_CPU_X18_OFFSET, "Probe::State::cpu.gprs[x18]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x19]) == PROBE_CPU_X19_OFFSET, "Probe::State::cpu.gprs[x19]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x20]) == PROBE_CPU_X20_OFFSET, "Probe::State::cpu.gprs[x20]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x21]) == PROBE_CPU_X21_OFFSET, "Probe::State::cpu.gprs[x21]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x22]) == PROBE_CPU_X22_OFFSET, "Probe::State::cpu.gprs[x22]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x23]) == PROBE_CPU_X23_OFFSET, "Probe::State::cpu.gprs[x23]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x24]) == PROBE_CPU_X24_OFFSET, "Probe::State::cpu.gprs[x24]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x25]) == PROBE_CPU_X25_OFFSET, "Probe::State::cpu.gprs[x25]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x26]) == PROBE_CPU_X26_OFFSET, "Probe::State::cpu.gprs[x26]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x27]) == PROBE_CPU_X27_OFFSET, "Probe::State::cpu.gprs[x27]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::x28]) == PROBE_CPU_X28_OFFSET, "Probe::State::cpu.gprs[x28]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::fp]) == PROBE_CPU_FP_OFFSET, "Probe::State::cpu.gprs[fp]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::lr]) == PROBE_CPU_LR_OFFSET, "Probe::State::cpu.gprs[lr]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.gprs[ARM64Registers::sp]) == PROBE_CPU_SP_OFFSET, "Probe::State::cpu.gprs[sp]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.sprs[ARM64Registers::pc]) == PROBE_CPU_PC_OFFSET, "Probe::State::cpu.sprs[pc]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.sprs[ARM64Registers::nzcv]) == PROBE_CPU_NZCV_OFFSET, "Probe::State::cpu.sprs[nzcv]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.sprs[ARM64Registers::fpsr]) == PROBE_CPU_FPSR_OFFSET, "Probe::State::cpu.sprs[fpsr]'s offset matches ctiMasmProbeTrampoline");
static_assert(!(PROBE_CPU_Q0_OFFSET & 0x7), "Probe::State::cpu.fprs[q0]'s offset should be 8 byte aligned");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q0]) == PROBE_CPU_Q0_OFFSET, "Probe::State::cpu.fprs[q0]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q1]) == PROBE_CPU_Q1_OFFSET, "Probe::State::cpu.fprs[q1]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q2]) == PROBE_CPU_Q2_OFFSET, "Probe::State::cpu.fprs[q2]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q3]) == PROBE_CPU_Q3_OFFSET, "Probe::State::cpu.fprs[q3]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q4]) == PROBE_CPU_Q4_OFFSET, "Probe::State::cpu.fprs[q4]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q5]) == PROBE_CPU_Q5_OFFSET, "Probe::State::cpu.fprs[q5]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q6]) == PROBE_CPU_Q6_OFFSET, "Probe::State::cpu.fprs[q6]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q7]) == PROBE_CPU_Q7_OFFSET, "Probe::State::cpu.fprs[q7]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q8]) == PROBE_CPU_Q8_OFFSET, "Probe::State::cpu.fprs[q8]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q9]) == PROBE_CPU_Q9_OFFSET, "Probe::State::cpu.fprs[q9]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q10]) == PROBE_CPU_Q10_OFFSET, "Probe::State::cpu.fprs[q10]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q11]) == PROBE_CPU_Q11_OFFSET, "Probe::State::cpu.fprs[q11]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q12]) == PROBE_CPU_Q12_OFFSET, "Probe::State::cpu.fprs[q12]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q13]) == PROBE_CPU_Q13_OFFSET, "Probe::State::cpu.fprs[q13]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q14]) == PROBE_CPU_Q14_OFFSET, "Probe::State::cpu.fprs[q14]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q15]) == PROBE_CPU_Q15_OFFSET, "Probe::State::cpu.fprs[q15]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q16]) == PROBE_CPU_Q16_OFFSET, "Probe::State::cpu.fprs[q16]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q17]) == PROBE_CPU_Q17_OFFSET, "Probe::State::cpu.fprs[q17]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q18]) == PROBE_CPU_Q18_OFFSET, "Probe::State::cpu.fprs[q18]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q19]) == PROBE_CPU_Q19_OFFSET, "Probe::State::cpu.fprs[q19]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q20]) == PROBE_CPU_Q20_OFFSET, "Probe::State::cpu.fprs[q20]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q21]) == PROBE_CPU_Q21_OFFSET, "Probe::State::cpu.fprs[q21]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q22]) == PROBE_CPU_Q22_OFFSET, "Probe::State::cpu.fprs[q22]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q23]) == PROBE_CPU_Q23_OFFSET, "Probe::State::cpu.fprs[q23]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q24]) == PROBE_CPU_Q24_OFFSET, "Probe::State::cpu.fprs[q24]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q25]) == PROBE_CPU_Q25_OFFSET, "Probe::State::cpu.fprs[q25]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q26]) == PROBE_CPU_Q26_OFFSET, "Probe::State::cpu.fprs[q26]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q27]) == PROBE_CPU_Q27_OFFSET, "Probe::State::cpu.fprs[q27]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q28]) == PROBE_CPU_Q28_OFFSET, "Probe::State::cpu.fprs[q28]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q29]) == PROBE_CPU_Q29_OFFSET, "Probe::State::cpu.fprs[q29]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q30]) == PROBE_CPU_Q30_OFFSET, "Probe::State::cpu.fprs[q30]'s offset matches ctiMasmProbeTrampoline");
static_assert(PROBE_OFFSETOF(cpu.fprs[ARM64Registers::q31]) == PROBE_CPU_Q31_OFFSET, "Probe::State::cpu.fprs[q31]'s offset matches ctiMasmProbeTrampoline");
static_assert(sizeof(Probe::State) == PROBE_SIZE, "Probe::State's size matches ctiMasmProbeTrampoline");
// Conditions for using ldp and stp.
static_assert(PROBE_CPU_PC_OFFSET == PROBE_CPU_SP_OFFSET + GPREG_SIZE, "PROBE_CPU_SP_OFFSET and PROBE_CPU_PC_OFFSET must be adjacent");
static_assert(!(PROBE_SIZE_PLUS_EXTRAS & 0xf), "PROBE_SIZE_PLUS_EXTRAS should be 16 byte aligned"); // the Probe::State copying code relies on this.
#undef PROBE_OFFSETOF
#define FPR_OFFSET(fpr) (PROBE_CPU_##fpr##_OFFSET - PROBE_CPU_Q0_OFFSET)
struct IncomingProbeRecord {
UCPURegister x24;
UCPURegister x25;
UCPURegister x26;
UCPURegister x27;
UCPURegister x28;
UCPURegister x30; // lr
};
#define IN_X24_OFFSET (0 * GPREG_SIZE)
#define IN_X25_OFFSET (1 * GPREG_SIZE)
#define IN_X26_OFFSET (2 * GPREG_SIZE)
#define IN_X27_OFFSET (3 * GPREG_SIZE)
#define IN_X28_OFFSET (4 * GPREG_SIZE)
#define IN_X30_OFFSET (5 * GPREG_SIZE)
#define IN_SIZE (6 * GPREG_SIZE)
static_assert(IN_X24_OFFSET == offsetof(IncomingProbeRecord, x24), "IN_X24_OFFSET is incorrect");
static_assert(IN_X25_OFFSET == offsetof(IncomingProbeRecord, x25), "IN_X25_OFFSET is incorrect");
static_assert(IN_X26_OFFSET == offsetof(IncomingProbeRecord, x26), "IN_X26_OFFSET is incorrect");
static_assert(IN_X27_OFFSET == offsetof(IncomingProbeRecord, x27), "IN_X27_OFFSET is incorrect");
static_assert(IN_X28_OFFSET == offsetof(IncomingProbeRecord, x28), "IN_X22_OFFSET is incorrect");
static_assert(IN_X30_OFFSET == offsetof(IncomingProbeRecord, x30), "IN_X23_OFFSET is incorrect");
static_assert(IN_SIZE == sizeof(IncomingProbeRecord), "IN_SIZE is incorrect");
static_assert(!(sizeof(IncomingProbeRecord) & 0xf), "IncomingProbeStack must be 16-byte aligned");
struct OutgoingProbeRecord {
UCPURegister nzcv;
UCPURegister fpsr;
UCPURegister x27;
UCPURegister x28;
UCPURegister fp;
UCPURegister lr;
};
#define OUT_NZCV_OFFSET (0 * GPREG_SIZE)
#define OUT_FPSR_OFFSET (1 * GPREG_SIZE)
#define OUT_X27_OFFSET (2 * GPREG_SIZE)
#define OUT_X28_OFFSET (3 * GPREG_SIZE)
#define OUT_FP_OFFSET (4 * GPREG_SIZE)
#define OUT_LR_OFFSET (5 * GPREG_SIZE)
#define OUT_SIZE (6 * GPREG_SIZE)
static_assert(OUT_NZCV_OFFSET == offsetof(OutgoingProbeRecord, nzcv), "OUT_NZCV_OFFSET is incorrect");
static_assert(OUT_FPSR_OFFSET == offsetof(OutgoingProbeRecord, fpsr), "OUT_FPSR_OFFSET is incorrect");
static_assert(OUT_X27_OFFSET == offsetof(OutgoingProbeRecord, x27), "OUT_X27_OFFSET is incorrect");
static_assert(OUT_X28_OFFSET == offsetof(OutgoingProbeRecord, x28), "OUT_X28_OFFSET is incorrect");
static_assert(OUT_FP_OFFSET == offsetof(OutgoingProbeRecord, fp), "OUT_FP_OFFSET is incorrect");
static_assert(OUT_LR_OFFSET == offsetof(OutgoingProbeRecord, lr), "OUT_LR_OFFSET is incorrect");
static_assert(OUT_SIZE == sizeof(OutgoingProbeRecord), "OUT_SIZE is incorrect");
static_assert(!(sizeof(OutgoingProbeRecord) & 0xf), "OutgoingProbeStack must be 16-byte aligned");
struct LRRestorationRecord {
UCPURegister lr;
UCPURegister unusedDummyToEnsureSizeIs16ByteAligned;
};
#define LR_RESTORATION_LR_OFFSET (0 * GPREG_SIZE)
#define LR_RESTORATION_SIZE (2 * GPREG_SIZE)
static_assert(LR_RESTORATION_LR_OFFSET == offsetof(LRRestorationRecord, lr), "LR_RESTORATION_LR_OFFSET is incorrect");
static_assert(LR_RESTORATION_SIZE == sizeof(LRRestorationRecord), "LR_RESTORATION_SIZE is incorrect");
static_assert(!(sizeof(LRRestorationRecord) & 0xf), "LRRestorationRecord must be 16-byte aligned");
// We use x29 and x30 instead of fp and lr because GCC's inline assembler does not recognize fp and lr.
// See https://bugs.webkit.org/show_bug.cgi?id=175512 for details.
asm (
".text" "\n"
".balign 16" "\n"
".globl " SYMBOL_STRING(ctiMasmProbeTrampoline) "\n"
HIDE_SYMBOL(ctiMasmProbeTrampoline) "\n"
SYMBOL_STRING(ctiMasmProbeTrampoline) ":" "\n"
// MacroAssemblerARM64::probe() has already generated code to store some values in an
// IncomingProbeRecord. sp points to the IncomingProbeRecord.
//
// Incoming register values:
// x24: probe function
// x25: probe arg
// x26: scratch, was ctiMasmProbeTrampoline
// x27: scratch
// x28: Probe::executeProbe
// x30: return address
"mov x26, sp" "\n"
"mov x27, sp" "\n"
"sub x27, x27, #" STRINGIZE_VALUE_OF(PROBE_SIZE_PLUS_EXTRAS + OUT_SIZE) "\n"
"bic x27, x27, #0xf" "\n" // The ARM EABI specifies that the stack needs to be 16 byte aligned.
"mov sp, x27" "\n" // Set the sp to protect the Probe::State from interrupts before we initialize it.
"stp x24, x25, [sp, #" STRINGIZE_VALUE_OF(PROBE_PROBE_FUNCTION_OFFSET) "]" "\n" // Store the probe handler function and arg (preloaded into x24 and x25
"stp x0, x1, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X0_OFFSET) "]" "\n"
"mrs x0, nzcv" "\n" // Preload nzcv.
"stp x2, x3, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X2_OFFSET) "]" "\n"
"stp x4, x5, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X4_OFFSET) "]" "\n"
"mrs x1, fpsr" "\n" // Preload fpsr.
"stp x6, x7, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X6_OFFSET) "]" "\n"
"stp x8, x9, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X8_OFFSET) "]" "\n"
"ldp x2, x3, [x26, #" STRINGIZE_VALUE_OF(IN_X24_OFFSET) "]" "\n" // Preload saved x24 and x25.
"ldp x4, x5, [x26, #" STRINGIZE_VALUE_OF(IN_X26_OFFSET) "]" "\n" // Preload saved x26 and x27.
"ldp x6, x7, [x26, #" STRINGIZE_VALUE_OF(IN_X28_OFFSET) "]" "\n" // Preload saved x28 and lr.
"add x26, x26, #" STRINGIZE_VALUE_OF(IN_SIZE) "\n" // Compute the sp before the probe.
"stp x10, x11, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X10_OFFSET) "]" "\n"
"stp x12, x13, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X12_OFFSET) "]" "\n"
"stp x14, x15, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X14_OFFSET) "]" "\n"
"stp x16, x17, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X16_OFFSET) "]" "\n"
"stp x18, x19, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X18_OFFSET) "]" "\n"
"stp x20, x21, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X20_OFFSET) "]" "\n"
"stp x22, x23, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X22_OFFSET) "]" "\n"
"stp x2, x3, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X24_OFFSET) "]" "\n" // Store saved r24 and r25 (preloaded into x2 and x3 above).
"stp x4, x5, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X26_OFFSET) "]" "\n" // Store saved r26 and r27 (preloaded into x4 and x5 above).
"stp x6, x29, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X28_OFFSET) "]" "\n"
"stp x7, x26, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_LR_OFFSET) "]" "\n" // Save values lr and sp (original sp value computed into x26 above).
"str x30, [sp, #" STRINGIZE_VALUE_OF(SAVED_PROBE_RETURN_PC_OFFSET) "]" "\n" // Save a duplicate copy of return pc (in lr).
"add x30, x30, #" STRINGIZE_VALUE_OF(2 * GPREG_SIZE) "\n" // The PC after the probe is at 2 instructions past the return point.
"str x30, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_PC_OFFSET) "]" "\n"
"stp x0, x1, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_NZCV_OFFSET) "]" "\n" // Store nzcv and fpsr (preloaded into x0 and x1 above).
"add x9, sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_Q0_OFFSET) "\n"
"stp d0, d1, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q0)) "]" "\n"
"stp d2, d3, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q2)) "]" "\n"
"stp d4, d5, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q4)) "]" "\n"
"stp d6, d7, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q6)) "]" "\n"
"stp d8, d9, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q8)) "]" "\n"
"stp d10, d11, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q10)) "]" "\n"
"stp d12, d13, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q12)) "]" "\n"
"stp d14, d15, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q14)) "]" "\n"
"stp d16, d17, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q16)) "]" "\n"
"stp d18, d19, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q18)) "]" "\n"
"stp d20, d21, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q20)) "]" "\n"
"stp d22, d23, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q22)) "]" "\n"
"stp d24, d25, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q24)) "]" "\n"
"stp d26, d27, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q26)) "]" "\n"
"stp d28, d29, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q28)) "]" "\n"
"stp d30, d31, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q30)) "]" "\n"
"mov x27, sp" "\n" // Save the Probe::State* in a callee saved register.
// Note: we haven't changed the value of fp. Hence, it is still pointing to the frame of
// the caller of the probe (which is what we want in order to play nice with debuggers e.g. lldb).
"mov x0, sp" "\n" // Set the Probe::State* arg.
#if CPU(ARM64E)
"blraaz x28" "\n" // Call the probe handler.
#else
"blr x28" "\n" // Call the probe handler.
#endif
// Make sure the Probe::State is entirely below the result stack pointer so
// that register values are still preserved when we call the initializeStack
// function.
"ldr x1, [x27, #" STRINGIZE_VALUE_OF(PROBE_CPU_SP_OFFSET) "]" "\n" // Result sp.
"add x2, x27, #" STRINGIZE_VALUE_OF(PROBE_SIZE_PLUS_EXTRAS + OUT_SIZE) "\n" // End of Probe::State + buffer.
"cmp x1, x2" "\n"
"bge " LOCAL_LABEL_STRING(ctiMasmProbeTrampolineProbeStateIsSafe) "\n"
// Allocate a safe place on the stack below the result stack pointer to stash the Probe::State.
"sub x1, x1, #" STRINGIZE_VALUE_OF(PROBE_SIZE_PLUS_EXTRAS + OUT_SIZE) "\n"
"bic x1, x1, #0xf" "\n" // The ARM EABI specifies that the stack needs to be 16 byte aligned.
"mov sp, x1" "\n" // Set the new sp to protect that memory from interrupts before we copy the Probe::State.
// Copy the Probe::State to the safe place.
// Note: we have to copy from low address to higher address because we're moving the
// Probe::State to a lower address.
"mov x5, x27" "\n"
"mov x6, x1" "\n"
"add x7, x27, #" STRINGIZE_VALUE_OF(PROBE_SIZE_PLUS_EXTRAS) "\n"
LOCAL_LABEL_STRING(ctiMasmProbeTrampolineCopyLoop) ":" "\n"
"ldp x3, x4, [x5], #16" "\n"
"stp x3, x4, [x6], #16" "\n"
"cmp x5, x7" "\n"
"blt " LOCAL_LABEL_STRING(ctiMasmProbeTrampolineCopyLoop) "\n"
"mov x27, x1" "\n"
// Call initializeStackFunction if present.
LOCAL_LABEL_STRING(ctiMasmProbeTrampolineProbeStateIsSafe) ":" "\n"
"ldr x2, [x27, #" STRINGIZE_VALUE_OF(PROBE_INIT_STACK_FUNCTION_OFFSET) "]" "\n"
"cbz x2, " LOCAL_LABEL_STRING(ctiMasmProbeTrampolineRestoreRegisters) "\n"
"mov x0, x27" "\n" // Set the Probe::State* arg.
#if CPU(ARM64E)
"blraaz x2" "\n" // Call the initializeStackFunction (loaded into x2 above).
#else
"blr x2" "\n" // Call the initializeStackFunction (loaded into x2 above).
#endif
LOCAL_LABEL_STRING(ctiMasmProbeTrampolineRestoreRegisters) ":" "\n"
"mov sp, x27" "\n"
// To enable probes to modify register state, we copy all registers
// out of the Probe::State before returning. That is except for x18.
// x18 is "reserved for the platform. Conforming software should not make use of it."
// Hence, the JITs would not be using it, and the probe should also not be modifying it.
// See https://developer.apple.com/library/ios/documentation/Xcode/Conceptual/iPhoneOSABIReference/Articles/ARM64FunctionCallingConventions.html.
"add x9, sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_Q0_OFFSET) "\n"
"ldp d0, d1, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q0)) "]" "\n"
"ldp d2, d3, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q2)) "]" "\n"
"ldp d4, d5, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q4)) "]" "\n"
"ldp d6, d7, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q6)) "]" "\n"
"ldp d8, d9, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q8)) "]" "\n"
"ldp d10, d11, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q10)) "]" "\n"
"ldp d12, d13, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q12)) "]" "\n"
"ldp d14, d15, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q14)) "]" "\n"
"ldp d16, d17, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q16)) "]" "\n"
"ldp d18, d19, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q18)) "]" "\n"
"ldp d20, d21, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q20)) "]" "\n"
"ldp d22, d23, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q22)) "]" "\n"
"ldp d24, d25, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q24)) "]" "\n"
"ldp d26, d27, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q26)) "]" "\n"
"ldp d28, d29, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q28)) "]" "\n"
"ldp d30, d31, [x9, #" STRINGIZE_VALUE_OF(FPR_OFFSET(Q30)) "]" "\n"
"ldp x0, x1, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X0_OFFSET) "]" "\n"
"ldp x2, x3, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X2_OFFSET) "]" "\n"
"ldp x4, x5, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X4_OFFSET) "]" "\n"
"ldp x6, x7, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X6_OFFSET) "]" "\n"
"ldp x8, x9, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X8_OFFSET) "]" "\n"
"ldp x10, x11, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X10_OFFSET) "]" "\n"
"ldp x12, x13, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X12_OFFSET) "]" "\n"
"ldp x14, x15, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X14_OFFSET) "]" "\n"
"ldp x16, x17, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X16_OFFSET) "]" "\n"
// x18 should not be modified by the probe. See comment above for details.
"ldp x19, x20, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X19_OFFSET) "]" "\n"
"ldp x21, x22, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X21_OFFSET) "]" "\n"
"ldp x23, x24, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X23_OFFSET) "]" "\n"
"ldp x25, x26, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X25_OFFSET) "]" "\n"
// Remaining registers to restore are: fpsr, nzcv, x27, x28, fp, lr, sp, and pc.
// The only way to set the pc on ARM64 (from user space) is via an indirect branch
// or a ret, which means we'll need a free register to do so. For our purposes, lr
// happens to be available in applications of the probe where we may want to
// continue executing at a different location (i.e. change the pc) after the probe
// returns. So, the ARM64 probe implementation will allow the probe handler to
// either modify lr or pc, but not both in the same probe invocation. The probe
// mechanism ensures that we never try to modify both lr and pc with a RELEASE_ASSERT
// in Probe::executeProbe().
// Determine if the probe handler changed the pc.
"ldr x30, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_SP_OFFSET) "]" "\n" // preload the target sp.
"ldr x27, [sp, #" STRINGIZE_VALUE_OF(SAVED_PROBE_RETURN_PC_OFFSET) "]" "\n"
"ldr x28, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_PC_OFFSET) "]" "\n"
"add x27, x27, #" STRINGIZE_VALUE_OF(2 * GPREG_SIZE) "\n"
"cmp x27, x28" "\n"
"bne " LOCAL_LABEL_STRING(ctiMasmProbeTrampolineEnd) "\n"
// We didn't change the PC. So, let's prepare for setting a potentially new lr value.
// 1. Make room for the LRRestorationRecord. The probe site will pop this off later.
"sub x30, x30, #" STRINGIZE_VALUE_OF(LR_RESTORATION_SIZE) "\n"
// 2. Store the lp value to restore at the probe return site.
"ldr x27, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_LR_OFFSET) "]" "\n"
"str x27, [x30, #" STRINGIZE_VALUE_OF(LR_RESTORATION_LR_OFFSET) "]" "\n"
// 3. Force the return ramp to return to the probe return site.
"ldr x27, [sp, #" STRINGIZE_VALUE_OF(SAVED_PROBE_RETURN_PC_OFFSET) "]" "\n"
"str x27, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_PC_OFFSET) "]" "\n"
LOCAL_LABEL_STRING(ctiMasmProbeTrampolineEnd) ":" "\n"
// Fill in the OutgoingProbeRecord.
"sub x30, x30, #" STRINGIZE_VALUE_OF(OUT_SIZE) "\n"
"ldp x27, x28, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_NZCV_OFFSET) "]" "\n"
"stp x27, x28, [x30, #" STRINGIZE_VALUE_OF(OUT_NZCV_OFFSET) "]" "\n"
"ldp x27, x28, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_X27_OFFSET) "]" "\n"
"stp x27, x28, [x30, #" STRINGIZE_VALUE_OF(OUT_X27_OFFSET) "]" "\n"
"ldr x27, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_FP_OFFSET) "]" "\n"
"ldr x28, [sp, #" STRINGIZE_VALUE_OF(PROBE_CPU_PC_OFFSET) "]" "\n" // Set up the outgoing record so that we'll jump to the new PC.
"stp x27, x28, [x30, #" STRINGIZE_VALUE_OF(OUT_FP_OFFSET) "]" "\n"
"mov sp, x30" "\n"
// Restore the remaining registers and pop the OutgoingProbeRecord.
"ldp x27, x28, [sp], #" STRINGIZE_VALUE_OF(2 * GPREG_SIZE) "\n"
"msr nzcv, x27" "\n"
"msr fpsr, x28" "\n"
"ldp x27, x28, [sp], #" STRINGIZE_VALUE_OF(2 * GPREG_SIZE) "\n"
"ldp x29, x30, [sp], #" STRINGIZE_VALUE_OF(2 * GPREG_SIZE) "\n"
"ret" "\n"
);
#endif // COMPILER(GCC_COMPATIBLE)
void MacroAssembler::probe(Probe::Function function, void* arg)
{
sub64(TrustedImm32(sizeof(IncomingProbeRecord)), sp);
storePair64(x24, x25, sp, TrustedImm32(offsetof(IncomingProbeRecord, x24)));
storePair64(x26, x27, sp, TrustedImm32(offsetof(IncomingProbeRecord, x26)));
storePair64(x28, x30, sp, TrustedImm32(offsetof(IncomingProbeRecord, x28))); // Note: x30 is lr.
move(TrustedImmPtr(reinterpret_cast<void*>(ctiMasmProbeTrampoline)), x26);
move(TrustedImmPtr(reinterpret_cast<void*>(Probe::executeProbe)), x28);
move(TrustedImmPtr(reinterpret_cast<void*>(function)), x24);
move(TrustedImmPtr(arg), x25);
call(x26, CFunctionPtrTag);
// ctiMasmProbeTrampoline should have restored every register except for lr and the sp.
load64(Address(sp, offsetof(LRRestorationRecord, lr)), lr);
add64(TrustedImm32(sizeof(LRRestorationRecord)), sp);
}
#endif // ENABLE(MASM_PROBE)
void MacroAssemblerARM64::collectCPUFeatures()
{
#if OS(LINUX)
static std::once_flag onceKey;
std::call_once(onceKey, [] {
// A register for describing ARM64 CPU features are only accessible in kernel mode.
// Thus, some kernel support is necessary to collect CPU features. In Linux, the
// kernel passes CPU feature flags in AT_HWCAP auxiliary vector which is passed
// when the process starts. While this may pose a bit conservative information
// (for example, the Linux kernel may add a flag for a feature after the feature
// is shipped and implemented in some CPUs. In that case, even if the CPU has
// that feature, the kernel does not tell it to users.), it is a stable approach.
// https://www.kernel.org/doc/Documentation/arm64/elf_hwcaps.txt
uint64_t hwcaps = getauxval(AT_HWCAP);
#if !defined(HWCAP_JSCVT)
#define HWCAP_JSCVT (1 << 13)
#endif
s_jscvtCheckState = (hwcaps & HWCAP_JSCVT) ? CPUIDCheckState::Set : CPUIDCheckState::Clear;
});
#elif HAVE(FJCVTZS_INSTRUCTION)
s_jscvtCheckState = CPUIDCheckState::Set;
#else
s_jscvtCheckState = CPUIDCheckState::Clear;
#endif
}
MacroAssemblerARM64::CPUIDCheckState MacroAssemblerARM64::s_jscvtCheckState = CPUIDCheckState::NotChecked;
} // namespace JSC
#endif // ENABLE(ASSEMBLER) && CPU(ARM64)