6976186: integrate Shark HotSpot changes
Summary: Shark is a JIT compiler for Zero that uses the LLVM compiler infrastructure.
Reviewed-by: kvn, twisti
Contributed-by: Gary Benson <gbenson@redhat.com>
/*
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* Copyright 2008, 2009, 2010 Red Hat, Inc.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
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* 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
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*/
#include "incls/_precompiled.incl"
#include "incls/_sharkBuilder.cpp.incl"
using namespace llvm;
SharkBuilder::SharkBuilder(SharkCodeBuffer* code_buffer)
: IRBuilder<>(SharkContext::current()),
_code_buffer(code_buffer) {
}
// Helpers for accessing structures
Value* SharkBuilder::CreateAddressOfStructEntry(Value* base,
ByteSize offset,
const Type* type,
const char* name) {
return CreateBitCast(CreateStructGEP(base, in_bytes(offset)), type, name);
}
LoadInst* SharkBuilder::CreateValueOfStructEntry(Value* base,
ByteSize offset,
const Type* type,
const char* name) {
return CreateLoad(
CreateAddressOfStructEntry(
base, offset, PointerType::getUnqual(type)),
name);
}
// Helpers for accessing arrays
LoadInst* SharkBuilder::CreateArrayLength(Value* arrayoop) {
return CreateValueOfStructEntry(
arrayoop, in_ByteSize(arrayOopDesc::length_offset_in_bytes()),
SharkType::jint_type(), "length");
}
Value* SharkBuilder::CreateArrayAddress(Value* arrayoop,
const Type* element_type,
int element_bytes,
ByteSize base_offset,
Value* index,
const char* name) {
Value* offset = CreateIntCast(index, SharkType::intptr_type(), false);
if (element_bytes != 1)
offset = CreateShl(
offset,
LLVMValue::intptr_constant(exact_log2(element_bytes)));
offset = CreateAdd(
LLVMValue::intptr_constant(in_bytes(base_offset)), offset);
return CreateIntToPtr(
CreateAdd(CreatePtrToInt(arrayoop, SharkType::intptr_type()), offset),
PointerType::getUnqual(element_type),
name);
}
Value* SharkBuilder::CreateArrayAddress(Value* arrayoop,
BasicType basic_type,
ByteSize base_offset,
Value* index,
const char* name) {
return CreateArrayAddress(
arrayoop,
SharkType::to_arrayType(basic_type),
type2aelembytes(basic_type),
base_offset, index, name);
}
Value* SharkBuilder::CreateArrayAddress(Value* arrayoop,
BasicType basic_type,
Value* index,
const char* name) {
return CreateArrayAddress(
arrayoop, basic_type,
in_ByteSize(arrayOopDesc::base_offset_in_bytes(basic_type)),
index, name);
}
// Helpers for creating intrinsics and external functions.
const Type* SharkBuilder::make_type(char type, bool void_ok) {
switch (type) {
// Primitive types
case 'c':
return SharkType::jbyte_type();
case 'i':
return SharkType::jint_type();
case 'l':
return SharkType::jlong_type();
case 'x':
return SharkType::intptr_type();
case 'f':
return SharkType::jfloat_type();
case 'd':
return SharkType::jdouble_type();
// Pointers to primitive types
case 'C':
case 'I':
case 'L':
case 'X':
case 'F':
case 'D':
return PointerType::getUnqual(make_type(tolower(type), false));
// VM objects
case 'T':
return SharkType::thread_type();
case 'M':
return PointerType::getUnqual(SharkType::monitor_type());
case 'O':
return SharkType::oop_type();
// Miscellaneous
case 'v':
assert(void_ok, "should be");
return SharkType::void_type();
case '1':
return SharkType::bit_type();
default:
ShouldNotReachHere();
}
}
const FunctionType* SharkBuilder::make_ftype(const char* params,
const char* ret) {
std::vector<const Type*> param_types;
for (const char* c = params; *c; c++)
param_types.push_back(make_type(*c, false));
assert(strlen(ret) == 1, "should be");
const Type *return_type = make_type(*ret, true);
return FunctionType::get(return_type, param_types, false);
}
// Create an object representing an intrinsic or external function by
// referencing the symbol by name. This is the LLVM-style approach,
// but it cannot be used on functions within libjvm.so its symbols
// are not exported. Note that you cannot make this work simply by
// exporting the symbols, as some symbols have the same names as
// symbols in the standard libraries (eg, atan2, fabs) and would
// obscure them were they visible.
Value* SharkBuilder::make_function(const char* name,
const char* params,
const char* ret) {
return SharkContext::current().get_external(name, make_ftype(params, ret));
}
// Create an object representing an external function by inlining a
// function pointer in the code. This is not the LLVM way, but it's
// the only way to access functions in libjvm.so and functions like
// __kernel_dmb on ARM which is accessed via an absolute address.
Value* SharkBuilder::make_function(address func,
const char* params,
const char* ret) {
return CreateIntToPtr(
LLVMValue::intptr_constant((intptr_t) func),
PointerType::getUnqual(make_ftype(params, ret)));
}
// VM calls
Value* SharkBuilder::find_exception_handler() {
return make_function(
(address) SharkRuntime::find_exception_handler, "TIi", "i");
}
Value* SharkBuilder::monitorenter() {
return make_function((address) SharkRuntime::monitorenter, "TM", "v");
}
Value* SharkBuilder::monitorexit() {
return make_function((address) SharkRuntime::monitorexit, "TM", "v");
}
Value* SharkBuilder::new_instance() {
return make_function((address) SharkRuntime::new_instance, "Ti", "v");
}
Value* SharkBuilder::newarray() {
return make_function((address) SharkRuntime::newarray, "Tii", "v");
}
Value* SharkBuilder::anewarray() {
return make_function((address) SharkRuntime::anewarray, "Tii", "v");
}
Value* SharkBuilder::multianewarray() {
return make_function((address) SharkRuntime::multianewarray, "TiiI", "v");
}
Value* SharkBuilder::register_finalizer() {
return make_function((address) SharkRuntime::register_finalizer, "TO", "v");
}
Value* SharkBuilder::safepoint() {
return make_function((address) SafepointSynchronize::block, "T", "v");
}
Value* SharkBuilder::throw_ArithmeticException() {
return make_function(
(address) SharkRuntime::throw_ArithmeticException, "TCi", "v");
}
Value* SharkBuilder::throw_ArrayIndexOutOfBoundsException() {
return make_function(
(address) SharkRuntime::throw_ArrayIndexOutOfBoundsException, "TCii", "v");
}
Value* SharkBuilder::throw_ClassCastException() {
return make_function(
(address) SharkRuntime::throw_ClassCastException, "TCi", "v");
}
Value* SharkBuilder::throw_NullPointerException() {
return make_function(
(address) SharkRuntime::throw_NullPointerException, "TCi", "v");
}
// High-level non-VM calls
Value* SharkBuilder::f2i() {
return make_function((address) SharedRuntime::f2i, "f", "i");
}
Value* SharkBuilder::f2l() {
return make_function((address) SharedRuntime::f2l, "f", "l");
}
Value* SharkBuilder::d2i() {
return make_function((address) SharedRuntime::d2i, "d", "i");
}
Value* SharkBuilder::d2l() {
return make_function((address) SharedRuntime::d2l, "d", "l");
}
Value* SharkBuilder::is_subtype_of() {
return make_function((address) SharkRuntime::is_subtype_of, "OO", "c");
}
Value* SharkBuilder::current_time_millis() {
return make_function((address) os::javaTimeMillis, "", "l");
}
Value* SharkBuilder::sin() {
return make_function("llvm.sin.f64", "d", "d");
}
Value* SharkBuilder::cos() {
return make_function("llvm.cos.f64", "d", "d");
}
Value* SharkBuilder::tan() {
return make_function((address) ::tan, "d", "d");
}
Value* SharkBuilder::atan2() {
return make_function((address) ::atan2, "dd", "d");
}
Value* SharkBuilder::sqrt() {
return make_function("llvm.sqrt.f64", "d", "d");
}
Value* SharkBuilder::log() {
return make_function("llvm.log.f64", "d", "d");
}
Value* SharkBuilder::log10() {
return make_function("llvm.log10.f64", "d", "d");
}
Value* SharkBuilder::pow() {
return make_function("llvm.pow.f64", "dd", "d");
}
Value* SharkBuilder::exp() {
return make_function("llvm.exp.f64", "d", "d");
}
Value* SharkBuilder::fabs() {
return make_function((address) ::fabs, "d", "d");
}
Value* SharkBuilder::unsafe_field_offset_to_byte_offset() {
extern jlong Unsafe_field_offset_to_byte_offset(jlong field_offset);
return make_function((address) Unsafe_field_offset_to_byte_offset, "l", "l");
}
Value* SharkBuilder::osr_migration_end() {
return make_function((address) SharedRuntime::OSR_migration_end, "C", "v");
}
// Semi-VM calls
Value* SharkBuilder::throw_StackOverflowError() {
return make_function((address) ZeroStack::handle_overflow, "T", "v");
}
Value* SharkBuilder::uncommon_trap() {
return make_function((address) SharkRuntime::uncommon_trap, "Ti", "i");
}
Value* SharkBuilder::deoptimized_entry_point() {
return make_function((address) CppInterpreter::main_loop, "iT", "v");
}
// Native-Java transition
Value* SharkBuilder::check_special_condition_for_native_trans() {
return make_function(
(address) JavaThread::check_special_condition_for_native_trans,
"T", "v");
}
// Low-level non-VM calls
// The ARM-specific code here is to work around unimplemented
// atomic exchange and memory barrier intrinsics in LLVM.
//
// Delegating to external functions for these would normally
// incur a speed penalty, but Linux on ARM is a special case
// in that atomic operations on that platform are handled by
// external functions anyway. It would be *preferable* for
// the calls to be hidden away in LLVM, but it's not hurting
// performance so having the calls here is acceptable.
//
// If you are building Shark on a platform without atomic
// exchange and/or memory barrier intrinsics then it is only
// acceptable to mimic this approach if your platform cannot
// perform these operations without delegating to a function.
#ifdef ARM
static jint zero_cmpxchg_int(volatile jint *ptr, jint oldval, jint newval) {
return Atomic::cmpxchg(newval, ptr, oldval);
}
#endif // ARM
Value* SharkBuilder::cmpxchg_int() {
return make_function(
#ifdef ARM
(address) zero_cmpxchg_int,
#else
"llvm.atomic.cmp.swap.i32.p0i32",
#endif // ARM
"Iii", "i");
}
#ifdef ARM
static intptr_t zero_cmpxchg_ptr(volatile intptr_t* ptr,
intptr_t oldval,
intptr_t newval) {
return Atomic::cmpxchg_ptr(newval, ptr, oldval);
}
#endif // ARM
Value* SharkBuilder::cmpxchg_ptr() {
return make_function(
#ifdef ARM
(address) zero_cmpxchg_ptr,
#else
"llvm.atomic.cmp.swap.i" LP64_ONLY("64") NOT_LP64("32") ".p0i" LP64_ONLY("64") NOT_LP64("32"),
#endif // ARM
"Xxx", "x");
}
Value* SharkBuilder::frame_address() {
return make_function("llvm.frameaddress", "i", "C");
}
Value* SharkBuilder::memory_barrier() {
return make_function(
#ifdef ARM
(address) 0xffff0fa0, // __kernel_dmb
#else
"llvm.memory.barrier",
#endif // ARM
"11111", "v");
}
Value* SharkBuilder::memset() {
#if SHARK_LLVM_VERSION >= 28
// LLVM 2.8 added a fifth isVolatile field for memset
// introduced with LLVM r100304
return make_function("llvm.memset.i32", "Cciii", "v");
#else
return make_function("llvm.memset.i32", "Ccii", "v");
#endif
}
Value* SharkBuilder::unimplemented() {
return make_function((address) report_unimplemented, "Ci", "v");
}
Value* SharkBuilder::should_not_reach_here() {
return make_function((address) report_should_not_reach_here, "Ci", "v");
}
Value* SharkBuilder::dump() {
return make_function((address) SharkRuntime::dump, "Cx", "v");
}
// Public interface to low-level non-VM calls
CallInst* SharkBuilder::CreateCmpxchgInt(Value* exchange_value,
Value* dst,
Value* compare_value) {
return CreateCall3(cmpxchg_int(), dst, compare_value, exchange_value);
}
CallInst* SharkBuilder::CreateCmpxchgPtr(Value* exchange_value,
Value* dst,
Value* compare_value) {
return CreateCall3(cmpxchg_ptr(), dst, compare_value, exchange_value);
}
CallInst* SharkBuilder::CreateGetFrameAddress() {
return CreateCall(frame_address(), LLVMValue::jint_constant(0));
}
CallInst *SharkBuilder::CreateMemoryBarrier(int flags) {
Value *args[] = {
LLVMValue::bit_constant((flags & BARRIER_LOADLOAD) ? 1 : 0),
LLVMValue::bit_constant((flags & BARRIER_LOADSTORE) ? 1 : 0),
LLVMValue::bit_constant((flags & BARRIER_STORELOAD) ? 1 : 0),
LLVMValue::bit_constant((flags & BARRIER_STORESTORE) ? 1 : 0),
LLVMValue::bit_constant(1)};
return CreateCall(memory_barrier(), args, args + 5);
}
CallInst* SharkBuilder::CreateMemset(Value* dst,
Value* value,
Value* len,
Value* align) {
#if SHARK_LLVM_VERSION >= 28
return CreateCall5(memset(), dst, value, len, align,
LLVMValue::jint_constant(0));
#else
return CreateCall4(memset(), dst, value, len, align);
#endif
}
CallInst* SharkBuilder::CreateUnimplemented(const char* file, int line) {
return CreateCall2(
unimplemented(),
CreateIntToPtr(
LLVMValue::intptr_constant((intptr_t) file),
PointerType::getUnqual(SharkType::jbyte_type())),
LLVMValue::jint_constant(line));
}
CallInst* SharkBuilder::CreateShouldNotReachHere(const char* file, int line) {
return CreateCall2(
should_not_reach_here(),
CreateIntToPtr(
LLVMValue::intptr_constant((intptr_t) file),
PointerType::getUnqual(SharkType::jbyte_type())),
LLVMValue::jint_constant(line));
}
#ifndef PRODUCT
CallInst* SharkBuilder::CreateDump(Value* value) {
const char *name;
if (value->hasName())
// XXX this leaks, but it's only debug code
name = strdup(value->getName().str().c_str());
else
name = "unnamed_value";
if (isa<PointerType>(value->getType()))
value = CreatePtrToInt(value, SharkType::intptr_type());
else if (value->getType()->
#if SHARK_LLVM_VERSION >= 27
isIntegerTy()
#else
isInteger()
#endif
)
value = CreateIntCast(value, SharkType::intptr_type(), false);
else
Unimplemented();
return CreateCall2(
dump(),
CreateIntToPtr(
LLVMValue::intptr_constant((intptr_t) name),
PointerType::getUnqual(SharkType::jbyte_type())),
value);
}
#endif // PRODUCT
// HotSpot memory barriers
void SharkBuilder::CreateUpdateBarrierSet(BarrierSet* bs, Value* field) {
if (bs->kind() != BarrierSet::CardTableModRef)
Unimplemented();
CreateStore(
LLVMValue::jbyte_constant(CardTableModRefBS::dirty_card),
CreateIntToPtr(
CreateAdd(
LLVMValue::intptr_constant(
(intptr_t) ((CardTableModRefBS *) bs)->byte_map_base),
CreateLShr(
CreatePtrToInt(field, SharkType::intptr_type()),
LLVMValue::intptr_constant(CardTableModRefBS::card_shift))),
PointerType::getUnqual(SharkType::jbyte_type())));
}
// Helpers for accessing the code buffer
Value* SharkBuilder::code_buffer_address(int offset) {
return CreateAdd(
code_buffer()->base_pc(),
LLVMValue::intptr_constant(offset));
}
Value* SharkBuilder::CreateInlineOop(jobject object, const char* name) {
return CreateLoad(
CreateIntToPtr(
code_buffer_address(code_buffer()->inline_oop(object)),
PointerType::getUnqual(SharkType::oop_type())),
name);
}
Value* SharkBuilder::CreateInlineData(void* data,
size_t size,
const Type* type,
const char* name) {
return CreateIntToPtr(
code_buffer_address(code_buffer()->inline_data(data, size)),
type,
name);
}
// Helpers for creating basic blocks.
BasicBlock* SharkBuilder::GetBlockInsertionPoint() const {
BasicBlock *cur = GetInsertBlock();
// BasicBlock::Create takes an insertBefore argument, so
// we need to find the block _after_ the current block
Function::iterator iter = cur->getParent()->begin();
Function::iterator end = cur->getParent()->end();
while (iter != end) {
iter++;
if (&*iter == cur) {
iter++;
break;
}
}
if (iter == end)
return NULL;
else
return iter;
}
BasicBlock* SharkBuilder::CreateBlock(BasicBlock* ip, const char* name) const {
return BasicBlock::Create(
SharkContext::current(), name, GetInsertBlock()->getParent(), ip);
}