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jdk/src/hotspot/cpu/riscv/macroAssembler_riscv.cpp
Axel Boldt-Christmas c7056737e3 8299089: Instrument global jni handles with tag to make them distinguishable 
Co-authored-by: Stefan Karlsson <stefank@openjdk.org>
Co-authored-by: Martin Doerr <mdoerr@openjdk.org>
Co-authored-by: Leslie Zhai <lzhai@openjdk.org>
Reviewed-by: eosterlund, stefank, ayang
2023-01-18 09:21:08 +00:00

4492 lines
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/*
* Copyright (c) 1997, 2023, Oracle and/or its affiliates. All rights reserved.
* Copyright (c) 2014, 2020, Red Hat Inc. All rights reserved.
* Copyright (c) 2020, 2022, Huawei Technologies Co., Ltd. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
* or visit www.oracle.com if you need additional information or have any
* questions.
*
*/
#include "precompiled.hpp"
#include "asm/assembler.hpp"
#include "asm/assembler.inline.hpp"
#include "compiler/disassembler.hpp"
#include "gc/shared/barrierSet.hpp"
#include "gc/shared/barrierSetAssembler.hpp"
#include "gc/shared/cardTable.hpp"
#include "gc/shared/cardTableBarrierSet.hpp"
#include "gc/shared/collectedHeap.hpp"
#include "interpreter/bytecodeHistogram.hpp"
#include "interpreter/interpreter.hpp"
#include "memory/resourceArea.hpp"
#include "memory/universe.hpp"
#include "nativeInst_riscv.hpp"
#include "oops/accessDecorators.hpp"
#include "oops/compressedOops.inline.hpp"
#include "oops/klass.inline.hpp"
#include "oops/oop.hpp"
#include "runtime/interfaceSupport.inline.hpp"
#include "runtime/javaThread.hpp"
#include "runtime/jniHandles.inline.hpp"
#include "runtime/sharedRuntime.hpp"
#include "runtime/stubRoutines.hpp"
#include "utilities/powerOfTwo.hpp"
#ifdef COMPILER2
#include "opto/compile.hpp"
#include "opto/node.hpp"
#include "opto/output.hpp"
#endif
#ifdef PRODUCT
#define BLOCK_COMMENT(str) /* nothing */
#else
#define BLOCK_COMMENT(str) block_comment(str)
#endif
#define BIND(label) bind(label); __ BLOCK_COMMENT(#label ":")
static void pass_arg0(MacroAssembler* masm, Register arg) {
if (c_rarg0 != arg) {
masm->mv(c_rarg0, arg);
}
}
static void pass_arg1(MacroAssembler* masm, Register arg) {
if (c_rarg1 != arg) {
masm->mv(c_rarg1, arg);
}
}
static void pass_arg2(MacroAssembler* masm, Register arg) {
if (c_rarg2 != arg) {
masm->mv(c_rarg2, arg);
}
}
static void pass_arg3(MacroAssembler* masm, Register arg) {
if (c_rarg3 != arg) {
masm->mv(c_rarg3, arg);
}
}
void MacroAssembler::push_cont_fastpath(Register java_thread) {
if (!Continuations::enabled()) return;
Label done;
ld(t0, Address(java_thread, JavaThread::cont_fastpath_offset()));
bleu(sp, t0, done);
sd(sp, Address(java_thread, JavaThread::cont_fastpath_offset()));
bind(done);
}
void MacroAssembler::pop_cont_fastpath(Register java_thread) {
if (!Continuations::enabled()) return;
Label done;
ld(t0, Address(java_thread, JavaThread::cont_fastpath_offset()));
bltu(sp, t0, done);
sd(zr, Address(java_thread, JavaThread::cont_fastpath_offset()));
bind(done);
}
int MacroAssembler::align(int modulus, int extra_offset) {
CompressibleRegion cr(this);
intptr_t before = offset();
while ((offset() + extra_offset) % modulus != 0) { nop(); }
return (int)(offset() - before);
}
void MacroAssembler::call_VM_helper(Register oop_result, address entry_point, int number_of_arguments, bool check_exceptions) {
call_VM_base(oop_result, noreg, noreg, entry_point, number_of_arguments, check_exceptions);
}
// Implementation of call_VM versions
void MacroAssembler::call_VM(Register oop_result,
address entry_point,
bool check_exceptions) {
call_VM_helper(oop_result, entry_point, 0, check_exceptions);
}
void MacroAssembler::call_VM(Register oop_result,
address entry_point,
Register arg_1,
bool check_exceptions) {
pass_arg1(this, arg_1);
call_VM_helper(oop_result, entry_point, 1, check_exceptions);
}
void MacroAssembler::call_VM(Register oop_result,
address entry_point,
Register arg_1,
Register arg_2,
bool check_exceptions) {
assert(arg_1 != c_rarg2, "smashed arg");
pass_arg2(this, arg_2);
pass_arg1(this, arg_1);
call_VM_helper(oop_result, entry_point, 2, check_exceptions);
}
void MacroAssembler::call_VM(Register oop_result,
address entry_point,
Register arg_1,
Register arg_2,
Register arg_3,
bool check_exceptions) {
assert(arg_1 != c_rarg3, "smashed arg");
assert(arg_2 != c_rarg3, "smashed arg");
pass_arg3(this, arg_3);
assert(arg_1 != c_rarg2, "smashed arg");
pass_arg2(this, arg_2);
pass_arg1(this, arg_1);
call_VM_helper(oop_result, entry_point, 3, check_exceptions);
}
void MacroAssembler::call_VM(Register oop_result,
Register last_java_sp,
address entry_point,
int number_of_arguments,
bool check_exceptions) {
call_VM_base(oop_result, xthread, last_java_sp, entry_point, number_of_arguments, check_exceptions);
}
void MacroAssembler::call_VM(Register oop_result,
Register last_java_sp,
address entry_point,
Register arg_1,
bool check_exceptions) {
pass_arg1(this, arg_1);
call_VM(oop_result, last_java_sp, entry_point, 1, check_exceptions);
}
void MacroAssembler::call_VM(Register oop_result,
Register last_java_sp,
address entry_point,
Register arg_1,
Register arg_2,
bool check_exceptions) {
assert(arg_1 != c_rarg2, "smashed arg");
pass_arg2(this, arg_2);
pass_arg1(this, arg_1);
call_VM(oop_result, last_java_sp, entry_point, 2, check_exceptions);
}
void MacroAssembler::call_VM(Register oop_result,
Register last_java_sp,
address entry_point,
Register arg_1,
Register arg_2,
Register arg_3,
bool check_exceptions) {
assert(arg_1 != c_rarg3, "smashed arg");
assert(arg_2 != c_rarg3, "smashed arg");
pass_arg3(this, arg_3);
assert(arg_1 != c_rarg2, "smashed arg");
pass_arg2(this, arg_2);
pass_arg1(this, arg_1);
call_VM(oop_result, last_java_sp, entry_point, 3, check_exceptions);
}
void MacroAssembler::post_call_nop() {
if (!Continuations::enabled()) {
return;
}
relocate(post_call_nop_Relocation::spec(), [&] {
nop();
li32(zr, 0);
});
}
// these are no-ops overridden by InterpreterMacroAssembler
void MacroAssembler::check_and_handle_earlyret(Register java_thread) {}
void MacroAssembler::check_and_handle_popframe(Register java_thread) {}
// Calls to C land
//
// When entering C land, the fp, & esp of the last Java frame have to be recorded
// in the (thread-local) JavaThread object. When leaving C land, the last Java fp
// has to be reset to 0. This is required to allow proper stack traversal.
void MacroAssembler::set_last_Java_frame(Register last_java_sp,
Register last_java_fp,
Register last_java_pc,
Register tmp) {
if (last_java_pc->is_valid()) {
sd(last_java_pc, Address(xthread,
JavaThread::frame_anchor_offset() +
JavaFrameAnchor::last_Java_pc_offset()));
}
// determine last_java_sp register
if (last_java_sp == sp) {
mv(tmp, sp);
last_java_sp = tmp;
} else if (!last_java_sp->is_valid()) {
last_java_sp = esp;
}
sd(last_java_sp, Address(xthread, JavaThread::last_Java_sp_offset()));
// last_java_fp is optional
if (last_java_fp->is_valid()) {
sd(last_java_fp, Address(xthread, JavaThread::last_Java_fp_offset()));
}
}
void MacroAssembler::set_last_Java_frame(Register last_java_sp,
Register last_java_fp,
address last_java_pc,
Register tmp) {
assert(last_java_pc != NULL, "must provide a valid PC");
la(tmp, last_java_pc);
sd(tmp, Address(xthread, JavaThread::frame_anchor_offset() + JavaFrameAnchor::last_Java_pc_offset()));
set_last_Java_frame(last_java_sp, last_java_fp, noreg, tmp);
}
void MacroAssembler::set_last_Java_frame(Register last_java_sp,
Register last_java_fp,
Label &L,
Register tmp) {
if (L.is_bound()) {
set_last_Java_frame(last_java_sp, last_java_fp, target(L), tmp);
} else {
L.add_patch_at(code(), locator());
IncompressibleRegion ir(this); // the label address will be patched back.
set_last_Java_frame(last_java_sp, last_java_fp, pc() /* Patched later */, tmp);
}
}
void MacroAssembler::reset_last_Java_frame(bool clear_fp) {
// we must set sp to zero to clear frame
sd(zr, Address(xthread, JavaThread::last_Java_sp_offset()));
// must clear fp, so that compiled frames are not confused; it is
// possible that we need it only for debugging
if (clear_fp) {
sd(zr, Address(xthread, JavaThread::last_Java_fp_offset()));
}
// Always clear the pc because it could have been set by make_walkable()
sd(zr, Address(xthread, JavaThread::last_Java_pc_offset()));
}
void MacroAssembler::call_VM_base(Register oop_result,
Register java_thread,
Register last_java_sp,
address entry_point,
int number_of_arguments,
bool check_exceptions) {
// determine java_thread register
if (!java_thread->is_valid()) {
java_thread = xthread;
}
// determine last_java_sp register
if (!last_java_sp->is_valid()) {
last_java_sp = esp;
}
// debugging support
assert(number_of_arguments >= 0 , "cannot have negative number of arguments");
assert(java_thread == xthread, "unexpected register");
assert(java_thread != oop_result , "cannot use the same register for java_thread & oop_result");
assert(java_thread != last_java_sp, "cannot use the same register for java_thread & last_java_sp");
// push java thread (becomes first argument of C function)
mv(c_rarg0, java_thread);
// set last Java frame before call
assert(last_java_sp != fp, "can't use fp");
Label l;
set_last_Java_frame(last_java_sp, fp, l, t0);
// do the call, remove parameters
MacroAssembler::call_VM_leaf_base(entry_point, number_of_arguments, &l);
// reset last Java frame
// Only interpreter should have to clear fp
reset_last_Java_frame(true);
// C++ interp handles this in the interpreter
check_and_handle_popframe(java_thread);
check_and_handle_earlyret(java_thread);
if (check_exceptions) {
// check for pending exceptions (java_thread is set upon return)
ld(t0, Address(java_thread, in_bytes(Thread::pending_exception_offset())));
Label ok;
beqz(t0, ok);
RuntimeAddress target(StubRoutines::forward_exception_entry());
relocate(target.rspec(), [&] {
int32_t offset;
la_patchable(t0, target, offset);
jalr(x0, t0, offset);
});
bind(ok);
}
// get oop result if there is one and reset the value in the thread
if (oop_result->is_valid()) {
get_vm_result(oop_result, java_thread);
}
}
void MacroAssembler::get_vm_result(Register oop_result, Register java_thread) {
ld(oop_result, Address(java_thread, JavaThread::vm_result_offset()));
sd(zr, Address(java_thread, JavaThread::vm_result_offset()));
verify_oop_msg(oop_result, "broken oop in call_VM_base");
}
void MacroAssembler::get_vm_result_2(Register metadata_result, Register java_thread) {
ld(metadata_result, Address(java_thread, JavaThread::vm_result_2_offset()));
sd(zr, Address(java_thread, JavaThread::vm_result_2_offset()));
}
void MacroAssembler::clinit_barrier(Register klass, Register tmp, Label* L_fast_path, Label* L_slow_path) {
assert(L_fast_path != NULL || L_slow_path != NULL, "at least one is required");
assert_different_registers(klass, xthread, tmp);
Label L_fallthrough, L_tmp;
if (L_fast_path == NULL) {
L_fast_path = &L_fallthrough;
} else if (L_slow_path == NULL) {
L_slow_path = &L_fallthrough;
}
// Fast path check: class is fully initialized
lbu(tmp, Address(klass, InstanceKlass::init_state_offset()));
sub(tmp, tmp, InstanceKlass::fully_initialized);
beqz(tmp, *L_fast_path);
// Fast path check: current thread is initializer thread
ld(tmp, Address(klass, InstanceKlass::init_thread_offset()));
if (L_slow_path == &L_fallthrough) {
beq(xthread, tmp, *L_fast_path);
bind(*L_slow_path);
} else if (L_fast_path == &L_fallthrough) {
bne(xthread, tmp, *L_slow_path);
bind(*L_fast_path);
} else {
Unimplemented();
}
}
void MacroAssembler::_verify_oop(Register reg, const char* s, const char* file, int line) {
if (!VerifyOops) { return; }
// Pass register number to verify_oop_subroutine
const char* b = NULL;
{
ResourceMark rm;
stringStream ss;
ss.print("verify_oop: %s: %s (%s:%d)", reg->name(), s, file, line);
b = code_string(ss.as_string());
}
BLOCK_COMMENT("verify_oop {");
push_reg(RegSet::of(ra, t0, t1, c_rarg0), sp);
mv(c_rarg0, reg); // c_rarg0 : x10
{
// The length of the instruction sequence emitted should not depend
// on the address of the char buffer so that the size of mach nodes for
// scratch emit and normal emit matches.
IncompressibleRegion ir(this); // Fixed length
movptr(t0, (address) b);
}
// call indirectly to solve generation ordering problem
ExternalAddress target(StubRoutines::verify_oop_subroutine_entry_address());
relocate(target.rspec(), [&] {
int32_t offset;
la_patchable(t1, target, offset);
ld(t1, Address(t1, offset));
});
jalr(t1);
pop_reg(RegSet::of(ra, t0, t1, c_rarg0), sp);
BLOCK_COMMENT("} verify_oop");
}
void MacroAssembler::_verify_oop_addr(Address addr, const char* s, const char* file, int line) {
if (!VerifyOops) {
return;
}
const char* b = NULL;
{
ResourceMark rm;
stringStream ss;
ss.print("verify_oop_addr: %s (%s:%d)", s, file, line);
b = code_string(ss.as_string());
}
BLOCK_COMMENT("verify_oop_addr {");
push_reg(RegSet::of(ra, t0, t1, c_rarg0), sp);
if (addr.uses(sp)) {
la(x10, addr);
ld(x10, Address(x10, 4 * wordSize));
} else {
ld(x10, addr);
}
{
// The length of the instruction sequence emitted should not depend
// on the address of the char buffer so that the size of mach nodes for
// scratch emit and normal emit matches.
IncompressibleRegion ir(this); // Fixed length
movptr(t0, (address) b);
}
// call indirectly to solve generation ordering problem
ExternalAddress target(StubRoutines::verify_oop_subroutine_entry_address());
relocate(target.rspec(), [&] {
int32_t offset;
la_patchable(t1, target, offset);
ld(t1, Address(t1, offset));
});
jalr(t1);
pop_reg(RegSet::of(ra, t0, t1, c_rarg0), sp);
BLOCK_COMMENT("} verify_oop_addr");
}
Address MacroAssembler::argument_address(RegisterOrConstant arg_slot,
int extra_slot_offset) {
// cf. TemplateTable::prepare_invoke(), if (load_receiver).
int stackElementSize = Interpreter::stackElementSize;
int offset = Interpreter::expr_offset_in_bytes(extra_slot_offset+0);
#ifdef ASSERT
int offset1 = Interpreter::expr_offset_in_bytes(extra_slot_offset+1);
assert(offset1 - offset == stackElementSize, "correct arithmetic");
#endif
if (arg_slot.is_constant()) {
return Address(esp, arg_slot.as_constant() * stackElementSize + offset);
} else {
assert_different_registers(t0, arg_slot.as_register());
shadd(t0, arg_slot.as_register(), esp, t0, exact_log2(stackElementSize));
return Address(t0, offset);
}
}
#ifndef PRODUCT
extern "C" void findpc(intptr_t x);
#endif
void MacroAssembler::debug64(char* msg, int64_t pc, int64_t regs[])
{
// In order to get locks to work, we need to fake a in_VM state
if (ShowMessageBoxOnError) {
JavaThread* thread = JavaThread::current();
JavaThreadState saved_state = thread->thread_state();
thread->set_thread_state(_thread_in_vm);
#ifndef PRODUCT
if (CountBytecodes || TraceBytecodes || StopInterpreterAt) {
ttyLocker ttyl;
BytecodeCounter::print();
}
#endif
if (os::message_box(msg, "Execution stopped, print registers?")) {
ttyLocker ttyl;
tty->print_cr(" pc = 0x%016lx", pc);
#ifndef PRODUCT
tty->cr();
findpc(pc);
tty->cr();
#endif
tty->print_cr(" x0 = 0x%016lx", regs[0]);
tty->print_cr(" x1 = 0x%016lx", regs[1]);
tty->print_cr(" x2 = 0x%016lx", regs[2]);
tty->print_cr(" x3 = 0x%016lx", regs[3]);
tty->print_cr(" x4 = 0x%016lx", regs[4]);
tty->print_cr(" x5 = 0x%016lx", regs[5]);
tty->print_cr(" x6 = 0x%016lx", regs[6]);
tty->print_cr(" x7 = 0x%016lx", regs[7]);
tty->print_cr(" x8 = 0x%016lx", regs[8]);
tty->print_cr(" x9 = 0x%016lx", regs[9]);
tty->print_cr("x10 = 0x%016lx", regs[10]);
tty->print_cr("x11 = 0x%016lx", regs[11]);
tty->print_cr("x12 = 0x%016lx", regs[12]);
tty->print_cr("x13 = 0x%016lx", regs[13]);
tty->print_cr("x14 = 0x%016lx", regs[14]);
tty->print_cr("x15 = 0x%016lx", regs[15]);
tty->print_cr("x16 = 0x%016lx", regs[16]);
tty->print_cr("x17 = 0x%016lx", regs[17]);
tty->print_cr("x18 = 0x%016lx", regs[18]);
tty->print_cr("x19 = 0x%016lx", regs[19]);
tty->print_cr("x20 = 0x%016lx", regs[20]);
tty->print_cr("x21 = 0x%016lx", regs[21]);
tty->print_cr("x22 = 0x%016lx", regs[22]);
tty->print_cr("x23 = 0x%016lx", regs[23]);
tty->print_cr("x24 = 0x%016lx", regs[24]);
tty->print_cr("x25 = 0x%016lx", regs[25]);
tty->print_cr("x26 = 0x%016lx", regs[26]);
tty->print_cr("x27 = 0x%016lx", regs[27]);
tty->print_cr("x28 = 0x%016lx", regs[28]);
tty->print_cr("x30 = 0x%016lx", regs[30]);
tty->print_cr("x31 = 0x%016lx", regs[31]);
BREAKPOINT;
}
}
fatal("DEBUG MESSAGE: %s", msg);
}
void MacroAssembler::resolve_jobject(Register value, Register tmp1, Register tmp2) {
assert_different_registers(value, tmp1, tmp2);
Label done, tagged, weak_tagged;
beqz(value, done); // Use NULL as-is.
// Test for tag.
andi(t0, value, JNIHandles::tag_mask);
bnez(t0, tagged);
// Resolve local handle
access_load_at(T_OBJECT, IN_NATIVE | AS_RAW, value, Address(value, 0), tmp1, tmp2);
verify_oop(value);
j(done);
bind(tagged);
// Test for jweak tag.
andi(t0, value, JNIHandles::TypeTag::weak_global);
bnez(t0, weak_tagged);
// Resolve global handle
access_load_at(T_OBJECT, IN_NATIVE, value,
Address(value, -JNIHandles::TypeTag::global), tmp1, tmp2);
j(done);
bind(weak_tagged);
// Resolve jweak.
access_load_at(T_OBJECT, IN_NATIVE | ON_PHANTOM_OOP_REF, value,
Address(value, -JNIHandles::TypeTag::weak_global), tmp1, tmp2);
verify_oop(value);
bind(done);
}
void MacroAssembler::resolve_global_jobject(Register value, Register tmp1, Register tmp2) {
assert_different_registers(value, tmp1, tmp2);
Label done;
beqz(value, done); // Use NULL as-is.
#ifdef ASSERT
{
Label valid_global_tag;
andi(t0, value, JNIHandles::TypeTag::global); // Test for global tag.
bnez(t0, valid_global_tag);
stop("non global jobject using resolve_global_jobject");
bind(valid_global_tag);
}
#endif
// Resolve global handle
access_load_at(T_OBJECT, IN_NATIVE, value,
Address(value, -JNIHandles::TypeTag::global), tmp1, tmp2);
verify_oop(value);
bind(done);
}
void MacroAssembler::stop(const char* msg) {
BLOCK_COMMENT(msg);
illegal_instruction(Assembler::csr::time);
emit_int64((uintptr_t)msg);
}
void MacroAssembler::unimplemented(const char* what) {
const char* buf = NULL;
{
ResourceMark rm;
stringStream ss;
ss.print("unimplemented: %s", what);
buf = code_string(ss.as_string());
}
stop(buf);
}
void MacroAssembler::emit_static_call_stub() {
IncompressibleRegion ir(this); // Fixed length: see CompiledStaticCall::to_interp_stub_size().
// CompiledDirectStaticCall::set_to_interpreted knows the
// exact layout of this stub.
mov_metadata(xmethod, (Metadata*)NULL);
// Jump to the entry point of the c2i stub.
int32_t offset = 0;
movptr(t0, 0, offset);
jalr(x0, t0, offset);
}
void MacroAssembler::call_VM_leaf_base(address entry_point,
int number_of_arguments,
Label *retaddr) {
push_reg(RegSet::of(t0, xmethod), sp); // push << t0 & xmethod >> to sp
call(entry_point);
if (retaddr != NULL) {
bind(*retaddr);
}
pop_reg(RegSet::of(t0, xmethod), sp); // pop << t0 & xmethod >> from sp
}
void MacroAssembler::call_VM_leaf(address entry_point, int number_of_arguments) {
call_VM_leaf_base(entry_point, number_of_arguments);
}
void MacroAssembler::call_VM_leaf(address entry_point, Register arg_0) {
pass_arg0(this, arg_0);
call_VM_leaf_base(entry_point, 1);
}
void MacroAssembler::call_VM_leaf(address entry_point, Register arg_0, Register arg_1) {
pass_arg0(this, arg_0);
pass_arg1(this, arg_1);
call_VM_leaf_base(entry_point, 2);
}
void MacroAssembler::call_VM_leaf(address entry_point, Register arg_0,
Register arg_1, Register arg_2) {
pass_arg0(this, arg_0);
pass_arg1(this, arg_1);
pass_arg2(this, arg_2);
call_VM_leaf_base(entry_point, 3);
}
void MacroAssembler::super_call_VM_leaf(address entry_point, Register arg_0) {
pass_arg0(this, arg_0);
MacroAssembler::call_VM_leaf_base(entry_point, 1);
}
void MacroAssembler::super_call_VM_leaf(address entry_point, Register arg_0, Register arg_1) {
assert(arg_0 != c_rarg1, "smashed arg");
pass_arg1(this, arg_1);
pass_arg0(this, arg_0);
MacroAssembler::call_VM_leaf_base(entry_point, 2);
}
void MacroAssembler::super_call_VM_leaf(address entry_point, Register arg_0, Register arg_1, Register arg_2) {
assert(arg_0 != c_rarg2, "smashed arg");
assert(arg_1 != c_rarg2, "smashed arg");
pass_arg2(this, arg_2);
assert(arg_0 != c_rarg1, "smashed arg");
pass_arg1(this, arg_1);
pass_arg0(this, arg_0);
MacroAssembler::call_VM_leaf_base(entry_point, 3);
}
void MacroAssembler::super_call_VM_leaf(address entry_point, Register arg_0, Register arg_1, Register arg_2, Register arg_3) {
assert(arg_0 != c_rarg3, "smashed arg");
assert(arg_1 != c_rarg3, "smashed arg");
assert(arg_2 != c_rarg3, "smashed arg");
pass_arg3(this, arg_3);
assert(arg_0 != c_rarg2, "smashed arg");
assert(arg_1 != c_rarg2, "smashed arg");
pass_arg2(this, arg_2);
assert(arg_0 != c_rarg1, "smashed arg");
pass_arg1(this, arg_1);
pass_arg0(this, arg_0);
MacroAssembler::call_VM_leaf_base(entry_point, 4);
}
void MacroAssembler::baseOffset32(Register Rd, const Address &adr, int32_t &offset) {
assert(Rd != noreg, "Rd must not be empty register!");
guarantee(Rd != adr.base(), "should use different registers!");
if (is_offset_in_range(adr.offset(), 32)) {
int32_t imm = adr.offset();
int32_t upper = imm, lower = imm;
lower = (imm << 20) >> 20;
upper -= lower;
lui(Rd, upper);
offset = lower;
} else {
offset = ((int32_t)adr.offset() << 20) >> 20;
li(Rd, adr.offset() - offset);
}
add(Rd, Rd, adr.base());
}
void MacroAssembler::baseOffset(Register Rd, const Address &adr, int32_t &offset) {
if (is_offset_in_range(adr.offset(), 12)) {
assert(Rd != noreg, "Rd must not be empty register!");
addi(Rd, adr.base(), adr.offset());
offset = 0;
} else {
baseOffset32(Rd, adr, offset);
}
}
void MacroAssembler::la(Register Rd, const address dest) {
int64_t offset = dest - pc();
if (is_offset_in_range(offset, 32)) {
auipc(Rd, (int32_t)offset + 0x800); //0x800, Note:the 11th sign bit
addi(Rd, Rd, ((int64_t)offset << 52) >> 52);
} else {
movptr(Rd, dest);
}
}
void MacroAssembler::la(Register Rd, const Address &adr) {
switch (adr.getMode()) {
case Address::literal: {
relocInfo::relocType rtype = adr.rspec().reloc()->type();
if (rtype == relocInfo::none) {
mv(Rd, (intptr_t)(adr.target()));
} else {
relocate(adr.rspec(), [&] {
movptr(Rd, adr.target());
});
}
break;
}
case Address::base_plus_offset: {
int32_t offset = 0;
baseOffset(Rd, adr, offset);
addi(Rd, Rd, offset);
break;
}
default:
ShouldNotReachHere();
}
}
void MacroAssembler::la(Register Rd, Label &label) {
IncompressibleRegion ir(this); // the label address may be patched back.
wrap_label(Rd, label, &MacroAssembler::la);
}
void MacroAssembler::li32(Register Rd, int32_t imm) {
// int32_t is in range 0x8000 0000 ~ 0x7fff ffff, and imm[31] is the sign bit
int64_t upper = imm, lower = imm;
lower = (imm << 20) >> 20;
upper -= lower;
upper = (int32_t)upper;
// lui Rd, imm[31:12] + imm[11]
lui(Rd, upper);
// use addiw to distinguish li32 to li64
addiw(Rd, Rd, lower);
}
void MacroAssembler::li64(Register Rd, int64_t imm) {
// Load upper 32 bits. upper = imm[63:32], but if imm[31] == 1 or
// (imm[31:20] == 0x7ff && imm[19] == 1), upper = imm[63:32] + 1.
int64_t lower = imm & 0xffffffff;
lower -= ((lower << 44) >> 44);
int64_t tmp_imm = ((uint64_t)(imm & 0xffffffff00000000)) + (uint64_t)lower;
int32_t upper = (tmp_imm - (int32_t)lower) >> 32;
// Load upper 32 bits
int64_t up = upper, lo = upper;
lo = (lo << 52) >> 52;
up -= lo;
up = (int32_t)up;
lui(Rd, up);
addi(Rd, Rd, lo);
// Load the rest 32 bits.
slli(Rd, Rd, 12);
addi(Rd, Rd, (int32_t)lower >> 20);
slli(Rd, Rd, 12);
lower = ((int32_t)imm << 12) >> 20;
addi(Rd, Rd, lower);
slli(Rd, Rd, 8);
lower = imm & 0xff;
addi(Rd, Rd, lower);
}
void MacroAssembler::li(Register Rd, int64_t imm) {
// int64_t is in range 0x8000 0000 0000 0000 ~ 0x7fff ffff ffff ffff
// li -> c.li
if (do_compress() && (is_imm_in_range(imm, 6, 0) && Rd != x0)) {
c_li(Rd, imm);
return;
}
int shift = 12;
int64_t upper = imm, lower = imm;
// Split imm to a lower 12-bit sign-extended part and the remainder,
// because addi will sign-extend the lower imm.
lower = ((int32_t)imm << 20) >> 20;
upper -= lower;
// Test whether imm is a 32-bit integer.
if (!(((imm) & ~(int64_t)0x7fffffff) == 0 ||
(((imm) & ~(int64_t)0x7fffffff) == ~(int64_t)0x7fffffff))) {
while (((upper >> shift) & 1) == 0) { shift++; }
upper >>= shift;
li(Rd, upper);
slli(Rd, Rd, shift);
if (lower != 0) {
addi(Rd, Rd, lower);
}
} else {
// 32-bit integer
Register hi_Rd = zr;
if (upper != 0) {
lui(Rd, (int32_t)upper);
hi_Rd = Rd;
}
if (lower != 0 || hi_Rd == zr) {
addiw(Rd, hi_Rd, lower);
}
}
}
#define INSN(NAME, REGISTER) \
void MacroAssembler::NAME(const address dest, Register temp) { \
assert_cond(dest != NULL); \
int64_t distance = dest - pc(); \
if (is_imm_in_range(distance, 20, 1)) { \
Assembler::jal(REGISTER, distance); \
} else { \
assert(temp != noreg, "temp must not be empty register!"); \
int32_t offset = 0; \
movptr(temp, dest, offset); \
Assembler::jalr(REGISTER, temp, offset); \
} \
} \
INSN(j, x0);
INSN(jal, x1);
#undef INSN
#define INSN(NAME, REGISTER) \
void MacroAssembler::NAME(const Address &adr, Register temp) { \
switch (adr.getMode()) { \
case Address::literal: { \
relocate(adr.rspec(), [&] { \
NAME(adr.target(), temp); \
}); \
break; \
} \
case Address::base_plus_offset: { \
int32_t offset = 0; \
baseOffset(temp, adr, offset); \
Assembler::jalr(REGISTER, temp, offset); \
break; \
} \
default: \
ShouldNotReachHere(); \
} \
}
INSN(j, x0);
INSN(jal, x1);
#undef INSN
#define INSN(NAME) \
void MacroAssembler::NAME(Register Rd, const address dest, Register temp) { \
assert_cond(dest != NULL); \
int64_t distance = dest - pc(); \
if (is_imm_in_range(distance, 20, 1)) { \
Assembler::NAME(Rd, distance); \
} else { \
assert_different_registers(Rd, temp); \
int32_t offset = 0; \
movptr(temp, dest, offset); \
jalr(Rd, temp, offset); \
} \
} \
void MacroAssembler::NAME(Register Rd, Label &L, Register temp) { \
assert_different_registers(Rd, temp); \
wrap_label(Rd, L, temp, &MacroAssembler::NAME); \
}
INSN(jal);
#undef INSN
#define INSN(NAME, REGISTER) \
void MacroAssembler::NAME(Label &l, Register temp) { \
jal(REGISTER, l, temp); \
} \
INSN(j, x0);
INSN(jal, x1);
#undef INSN
void MacroAssembler::wrap_label(Register Rt, Label &L, Register tmp, load_insn_by_temp insn) {
if (L.is_bound()) {
(this->*insn)(Rt, target(L), tmp);
} else {
L.add_patch_at(code(), locator());
(this->*insn)(Rt, pc(), tmp);
}
}
void MacroAssembler::wrap_label(Register Rt, Label &L, jal_jalr_insn insn) {
if (L.is_bound()) {
(this->*insn)(Rt, target(L));
} else {
L.add_patch_at(code(), locator());
(this->*insn)(Rt, pc());
}
}
void MacroAssembler::wrap_label(Register r1, Register r2, Label &L,
compare_and_branch_insn insn,
compare_and_branch_label_insn neg_insn, bool is_far) {
if (is_far) {
Label done;
(this->*neg_insn)(r1, r2, done, /* is_far */ false);
j(L);
bind(done);
} else {
if (L.is_bound()) {
(this->*insn)(r1, r2, target(L));
} else {
L.add_patch_at(code(), locator());
(this->*insn)(r1, r2, pc());
}
}
}
#define INSN(NAME, NEG_INSN) \
void MacroAssembler::NAME(Register Rs1, Register Rs2, Label &L, bool is_far) { \
wrap_label(Rs1, Rs2, L, &MacroAssembler::NAME, &MacroAssembler::NEG_INSN, is_far); \
}
INSN(beq, bne);
INSN(bne, beq);
INSN(blt, bge);
INSN(bge, blt);
INSN(bltu, bgeu);
INSN(bgeu, bltu);
#undef INSN
#define INSN(NAME) \
void MacroAssembler::NAME##z(Register Rs, const address dest) { \
NAME(Rs, zr, dest); \
} \
void MacroAssembler::NAME##z(Register Rs, Label &l, bool is_far) { \
NAME(Rs, zr, l, is_far); \
} \
INSN(beq);
INSN(bne);
INSN(blt);
INSN(ble);
INSN(bge);
INSN(bgt);
#undef INSN
#define INSN(NAME, NEG_INSN) \
void MacroAssembler::NAME(Register Rs, Register Rt, const address dest) { \
NEG_INSN(Rt, Rs, dest); \
} \
void MacroAssembler::NAME(Register Rs, Register Rt, Label &l, bool is_far) { \
NEG_INSN(Rt, Rs, l, is_far); \
}
INSN(bgt, blt);
INSN(ble, bge);
INSN(bgtu, bltu);
INSN(bleu, bgeu);
#undef INSN
// Float compare branch instructions
#define INSN(NAME, FLOATCMP, BRANCH) \
void MacroAssembler::float_##NAME(FloatRegister Rs1, FloatRegister Rs2, Label &l, bool is_far, bool is_unordered) { \
FLOATCMP##_s(t0, Rs1, Rs2); \
BRANCH(t0, l, is_far); \
} \
void MacroAssembler::double_##NAME(FloatRegister Rs1, FloatRegister Rs2, Label &l, bool is_far, bool is_unordered) { \
FLOATCMP##_d(t0, Rs1, Rs2); \
BRANCH(t0, l, is_far); \
}
INSN(beq, feq, bnez);
INSN(bne, feq, beqz);
#undef INSN
#define INSN(NAME, FLOATCMP1, FLOATCMP2) \
void MacroAssembler::float_##NAME(FloatRegister Rs1, FloatRegister Rs2, Label &l, \
bool is_far, bool is_unordered) { \
if (is_unordered) { \
/* jump if either source is NaN or condition is expected */ \
FLOATCMP2##_s(t0, Rs2, Rs1); \
beqz(t0, l, is_far); \
} else { \
/* jump if no NaN in source and condition is expected */ \
FLOATCMP1##_s(t0, Rs1, Rs2); \
bnez(t0, l, is_far); \
} \
} \
void MacroAssembler::double_##NAME(FloatRegister Rs1, FloatRegister Rs2, Label &l, \
bool is_far, bool is_unordered) { \
if (is_unordered) { \
/* jump if either source is NaN or condition is expected */ \
FLOATCMP2##_d(t0, Rs2, Rs1); \
beqz(t0, l, is_far); \
} else { \
/* jump if no NaN in source and condition is expected */ \
FLOATCMP1##_d(t0, Rs1, Rs2); \
bnez(t0, l, is_far); \
} \
}
INSN(ble, fle, flt);
INSN(blt, flt, fle);
#undef INSN
#define INSN(NAME, CMP) \
void MacroAssembler::float_##NAME(FloatRegister Rs1, FloatRegister Rs2, Label &l, \
bool is_far, bool is_unordered) { \
float_##CMP(Rs2, Rs1, l, is_far, is_unordered); \
} \
void MacroAssembler::double_##NAME(FloatRegister Rs1, FloatRegister Rs2, Label &l, \
bool is_far, bool is_unordered) { \
double_##CMP(Rs2, Rs1, l, is_far, is_unordered); \
}
INSN(bgt, blt);
INSN(bge, ble);
#undef INSN
#define INSN(NAME, CSR) \
void MacroAssembler::NAME(Register Rd) { \
csrr(Rd, CSR); \
}
INSN(rdinstret, CSR_INSTERT);
INSN(rdcycle, CSR_CYCLE);
INSN(rdtime, CSR_TIME);
INSN(frcsr, CSR_FCSR);
INSN(frrm, CSR_FRM);
INSN(frflags, CSR_FFLAGS);
#undef INSN
void MacroAssembler::csrr(Register Rd, unsigned csr) {
csrrs(Rd, csr, x0);
}
#define INSN(NAME, OPFUN) \
void MacroAssembler::NAME(unsigned csr, Register Rs) { \
OPFUN(x0, csr, Rs); \
}
INSN(csrw, csrrw);
INSN(csrs, csrrs);
INSN(csrc, csrrc);
#undef INSN
#define INSN(NAME, OPFUN) \
void MacroAssembler::NAME(unsigned csr, unsigned imm) { \
OPFUN(x0, csr, imm); \
}
INSN(csrwi, csrrwi);
INSN(csrsi, csrrsi);
INSN(csrci, csrrci);
#undef INSN
#define INSN(NAME, CSR) \
void MacroAssembler::NAME(Register Rd, Register Rs) { \
csrrw(Rd, CSR, Rs); \
}
INSN(fscsr, CSR_FCSR);
INSN(fsrm, CSR_FRM);
INSN(fsflags, CSR_FFLAGS);
#undef INSN
#define INSN(NAME) \
void MacroAssembler::NAME(Register Rs) { \
NAME(x0, Rs); \
}
INSN(fscsr);
INSN(fsrm);
INSN(fsflags);
#undef INSN
void MacroAssembler::fsrmi(Register Rd, unsigned imm) {
guarantee(imm < 5, "Rounding Mode is invalid in Rounding Mode register");
csrrwi(Rd, CSR_FRM, imm);
}
void MacroAssembler::fsflagsi(Register Rd, unsigned imm) {
csrrwi(Rd, CSR_FFLAGS, imm);
}
#define INSN(NAME) \
void MacroAssembler::NAME(unsigned imm) { \
NAME(x0, imm); \
}
INSN(fsrmi);
INSN(fsflagsi);
#undef INSN
void MacroAssembler::push_reg(Register Rs)
{
addi(esp, esp, 0 - wordSize);
sd(Rs, Address(esp, 0));
}
void MacroAssembler::pop_reg(Register Rd)
{
ld(Rd, Address(esp, 0));
addi(esp, esp, wordSize);
}
int MacroAssembler::bitset_to_regs(unsigned int bitset, unsigned char* regs) {
int count = 0;
// Scan bitset to accumulate register pairs
for (int reg = 31; reg >= 0; reg--) {
if ((1U << 31) & bitset) {
regs[count++] = reg;
}
bitset <<= 1;
}
return count;
}
// Push integer registers in the bitset supplied. Don't push sp.
// Return the number of words pushed
int MacroAssembler::push_reg(unsigned int bitset, Register stack) {
DEBUG_ONLY(int words_pushed = 0;)
unsigned char regs[32];
int count = bitset_to_regs(bitset, regs);
// reserve one slot to align for odd count
int offset = is_even(count) ? 0 : wordSize;
if (count) {
addi(stack, stack, -count * wordSize - offset);
}
for (int i = count - 1; i >= 0; i--) {
sd(as_Register(regs[i]), Address(stack, (count - 1 - i) * wordSize + offset));
DEBUG_ONLY(words_pushed++;)
}
assert(words_pushed == count, "oops, pushed != count");
return count;
}
int MacroAssembler::pop_reg(unsigned int bitset, Register stack) {
DEBUG_ONLY(int words_popped = 0;)
unsigned char regs[32];
int count = bitset_to_regs(bitset, regs);
// reserve one slot to align for odd count
int offset = is_even(count) ? 0 : wordSize;
for (int i = count - 1; i >= 0; i--) {
ld(as_Register(regs[i]), Address(stack, (count - 1 - i) * wordSize + offset));
DEBUG_ONLY(words_popped++;)
}
if (count) {
addi(stack, stack, count * wordSize + offset);
}
assert(words_popped == count, "oops, popped != count");
return count;
}
// Push floating-point registers in the bitset supplied.
// Return the number of words pushed
int MacroAssembler::push_fp(unsigned int bitset, Register stack) {
DEBUG_ONLY(int words_pushed = 0;)
unsigned char regs[32];
int count = bitset_to_regs(bitset, regs);
int push_slots = count + (count & 1);
if (count) {
addi(stack, stack, -push_slots * wordSize);
}
for (int i = count - 1; i >= 0; i--) {
fsd(as_FloatRegister(regs[i]), Address(stack, (push_slots - 1 - i) * wordSize));
DEBUG_ONLY(words_pushed++;)
}
assert(words_pushed == count, "oops, pushed(%d) != count(%d)", words_pushed, count);
return count;
}
int MacroAssembler::pop_fp(unsigned int bitset, Register stack) {
DEBUG_ONLY(int words_popped = 0;)
unsigned char regs[32];
int count = bitset_to_regs(bitset, regs);
int pop_slots = count + (count & 1);
for (int i = count - 1; i >= 0; i--) {
fld(as_FloatRegister(regs[i]), Address(stack, (pop_slots - 1 - i) * wordSize));
DEBUG_ONLY(words_popped++;)
}
if (count) {
addi(stack, stack, pop_slots * wordSize);
}
assert(words_popped == count, "oops, popped(%d) != count(%d)", words_popped, count);
return count;
}
#ifdef COMPILER2
// Push vector registers in the bitset supplied.
// Return the number of words pushed
int MacroAssembler::push_v(unsigned int bitset, Register stack) {
int vector_size_in_bytes = Matcher::scalable_vector_reg_size(T_BYTE);
// Scan bitset to accumulate register pairs
unsigned char regs[32];
int count = bitset_to_regs(bitset, regs);
for (int i = 0; i < count; i++) {
sub(stack, stack, vector_size_in_bytes);
vs1r_v(as_VectorRegister(regs[i]), stack);
}
return count * vector_size_in_bytes / wordSize;
}
int MacroAssembler::pop_v(unsigned int bitset, Register stack) {
int vector_size_in_bytes = Matcher::scalable_vector_reg_size(T_BYTE);
// Scan bitset to accumulate register pairs
unsigned char regs[32];
int count = bitset_to_regs(bitset, regs);
for (int i = count - 1; i >= 0; i--) {
vl1re8_v(as_VectorRegister(regs[i]), stack);
add(stack, stack, vector_size_in_bytes);
}
return count * vector_size_in_bytes / wordSize;
}
#endif // COMPILER2
void MacroAssembler::push_call_clobbered_registers_except(RegSet exclude) {
// Push integer registers x7, x10-x17, x28-x31.
push_reg(RegSet::of(x7) + RegSet::range(x10, x17) + RegSet::range(x28, x31) - exclude, sp);
// Push float registers f0-f7, f10-f17, f28-f31.
addi(sp, sp, - wordSize * 20);
int offset = 0;
for (int i = 0; i < 32; i++) {
if (i <= f7->encoding() || i >= f28->encoding() || (i >= f10->encoding() && i <= f17->encoding())) {
fsd(as_FloatRegister(i), Address(sp, wordSize * (offset++)));
}
}
}
void MacroAssembler::pop_call_clobbered_registers_except(RegSet exclude) {
int offset = 0;
for (int i = 0; i < 32; i++) {
if (i <= f7->encoding() || i >= f28->encoding() || (i >= f10->encoding() && i <= f17->encoding())) {
fld(as_FloatRegister(i), Address(sp, wordSize * (offset++)));
}
}
addi(sp, sp, wordSize * 20);
pop_reg(RegSet::of(x7) + RegSet::range(x10, x17) + RegSet::range(x28, x31) - exclude, sp);
}
void MacroAssembler::push_CPU_state(bool save_vectors, int vector_size_in_bytes) {
// integer registers, except zr(x0) & ra(x1) & sp(x2) & gp(x3) & tp(x4)
push_reg(RegSet::range(x5, x31), sp);
// float registers
addi(sp, sp, - 32 * wordSize);
for (int i = 0; i < 32; i++) {
fsd(as_FloatRegister(i), Address(sp, i * wordSize));
}
// vector registers
if (save_vectors) {
sub(sp, sp, vector_size_in_bytes * VectorRegister::number_of_registers);
vsetvli(t0, x0, Assembler::e64, Assembler::m8);
for (int i = 0; i < VectorRegister::number_of_registers; i += 8) {
add(t0, sp, vector_size_in_bytes * i);
vse64_v(as_VectorRegister(i), t0);
}
}
}
void MacroAssembler::pop_CPU_state(bool restore_vectors, int vector_size_in_bytes) {
// vector registers
if (restore_vectors) {
vsetvli(t0, x0, Assembler::e64, Assembler::m8);
for (int i = 0; i < VectorRegister::number_of_registers; i += 8) {
vle64_v(as_VectorRegister(i), sp);
add(sp, sp, vector_size_in_bytes * 8);
}
}
// float registers
for (int i = 0; i < 32; i++) {
fld(as_FloatRegister(i), Address(sp, i * wordSize));
}
addi(sp, sp, 32 * wordSize);
// integer registers, except zr(x0) & ra(x1) & sp(x2) & gp(x3) & tp(x4)
pop_reg(RegSet::range(x5, x31), sp);
}
static int patch_offset_in_jal(address branch, int64_t offset) {
assert(is_imm_in_range(offset, 20, 1), "offset is too large to be patched in one jal insrusction!\n");
Assembler::patch(branch, 31, 31, (offset >> 20) & 0x1); // offset[20] ==> branch[31]
Assembler::patch(branch, 30, 21, (offset >> 1) & 0x3ff); // offset[10:1] ==> branch[30:21]
Assembler::patch(branch, 20, 20, (offset >> 11) & 0x1); // offset[11] ==> branch[20]
Assembler::patch(branch, 19, 12, (offset >> 12) & 0xff); // offset[19:12] ==> branch[19:12]
return NativeInstruction::instruction_size; // only one instruction
}
static int patch_offset_in_conditional_branch(address branch, int64_t offset) {
assert(is_imm_in_range(offset, 12, 1), "offset is too large to be patched in one beq/bge/bgeu/blt/bltu/bne insrusction!\n");
Assembler::patch(branch, 31, 31, (offset >> 12) & 0x1); // offset[12] ==> branch[31]
Assembler::patch(branch, 30, 25, (offset >> 5) & 0x3f); // offset[10:5] ==> branch[30:25]
Assembler::patch(branch, 7, 7, (offset >> 11) & 0x1); // offset[11] ==> branch[7]
Assembler::patch(branch, 11, 8, (offset >> 1) & 0xf); // offset[4:1] ==> branch[11:8]
return NativeInstruction::instruction_size; // only one instruction
}
static int patch_offset_in_pc_relative(address branch, int64_t offset) {
const int PC_RELATIVE_INSTRUCTION_NUM = 2; // auipc, addi/jalr/load
Assembler::patch(branch, 31, 12, ((offset + 0x800) >> 12) & 0xfffff); // Auipc. offset[31:12] ==> branch[31:12]
Assembler::patch(branch + 4, 31, 20, offset & 0xfff); // Addi/Jalr/Load. offset[11:0] ==> branch[31:20]
return PC_RELATIVE_INSTRUCTION_NUM * NativeInstruction::instruction_size;
}
static int patch_addr_in_movptr(address branch, address target) {
const int MOVPTR_INSTRUCTIONS_NUM = 6; // lui + addi + slli + addi + slli + addi/jalr/load
int32_t lower = ((intptr_t)target << 35) >> 35;
int64_t upper = ((intptr_t)target - lower) >> 29;
Assembler::patch(branch + 0, 31, 12, upper & 0xfffff); // Lui. target[48:29] + target[28] ==> branch[31:12]
Assembler::patch(branch + 4, 31, 20, (lower >> 17) & 0xfff); // Addi. target[28:17] ==> branch[31:20]
Assembler::patch(branch + 12, 31, 20, (lower >> 6) & 0x7ff); // Addi. target[16: 6] ==> branch[31:20]
Assembler::patch(branch + 20, 31, 20, lower & 0x3f); // Addi/Jalr/Load. target[ 5: 0] ==> branch[31:20]
return MOVPTR_INSTRUCTIONS_NUM * NativeInstruction::instruction_size;
}
static int patch_imm_in_li64(address branch, address target) {
const int LI64_INSTRUCTIONS_NUM = 8; // lui + addi + slli + addi + slli + addi + slli + addi
int64_t lower = (intptr_t)target & 0xffffffff;
lower = lower - ((lower << 44) >> 44);
int64_t tmp_imm = ((uint64_t)((intptr_t)target & 0xffffffff00000000)) + (uint64_t)lower;
int32_t upper = (tmp_imm - (int32_t)lower) >> 32;
int64_t tmp_upper = upper, tmp_lower = upper;
tmp_lower = (tmp_lower << 52) >> 52;
tmp_upper -= tmp_lower;
tmp_upper >>= 12;
// Load upper 32 bits. Upper = target[63:32], but if target[31] = 1 or (target[31:20] == 0x7ff && target[19] == 1),
// upper = target[63:32] + 1.
Assembler::patch(branch + 0, 31, 12, tmp_upper & 0xfffff); // Lui.
Assembler::patch(branch + 4, 31, 20, tmp_lower & 0xfff); // Addi.
// Load the rest 32 bits.
Assembler::patch(branch + 12, 31, 20, ((int32_t)lower >> 20) & 0xfff); // Addi.
Assembler::patch(branch + 20, 31, 20, (((intptr_t)target << 44) >> 52) & 0xfff); // Addi.
Assembler::patch(branch + 28, 31, 20, (intptr_t)target & 0xff); // Addi.
return LI64_INSTRUCTIONS_NUM * NativeInstruction::instruction_size;
}
int MacroAssembler::patch_imm_in_li32(address branch, int32_t target) {
const int LI32_INSTRUCTIONS_NUM = 2; // lui + addiw
int64_t upper = (intptr_t)target;
int32_t lower = (((int32_t)target) << 20) >> 20;
upper -= lower;
upper = (int32_t)upper;
Assembler::patch(branch + 0, 31, 12, (upper >> 12) & 0xfffff); // Lui.
Assembler::patch(branch + 4, 31, 20, lower & 0xfff); // Addiw.
return LI32_INSTRUCTIONS_NUM * NativeInstruction::instruction_size;
}
static long get_offset_of_jal(address insn_addr) {
assert_cond(insn_addr != NULL);
long offset = 0;
unsigned insn = *(unsigned*)insn_addr;
long val = (long)Assembler::sextract(insn, 31, 12);
offset |= ((val >> 19) & 0x1) << 20;
offset |= (val & 0xff) << 12;
offset |= ((val >> 8) & 0x1) << 11;
offset |= ((val >> 9) & 0x3ff) << 1;
offset = (offset << 43) >> 43;
return offset;
}
static long get_offset_of_conditional_branch(address insn_addr) {
long offset = 0;
assert_cond(insn_addr != NULL);
unsigned insn = *(unsigned*)insn_addr;
offset = (long)Assembler::sextract(insn, 31, 31);
offset = (offset << 12) | (((long)(Assembler::sextract(insn, 7, 7) & 0x1)) << 11);
offset = offset | (((long)(Assembler::sextract(insn, 30, 25) & 0x3f)) << 5);
offset = offset | (((long)(Assembler::sextract(insn, 11, 8) & 0xf)) << 1);
offset = (offset << 41) >> 41;
return offset;
}
static long get_offset_of_pc_relative(address insn_addr) {
long offset = 0;
assert_cond(insn_addr != NULL);
offset = ((long)(Assembler::sextract(((unsigned*)insn_addr)[0], 31, 12))) << 12; // Auipc.
offset += ((long)Assembler::sextract(((unsigned*)insn_addr)[1], 31, 20)); // Addi/Jalr/Load.
offset = (offset << 32) >> 32;
return offset;
}
static address get_target_of_movptr(address insn_addr) {
assert_cond(insn_addr != NULL);
intptr_t target_address = (((int64_t)Assembler::sextract(((unsigned*)insn_addr)[0], 31, 12)) & 0xfffff) << 29; // Lui.
target_address += ((int64_t)Assembler::sextract(((unsigned*)insn_addr)[1], 31, 20)) << 17; // Addi.
target_address += ((int64_t)Assembler::sextract(((unsigned*)insn_addr)[3], 31, 20)) << 6; // Addi.
target_address += ((int64_t)Assembler::sextract(((unsigned*)insn_addr)[5], 31, 20)); // Addi/Jalr/Load.
return (address) target_address;
}
static address get_target_of_li64(address insn_addr) {
assert_cond(insn_addr != NULL);
intptr_t target_address = (((int64_t)Assembler::sextract(((unsigned*)insn_addr)[0], 31, 12)) & 0xfffff) << 44; // Lui.
target_address += ((int64_t)Assembler::sextract(((unsigned*)insn_addr)[1], 31, 20)) << 32; // Addi.
target_address += ((int64_t)Assembler::sextract(((unsigned*)insn_addr)[3], 31, 20)) << 20; // Addi.
target_address += ((int64_t)Assembler::sextract(((unsigned*)insn_addr)[5], 31, 20)) << 8; // Addi.
target_address += ((int64_t)Assembler::sextract(((unsigned*)insn_addr)[7], 31, 20)); // Addi.
return (address)target_address;
}
address MacroAssembler::get_target_of_li32(address insn_addr) {
assert_cond(insn_addr != NULL);
intptr_t target_address = (((int64_t)Assembler::sextract(((unsigned*)insn_addr)[0], 31, 12)) & 0xfffff) << 12; // Lui.
target_address += ((int64_t)Assembler::sextract(((unsigned*)insn_addr)[1], 31, 20)); // Addiw.
return (address)target_address;
}
// Patch any kind of instruction; there may be several instructions.
// Return the total length (in bytes) of the instructions.
int MacroAssembler::pd_patch_instruction_size(address branch, address target) {
assert_cond(branch != NULL);
int64_t offset = target - branch;
if (NativeInstruction::is_jal_at(branch)) { // jal
return patch_offset_in_jal(branch, offset);
} else if (NativeInstruction::is_branch_at(branch)) { // beq/bge/bgeu/blt/bltu/bne
return patch_offset_in_conditional_branch(branch, offset);
} else if (NativeInstruction::is_pc_relative_at(branch)) { // auipc, addi/jalr/load
return patch_offset_in_pc_relative(branch, offset);
} else if (NativeInstruction::is_movptr_at(branch)) { // movptr
return patch_addr_in_movptr(branch, target);
} else if (NativeInstruction::is_li64_at(branch)) { // li64
return patch_imm_in_li64(branch, target);
} else if (NativeInstruction::is_li32_at(branch)) { // li32
int64_t imm = (intptr_t)target;
return patch_imm_in_li32(branch, (int32_t)imm);
} else {
#ifdef ASSERT
tty->print_cr("pd_patch_instruction_size: instruction 0x%x at " INTPTR_FORMAT " could not be patched!\n",
*(unsigned*)branch, p2i(branch));
Disassembler::decode(branch - 16, branch + 16);
#endif
ShouldNotReachHere();
return -1;
}
}
address MacroAssembler::target_addr_for_insn(address insn_addr) {
long offset = 0;
assert_cond(insn_addr != NULL);
if (NativeInstruction::is_jal_at(insn_addr)) { // jal
offset = get_offset_of_jal(insn_addr);
} else if (NativeInstruction::is_branch_at(insn_addr)) { // beq/bge/bgeu/blt/bltu/bne
offset = get_offset_of_conditional_branch(insn_addr);
} else if (NativeInstruction::is_pc_relative_at(insn_addr)) { // auipc, addi/jalr/load
offset = get_offset_of_pc_relative(insn_addr);
} else if (NativeInstruction::is_movptr_at(insn_addr)) { // movptr
return get_target_of_movptr(insn_addr);
} else if (NativeInstruction::is_li64_at(insn_addr)) { // li64
return get_target_of_li64(insn_addr);
} else if (NativeInstruction::is_li32_at(insn_addr)) { // li32
return get_target_of_li32(insn_addr);
} else {
ShouldNotReachHere();
}
return address(((uintptr_t)insn_addr + offset));
}
int MacroAssembler::patch_oop(address insn_addr, address o) {
// OOPs are either narrow (32 bits) or wide (48 bits). We encode
// narrow OOPs by setting the upper 16 bits in the first
// instruction.
if (NativeInstruction::is_li32_at(insn_addr)) {
// Move narrow OOP
uint32_t n = CompressedOops::narrow_oop_value(cast_to_oop(o));
return patch_imm_in_li32(insn_addr, (int32_t)n);
} else if (NativeInstruction::is_movptr_at(insn_addr)) {
// Move wide OOP
return patch_addr_in_movptr(insn_addr, o);
}
ShouldNotReachHere();
return -1;
}
void MacroAssembler::reinit_heapbase() {
if (UseCompressedOops) {
if (Universe::is_fully_initialized()) {
mv(xheapbase, CompressedOops::ptrs_base());
} else {
ExternalAddress target(CompressedOops::ptrs_base_addr());
relocate(target.rspec(), [&] {
int32_t offset;
la_patchable(xheapbase, target, offset);
ld(xheapbase, Address(xheapbase, offset));
});
}
}
}
void MacroAssembler::movptr(Register Rd, address addr, int32_t &offset) {
int64_t imm64 = (int64_t)addr;
#ifndef PRODUCT
{
char buffer[64];
snprintf(buffer, sizeof(buffer), "0x%" PRIx64, imm64);
block_comment(buffer);
}
#endif
assert(is_unsigned_imm_in_range(imm64, 47, 0) || (imm64 == (int64_t)-1),
"bit 47 overflows in address constant");
// Load upper 31 bits
int64_t imm = imm64 >> 17;
int64_t upper = imm, lower = imm;
lower = (lower << 52) >> 52;
upper -= lower;
upper = (int32_t)upper;
lui(Rd, upper);
addi(Rd, Rd, lower);
// Load the rest 17 bits.
slli(Rd, Rd, 11);
addi(Rd, Rd, (imm64 >> 6) & 0x7ff);
slli(Rd, Rd, 6);
// This offset will be used by following jalr/ld.
offset = imm64 & 0x3f;
}
void MacroAssembler::add(Register Rd, Register Rn, int64_t increment, Register temp) {
if (is_imm_in_range(increment, 12, 0)) {
addi(Rd, Rn, increment);
} else {
assert_different_registers(Rn, temp);
li(temp, increment);
add(Rd, Rn, temp);
}
}
void MacroAssembler::addw(Register Rd, Register Rn, int32_t increment, Register temp) {
if (is_imm_in_range(increment, 12, 0)) {
addiw(Rd, Rn, increment);
} else {
assert_different_registers(Rn, temp);
li(temp, increment);
addw(Rd, Rn, temp);
}
}
void MacroAssembler::sub(Register Rd, Register Rn, int64_t decrement, Register temp) {
if (is_imm_in_range(-decrement, 12, 0)) {
addi(Rd, Rn, -decrement);
} else {
assert_different_registers(Rn, temp);
li(temp, decrement);
sub(Rd, Rn, temp);
}
}
void MacroAssembler::subw(Register Rd, Register Rn, int32_t decrement, Register temp) {
if (is_imm_in_range(-decrement, 12, 0)) {
addiw(Rd, Rn, -decrement);
} else {
assert_different_registers(Rn, temp);
li(temp, decrement);
subw(Rd, Rn, temp);
}
}
void MacroAssembler::andrw(Register Rd, Register Rs1, Register Rs2) {
andr(Rd, Rs1, Rs2);
// addw: The result is clipped to 32 bits, then the sign bit is extended,
// and the result is stored in Rd
addw(Rd, Rd, zr);
}
void MacroAssembler::orrw(Register Rd, Register Rs1, Register Rs2) {
orr(Rd, Rs1, Rs2);
// addw: The result is clipped to 32 bits, then the sign bit is extended,
// and the result is stored in Rd
addw(Rd, Rd, zr);
}
void MacroAssembler::xorrw(Register Rd, Register Rs1, Register Rs2) {
xorr(Rd, Rs1, Rs2);
// addw: The result is clipped to 32 bits, then the sign bit is extended,
// and the result is stored in Rd
addw(Rd, Rd, zr);
}
// Note: load_unsigned_short used to be called load_unsigned_word.
int MacroAssembler::load_unsigned_short(Register dst, Address src) {
int off = offset();
lhu(dst, src);
return off;
}
int MacroAssembler::load_unsigned_byte(Register dst, Address src) {
int off = offset();
lbu(dst, src);
return off;
}
int MacroAssembler::load_signed_short(Register dst, Address src) {
int off = offset();
lh(dst, src);
return off;
}
int MacroAssembler::load_signed_byte(Register dst, Address src) {
int off = offset();
lb(dst, src);
return off;
}
void MacroAssembler::load_sized_value(Register dst, Address src, size_t size_in_bytes, bool is_signed) {
switch (size_in_bytes) {
case 8: ld(dst, src); break;
case 4: is_signed ? lw(dst, src) : lwu(dst, src); break;
case 2: is_signed ? load_signed_short(dst, src) : load_unsigned_short(dst, src); break;
case 1: is_signed ? load_signed_byte( dst, src) : load_unsigned_byte( dst, src); break;
default: ShouldNotReachHere();
}
}
void MacroAssembler::store_sized_value(Address dst, Register src, size_t size_in_bytes) {
switch (size_in_bytes) {
case 8: sd(src, dst); break;
case 4: sw(src, dst); break;
case 2: sh(src, dst); break;
case 1: sb(src, dst); break;
default: ShouldNotReachHere();
}
}
// reverse bytes in halfword in lower 16 bits and sign-extend
// Rd[15:0] = Rs[7:0] Rs[15:8] (sign-extend to 64 bits)
void MacroAssembler::revb_h_h(Register Rd, Register Rs, Register tmp) {
if (UseZbb) {
rev8(Rd, Rs);
srai(Rd, Rd, 48);
return;
}
assert_different_registers(Rs, tmp);
assert_different_registers(Rd, tmp);
srli(tmp, Rs, 8);
andi(tmp, tmp, 0xFF);
slli(Rd, Rs, 56);
srai(Rd, Rd, 48); // sign-extend
orr(Rd, Rd, tmp);
}
// reverse bytes in lower word and sign-extend
// Rd[31:0] = Rs[7:0] Rs[15:8] Rs[23:16] Rs[31:24] (sign-extend to 64 bits)
void MacroAssembler::revb_w_w(Register Rd, Register Rs, Register tmp1, Register tmp2) {
if (UseZbb) {
rev8(Rd, Rs);
srai(Rd, Rd, 32);
return;
}
assert_different_registers(Rs, tmp1, tmp2);
assert_different_registers(Rd, tmp1, tmp2);
revb_h_w_u(Rd, Rs, tmp1, tmp2);
slli(tmp2, Rd, 48);
srai(tmp2, tmp2, 32); // sign-extend
srli(Rd, Rd, 16);
orr(Rd, Rd, tmp2);
}
// reverse bytes in halfword in lower 16 bits and zero-extend
// Rd[15:0] = Rs[7:0] Rs[15:8] (zero-extend to 64 bits)
void MacroAssembler::revb_h_h_u(Register Rd, Register Rs, Register tmp) {
if (UseZbb) {
rev8(Rd, Rs);
srli(Rd, Rd, 48);
return;
}
assert_different_registers(Rs, tmp);
assert_different_registers(Rd, tmp);
srli(tmp, Rs, 8);
andi(tmp, tmp, 0xFF);
andi(Rd, Rs, 0xFF);
slli(Rd, Rd, 8);
orr(Rd, Rd, tmp);
}
// reverse bytes in halfwords in lower 32 bits and zero-extend
// Rd[31:0] = Rs[23:16] Rs[31:24] Rs[7:0] Rs[15:8] (zero-extend to 64 bits)
void MacroAssembler::revb_h_w_u(Register Rd, Register Rs, Register tmp1, Register tmp2) {
if (UseZbb) {
rev8(Rd, Rs);
rori(Rd, Rd, 32);
roriw(Rd, Rd, 16);
zero_extend(Rd, Rd, 32);
return;
}
assert_different_registers(Rs, tmp1, tmp2);
assert_different_registers(Rd, tmp1, tmp2);
srli(tmp2, Rs, 16);
revb_h_h_u(tmp2, tmp2, tmp1);
revb_h_h_u(Rd, Rs, tmp1);
slli(tmp2, tmp2, 16);
orr(Rd, Rd, tmp2);
}
// This method is only used for revb_h
// Rd = Rs[47:0] Rs[55:48] Rs[63:56]
void MacroAssembler::revb_h_helper(Register Rd, Register Rs, Register tmp1, Register tmp2) {
assert_different_registers(Rs, tmp1, tmp2);
assert_different_registers(Rd, tmp1);
srli(tmp1, Rs, 48);
andi(tmp2, tmp1, 0xFF);
slli(tmp2, tmp2, 8);
srli(tmp1, tmp1, 8);
orr(tmp1, tmp1, tmp2);
slli(Rd, Rs, 16);
orr(Rd, Rd, tmp1);
}
// reverse bytes in each halfword
// Rd[63:0] = Rs[55:48] Rs[63:56] Rs[39:32] Rs[47:40] Rs[23:16] Rs[31:24] Rs[7:0] Rs[15:8]
void MacroAssembler::revb_h(Register Rd, Register Rs, Register tmp1, Register tmp2) {
if (UseZbb) {
assert_different_registers(Rs, tmp1);
assert_different_registers(Rd, tmp1);
rev8(Rd, Rs);
zero_extend(tmp1, Rd, 32);
roriw(tmp1, tmp1, 16);
slli(tmp1, tmp1, 32);
srli(Rd, Rd, 32);
roriw(Rd, Rd, 16);
zero_extend(Rd, Rd, 32);
orr(Rd, Rd, tmp1);
return;
}
assert_different_registers(Rs, tmp1, tmp2);
assert_different_registers(Rd, tmp1, tmp2);
revb_h_helper(Rd, Rs, tmp1, tmp2);
for (int i = 0; i < 3; ++i) {
revb_h_helper(Rd, Rd, tmp1, tmp2);
}
}
// reverse bytes in each word
// Rd[63:0] = Rs[39:32] Rs[47:40] Rs[55:48] Rs[63:56] Rs[7:0] Rs[15:8] Rs[23:16] Rs[31:24]
void MacroAssembler::revb_w(Register Rd, Register Rs, Register tmp1, Register tmp2) {
if (UseZbb) {
rev8(Rd, Rs);
rori(Rd, Rd, 32);
return;
}
assert_different_registers(Rs, tmp1, tmp2);
assert_different_registers(Rd, tmp1, tmp2);
revb(Rd, Rs, tmp1, tmp2);
ror_imm(Rd, Rd, 32);
}
// reverse bytes in doubleword
// Rd[63:0] = Rs[7:0] Rs[15:8] Rs[23:16] Rs[31:24] Rs[39:32] Rs[47,40] Rs[55,48] Rs[63:56]
void MacroAssembler::revb(Register Rd, Register Rs, Register tmp1, Register tmp2) {
if (UseZbb) {
rev8(Rd, Rs);
return;
}
assert_different_registers(Rs, tmp1, tmp2);
assert_different_registers(Rd, tmp1, tmp2);
andi(tmp1, Rs, 0xFF);
slli(tmp1, tmp1, 8);
for (int step = 8; step < 56; step += 8) {
srli(tmp2, Rs, step);
andi(tmp2, tmp2, 0xFF);
orr(tmp1, tmp1, tmp2);
slli(tmp1, tmp1, 8);
}
srli(Rd, Rs, 56);
andi(Rd, Rd, 0xFF);
orr(Rd, tmp1, Rd);
}
// rotate right with shift bits
void MacroAssembler::ror_imm(Register dst, Register src, uint32_t shift, Register tmp)
{
if (UseZbb) {
rori(dst, src, shift);
return;
}
assert_different_registers(dst, tmp);
assert_different_registers(src, tmp);
assert(shift < 64, "shift amount must be < 64");
slli(tmp, src, 64 - shift);
srli(dst, src, shift);
orr(dst, dst, tmp);
}
void MacroAssembler::andi(Register Rd, Register Rn, int64_t imm, Register tmp) {
if (is_imm_in_range(imm, 12, 0)) {
and_imm12(Rd, Rn, imm);
} else {
assert_different_registers(Rn, tmp);
mv(tmp, imm);
andr(Rd, Rn, tmp);
}
}
void MacroAssembler::orptr(Address adr, RegisterOrConstant src, Register tmp1, Register tmp2) {
ld(tmp1, adr);
if (src.is_register()) {
orr(tmp1, tmp1, src.as_register());
} else {
if (is_imm_in_range(src.as_constant(), 12, 0)) {
ori(tmp1, tmp1, src.as_constant());
} else {
assert_different_registers(tmp1, tmp2);
mv(tmp2, src.as_constant());
orr(tmp1, tmp1, tmp2);
}
}
sd(tmp1, adr);
}
void MacroAssembler::cmp_klass(Register oop, Register trial_klass, Register tmp1, Register tmp2, Label &L) {
assert_different_registers(oop, trial_klass, tmp1, tmp2);
if (UseCompressedClassPointers) {
lwu(tmp1, Address(oop, oopDesc::klass_offset_in_bytes()));
if (CompressedKlassPointers::base() == NULL) {
slli(tmp1, tmp1, CompressedKlassPointers::shift());
beq(trial_klass, tmp1, L);
return;
}
decode_klass_not_null(tmp1, tmp2);
} else {
ld(tmp1, Address(oop, oopDesc::klass_offset_in_bytes()));
}
beq(trial_klass, tmp1, L);
}
// Move an oop into a register.
void MacroAssembler::movoop(Register dst, jobject obj) {
int oop_index;
if (obj == NULL) {
oop_index = oop_recorder()->allocate_oop_index(obj);
} else {
#ifdef ASSERT
{
ThreadInVMfromUnknown tiv;
assert(Universe::heap()->is_in(JNIHandles::resolve(obj)), "should be real oop");
}
#endif
oop_index = oop_recorder()->find_index(obj);
}
RelocationHolder rspec = oop_Relocation::spec(oop_index);
if (BarrierSet::barrier_set()->barrier_set_assembler()->supports_instruction_patching()) {
mv(dst, Address((address)obj, rspec));
} else {
address dummy = address(uintptr_t(pc()) & -wordSize); // A nearby aligned address
ld_constant(dst, Address(dummy, rspec));
}
}
// Move a metadata address into a register.
void MacroAssembler::mov_metadata(Register dst, Metadata* obj) {
int oop_index;
if (obj == NULL) {
oop_index = oop_recorder()->allocate_metadata_index(obj);
} else {
oop_index = oop_recorder()->find_index(obj);
}
RelocationHolder rspec = metadata_Relocation::spec(oop_index);
mv(dst, Address((address)obj, rspec));
}
// Writes to stack successive pages until offset reached to check for
// stack overflow + shadow pages. This clobbers tmp.
void MacroAssembler::bang_stack_size(Register size, Register tmp) {
assert_different_registers(tmp, size, t0);
// Bang stack for total size given plus shadow page size.
// Bang one page at a time because large size can bang beyond yellow and
// red zones.
mv(t0, os::vm_page_size());
Label loop;
bind(loop);
sub(tmp, sp, t0);
subw(size, size, t0);
sd(size, Address(tmp));
bgtz(size, loop);
// Bang down shadow pages too.
// At this point, (tmp-0) is the last address touched, so don't
// touch it again. (It was touched as (tmp-pagesize) but then tmp
// was post-decremented.) Skip this address by starting at i=1, and
// touch a few more pages below. N.B. It is important to touch all
// the way down to and including i=StackShadowPages.
for (int i = 0; i < (int)(StackOverflow::stack_shadow_zone_size() / os::vm_page_size()) - 1; i++) {
// this could be any sized move but this is can be a debugging crumb
// so the bigger the better.
sub(tmp, tmp, os::vm_page_size());
sd(size, Address(tmp, 0));
}
}
SkipIfEqual::SkipIfEqual(MacroAssembler* masm, const bool* flag_addr, bool value) {
int32_t offset = 0;
_masm = masm;
ExternalAddress target((address)flag_addr);
_masm->relocate(target.rspec(), [&] {
int32_t offset;
_masm->la_patchable(t0, target, offset);
_masm->lbu(t0, Address(t0, offset));
});
if (value) {
_masm->bnez(t0, _label);
} else {
_masm->beqz(t0, _label);
}
}
SkipIfEqual::~SkipIfEqual() {
_masm->bind(_label);
_masm = NULL;
}
void MacroAssembler::load_mirror(Register dst, Register method, Register tmp1, Register tmp2) {
const int mirror_offset = in_bytes(Klass::java_mirror_offset());
ld(dst, Address(xmethod, Method::const_offset()));
ld(dst, Address(dst, ConstMethod::constants_offset()));
ld(dst, Address(dst, ConstantPool::pool_holder_offset_in_bytes()));
ld(dst, Address(dst, mirror_offset));
resolve_oop_handle(dst, tmp1, tmp2);
}
void MacroAssembler::resolve_oop_handle(Register result, Register tmp1, Register tmp2) {
// OopHandle::resolve is an indirection.
assert_different_registers(result, tmp1, tmp2);
access_load_at(T_OBJECT, IN_NATIVE, result, Address(result, 0), tmp1, tmp2);
}
// ((WeakHandle)result).resolve()
void MacroAssembler::resolve_weak_handle(Register result, Register tmp1, Register tmp2) {
assert_different_registers(result, tmp1, tmp2);
Label resolved;
// A null weak handle resolves to null.
beqz(result, resolved);
// Only 64 bit platforms support GCs that require a tmp register
// Only IN_HEAP loads require a thread_tmp register
// WeakHandle::resolve is an indirection like jweak.
access_load_at(T_OBJECT, IN_NATIVE | ON_PHANTOM_OOP_REF,
result, Address(result), tmp1, tmp2);
bind(resolved);
}
void MacroAssembler::access_load_at(BasicType type, DecoratorSet decorators,
Register dst, Address src,
Register tmp1, Register tmp2) {
BarrierSetAssembler *bs = BarrierSet::barrier_set()->barrier_set_assembler();
decorators = AccessInternal::decorator_fixup(decorators, type);
bool as_raw = (decorators & AS_RAW) != 0;
if (as_raw) {
bs->BarrierSetAssembler::load_at(this, decorators, type, dst, src, tmp1, tmp2);
} else {
bs->load_at(this, decorators, type, dst, src, tmp1, tmp2);
}
}
void MacroAssembler::null_check(Register reg, int offset) {
if (needs_explicit_null_check(offset)) {
// provoke OS NULL exception if reg = NULL by
// accessing M[reg] w/o changing any registers
// NOTE: this is plenty to provoke a segv
ld(zr, Address(reg, 0));
} else {
// nothing to do, (later) access of M[reg + offset]
// will provoke OS NULL exception if reg = NULL
}
}
void MacroAssembler::access_store_at(BasicType type, DecoratorSet decorators,
Address dst, Register val,
Register tmp1, Register tmp2, Register tmp3) {
BarrierSetAssembler *bs = BarrierSet::barrier_set()->barrier_set_assembler();
decorators = AccessInternal::decorator_fixup(decorators, type);
bool as_raw = (decorators & AS_RAW) != 0;
if (as_raw) {
bs->BarrierSetAssembler::store_at(this, decorators, type, dst, val, tmp1, tmp2, tmp3);
} else {
bs->store_at(this, decorators, type, dst, val, tmp1, tmp2, tmp3);
}
}
// Algorithm must match CompressedOops::encode.
void MacroAssembler::encode_heap_oop(Register d, Register s) {
verify_oop_msg(s, "broken oop in encode_heap_oop");
if (CompressedOops::base() == NULL) {
if (CompressedOops::shift() != 0) {
assert (LogMinObjAlignmentInBytes == CompressedOops::shift(), "decode alg wrong");
srli(d, s, LogMinObjAlignmentInBytes);
} else {
mv(d, s);
}
} else {
Label notNull;
sub(d, s, xheapbase);
bgez(d, notNull);
mv(d, zr);
bind(notNull);
if (CompressedOops::shift() != 0) {
assert (LogMinObjAlignmentInBytes == CompressedOops::shift(), "decode alg wrong");
srli(d, d, CompressedOops::shift());
}
}
}
void MacroAssembler::load_klass(Register dst, Register src, Register tmp) {
assert_different_registers(dst, tmp);
assert_different_registers(src, tmp);
if (UseCompressedClassPointers) {
lwu(dst, Address(src, oopDesc::klass_offset_in_bytes()));
decode_klass_not_null(dst, tmp);
} else {
ld(dst, Address(src, oopDesc::klass_offset_in_bytes()));
}
}
void MacroAssembler::store_klass(Register dst, Register src, Register tmp) {
// FIXME: Should this be a store release? concurrent gcs assumes
// klass length is valid if klass field is not null.
if (UseCompressedClassPointers) {
encode_klass_not_null(src, tmp);
sw(src, Address(dst, oopDesc::klass_offset_in_bytes()));
} else {
sd(src, Address(dst, oopDesc::klass_offset_in_bytes()));
}
}
void MacroAssembler::store_klass_gap(Register dst, Register src) {
if (UseCompressedClassPointers) {
// Store to klass gap in destination
sw(src, Address(dst, oopDesc::klass_gap_offset_in_bytes()));
}
}
void MacroAssembler::decode_klass_not_null(Register r, Register tmp) {
assert_different_registers(r, tmp);
decode_klass_not_null(r, r, tmp);
}
void MacroAssembler::decode_klass_not_null(Register dst, Register src, Register tmp) {
assert(UseCompressedClassPointers, "should only be used for compressed headers");
if (CompressedKlassPointers::base() == NULL) {
if (CompressedKlassPointers::shift() != 0) {
assert(LogKlassAlignmentInBytes == CompressedKlassPointers::shift(), "decode alg wrong");
slli(dst, src, LogKlassAlignmentInBytes);
} else {
mv(dst, src);
}
return;
}
Register xbase = dst;
if (dst == src) {
xbase = tmp;
}
assert_different_registers(src, xbase);
mv(xbase, (uintptr_t)CompressedKlassPointers::base());
if (CompressedKlassPointers::shift() != 0) {
assert(LogKlassAlignmentInBytes == CompressedKlassPointers::shift(), "decode alg wrong");
assert_different_registers(t0, xbase);
shadd(dst, src, xbase, t0, LogKlassAlignmentInBytes);
} else {
add(dst, xbase, src);
}
}
void MacroAssembler::encode_klass_not_null(Register r, Register tmp) {
assert_different_registers(r, tmp);
encode_klass_not_null(r, r, tmp);
}
void MacroAssembler::encode_klass_not_null(Register dst, Register src, Register tmp) {
assert(UseCompressedClassPointers, "should only be used for compressed headers");
if (CompressedKlassPointers::base() == NULL) {
if (CompressedKlassPointers::shift() != 0) {
assert(LogKlassAlignmentInBytes == CompressedKlassPointers::shift(), "decode alg wrong");
srli(dst, src, LogKlassAlignmentInBytes);
} else {
mv(dst, src);
}
return;
}
if (((uint64_t)(uintptr_t)CompressedKlassPointers::base() & 0xffffffff) == 0 &&
CompressedKlassPointers::shift() == 0) {
zero_extend(dst, src, 32);
return;
}
Register xbase = dst;
if (dst == src) {
xbase = tmp;
}
assert_different_registers(src, xbase);
mv(xbase, (intptr_t)CompressedKlassPointers::base());
sub(dst, src, xbase);
if (CompressedKlassPointers::shift() != 0) {
assert(LogKlassAlignmentInBytes == CompressedKlassPointers::shift(), "decode alg wrong");
srli(dst, dst, LogKlassAlignmentInBytes);
}
}
void MacroAssembler::decode_heap_oop_not_null(Register r) {
decode_heap_oop_not_null(r, r);
}
void MacroAssembler::decode_heap_oop_not_null(Register dst, Register src) {
assert(UseCompressedOops, "should only be used for compressed headers");
assert(Universe::heap() != NULL, "java heap should be initialized");
// Cannot assert, unverified entry point counts instructions (see .ad file)
// vtableStubs also counts instructions in pd_code_size_limit.
// Also do not verify_oop as this is called by verify_oop.
if (CompressedOops::shift() != 0) {
assert(LogMinObjAlignmentInBytes == CompressedOops::shift(), "decode alg wrong");
slli(dst, src, LogMinObjAlignmentInBytes);
if (CompressedOops::base() != NULL) {
add(dst, xheapbase, dst);
}
} else {
assert(CompressedOops::base() == NULL, "sanity");
mv(dst, src);
}
}
void MacroAssembler::decode_heap_oop(Register d, Register s) {
if (CompressedOops::base() == NULL) {
if (CompressedOops::shift() != 0 || d != s) {
slli(d, s, CompressedOops::shift());
}
} else {
Label done;
mv(d, s);
beqz(s, done);
shadd(d, s, xheapbase, d, LogMinObjAlignmentInBytes);
bind(done);
}
verify_oop_msg(d, "broken oop in decode_heap_oop");
}
void MacroAssembler::store_heap_oop(Address dst, Register val, Register tmp1,
Register tmp2, Register tmp3, DecoratorSet decorators) {
access_store_at(T_OBJECT, IN_HEAP | decorators, dst, val, tmp1, tmp2, tmp3);
}
void MacroAssembler::load_heap_oop(Register dst, Address src, Register tmp1,
Register tmp2, DecoratorSet decorators) {
access_load_at(T_OBJECT, IN_HEAP | decorators, dst, src, tmp1, tmp2);
}
void MacroAssembler::load_heap_oop_not_null(Register dst, Address src, Register tmp1,
Register tmp2, DecoratorSet decorators) {
access_load_at(T_OBJECT, IN_HEAP | IS_NOT_NULL, dst, src, tmp1, tmp2);
}
// Used for storing NULLs.
void MacroAssembler::store_heap_oop_null(Address dst) {
access_store_at(T_OBJECT, IN_HEAP, dst, noreg, noreg, noreg, noreg);
}
int MacroAssembler::corrected_idivl(Register result, Register rs1, Register rs2,
bool want_remainder)
{
// Full implementation of Java idiv and irem. The function
// returns the (pc) offset of the div instruction - may be needed
// for implicit exceptions.
//
// input : rs1: dividend
// rs2: divisor
//
// result: either
// quotient (= rs1 idiv rs2)
// remainder (= rs1 irem rs2)
int idivl_offset = offset();
if (!want_remainder) {
divw(result, rs1, rs2);
} else {
remw(result, rs1, rs2); // result = rs1 % rs2;
}
return idivl_offset;
}
int MacroAssembler::corrected_idivq(Register result, Register rs1, Register rs2,
bool want_remainder)
{
// Full implementation of Java ldiv and lrem. The function
// returns the (pc) offset of the div instruction - may be needed
// for implicit exceptions.
//
// input : rs1: dividend
// rs2: divisor
//
// result: either
// quotient (= rs1 idiv rs2)
// remainder (= rs1 irem rs2)
int idivq_offset = offset();
if (!want_remainder) {
div(result, rs1, rs2);
} else {
rem(result, rs1, rs2); // result = rs1 % rs2;
}
return idivq_offset;
}
// Look up the method for a megamorpic invkkeinterface call.
// The target method is determined by <intf_klass, itable_index>.
// The receiver klass is in recv_klass.
// On success, the result will be in method_result, and execution falls through.
// On failure, execution transfers to the given label.
void MacroAssembler::lookup_interface_method(Register recv_klass,
Register intf_klass,
RegisterOrConstant itable_index,
Register method_result,
Register scan_tmp,
Label& L_no_such_interface,
bool return_method) {
assert_different_registers(recv_klass, intf_klass, scan_tmp);
assert_different_registers(method_result, intf_klass, scan_tmp);
assert(recv_klass != method_result || !return_method,
"recv_klass can be destroyed when mehtid isn't needed");
assert(itable_index.is_constant() || itable_index.as_register() == method_result,
"caller must be same register for non-constant itable index as for method");
// Compute start of first itableOffsetEntry (which is at the end of the vtable).
int vtable_base = in_bytes(Klass::vtable_start_offset());
int itentry_off = itableMethodEntry::method_offset_in_bytes();
int scan_step = itableOffsetEntry::size() * wordSize;
int vte_size = vtableEntry::size_in_bytes();
assert(vte_size == wordSize, "else adjust times_vte_scale");
lwu(scan_tmp, Address(recv_klass, Klass::vtable_length_offset()));
// %%% Could store the aligned, prescaled offset in the klassoop.
shadd(scan_tmp, scan_tmp, recv_klass, scan_tmp, 3);
add(scan_tmp, scan_tmp, vtable_base);
if (return_method) {
// Adjust recv_klass by scaled itable_index, so we can free itable_index.
assert(itableMethodEntry::size() * wordSize == wordSize, "adjust the scaling in the code below");
if (itable_index.is_register()) {
slli(t0, itable_index.as_register(), 3);
} else {
mv(t0, itable_index.as_constant() << 3);
}
add(recv_klass, recv_klass, t0);
if (itentry_off) {
add(recv_klass, recv_klass, itentry_off);
}
}
Label search, found_method;
ld(method_result, Address(scan_tmp, itableOffsetEntry::interface_offset_in_bytes()));
beq(intf_klass, method_result, found_method);
bind(search);
// Check that the previous entry is non-null. A null entry means that
// the receiver class doesn't implement the interface, and wasn't the
// same as when the caller was compiled.
beqz(method_result, L_no_such_interface, /* is_far */ true);
addi(scan_tmp, scan_tmp, scan_step);
ld(method_result, Address(scan_tmp, itableOffsetEntry::interface_offset_in_bytes()));
bne(intf_klass, method_result, search);
bind(found_method);
// Got a hit.
if (return_method) {
lwu(scan_tmp, Address(scan_tmp, itableOffsetEntry::offset_offset_in_bytes()));
add(method_result, recv_klass, scan_tmp);
ld(method_result, Address(method_result));
}
}
// virtual method calling
void MacroAssembler::lookup_virtual_method(Register recv_klass,
RegisterOrConstant vtable_index,
Register method_result) {
const int base = in_bytes(Klass::vtable_start_offset());
assert(vtableEntry::size() * wordSize == 8,
"adjust the scaling in the code below");
int vtable_offset_in_bytes = base + vtableEntry::method_offset_in_bytes();
if (vtable_index.is_register()) {
shadd(method_result, vtable_index.as_register(), recv_klass, method_result, LogBytesPerWord);
ld(method_result, Address(method_result, vtable_offset_in_bytes));
} else {
vtable_offset_in_bytes += vtable_index.as_constant() * wordSize;
ld(method_result, form_address(method_result, recv_klass, vtable_offset_in_bytes));
}
}
void MacroAssembler::membar(uint32_t order_constraint) {
address prev = pc() - NativeMembar::instruction_size;
address last = code()->last_insn();
if (last != NULL && nativeInstruction_at(last)->is_membar() && prev == last) {
NativeMembar *bar = NativeMembar_at(prev);
// We are merging two memory barrier instructions. On RISCV we
// can do this simply by ORing them together.
bar->set_kind(bar->get_kind() | order_constraint);
BLOCK_COMMENT("merged membar");
} else {
code()->set_last_insn(pc());
uint32_t predecessor = 0;
uint32_t successor = 0;
membar_mask_to_pred_succ(order_constraint, predecessor, successor);
fence(predecessor, successor);
}
}
// Form an address from base + offset in Rd. Rd my or may not
// actually be used: you must use the Address that is returned. It
// is up to you to ensure that the shift provided matches the size
// of your data.
Address MacroAssembler::form_address(Register Rd, Register base, long byte_offset) {
if (is_offset_in_range(byte_offset, 12)) { // 12: imm in range 2^12
return Address(base, byte_offset);
}
// Do it the hard way
mv(Rd, byte_offset);
add(Rd, base, Rd);
return Address(Rd);
}
void MacroAssembler::check_klass_subtype(Register sub_klass,
Register super_klass,
Register tmp_reg,
Label& L_success) {
Label L_failure;
check_klass_subtype_fast_path(sub_klass, super_klass, tmp_reg, &L_success, &L_failure, NULL);
check_klass_subtype_slow_path(sub_klass, super_klass, tmp_reg, noreg, &L_success, NULL);
bind(L_failure);
}
void MacroAssembler::safepoint_poll(Label& slow_path, bool at_return, bool acquire, bool in_nmethod) {
ld(t0, Address(xthread, JavaThread::polling_word_offset()));
if (acquire) {
membar(MacroAssembler::LoadLoad | MacroAssembler::LoadStore);
}
if (at_return) {
bgtu(in_nmethod ? sp : fp, t0, slow_path, true /* is_far */);
} else {
andi(t0, t0, SafepointMechanism::poll_bit());
bnez(t0, slow_path, true /* is_far */);
}
}
void MacroAssembler::cmpxchgptr(Register oldv, Register newv, Register addr, Register tmp,
Label &succeed, Label *fail) {
// oldv holds comparison value
// newv holds value to write in exchange
// addr identifies memory word to compare against/update
Label retry_load, nope;
bind(retry_load);
// Load reserved from the memory location
lr_d(tmp, addr, Assembler::aqrl);
// Fail and exit if it is not what we expect
bne(tmp, oldv, nope);
// If the store conditional succeeds, tmp will be zero
sc_d(tmp, newv, addr, Assembler::rl);
beqz(tmp, succeed);
// Retry only when the store conditional failed
j(retry_load);
bind(nope);
membar(AnyAny);
mv(oldv, tmp);
if (fail != NULL) {
j(*fail);
}
}
void MacroAssembler::cmpxchg_obj_header(Register oldv, Register newv, Register obj, Register tmp,
Label &succeed, Label *fail) {
assert(oopDesc::mark_offset_in_bytes() == 0, "assumption");
cmpxchgptr(oldv, newv, obj, tmp, succeed, fail);
}
void MacroAssembler::load_reserved(Register addr,
enum operand_size size,
Assembler::Aqrl acquire) {
switch (size) {
case int64:
lr_d(t0, addr, acquire);
break;
case int32:
lr_w(t0, addr, acquire);
break;
case uint32:
lr_w(t0, addr, acquire);
zero_extend(t0, t0, 32);
break;
default:
ShouldNotReachHere();
}
}
void MacroAssembler::store_conditional(Register addr,
Register new_val,
enum operand_size size,
Assembler::Aqrl release) {
switch (size) {
case int64:
sc_d(t0, new_val, addr, release);
break;
case int32:
case uint32:
sc_w(t0, new_val, addr, release);
break;
default:
ShouldNotReachHere();
}
}
void MacroAssembler::cmpxchg_narrow_value_helper(Register addr, Register expected,
Register new_val,
enum operand_size size,
Register tmp1, Register tmp2, Register tmp3) {
assert(size == int8 || size == int16, "unsupported operand size");
Register aligned_addr = t1, shift = tmp1, mask = tmp2, not_mask = tmp3;
andi(shift, addr, 3);
slli(shift, shift, 3);
andi(aligned_addr, addr, ~3);
if (size == int8) {
mv(mask, 0xff);
} else {
// size == int16 case
mv(mask, -1);
zero_extend(mask, mask, 16);
}
sll(mask, mask, shift);
xori(not_mask, mask, -1);
sll(expected, expected, shift);
andr(expected, expected, mask);
sll(new_val, new_val, shift);
andr(new_val, new_val, mask);
}
// cmpxchg_narrow_value will kill t0, t1, expected, new_val and tmps.
// It's designed to implement compare and swap byte/boolean/char/short by lr.w/sc.w,
// which are forced to work with 4-byte aligned address.
void MacroAssembler::cmpxchg_narrow_value(Register addr, Register expected,
Register new_val,
enum operand_size size,
Assembler::Aqrl acquire, Assembler::Aqrl release,
Register result, bool result_as_bool,
Register tmp1, Register tmp2, Register tmp3) {
Register aligned_addr = t1, shift = tmp1, mask = tmp2, not_mask = tmp3, old = result, tmp = t0;
assert_different_registers(addr, old, mask, not_mask, new_val, expected, shift, tmp);
cmpxchg_narrow_value_helper(addr, expected, new_val, size, tmp1, tmp2, tmp3);
Label retry, fail, done;
bind(retry);
lr_w(old, aligned_addr, acquire);
andr(tmp, old, mask);
bne(tmp, expected, fail);
andr(tmp, old, not_mask);
orr(tmp, tmp, new_val);
sc_w(tmp, tmp, aligned_addr, release);
bnez(tmp, retry);
if (result_as_bool) {
mv(result, 1);
j(done);
bind(fail);
mv(result, zr);
bind(done);
} else {
andr(tmp, old, mask);
bind(fail);
srl(result, tmp, shift);
if (size == int8) {
sign_extend(result, result, 8);
} else {
// size == int16 case
sign_extend(result, result, 16);
}
}
}
// weak_cmpxchg_narrow_value is a weak version of cmpxchg_narrow_value, to implement
// the weak CAS stuff. The major difference is that it just failed when store conditional
// failed.
void MacroAssembler::weak_cmpxchg_narrow_value(Register addr, Register expected,
Register new_val,
enum operand_size size,
Assembler::Aqrl acquire, Assembler::Aqrl release,
Register result,
Register tmp1, Register tmp2, Register tmp3) {
Register aligned_addr = t1, shift = tmp1, mask = tmp2, not_mask = tmp3, old = result, tmp = t0;
assert_different_registers(addr, old, mask, not_mask, new_val, expected, shift, tmp);
cmpxchg_narrow_value_helper(addr, expected, new_val, size, tmp1, tmp2, tmp3);
Label fail, done;
lr_w(old, aligned_addr, acquire);
andr(tmp, old, mask);
bne(tmp, expected, fail);
andr(tmp, old, not_mask);
orr(tmp, tmp, new_val);
sc_w(tmp, tmp, aligned_addr, release);
bnez(tmp, fail);
// Success
mv(result, 1);
j(done);
// Fail
bind(fail);
mv(result, zr);
bind(done);
}
void MacroAssembler::cmpxchg(Register addr, Register expected,
Register new_val,
enum operand_size size,
Assembler::Aqrl acquire, Assembler::Aqrl release,
Register result, bool result_as_bool) {
assert(size != int8 && size != int16, "unsupported operand size");
Label retry_load, done, ne_done;
bind(retry_load);
load_reserved(addr, size, acquire);
bne(t0, expected, ne_done);
store_conditional(addr, new_val, size, release);
bnez(t0, retry_load);
// equal, succeed
if (result_as_bool) {
mv(result, 1);
} else {
mv(result, expected);
}
j(done);
// not equal, failed
bind(ne_done);
if (result_as_bool) {
mv(result, zr);
} else {
mv(result, t0);
}
bind(done);
}
void MacroAssembler::cmpxchg_weak(Register addr, Register expected,
Register new_val,
enum operand_size size,
Assembler::Aqrl acquire, Assembler::Aqrl release,
Register result) {
Label fail, done;
load_reserved(addr, size, acquire);
bne(t0, expected, fail);
store_conditional(addr, new_val, size, release);
bnez(t0, fail);
// Success
mv(result, 1);
j(done);
// Fail
bind(fail);
mv(result, zr);
bind(done);
}
#define ATOMIC_OP(NAME, AOP, ACQUIRE, RELEASE) \
void MacroAssembler::atomic_##NAME(Register prev, RegisterOrConstant incr, Register addr) { \
prev = prev->is_valid() ? prev : zr; \
if (incr.is_register()) { \
AOP(prev, addr, incr.as_register(), (Assembler::Aqrl)(ACQUIRE | RELEASE)); \
} else { \
mv(t0, incr.as_constant()); \
AOP(prev, addr, t0, (Assembler::Aqrl)(ACQUIRE | RELEASE)); \
} \
return; \
}
ATOMIC_OP(add, amoadd_d, Assembler::relaxed, Assembler::relaxed)
ATOMIC_OP(addw, amoadd_w, Assembler::relaxed, Assembler::relaxed)
ATOMIC_OP(addal, amoadd_d, Assembler::aq, Assembler::rl)
ATOMIC_OP(addalw, amoadd_w, Assembler::aq, Assembler::rl)
#undef ATOMIC_OP
#define ATOMIC_XCHG(OP, AOP, ACQUIRE, RELEASE) \
void MacroAssembler::atomic_##OP(Register prev, Register newv, Register addr) { \
prev = prev->is_valid() ? prev : zr; \
AOP(prev, addr, newv, (Assembler::Aqrl)(ACQUIRE | RELEASE)); \
return; \
}
ATOMIC_XCHG(xchg, amoswap_d, Assembler::relaxed, Assembler::relaxed)
ATOMIC_XCHG(xchgw, amoswap_w, Assembler::relaxed, Assembler::relaxed)
ATOMIC_XCHG(xchgal, amoswap_d, Assembler::aq, Assembler::rl)
ATOMIC_XCHG(xchgalw, amoswap_w, Assembler::aq, Assembler::rl)
#undef ATOMIC_XCHG
#define ATOMIC_XCHGU(OP1, OP2) \
void MacroAssembler::atomic_##OP1(Register prev, Register newv, Register addr) { \
atomic_##OP2(prev, newv, addr); \
zero_extend(prev, prev, 32); \
return; \
}
ATOMIC_XCHGU(xchgwu, xchgw)
ATOMIC_XCHGU(xchgalwu, xchgalw)
#undef ATOMIC_XCHGU
void MacroAssembler::far_jump(Address entry, Register tmp) {
assert(ReservedCodeCacheSize < 4*G, "branch out of range");
assert(CodeCache::find_blob(entry.target()) != NULL,
"destination of far call not found in code cache");
assert(entry.rspec().type() == relocInfo::external_word_type
|| entry.rspec().type() == relocInfo::runtime_call_type
|| entry.rspec().type() == relocInfo::none, "wrong entry relocInfo type");
IncompressibleRegion ir(this); // Fixed length: see MacroAssembler::far_branch_size()
if (far_branches()) {
// We can use auipc + jalr here because we know that the total size of
// the code cache cannot exceed 2Gb.
relocate(entry.rspec(), [&] {
int32_t offset;
la_patchable(tmp, entry, offset);
jalr(x0, tmp, offset);
});
} else {
j(entry);
}
}
void MacroAssembler::far_call(Address entry, Register tmp) {
assert(ReservedCodeCacheSize < 4*G, "branch out of range");
assert(CodeCache::find_blob(entry.target()) != NULL,
"destination of far call not found in code cache");
assert(entry.rspec().type() == relocInfo::external_word_type
|| entry.rspec().type() == relocInfo::runtime_call_type
|| entry.rspec().type() == relocInfo::none, "wrong entry relocInfo type");
IncompressibleRegion ir(this); // Fixed length: see MacroAssembler::far_branch_size()
if (far_branches()) {
// We can use auipc + jalr here because we know that the total size of
// the code cache cannot exceed 2Gb.
relocate(entry.rspec(), [&] {
int32_t offset;
la_patchable(tmp, entry, offset);
jalr(x1, tmp, offset); // link
});
} else {
jal(entry); // link
}
}
void MacroAssembler::check_klass_subtype_fast_path(Register sub_klass,
Register super_klass,
Register tmp_reg,
Label* L_success,
Label* L_failure,
Label* L_slow_path,
Register super_check_offset) {
assert_different_registers(sub_klass, super_klass, tmp_reg);
bool must_load_sco = (super_check_offset == noreg);
if (must_load_sco) {
assert(tmp_reg != noreg, "supply either a temp or a register offset");
} else {
assert_different_registers(sub_klass, super_klass, super_check_offset);
}
Label L_fallthrough;
int label_nulls = 0;
if (L_success == NULL) { L_success = &L_fallthrough; label_nulls++; }
if (L_failure == NULL) { L_failure = &L_fallthrough; label_nulls++; }
if (L_slow_path == NULL) { L_slow_path = &L_fallthrough; label_nulls++; }
assert(label_nulls <= 1, "at most one NULL in batch");
int sc_offset = in_bytes(Klass::secondary_super_cache_offset());
int sco_offset = in_bytes(Klass::super_check_offset_offset());
Address super_check_offset_addr(super_klass, sco_offset);
// Hacked jmp, which may only be used just before L_fallthrough.
#define final_jmp(label) \
if (&(label) == &L_fallthrough) { /*do nothing*/ } \
else j(label) /*omit semi*/
// If the pointers are equal, we are done (e.g., String[] elements).
// This self-check enables sharing of secondary supertype arrays among
// non-primary types such as array-of-interface. Otherwise, each such
// type would need its own customized SSA.
// We move this check to the front of the fast path because many
// type checks are in fact trivially successful in this manner,
// so we get a nicely predicted branch right at the start of the check.
beq(sub_klass, super_klass, *L_success);
// Check the supertype display:
if (must_load_sco) {
lwu(tmp_reg, super_check_offset_addr);
super_check_offset = tmp_reg;
}
add(t0, sub_klass, super_check_offset);
Address super_check_addr(t0);
ld(t0, super_check_addr); // load displayed supertype
// This check has worked decisively for primary supers.
// Secondary supers are sought in the super_cache ('super_cache_addr').
// (Secondary supers are interfaces and very deeply nested subtypes.)
// This works in the same check above because of a tricky aliasing
// between the super_Cache and the primary super display elements.
// (The 'super_check_addr' can address either, as the case requires.)
// Note that the cache is updated below if it does not help us find
// what we need immediately.
// So if it was a primary super, we can just fail immediately.
// Otherwise, it's the slow path for us (no success at this point).
beq(super_klass, t0, *L_success);
mv(t1, sc_offset);
if (L_failure == &L_fallthrough) {
beq(super_check_offset, t1, *L_slow_path);
} else {
bne(super_check_offset, t1, *L_failure, /* is_far */ true);
final_jmp(*L_slow_path);
}
bind(L_fallthrough);
#undef final_jmp
}
// Scans count pointer sized words at [addr] for occurrence of value,
// generic
void MacroAssembler::repne_scan(Register addr, Register value, Register count,
Register tmp) {
Label Lloop, Lexit;
beqz(count, Lexit);
bind(Lloop);
ld(tmp, addr);
beq(value, tmp, Lexit);
add(addr, addr, wordSize);
sub(count, count, 1);
bnez(count, Lloop);
bind(Lexit);
}
void MacroAssembler::check_klass_subtype_slow_path(Register sub_klass,
Register super_klass,
Register tmp1_reg,
Register tmp2_reg,
Label* L_success,
Label* L_failure) {
assert_different_registers(sub_klass, super_klass, tmp1_reg);
if (tmp2_reg != noreg) {
assert_different_registers(sub_klass, super_klass, tmp1_reg, tmp2_reg, t0);
}
#define IS_A_TEMP(reg) ((reg) == tmp1_reg || (reg) == tmp2_reg)
Label L_fallthrough;
int label_nulls = 0;
if (L_success == NULL) { L_success = &L_fallthrough; label_nulls++; }
if (L_failure == NULL) { L_failure = &L_fallthrough; label_nulls++; }
assert(label_nulls <= 1, "at most one NULL in the batch");
// A couple of useful fields in sub_klass:
int ss_offset = in_bytes(Klass::secondary_supers_offset());
int sc_offset = in_bytes(Klass::secondary_super_cache_offset());
Address secondary_supers_addr(sub_klass, ss_offset);
Address super_cache_addr( sub_klass, sc_offset);
BLOCK_COMMENT("check_klass_subtype_slow_path");
// Do a linear scan of the secondary super-klass chain.
// This code is rarely used, so simplicity is a virtue here.
// The repne_scan instruction uses fixed registers, which we must spill.
// Don't worry too much about pre-existing connections with the input regs.
assert(sub_klass != x10, "killed reg"); // killed by mv(x10, super)
assert(sub_klass != x12, "killed reg"); // killed by la(x12, &pst_counter)
RegSet pushed_registers;
if (!IS_A_TEMP(x12)) {
pushed_registers += x12;
}
if (!IS_A_TEMP(x15)) {
pushed_registers += x15;
}
if (super_klass != x10) {
if (!IS_A_TEMP(x10)) {
pushed_registers += x10;
}
}
push_reg(pushed_registers, sp);
// Get super_klass value into x10 (even if it was in x15 or x12)
mv(x10, super_klass);
#ifndef PRODUCT
mv(t1, (address)&SharedRuntime::_partial_subtype_ctr);
Address pst_counter_addr(t1);
ld(t0, pst_counter_addr);
add(t0, t0, 1);
sd(t0, pst_counter_addr);
#endif // PRODUCT
// We will consult the secondary-super array.
ld(x15, secondary_supers_addr);
// Load the array length.
lwu(x12, Address(x15, Array<Klass*>::length_offset_in_bytes()));
// Skip to start of data.
add(x15, x15, Array<Klass*>::base_offset_in_bytes());
// Set t0 to an obvious invalid value, falling through by default
mv(t0, -1);
// Scan X12 words at [X15] for an occurrence of X10.
repne_scan(x15, x10, x12, t0);
// pop will restore x10, so we should use a temp register to keep its value
mv(t1, x10);
// Unspill the temp registers:
pop_reg(pushed_registers, sp);
bne(t1, t0, *L_failure);
// Success. Cache the super we found an proceed in triumph.
sd(super_klass, super_cache_addr);
if (L_success != &L_fallthrough) {
j(*L_success);
}
#undef IS_A_TEMP
bind(L_fallthrough);
}
// Defines obj, preserves var_size_in_bytes, okay for tmp2 == var_size_in_bytes.
void MacroAssembler::tlab_allocate(Register obj,
Register var_size_in_bytes,
int con_size_in_bytes,
Register tmp1,
Register tmp2,
Label& slow_case,
bool is_far) {
BarrierSetAssembler *bs = BarrierSet::barrier_set()->barrier_set_assembler();
bs->tlab_allocate(this, obj, var_size_in_bytes, con_size_in_bytes, tmp1, tmp2, slow_case, is_far);
}
// get_thread() can be called anywhere inside generated code so we
// need to save whatever non-callee save context might get clobbered
// by the call to Thread::current() or, indeed, the call setup code.
void MacroAssembler::get_thread(Register thread) {
// save all call-clobbered regs except thread
RegSet saved_regs = RegSet::range(x5, x7) + RegSet::range(x10, x17) +
RegSet::range(x28, x31) + ra - thread;
push_reg(saved_regs, sp);
mv(ra, CAST_FROM_FN_PTR(address, Thread::current));
jalr(ra);
if (thread != c_rarg0) {
mv(thread, c_rarg0);
}
// restore pushed registers
pop_reg(saved_regs, sp);
}
void MacroAssembler::load_byte_map_base(Register reg) {
CardTable::CardValue* byte_map_base =
((CardTableBarrierSet*)(BarrierSet::barrier_set()))->card_table()->byte_map_base();
mv(reg, (uint64_t)byte_map_base);
}
void MacroAssembler::la_patchable(Register reg1, const Address &dest, int32_t &offset) {
unsigned long low_address = (uintptr_t)CodeCache::low_bound();
unsigned long high_address = (uintptr_t)CodeCache::high_bound();
unsigned long dest_address = (uintptr_t)dest.target();
long offset_low = dest_address - low_address;
long offset_high = dest_address - high_address;
assert(is_valid_riscv64_address(dest.target()), "bad address");
assert(dest.getMode() == Address::literal, "la_patchable must be applied to a literal address");
// RISC-V doesn't compute a page-aligned address, in order to partially
// compensate for the use of *signed* offsets in its base+disp12
// addressing mode (RISC-V's PC-relative reach remains asymmetric
// [-(2G + 2K), 2G - 2K).
if (offset_high >= -((1L << 31) + (1L << 11)) && offset_low < (1L << 31) - (1L << 11)) {
int64_t distance = dest.target() - pc();
auipc(reg1, (int32_t)distance + 0x800);
offset = ((int32_t)distance << 20) >> 20;
} else {
movptr(reg1, dest.target(), offset);
}
}
void MacroAssembler::build_frame(int framesize) {
assert(framesize >= 2, "framesize must include space for FP/RA");
assert(framesize % (2*wordSize) == 0, "must preserve 2*wordSize alignment");
sub(sp, sp, framesize);
sd(fp, Address(sp, framesize - 2 * wordSize));
sd(ra, Address(sp, framesize - wordSize));
if (PreserveFramePointer) { add(fp, sp, framesize); }
}
void MacroAssembler::remove_frame(int framesize) {
assert(framesize >= 2, "framesize must include space for FP/RA");
assert(framesize % (2*wordSize) == 0, "must preserve 2*wordSize alignment");
ld(fp, Address(sp, framesize - 2 * wordSize));
ld(ra, Address(sp, framesize - wordSize));
add(sp, sp, framesize);
}
void MacroAssembler::reserved_stack_check() {
// testing if reserved zone needs to be enabled
Label no_reserved_zone_enabling;
ld(t0, Address(xthread, JavaThread::reserved_stack_activation_offset()));
bltu(sp, t0, no_reserved_zone_enabling);
enter(); // RA and FP are live.
mv(c_rarg0, xthread);
RuntimeAddress target(CAST_FROM_FN_PTR(address, SharedRuntime::enable_stack_reserved_zone));
relocate(target.rspec(), [&] {
int32_t offset;
la_patchable(t0, target, offset);
jalr(x1, t0, offset);
});
leave();
// We have already removed our own frame.
// throw_delayed_StackOverflowError will think that it's been
// called by our caller.
target = RuntimeAddress(StubRoutines::throw_delayed_StackOverflowError_entry());
relocate(target.rspec(), [&] {
int32_t offset;
la_patchable(t0, target, offset);
jalr(x0, t0, offset);
});
should_not_reach_here();
bind(no_reserved_zone_enabling);
}
// Move the address of the polling page into dest.
void MacroAssembler::get_polling_page(Register dest, relocInfo::relocType rtype) {
ld(dest, Address(xthread, JavaThread::polling_page_offset()));
}
// Read the polling page. The address of the polling page must
// already be in r.
void MacroAssembler::read_polling_page(Register r, int32_t offset, relocInfo::relocType rtype) {
relocate(rtype, [&] {
lwu(zr, Address(r, offset));
});
}
void MacroAssembler::set_narrow_oop(Register dst, jobject obj) {
#ifdef ASSERT
{
ThreadInVMfromUnknown tiv;
assert (UseCompressedOops, "should only be used for compressed oops");
assert (Universe::heap() != NULL, "java heap should be initialized");
assert (oop_recorder() != NULL, "this assembler needs an OopRecorder");
assert(Universe::heap()->is_in(JNIHandles::resolve(obj)), "should be real oop");
}
#endif
int oop_index = oop_recorder()->find_index(obj);
relocate(oop_Relocation::spec(oop_index), [&] {
li32(dst, 0xDEADBEEF);
});
zero_extend(dst, dst, 32);
}
void MacroAssembler::set_narrow_klass(Register dst, Klass* k) {
assert (UseCompressedClassPointers, "should only be used for compressed headers");
assert (oop_recorder() != NULL, "this assembler needs an OopRecorder");
int index = oop_recorder()->find_index(k);
assert(!Universe::heap()->is_in(k), "should not be an oop");
narrowKlass nk = CompressedKlassPointers::encode(k);
relocate(metadata_Relocation::spec(index), [&] {
li32(dst, nk);
});
zero_extend(dst, dst, 32);
}
// Maybe emit a call via a trampoline. If the code cache is small
// trampolines won't be emitted.
address MacroAssembler::trampoline_call(Address entry) {
assert(entry.rspec().type() == relocInfo::runtime_call_type ||
entry.rspec().type() == relocInfo::opt_virtual_call_type ||
entry.rspec().type() == relocInfo::static_call_type ||
entry.rspec().type() == relocInfo::virtual_call_type, "wrong reloc type");
address target = entry.target();
// We need a trampoline if branches are far.
if (far_branches()) {
if (!in_scratch_emit_size()) {
if (entry.rspec().type() == relocInfo::runtime_call_type) {
assert(CodeBuffer::supports_shared_stubs(), "must support shared stubs");
code()->share_trampoline_for(entry.target(), offset());
} else {
address stub = emit_trampoline_stub(offset(), target);
if (stub == NULL) {
postcond(pc() == badAddress);
return NULL; // CodeCache is full
}
}
}
target = pc();
}
address call_pc = pc();
#ifdef ASSERT
if (entry.rspec().type() != relocInfo::runtime_call_type) {
assert_alignment(call_pc);
}
#endif
relocate(entry.rspec(), [&] {
jal(target);
});
postcond(pc() != badAddress);
return call_pc;
}
address MacroAssembler::ic_call(address entry, jint method_index) {
RelocationHolder rh = virtual_call_Relocation::spec(pc(), method_index);
IncompressibleRegion ir(this); // relocations
movptr(t1, (address)Universe::non_oop_word());
assert_cond(entry != NULL);
return trampoline_call(Address(entry, rh));
}
// Emit a trampoline stub for a call to a target which is too far away.
//
// code sequences:
//
// call-site:
// branch-and-link to <destination> or <trampoline stub>
//
// Related trampoline stub for this call site in the stub section:
// load the call target from the constant pool
// branch (RA still points to the call site above)
address MacroAssembler::emit_trampoline_stub(int insts_call_instruction_offset,
address dest) {
address stub = start_a_stub(NativeInstruction::instruction_size
+ NativeCallTrampolineStub::instruction_size);
if (stub == NULL) {
return NULL; // CodeBuffer::expand failed
}
// We are always 4-byte aligned here.
assert_alignment(pc());
// Create a trampoline stub relocation which relates this trampoline stub
// with the call instruction at insts_call_instruction_offset in the
// instructions code-section.
// Make sure the address of destination 8-byte aligned after 3 instructions.
align(wordSize, NativeCallTrampolineStub::data_offset);
RelocationHolder rh = trampoline_stub_Relocation::spec(code()->insts()->start() +
insts_call_instruction_offset);
const int stub_start_offset = offset();
relocate(rh, [&] {
// Now, create the trampoline stub's code:
// - load the call
// - call
Label target;
ld(t0, target); // auipc + ld
jr(t0); // jalr
bind(target);
assert(offset() - stub_start_offset == NativeCallTrampolineStub::data_offset,
"should be");
assert(offset() % wordSize == 0, "bad alignment");
emit_int64((int64_t)dest);
});
const address stub_start_addr = addr_at(stub_start_offset);
assert(is_NativeCallTrampolineStub_at(stub_start_addr), "doesn't look like a trampoline");
end_a_stub();
return stub_start_addr;
}
Address MacroAssembler::add_memory_helper(const Address dst, Register tmp) {
switch (dst.getMode()) {
case Address::base_plus_offset:
// This is the expected mode, although we allow all the other
// forms below.
return form_address(tmp, dst.base(), dst.offset());
default:
la(tmp, dst);
return Address(tmp);
}
}
void MacroAssembler::increment(const Address dst, int64_t value, Register tmp1, Register tmp2) {
assert(((dst.getMode() == Address::base_plus_offset &&
is_offset_in_range(dst.offset(), 12)) || is_imm_in_range(value, 12, 0)),
"invalid value and address mode combination");
Address adr = add_memory_helper(dst, tmp2);
assert(!adr.uses(tmp1), "invalid dst for address increment");
ld(tmp1, adr);
add(tmp1, tmp1, value, tmp2);
sd(tmp1, adr);
}
void MacroAssembler::incrementw(const Address dst, int32_t value, Register tmp1, Register tmp2) {
assert(((dst.getMode() == Address::base_plus_offset &&
is_offset_in_range(dst.offset(), 12)) || is_imm_in_range(value, 12, 0)),
"invalid value and address mode combination");
Address adr = add_memory_helper(dst, tmp2);
assert(!adr.uses(tmp1), "invalid dst for address increment");
lwu(tmp1, adr);
addw(tmp1, tmp1, value, tmp2);
sw(tmp1, adr);
}
void MacroAssembler::decrement(const Address dst, int64_t value, Register tmp1, Register tmp2) {
assert(((dst.getMode() == Address::base_plus_offset &&
is_offset_in_range(dst.offset(), 12)) || is_imm_in_range(value, 12, 0)),
"invalid value and address mode combination");
Address adr = add_memory_helper(dst, tmp2);
assert(!adr.uses(tmp1), "invalid dst for address decrement");
ld(tmp1, adr);
sub(tmp1, tmp1, value, tmp2);
sd(tmp1, adr);
}
void MacroAssembler::decrementw(const Address dst, int32_t value, Register tmp1, Register tmp2) {
assert(((dst.getMode() == Address::base_plus_offset &&
is_offset_in_range(dst.offset(), 12)) || is_imm_in_range(value, 12, 0)),
"invalid value and address mode combination");
Address adr = add_memory_helper(dst, tmp2);
assert(!adr.uses(tmp1), "invalid dst for address decrement");
lwu(tmp1, adr);
subw(tmp1, tmp1, value, tmp2);
sw(tmp1, adr);
}
void MacroAssembler::cmpptr(Register src1, Address src2, Label& equal) {
assert_different_registers(src1, t0);
relocate(src2.rspec(), [&] {
int32_t offset;
la_patchable(t0, src2, offset);
ld(t0, Address(t0, offset));
});
beq(src1, t0, equal);
}
void MacroAssembler::load_method_holder_cld(Register result, Register method) {
load_method_holder(result, method);
ld(result, Address(result, InstanceKlass::class_loader_data_offset()));
}
void MacroAssembler::load_method_holder(Register holder, Register method) {
ld(holder, Address(method, Method::const_offset())); // ConstMethod*
ld(holder, Address(holder, ConstMethod::constants_offset())); // ConstantPool*
ld(holder, Address(holder, ConstantPool::pool_holder_offset_in_bytes())); // InstanceKlass*
}
// string indexof
// compute index by trailing zeros
void MacroAssembler::compute_index(Register haystack, Register trailing_zeros,
Register match_mask, Register result,
Register ch2, Register tmp,
bool haystack_isL) {
int haystack_chr_shift = haystack_isL ? 0 : 1;
srl(match_mask, match_mask, trailing_zeros);
srli(match_mask, match_mask, 1);
srli(tmp, trailing_zeros, LogBitsPerByte);
if (!haystack_isL) andi(tmp, tmp, 0xE);
add(haystack, haystack, tmp);
ld(ch2, Address(haystack));
if (!haystack_isL) srli(tmp, tmp, haystack_chr_shift);
add(result, result, tmp);
}
// string indexof
// Find pattern element in src, compute match mask,
// only the first occurrence of 0x80/0x8000 at low bits is the valid match index
// match mask patterns and corresponding indices would be like:
// - 0x8080808080808080 (Latin1)
// - 7 6 5 4 3 2 1 0 (match index)
// - 0x8000800080008000 (UTF16)
// - 3 2 1 0 (match index)
void MacroAssembler::compute_match_mask(Register src, Register pattern, Register match_mask,
Register mask1, Register mask2) {
xorr(src, pattern, src);
sub(match_mask, src, mask1);
orr(src, src, mask2);
notr(src, src);
andr(match_mask, match_mask, src);
}
#ifdef COMPILER2
// Code for BigInteger::mulAdd intrinsic
// out = x10
// in = x11
// offset = x12 (already out.length-offset)
// len = x13
// k = x14
// tmp = x28
//
// pseudo code from java implementation:
// long kLong = k & LONG_MASK;
// carry = 0;
// offset = out.length-offset - 1;
// for (int j = len - 1; j >= 0; j--) {
// product = (in[j] & LONG_MASK) * kLong + (out[offset] & LONG_MASK) + carry;
// out[offset--] = (int)product;
// carry = product >>> 32;
// }
// return (int)carry;
void MacroAssembler::mul_add(Register out, Register in, Register offset,
Register len, Register k, Register tmp) {
Label L_tail_loop, L_unroll, L_end;
mv(tmp, out);
mv(out, zr);
blez(len, L_end);
zero_extend(k, k, 32);
slliw(t0, offset, LogBytesPerInt);
add(offset, tmp, t0);
slliw(t0, len, LogBytesPerInt);
add(in, in, t0);
const int unroll = 8;
mv(tmp, unroll);
blt(len, tmp, L_tail_loop);
bind(L_unroll);
for (int i = 0; i < unroll; i++) {
sub(in, in, BytesPerInt);
lwu(t0, Address(in, 0));
mul(t1, t0, k);
add(t0, t1, out);
sub(offset, offset, BytesPerInt);
lwu(t1, Address(offset, 0));
add(t0, t0, t1);
sw(t0, Address(offset, 0));
srli(out, t0, 32);
}
subw(len, len, tmp);
bge(len, tmp, L_unroll);
bind(L_tail_loop);
blez(len, L_end);
sub(in, in, BytesPerInt);
lwu(t0, Address(in, 0));
mul(t1, t0, k);
add(t0, t1, out);
sub(offset, offset, BytesPerInt);
lwu(t1, Address(offset, 0));
add(t0, t0, t1);
sw(t0, Address(offset, 0));
srli(out, t0, 32);
subw(len, len, 1);
j(L_tail_loop);
bind(L_end);
}
// add two unsigned input and output carry
void MacroAssembler::cad(Register dst, Register src1, Register src2, Register carry)
{
assert_different_registers(dst, carry);
assert_different_registers(dst, src2);
add(dst, src1, src2);
sltu(carry, dst, src2);
}
// add two input with carry
void MacroAssembler::adc(Register dst, Register src1, Register src2, Register carry) {
assert_different_registers(dst, carry);
add(dst, src1, src2);
add(dst, dst, carry);
}
// add two unsigned input with carry and output carry
void MacroAssembler::cadc(Register dst, Register src1, Register src2, Register carry) {
assert_different_registers(dst, src2);
adc(dst, src1, src2, carry);
sltu(carry, dst, src2);
}
void MacroAssembler::add2_with_carry(Register final_dest_hi, Register dest_hi, Register dest_lo,
Register src1, Register src2, Register carry) {
cad(dest_lo, dest_lo, src1, carry);
add(dest_hi, dest_hi, carry);
cad(dest_lo, dest_lo, src2, carry);
add(final_dest_hi, dest_hi, carry);
}
/**
* Multiply 32 bit by 32 bit first loop.
*/
void MacroAssembler::multiply_32_x_32_loop(Register x, Register xstart, Register x_xstart,
Register y, Register y_idx, Register z,
Register carry, Register product,
Register idx, Register kdx) {
// jlong carry, x[], y[], z[];
// for (int idx=ystart, kdx=ystart+1+xstart; idx >= 0; idx--, kdx--) {
// long product = y[idx] * x[xstart] + carry;
// z[kdx] = (int)product;
// carry = product >>> 32;
// }
// z[xstart] = (int)carry;
Label L_first_loop, L_first_loop_exit;
blez(idx, L_first_loop_exit);
shadd(t0, xstart, x, t0, LogBytesPerInt);
lwu(x_xstart, Address(t0, 0));
bind(L_first_loop);
subw(idx, idx, 1);
shadd(t0, idx, y, t0, LogBytesPerInt);
lwu(y_idx, Address(t0, 0));
mul(product, x_xstart, y_idx);
add(product, product, carry);
srli(carry, product, 32);
subw(kdx, kdx, 1);
shadd(t0, kdx, z, t0, LogBytesPerInt);
sw(product, Address(t0, 0));
bgtz(idx, L_first_loop);
bind(L_first_loop_exit);
}
/**
* Multiply 64 bit by 64 bit first loop.
*/
void MacroAssembler::multiply_64_x_64_loop(Register x, Register xstart, Register x_xstart,
Register y, Register y_idx, Register z,
Register carry, Register product,
Register idx, Register kdx) {
//
// jlong carry, x[], y[], z[];
// for (int idx=ystart, kdx=ystart+1+xstart; idx >= 0; idx--, kdx--) {
// huge_128 product = y[idx] * x[xstart] + carry;
// z[kdx] = (jlong)product;
// carry = (jlong)(product >>> 64);
// }
// z[xstart] = carry;
//
Label L_first_loop, L_first_loop_exit;
Label L_one_x, L_one_y, L_multiply;
subw(xstart, xstart, 1);
bltz(xstart, L_one_x);
shadd(t0, xstart, x, t0, LogBytesPerInt);
ld(x_xstart, Address(t0, 0));
ror_imm(x_xstart, x_xstart, 32); // convert big-endian to little-endian
bind(L_first_loop);
subw(idx, idx, 1);
bltz(idx, L_first_loop_exit);
subw(idx, idx, 1);
bltz(idx, L_one_y);
shadd(t0, idx, y, t0, LogBytesPerInt);
ld(y_idx, Address(t0, 0));
ror_imm(y_idx, y_idx, 32); // convert big-endian to little-endian
bind(L_multiply);
mulhu(t0, x_xstart, y_idx);
mul(product, x_xstart, y_idx);
cad(product, product, carry, t1);
adc(carry, t0, zr, t1);
subw(kdx, kdx, 2);
ror_imm(product, product, 32); // back to big-endian
shadd(t0, kdx, z, t0, LogBytesPerInt);
sd(product, Address(t0, 0));
j(L_first_loop);
bind(L_one_y);
lwu(y_idx, Address(y, 0));
j(L_multiply);
bind(L_one_x);
lwu(x_xstart, Address(x, 0));
j(L_first_loop);
bind(L_first_loop_exit);
}
/**
* Multiply 128 bit by 128 bit. Unrolled inner loop.
*
*/
void MacroAssembler::multiply_128_x_128_loop(Register y, Register z,
Register carry, Register carry2,
Register idx, Register jdx,
Register yz_idx1, Register yz_idx2,
Register tmp, Register tmp3, Register tmp4,
Register tmp6, Register product_hi) {
// jlong carry, x[], y[], z[];
// int kdx = xstart+1;
// for (int idx=ystart-2; idx >= 0; idx -= 2) { // Third loop
// huge_128 tmp3 = (y[idx+1] * product_hi) + z[kdx+idx+1] + carry;
// jlong carry2 = (jlong)(tmp3 >>> 64);
// huge_128 tmp4 = (y[idx] * product_hi) + z[kdx+idx] + carry2;
// carry = (jlong)(tmp4 >>> 64);
// z[kdx+idx+1] = (jlong)tmp3;
// z[kdx+idx] = (jlong)tmp4;
// }
// idx += 2;
// if (idx > 0) {
// yz_idx1 = (y[idx] * product_hi) + z[kdx+idx] + carry;
// z[kdx+idx] = (jlong)yz_idx1;
// carry = (jlong)(yz_idx1 >>> 64);
// }
//
Label L_third_loop, L_third_loop_exit, L_post_third_loop_done;
srliw(jdx, idx, 2);
bind(L_third_loop);
subw(jdx, jdx, 1);
bltz(jdx, L_third_loop_exit);
subw(idx, idx, 4);
shadd(t0, idx, y, t0, LogBytesPerInt);
ld(yz_idx2, Address(t0, 0));
ld(yz_idx1, Address(t0, wordSize));
shadd(tmp6, idx, z, t0, LogBytesPerInt);
ror_imm(yz_idx1, yz_idx1, 32); // convert big-endian to little-endian
ror_imm(yz_idx2, yz_idx2, 32);
ld(t1, Address(tmp6, 0));
ld(t0, Address(tmp6, wordSize));
mul(tmp3, product_hi, yz_idx1); // yz_idx1 * product_hi -> tmp4:tmp3
mulhu(tmp4, product_hi, yz_idx1);
ror_imm(t0, t0, 32, tmp); // convert big-endian to little-endian
ror_imm(t1, t1, 32, tmp);
mul(tmp, product_hi, yz_idx2); // yz_idx2 * product_hi -> carry2:tmp
mulhu(carry2, product_hi, yz_idx2);
cad(tmp3, tmp3, carry, carry);
adc(tmp4, tmp4, zr, carry);
cad(tmp3, tmp3, t0, t0);
cadc(tmp4, tmp4, tmp, t0);
adc(carry, carry2, zr, t0);
cad(tmp4, tmp4, t1, carry2);
adc(carry, carry, zr, carry2);
ror_imm(tmp3, tmp3, 32); // convert little-endian to big-endian
ror_imm(tmp4, tmp4, 32);
sd(tmp4, Address(tmp6, 0));
sd(tmp3, Address(tmp6, wordSize));
j(L_third_loop);
bind(L_third_loop_exit);
andi(idx, idx, 0x3);
beqz(idx, L_post_third_loop_done);
Label L_check_1;
subw(idx, idx, 2);
bltz(idx, L_check_1);
shadd(t0, idx, y, t0, LogBytesPerInt);
ld(yz_idx1, Address(t0, 0));
ror_imm(yz_idx1, yz_idx1, 32);
mul(tmp3, product_hi, yz_idx1); // yz_idx1 * product_hi -> tmp4:tmp3
mulhu(tmp4, product_hi, yz_idx1);
shadd(t0, idx, z, t0, LogBytesPerInt);
ld(yz_idx2, Address(t0, 0));
ror_imm(yz_idx2, yz_idx2, 32, tmp);
add2_with_carry(carry, tmp4, tmp3, carry, yz_idx2, tmp);
ror_imm(tmp3, tmp3, 32, tmp);
sd(tmp3, Address(t0, 0));
bind(L_check_1);
andi(idx, idx, 0x1);
subw(idx, idx, 1);
bltz(idx, L_post_third_loop_done);
shadd(t0, idx, y, t0, LogBytesPerInt);
lwu(tmp4, Address(t0, 0));
mul(tmp3, tmp4, product_hi); // tmp4 * product_hi -> carry2:tmp3
mulhu(carry2, tmp4, product_hi);
shadd(t0, idx, z, t0, LogBytesPerInt);
lwu(tmp4, Address(t0, 0));
add2_with_carry(carry2, carry2, tmp3, tmp4, carry, t0);
shadd(t0, idx, z, t0, LogBytesPerInt);
sw(tmp3, Address(t0, 0));
slli(t0, carry2, 32);
srli(carry, tmp3, 32);
orr(carry, carry, t0);
bind(L_post_third_loop_done);
}
/**
* Code for BigInteger::multiplyToLen() intrinsic.
*
* x10: x
* x11: xlen
* x12: y
* x13: ylen
* x14: z
* x15: zlen
* x16: tmp1
* x17: tmp2
* x7: tmp3
* x28: tmp4
* x29: tmp5
* x30: tmp6
* x31: tmp7
*/
void MacroAssembler::multiply_to_len(Register x, Register xlen, Register y, Register ylen,
Register z, Register zlen,
Register tmp1, Register tmp2, Register tmp3, Register tmp4,
Register tmp5, Register tmp6, Register product_hi) {
assert_different_registers(x, xlen, y, ylen, z, zlen, tmp1, tmp2, tmp3, tmp4, tmp5, tmp6);
const Register idx = tmp1;
const Register kdx = tmp2;
const Register xstart = tmp3;
const Register y_idx = tmp4;
const Register carry = tmp5;
const Register product = xlen;
const Register x_xstart = zlen; // reuse register
mv(idx, ylen); // idx = ylen;
mv(kdx, zlen); // kdx = xlen+ylen;
mv(carry, zr); // carry = 0;
Label L_multiply_64_x_64_loop, L_done;
subw(xstart, xlen, 1);
bltz(xstart, L_done);
const Register jdx = tmp1;
if (AvoidUnalignedAccesses) {
// Check if x and y are both 8-byte aligned.
orr(t0, xlen, ylen);
andi(t0, t0, 0x1);
beqz(t0, L_multiply_64_x_64_loop);
multiply_32_x_32_loop(x, xstart, x_xstart, y, y_idx, z, carry, product, idx, kdx);
shadd(t0, xstart, z, t0, LogBytesPerInt);
sw(carry, Address(t0, 0));
Label L_second_loop_unaligned;
bind(L_second_loop_unaligned);
mv(carry, zr);
mv(jdx, ylen);
subw(xstart, xstart, 1);
bltz(xstart, L_done);
sub(sp, sp, 2 * wordSize);
sd(z, Address(sp, 0));
sd(zr, Address(sp, wordSize));
shadd(t0, xstart, z, t0, LogBytesPerInt);
addi(z, t0, 4);
shadd(t0, xstart, x, t0, LogBytesPerInt);
lwu(product, Address(t0, 0));
Label L_third_loop, L_third_loop_exit;
blez(jdx, L_third_loop_exit);
bind(L_third_loop);
subw(jdx, jdx, 1);
shadd(t0, jdx, y, t0, LogBytesPerInt);
lwu(t0, Address(t0, 0));
mul(t1, t0, product);
add(t0, t1, carry);
shadd(tmp6, jdx, z, t1, LogBytesPerInt);
lwu(t1, Address(tmp6, 0));
add(t0, t0, t1);
sw(t0, Address(tmp6, 0));
srli(carry, t0, 32);
bgtz(jdx, L_third_loop);
bind(L_third_loop_exit);
ld(z, Address(sp, 0));
addi(sp, sp, 2 * wordSize);
shadd(t0, xstart, z, t0, LogBytesPerInt);
sw(carry, Address(t0, 0));
j(L_second_loop_unaligned);
}
bind(L_multiply_64_x_64_loop);
multiply_64_x_64_loop(x, xstart, x_xstart, y, y_idx, z, carry, product, idx, kdx);
Label L_second_loop_aligned;
beqz(kdx, L_second_loop_aligned);
Label L_carry;
subw(kdx, kdx, 1);
beqz(kdx, L_carry);
shadd(t0, kdx, z, t0, LogBytesPerInt);
sw(carry, Address(t0, 0));
srli(carry, carry, 32);
subw(kdx, kdx, 1);
bind(L_carry);
shadd(t0, kdx, z, t0, LogBytesPerInt);
sw(carry, Address(t0, 0));
// Second and third (nested) loops.
//
// for (int i = xstart-1; i >= 0; i--) { // Second loop
// carry = 0;
// for (int jdx=ystart, k=ystart+1+i; jdx >= 0; jdx--, k--) { // Third loop
// long product = (y[jdx] & LONG_MASK) * (x[i] & LONG_MASK) +
// (z[k] & LONG_MASK) + carry;
// z[k] = (int)product;
// carry = product >>> 32;
// }
// z[i] = (int)carry;
// }
//
// i = xlen, j = tmp1, k = tmp2, carry = tmp5, x[i] = product_hi
bind(L_second_loop_aligned);
mv(carry, zr); // carry = 0;
mv(jdx, ylen); // j = ystart+1
subw(xstart, xstart, 1); // i = xstart-1;
bltz(xstart, L_done);
sub(sp, sp, 4 * wordSize);
sd(z, Address(sp, 0));
Label L_last_x;
shadd(t0, xstart, z, t0, LogBytesPerInt);
addi(z, t0, 4);
subw(xstart, xstart, 1); // i = xstart-1;
bltz(xstart, L_last_x);
shadd(t0, xstart, x, t0, LogBytesPerInt);
ld(product_hi, Address(t0, 0));
ror_imm(product_hi, product_hi, 32); // convert big-endian to little-endian
Label L_third_loop_prologue;
bind(L_third_loop_prologue);
sd(ylen, Address(sp, wordSize));
sd(x, Address(sp, 2 * wordSize));
sd(xstart, Address(sp, 3 * wordSize));
multiply_128_x_128_loop(y, z, carry, x, jdx, ylen, product,
tmp2, x_xstart, tmp3, tmp4, tmp6, product_hi);
ld(z, Address(sp, 0));
ld(ylen, Address(sp, wordSize));
ld(x, Address(sp, 2 * wordSize));
ld(xlen, Address(sp, 3 * wordSize)); // copy old xstart -> xlen
addi(sp, sp, 4 * wordSize);
addiw(tmp3, xlen, 1);
shadd(t0, tmp3, z, t0, LogBytesPerInt);
sw(carry, Address(t0, 0));
subw(tmp3, tmp3, 1);
bltz(tmp3, L_done);
srli(carry, carry, 32);
shadd(t0, tmp3, z, t0, LogBytesPerInt);
sw(carry, Address(t0, 0));
j(L_second_loop_aligned);
// Next infrequent code is moved outside loops.
bind(L_last_x);
lwu(product_hi, Address(x, 0));
j(L_third_loop_prologue);
bind(L_done);
}
#endif
// Count bits of trailing zero chars from lsb to msb until first non-zero element.
// For LL case, one byte for one element, so shift 8 bits once, and for other case,
// shift 16 bits once.
void MacroAssembler::ctzc_bit(Register Rd, Register Rs, bool isLL, Register tmp1, Register tmp2) {
if (UseZbb) {
assert_different_registers(Rd, Rs, tmp1);
int step = isLL ? 8 : 16;
ctz(Rd, Rs);
andi(tmp1, Rd, step - 1);
sub(Rd, Rd, tmp1);
return;
}
assert_different_registers(Rd, Rs, tmp1, tmp2);
Label Loop;
int step = isLL ? 8 : 16;
mv(Rd, -step);
mv(tmp2, Rs);
bind(Loop);
addi(Rd, Rd, step);
andi(tmp1, tmp2, ((1 << step) - 1));
srli(tmp2, tmp2, step);
beqz(tmp1, Loop);
}
// This instruction reads adjacent 4 bytes from the lower half of source register,
// inflate into a register, for example:
// Rs: A7A6A5A4A3A2A1A0
// Rd: 00A300A200A100A0
void MacroAssembler::inflate_lo32(Register Rd, Register Rs, Register tmp1, Register tmp2) {
assert_different_registers(Rd, Rs, tmp1, tmp2);
mv(tmp1, 0xFF);
mv(Rd, zr);
for (int i = 0; i <= 3; i++) {
andr(tmp2, Rs, tmp1);
if (i) {
slli(tmp2, tmp2, i * 8);
}
orr(Rd, Rd, tmp2);
if (i != 3) {
slli(tmp1, tmp1, 8);
}
}
}
// This instruction reads adjacent 4 bytes from the upper half of source register,
// inflate into a register, for example:
// Rs: A7A6A5A4A3A2A1A0
// Rd: 00A700A600A500A4
void MacroAssembler::inflate_hi32(Register Rd, Register Rs, Register tmp1, Register tmp2) {
assert_different_registers(Rd, Rs, tmp1, tmp2);
mv(tmp1, 0xFF00000000);
mv(Rd, zr);
for (int i = 0; i <= 3; i++) {
andr(tmp2, Rs, tmp1);
orr(Rd, Rd, tmp2);
srli(Rd, Rd, 8);
if (i != 3) {
slli(tmp1, tmp1, 8);
}
}
}
// The size of the blocks erased by the zero_blocks stub. We must
// handle anything smaller than this ourselves in zero_words().
const int MacroAssembler::zero_words_block_size = 8;
// zero_words() is used by C2 ClearArray patterns. It is as small as
// possible, handling small word counts locally and delegating
// anything larger to the zero_blocks stub. It is expanded many times
// in compiled code, so it is important to keep it short.
// ptr: Address of a buffer to be zeroed.
// cnt: Count in HeapWords.
//
// ptr, cnt, and t0 are clobbered.
address MacroAssembler::zero_words(Register ptr, Register cnt) {
assert(is_power_of_2(zero_words_block_size), "adjust this");
assert(ptr == x28 && cnt == x29, "mismatch in register usage");
assert_different_registers(cnt, t0);
BLOCK_COMMENT("zero_words {");
mv(t0, zero_words_block_size);
Label around, done, done16;
bltu(cnt, t0, around);
{
RuntimeAddress zero_blocks = RuntimeAddress(StubRoutines::riscv::zero_blocks());
assert(zero_blocks.target() != NULL, "zero_blocks stub has not been generated");
if (StubRoutines::riscv::complete()) {
address tpc = trampoline_call(zero_blocks);
if (tpc == NULL) {
DEBUG_ONLY(reset_labels(around));
postcond(pc() == badAddress);
return NULL;
}
} else {
jal(zero_blocks);
}
}
bind(around);
for (int i = zero_words_block_size >> 1; i > 1; i >>= 1) {
Label l;
andi(t0, cnt, i);
beqz(t0, l);
for (int j = 0; j < i; j++) {
sd(zr, Address(ptr, j * wordSize));
}
addi(ptr, ptr, i * wordSize);
bind(l);
}
{
Label l;
andi(t0, cnt, 1);
beqz(t0, l);
sd(zr, Address(ptr, 0));
bind(l);
}
BLOCK_COMMENT("} zero_words");
postcond(pc() != badAddress);
return pc();
}
#define SmallArraySize (18 * BytesPerLong)
// base: Address of a buffer to be zeroed, 8 bytes aligned.
// cnt: Immediate count in HeapWords.
void MacroAssembler::zero_words(Register base, uint64_t cnt) {
assert_different_registers(base, t0, t1);
BLOCK_COMMENT("zero_words {");
if (cnt <= SmallArraySize / BytesPerLong) {
for (int i = 0; i < (int)cnt; i++) {
sd(zr, Address(base, i * wordSize));
}
} else {
const int unroll = 8; // Number of sd(zr, adr), instructions we'll unroll
int remainder = cnt % unroll;
for (int i = 0; i < remainder; i++) {
sd(zr, Address(base, i * wordSize));
}
Label loop;
Register cnt_reg = t0;
Register loop_base = t1;
cnt = cnt - remainder;
mv(cnt_reg, cnt);
add(loop_base, base, remainder * wordSize);
bind(loop);
sub(cnt_reg, cnt_reg, unroll);
for (int i = 0; i < unroll; i++) {
sd(zr, Address(loop_base, i * wordSize));
}
add(loop_base, loop_base, unroll * wordSize);
bnez(cnt_reg, loop);
}
BLOCK_COMMENT("} zero_words");
}
// base: Address of a buffer to be filled, 8 bytes aligned.
// cnt: Count in 8-byte unit.
// value: Value to be filled with.
// base will point to the end of the buffer after filling.
void MacroAssembler::fill_words(Register base, Register cnt, Register value) {
// Algorithm:
//
// t0 = cnt & 7
// cnt -= t0
// p += t0
// switch (t0):
// switch start:
// do while cnt
// cnt -= 8
// p[-8] = value
// case 7:
// p[-7] = value
// case 6:
// p[-6] = value
// // ...
// case 1:
// p[-1] = value
// case 0:
// p += 8
// do-while end
// switch end
assert_different_registers(base, cnt, value, t0, t1);
Label fini, skip, entry, loop;
const int unroll = 8; // Number of sd instructions we'll unroll
beqz(cnt, fini);
andi(t0, cnt, unroll - 1);
sub(cnt, cnt, t0);
// align 8, so first sd n % 8 = mod, next loop sd 8 * n.
shadd(base, t0, base, t1, 3);
la(t1, entry);
slli(t0, t0, 2); // sd_inst_nums * 4; t0 is cnt % 8, so t1 = t1 - sd_inst_nums * 4, 4 is sizeof(inst)
sub(t1, t1, t0);
jr(t1);
bind(loop);
add(base, base, unroll * 8);
for (int i = -unroll; i < 0; i++) {
sd(value, Address(base, i * 8));
}
bind(entry);
sub(cnt, cnt, unroll);
bgez(cnt, loop);
bind(fini);
}
// Zero blocks of memory by using CBO.ZERO.
//
// Aligns the base address first sufficiently for CBO.ZERO, then uses
// CBO.ZERO repeatedly for every full block. cnt is the size to be
// zeroed in HeapWords. Returns the count of words left to be zeroed
// in cnt.
//
// NOTE: This is intended to be used in the zero_blocks() stub. If
// you want to use it elsewhere, note that cnt must be >= CacheLineSize.
void MacroAssembler::zero_dcache_blocks(Register base, Register cnt, Register tmp1, Register tmp2) {
Label initial_table_end, loop;
// Align base with cache line size.
neg(tmp1, base);
andi(tmp1, tmp1, CacheLineSize - 1);
// tmp1: the number of bytes to be filled to align the base with cache line size.
add(base, base, tmp1);
srai(tmp2, tmp1, 3);
sub(cnt, cnt, tmp2);
srli(tmp2, tmp1, 1);
la(tmp1, initial_table_end);
sub(tmp2, tmp1, tmp2);
jr(tmp2);
for (int i = -CacheLineSize + wordSize; i < 0; i += wordSize) {
sd(zr, Address(base, i));
}
bind(initial_table_end);
mv(tmp1, CacheLineSize / wordSize);
bind(loop);
cbo_zero(base);
sub(cnt, cnt, tmp1);
add(base, base, CacheLineSize);
bge(cnt, tmp1, loop);
}
#define FCVT_SAFE(FLOATCVT, FLOATEQ) \
void MacroAssembler:: FLOATCVT##_safe(Register dst, FloatRegister src, Register tmp) { \
Label L_Okay; \
fscsr(zr); \
FLOATCVT(dst, src); \
frcsr(tmp); \
andi(tmp, tmp, 0x1E); \
beqz(tmp, L_Okay); \
FLOATEQ(tmp, src, src); \
bnez(tmp, L_Okay); \
mv(dst, zr); \
bind(L_Okay); \
}
FCVT_SAFE(fcvt_w_s, feq_s)
FCVT_SAFE(fcvt_l_s, feq_s)
FCVT_SAFE(fcvt_w_d, feq_d)
FCVT_SAFE(fcvt_l_d, feq_d)
#undef FCVT_SAFE
#define FCMP(FLOATTYPE, FLOATSIG) \
void MacroAssembler::FLOATTYPE##_compare(Register result, FloatRegister Rs1, \
FloatRegister Rs2, int unordered_result) { \
Label Ldone; \
if (unordered_result < 0) { \
/* we want -1 for unordered or less than, 0 for equal and 1 for greater than. */ \
/* installs 1 if gt else 0 */ \
flt_##FLOATSIG(result, Rs2, Rs1); \
/* Rs1 > Rs2, install 1 */ \
bgtz(result, Ldone); \
feq_##FLOATSIG(result, Rs1, Rs2); \
addi(result, result, -1); \
/* Rs1 = Rs2, install 0 */ \
/* NaN or Rs1 < Rs2, install -1 */ \
bind(Ldone); \
} else { \
/* we want -1 for less than, 0 for equal and 1 for unordered or greater than. */ \
/* installs 1 if gt or unordered else 0 */ \
flt_##FLOATSIG(result, Rs1, Rs2); \
/* Rs1 < Rs2, install -1 */ \
bgtz(result, Ldone); \
feq_##FLOATSIG(result, Rs1, Rs2); \
addi(result, result, -1); \
/* Rs1 = Rs2, install 0 */ \
/* NaN or Rs1 > Rs2, install 1 */ \
bind(Ldone); \
neg(result, result); \
} \
}
FCMP(float, s);
FCMP(double, d);
#undef FCMP
// Zero words; len is in bytes
// Destroys all registers except addr
// len must be a nonzero multiple of wordSize
void MacroAssembler::zero_memory(Register addr, Register len, Register tmp) {
assert_different_registers(addr, len, tmp, t0, t1);
#ifdef ASSERT
{
Label L;
andi(t0, len, BytesPerWord - 1);
beqz(t0, L);
stop("len is not a multiple of BytesPerWord");
bind(L);
}
#endif // ASSERT
#ifndef PRODUCT
block_comment("zero memory");
#endif // PRODUCT
Label loop;
Label entry;
// Algorithm:
//
// t0 = cnt & 7
// cnt -= t0
// p += t0
// switch (t0) {
// do {
// cnt -= 8
// p[-8] = 0
// case 7:
// p[-7] = 0
// case 6:
// p[-6] = 0
// ...
// case 1:
// p[-1] = 0
// case 0:
// p += 8
// } while (cnt)
// }
const int unroll = 8; // Number of sd(zr) instructions we'll unroll
srli(len, len, LogBytesPerWord);
andi(t0, len, unroll - 1); // t0 = cnt % unroll
sub(len, len, t0); // cnt -= unroll
// tmp always points to the end of the region we're about to zero
shadd(tmp, t0, addr, t1, LogBytesPerWord);
la(t1, entry);
slli(t0, t0, 2);
sub(t1, t1, t0);
jr(t1);
bind(loop);
sub(len, len, unroll);
for (int i = -unroll; i < 0; i++) {
sd(zr, Address(tmp, i * wordSize));
}
bind(entry);
add(tmp, tmp, unroll * wordSize);
bnez(len, loop);
}
// shift left by shamt and add
// Rd = (Rs1 << shamt) + Rs2
void MacroAssembler::shadd(Register Rd, Register Rs1, Register Rs2, Register tmp, int shamt) {
if (UseZba) {
if (shamt == 1) {
sh1add(Rd, Rs1, Rs2);
return;
} else if (shamt == 2) {
sh2add(Rd, Rs1, Rs2);
return;
} else if (shamt == 3) {
sh3add(Rd, Rs1, Rs2);
return;
}
}
if (shamt != 0) {
slli(tmp, Rs1, shamt);
add(Rd, Rs2, tmp);
} else {
add(Rd, Rs1, Rs2);
}
}
void MacroAssembler::zero_extend(Register dst, Register src, int bits) {
if (UseZba && bits == 32) {
zext_w(dst, src);
return;
}
if (UseZbb && bits == 16) {
zext_h(dst, src);
return;
}
if (bits == 8) {
zext_b(dst, src);
} else {
slli(dst, src, XLEN - bits);
srli(dst, dst, XLEN - bits);
}
}
void MacroAssembler::sign_extend(Register dst, Register src, int bits) {
if (UseZbb) {
if (bits == 8) {
sext_b(dst, src);
return;
} else if (bits == 16) {
sext_h(dst, src);
return;
}
}
if (bits == 32) {
sext_w(dst, src);
} else {
slli(dst, src, XLEN - bits);
srai(dst, dst, XLEN - bits);
}
}
void MacroAssembler::cmp_l2i(Register dst, Register src1, Register src2, Register tmp)
{
if (src1 == src2) {
mv(dst, zr);
return;
}
Label done;
Register left = src1;
Register right = src2;
if (dst == src1) {
assert_different_registers(dst, src2, tmp);
mv(tmp, src1);
left = tmp;
} else if (dst == src2) {
assert_different_registers(dst, src1, tmp);
mv(tmp, src2);
right = tmp;
}
// installs 1 if gt else 0
slt(dst, right, left);
bnez(dst, done);
slt(dst, left, right);
// dst = -1 if lt; else if eq , dst = 0
neg(dst, dst);
bind(done);
}
// The java_calling_convention describes stack locations as ideal slots on
// a frame with no abi restrictions. Since we must observe abi restrictions
// (like the placement of the register window) the slots must be biased by
// the following value.
static int reg2offset_in(VMReg r) {
// Account for saved fp and ra
// This should really be in_preserve_stack_slots
return r->reg2stack() * VMRegImpl::stack_slot_size;
}
static int reg2offset_out(VMReg r) {
return (r->reg2stack() + SharedRuntime::out_preserve_stack_slots()) * VMRegImpl::stack_slot_size;
}
// On 64 bit we will store integer like items to the stack as
// 64 bits items (riscv64 abi) even though java would only store
// 32bits for a parameter. On 32bit it will simply be 32 bits
// So this routine will do 32->32 on 32bit and 32->64 on 64bit
void MacroAssembler::move32_64(VMRegPair src, VMRegPair dst, Register tmp) {
if (src.first()->is_stack()) {
if (dst.first()->is_stack()) {
// stack to stack
ld(tmp, Address(fp, reg2offset_in(src.first())));
sd(tmp, Address(sp, reg2offset_out(dst.first())));
} else {
// stack to reg
lw(dst.first()->as_Register(), Address(fp, reg2offset_in(src.first())));
}
} else if (dst.first()->is_stack()) {
// reg to stack
sd(src.first()->as_Register(), Address(sp, reg2offset_out(dst.first())));
} else {
if (dst.first() != src.first()) {
// 32bits extend sign
addw(dst.first()->as_Register(), src.first()->as_Register(), zr);
}
}
}
// An oop arg. Must pass a handle not the oop itself
void MacroAssembler::object_move(OopMap* map,
int oop_handle_offset,
int framesize_in_slots,
VMRegPair src,
VMRegPair dst,
bool is_receiver,
int* receiver_offset) {
assert_cond(map != NULL && receiver_offset != NULL);
// must pass a handle. First figure out the location we use as a handle
Register rHandle = dst.first()->is_stack() ? t1 : dst.first()->as_Register();
// See if oop is NULL if it is we need no handle
if (src.first()->is_stack()) {
// Oop is already on the stack as an argument
int offset_in_older_frame = src.first()->reg2stack() + SharedRuntime::out_preserve_stack_slots();
map->set_oop(VMRegImpl::stack2reg(offset_in_older_frame + framesize_in_slots));
if (is_receiver) {
*receiver_offset = (offset_in_older_frame + framesize_in_slots) * VMRegImpl::stack_slot_size;
}
ld(t0, Address(fp, reg2offset_in(src.first())));
la(rHandle, Address(fp, reg2offset_in(src.first())));
// conditionally move a NULL
Label notZero1;
bnez(t0, notZero1);
mv(rHandle, zr);
bind(notZero1);
} else {
// Oop is in a register we must store it to the space we reserve
// on the stack for oop_handles and pass a handle if oop is non-NULL
const Register rOop = src.first()->as_Register();
int oop_slot = -1;
if (rOop == j_rarg0) {
oop_slot = 0;
} else if (rOop == j_rarg1) {
oop_slot = 1;
} else if (rOop == j_rarg2) {
oop_slot = 2;
} else if (rOop == j_rarg3) {
oop_slot = 3;
} else if (rOop == j_rarg4) {
oop_slot = 4;
} else if (rOop == j_rarg5) {
oop_slot = 5;
} else if (rOop == j_rarg6) {
oop_slot = 6;
} else {
assert(rOop == j_rarg7, "wrong register");
oop_slot = 7;
}
oop_slot = oop_slot * VMRegImpl::slots_per_word + oop_handle_offset;
int offset = oop_slot * VMRegImpl::stack_slot_size;
map->set_oop(VMRegImpl::stack2reg(oop_slot));
// Store oop in handle area, may be NULL
sd(rOop, Address(sp, offset));
if (is_receiver) {
*receiver_offset = offset;
}
//rOop maybe the same as rHandle
if (rOop == rHandle) {
Label isZero;
beqz(rOop, isZero);
la(rHandle, Address(sp, offset));
bind(isZero);
} else {
Label notZero2;
la(rHandle, Address(sp, offset));
bnez(rOop, notZero2);
mv(rHandle, zr);
bind(notZero2);
}
}
// If arg is on the stack then place it otherwise it is already in correct reg.
if (dst.first()->is_stack()) {
sd(rHandle, Address(sp, reg2offset_out(dst.first())));
}
}
// A float arg may have to do float reg int reg conversion
void MacroAssembler::float_move(VMRegPair src, VMRegPair dst, Register tmp) {
assert(src.first()->is_stack() && dst.first()->is_stack() ||
src.first()->is_reg() && dst.first()->is_reg() ||
src.first()->is_stack() && dst.first()->is_reg(), "Unexpected error");
if (src.first()->is_stack()) {
if (dst.first()->is_stack()) {
lwu(tmp, Address(fp, reg2offset_in(src.first())));
sw(tmp, Address(sp, reg2offset_out(dst.first())));
} else if (dst.first()->is_Register()) {
lwu(dst.first()->as_Register(), Address(fp, reg2offset_in(src.first())));
} else {
ShouldNotReachHere();
}
} else if (src.first() != dst.first()) {
if (src.is_single_phys_reg() && dst.is_single_phys_reg()) {
fmv_s(dst.first()->as_FloatRegister(), src.first()->as_FloatRegister());
} else {
ShouldNotReachHere();
}
}
}
// A long move
void MacroAssembler::long_move(VMRegPair src, VMRegPair dst, Register tmp) {
if (src.first()->is_stack()) {
if (dst.first()->is_stack()) {
// stack to stack
ld(tmp, Address(fp, reg2offset_in(src.first())));
sd(tmp, Address(sp, reg2offset_out(dst.first())));
} else {
// stack to reg
ld(dst.first()->as_Register(), Address(fp, reg2offset_in(src.first())));
}
} else if (dst.first()->is_stack()) {
// reg to stack
sd(src.first()->as_Register(), Address(sp, reg2offset_out(dst.first())));
} else {
if (dst.first() != src.first()) {
mv(dst.first()->as_Register(), src.first()->as_Register());
}
}
}
// A double move
void MacroAssembler::double_move(VMRegPair src, VMRegPair dst, Register tmp) {
assert(src.first()->is_stack() && dst.first()->is_stack() ||
src.first()->is_reg() && dst.first()->is_reg() ||
src.first()->is_stack() && dst.first()->is_reg(), "Unexpected error");
if (src.first()->is_stack()) {
if (dst.first()->is_stack()) {
ld(tmp, Address(fp, reg2offset_in(src.first())));
sd(tmp, Address(sp, reg2offset_out(dst.first())));
} else if (dst.first()-> is_Register()) {
ld(dst.first()->as_Register(), Address(fp, reg2offset_in(src.first())));
} else {
ShouldNotReachHere();
}
} else if (src.first() != dst.first()) {
if (src.is_single_phys_reg() && dst.is_single_phys_reg()) {
fmv_d(dst.first()->as_FloatRegister(), src.first()->as_FloatRegister());
} else {
ShouldNotReachHere();
}
}
}
void MacroAssembler::rt_call(address dest, Register tmp) {
CodeBlob *cb = CodeCache::find_blob(dest);
RuntimeAddress target(dest);
if (cb) {
far_call(target);
} else {
relocate(target.rspec(), [&] {
int32_t offset;
la_patchable(tmp, target, offset);
jalr(x1, tmp, offset);
});
}
}
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