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unboxing.cpp
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unboxing.cpp
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#include <iostream>
#include <ciso646>
#include "unboxing.h"
#include "compiler.h"
#include "rift.h"
using namespace std;
using namespace llvm;
namespace rift {
char Unboxing::ID = 0;
#define RUNTIME_CALL(name, ...) CallInst::Create(name, std::vector<llvm::Value*>({__VA_ARGS__}), "", ins)
AType * Unboxing::updateAnalysis(llvm::Value * value, AType * type) {
return state().initialize(value, type);
}
llvm::Value * Unboxing::box(AType * what) {
llvm::Value * location = state().getLocation(what);
switch (what->kind) {
case AType::Kind::R:
return location;
case AType::Kind::D:
location = RUNTIME_CALL(m->doubleVectorLiteral, location);
what = state().initialize(location, new AType(AType::Kind::DV, what));
// fallthrough
case AType::Kind::DV:
location = RUNTIME_CALL(m->fromDoubleVector, location);
state().initialize(location, new AType(AType::Kind::R, what));
return location;
case AType::Kind::CV:
location = RUNTIME_CALL(m->fromCharacterVector, location);
state().initialize(location, new AType(AType::Kind::R, what));
return location;
case AType::Kind::F:
location = RUNTIME_CALL(m->fromFunction, location);
state().initialize(location, new AType(AType::Kind::R, what));
return location;
default:
assert(false and "Cannot unbox this type");
return nullptr;
}
}
llvm:: Value * Unboxing::unbox(AType * t) {
llvm::Value * location = state().getLocation(t);
assert(t->payload != nullptr and "Unboxing requested, but no information is available");
assert(location != nullptr and "Cannort unbox value with unknown location");
if (llvm::Value * payloadLocation = state().getLocation(t->payload))
return payloadLocation;
// payload's location is not known, we have to extract it from the boxed type
switch (t->kind) {
case AType::Kind::DV:
location = RUNTIME_CALL(m->doubleGetSingleElement, location, ConstantFP::get(getGlobalContext(), APFloat(0.0)));
state().initialize(location, t->payload);
break;
case AType::Kind::R:
switch (t->payload->kind) {
case AType::Kind::DV:
location = RUNTIME_CALL(m->doubleFromValue, location);
break;
case AType::Kind::CV:
location = RUNTIME_CALL(m->characterFromValue, location);
break;
case AType::Kind::F:
location = RUNTIME_CALL(m->functionFromValue, location);
break;
default:
assert(false and "Not possible");
}
state().initialize(location, t->payload);
break;
default:
assert(false and "Only double vector and RVals can be unboxed");
}
return location;
}
llvm::Value * Unboxing::getScalarPayload(AType * t) {
llvm::Value* location = state().getLocation(t);
assert (location != nullptr and "This would mean we are calling runtime funtcion with a value that we have effectively lost");
switch (t->kind) {
case AType::Kind::D:
return location;
case AType::Kind::DV:
assert(not t->payload->isTop() and "Not a scalar");
return unbox(t);
case AType::Kind::R:
assert(not t->payload->isTop() and "Not a scalar");
assert(t->payload->kind == AType::Kind::DV and "Not a scalar");
// first unboxing to double vector
unbox(t);
// second unboxing to scalar
return unbox(t->payload);
default:
assert(not t->payload->isTop() and "Not a scalar");
return nullptr;
}
}
/** This works for both cv's and dv's.
*/
llvm::Value * Unboxing::getVectorPayload(AType * t) {
llvm::Value * location = state().getLocation(t);
assert(location != nullptr and "This would mean we are calling runtime funtcion with a value that we have effectively lost");
switch (t->kind) {
case AType::Kind::DV:
case AType::Kind::CV:
return location;
case AType::Kind::R:
assert(not t->payload->isTop() and "Not a vector");
return unbox(t);
default:
assert(not t->payload->isTop() and "Not a vector");
return nullptr;
}
}
void Unboxing::doubleArithmetic(AType * lhs, AType * rhs, llvm::Instruction::BinaryOps op, llvm::Function * fop) {
assert(lhs->isDouble() and rhs->isDouble() and "Doubles expected");
AType * result_t;
if (lhs->isScalar() and rhs->isScalar()) {
llvm::Value * l = getScalarPayload(lhs);
llvm::Value * r = getScalarPayload(rhs);
result_t = updateAnalysis(
BinaryOperator::Create(op, l, r, "", ins),
new AType(AType::Kind::D));
} else {
// it has to be vector - we have already checked it is a double
result_t = updateAnalysis(
RUNTIME_CALL(fop, getVectorPayload(lhs), getVectorPayload(rhs)),
new AType(AType::Kind::DV));
}
ins->replaceAllUsesWith(box(result_t));
}
bool Unboxing::genericAdd() {
// first check if we are dealing with character add
AType * lhs = state().get(ins->getOperand(0));
AType * rhs = state().get(ins->getOperand(1));
if (lhs->isDouble() and rhs->isDouble()) {
doubleArithmetic(lhs, rhs, Instruction::FAdd, m->doubleAdd);
return true;
} else if (lhs->isCharacter() and rhs->isCharacter()) {
AType * result_t = updateAnalysis(
RUNTIME_CALL(m->characterAdd, getVectorPayload(lhs), getVectorPayload(rhs)),
new AType(AType::Kind::CV));
ins->replaceAllUsesWith(box(result_t));
return true;
} else {
return false;
}
}
bool Unboxing::genericArithmetic(llvm::Instruction::BinaryOps op, llvm::Function * fop) {
AType * lhs = state().get(ins->getOperand(0));
AType * rhs = state().get(ins->getOperand(1));
if (lhs->isDouble() and rhs->isDouble()) {
doubleArithmetic(lhs, rhs, op, fop);
return true;
} else {
return false;
}
}
void Unboxing::doubleRelational(AType * lhs, AType * rhs, llvm::CmpInst::Predicate op, llvm::Function * fop) {
assert(lhs->isDouble() and rhs->isDouble() and "Doubles expected");
AType * result_t;
if (lhs->isScalar() and rhs->isScalar()) {
llvm::Value * x = new FCmpInst(ins, op, getScalarPayload(lhs), getScalarPayload(rhs));
result_t = updateAnalysis(new UIToFPInst(x, type::Double, "", ins), new AType(AType::Kind::D));
} else {
// it has to be vector - we have already checked it is a double
result_t = updateAnalysis(RUNTIME_CALL(fop, getVectorPayload(lhs), getVectorPayload(rhs)), new AType(AType::Kind::DV));
}
ins->replaceAllUsesWith(box(result_t));
}
bool Unboxing::genericRelational(llvm::CmpInst::Predicate op, llvm::Function * fop) {
AType * lhs = state().get(ins->getOperand(0));
AType * rhs = state().get(ins->getOperand(1));
if (lhs->isDouble() and rhs->isDouble()) {
doubleRelational(lhs, rhs, op, fop);
return true;
} else {
return false;
}
}
bool Unboxing::genericComparison(AType * lhs, AType * rhs, llvm::CmpInst::Predicate op, llvm::Function * dop, llvm::Function * cop) {
if (lhs->isDouble() and rhs->isDouble()) {
doubleRelational(lhs, rhs, op, dop);
return true;
} else if (lhs->isCharacter() and rhs->isCharacter()) {
AType * result_t = updateAnalysis(RUNTIME_CALL(cop, getVectorPayload(lhs), getVectorPayload(rhs)), new AType(AType::Kind::DV));
ins->replaceAllUsesWith(box(result_t));
return true;
} else {
return false;
}
}
bool Unboxing::genericEq() {
AType * lhs = state().get(ins->getOperand(0));
AType * rhs = state().get(ins->getOperand(1));
if (genericComparison(lhs, rhs, FCmpInst::FCMP_OEQ, m->doubleEq, m->characterEq)) {
return true;
} else if (not lhs->canBeSameTypeAs(rhs)) {
AType * result_t = updateAnalysis(ConstantFP::get(getGlobalContext(), APFloat(0.0)), new AType(AType::Kind::D));
ins->replaceAllUsesWith(box(result_t));
return true;
} else {
return false;
}
}
bool Unboxing::genericNeq() {
AType * lhs = state().get(ins->getOperand(0));
AType * rhs = state().get(ins->getOperand(1));
if (genericComparison(lhs, rhs, FCmpInst::FCMP_ONE, m->doubleNeq, m->characterNeq)) {
return true;
} else if (not lhs->canBeSameTypeAs(rhs)) {
AType * result_t = updateAnalysis(ConstantFP::get(getGlobalContext(), APFloat(1.0)), new AType(AType::Kind::D));
ins->replaceAllUsesWith(box(result_t));
return true;
} else {
return false;
}
}
bool Unboxing::genericGetElement() {
AType * source = state().get(ins->getOperand(0));
AType * index = state().get(ins->getOperand(1));
AType * result_t;
if (source->isDouble()) {
if (index->isScalar()) {
result_t = updateAnalysis(RUNTIME_CALL(m->doubleGetSingleElement, getVectorPayload(source), getScalarPayload(index)), new AType(AType::Kind::D));
} else if (index->isDouble()) {
result_t = updateAnalysis(RUNTIME_CALL(m->doubleGetElement, getVectorPayload(source), getVectorPayload(index)), new AType(AType::Kind::DV));
} else {
return false;
}
} else if (source->isCharacter() and index->isDouble()) {
result_t = updateAnalysis(RUNTIME_CALL(m->characterGetElement, getVectorPayload(source), getVectorPayload(index)), new AType(AType::Kind::CV));
} else {
return false;
}
ins->replaceAllUsesWith(box(result_t));
return true;
}
bool Unboxing::genericSetElement() {
AType * target = state().get(ins->getOperand(0));
AType * index = state().get(ins->getOperand(1));
AType * value = state().get(ins->getOperand(2));
if (target->isDouble()) {
if (index->isScalar() and value->isScalar())
RUNTIME_CALL(m->scalarSetElement, getVectorPayload(target), getScalarPayload(index), getScalarPayload(value));
else if (index->isDouble() and value->isDouble())
RUNTIME_CALL(m->doubleSetElement, getVectorPayload(target), getVectorPayload(index), getVectorPayload(value));
else
return false;
return true;
} else if (target->isCharacter() and index->isDouble() and value->isCharacter()) {
RUNTIME_CALL(m->characterSetElement, getVectorPayload(target), getVectorPayload(index), getVectorPayload(value));
return true;
} else {
return false;
}
}
bool Unboxing::genericC() {
// if all are double, or all are character, we can do special versions
CallInst * ci = reinterpret_cast<CallInst*>(ins);
bool canBeDV = true;
bool canBeCV = true;
std::vector<AType *> args_t;
for (unsigned i = 1; i < ci->getNumArgOperands(); ++i) {
AType * t = state().get(ci->getArgOperand(i));
canBeDV = canBeDV and t->isDouble();
canBeCV = canBeCV and t->isCharacter();
if (not canBeDV and not canBeCV)
return false;
args_t.push_back(t);
}
std::vector<llvm::Value *> args;
args.push_back(ci->getArgOperand(0)); // size
for (AType * t : args_t)
args.push_back(getVectorPayload(t));
AType * result_t;
if (canBeDV) {
result_t = updateAnalysis(CallInst::Create(m->doublec, args, "", ins), new AType(AType::Kind::DV));
} else {
assert (canBeCV);
result_t = updateAnalysis(CallInst::Create(m->characterc, args, "", ins), new AType(AType::Kind::CV));
}
ins->replaceAllUsesWith(box(result_t));
return true;
}
bool Unboxing::genericEval() {
AType * arg =state().get(ins->getOperand(1));
if (arg->isCharacter()) {
AType * result_t = updateAnalysis(
RUNTIME_CALL(m->characterEval, ins->getOperand(0), getVectorPayload(arg)),
new AType(AType::Kind::R));
ins->replaceAllUsesWith(state().getLocation(result_t));
return true;
} else {
return false;
}
}
bool Unboxing::runOnFunction(llvm::Function & f) {
//std::cout << "running Unboxing optimization..." << std::endl;
m = reinterpret_cast<RiftModule*>(f.getParent());
ta = &getAnalysis<TypeAnalysis>();
for (auto & b : f) {
auto i = b.begin();
while (i != b.end()) {
ins = i;
bool erase = false;
if (CallInst * ci = dyn_cast<CallInst>(ins)) {
StringRef s = ci->getCalledFunction()->getName();
if (s == "genericAdd") {
erase = genericAdd();
} else if (s == "genericSub") {
erase = genericArithmetic(Instruction::FSub, m->doubleSub);
} else if (s == "genericMul") {
erase = genericArithmetic(Instruction::FMul, m->doubleMul);
} else if (s == "genericDiv") {
erase = genericArithmetic(Instruction::FDiv, m->doubleDiv);
} else if (s == "genericLt") {
erase = genericRelational(FCmpInst::FCMP_OLT, m->doubleLt);
} else if (s == "genericGt") {
erase = genericRelational(FCmpInst::FCMP_OGT, m->doubleGt);
} else if (s == "genericEq") {
erase = genericEq();
} else if (s == "genericNeq") {
erase = genericNeq();
} else if (s == "genericGetElement") {
erase = genericGetElement();
} else if (s == "genericSetElement") {
erase = genericSetElement();
} else if (s == "c") {
erase = genericC();
} else if (s == "genericEval") {
erase = genericEval();
}
}
if (erase) {
llvm::Instruction * v = i;
++i;
state().erase(v);
v->eraseFromParent();
} else {
++i;
}
}
}
if (DEBUG) {
cout << "After unboxing optimization: --------------------------------" << endl;
f.dump();
cout << state() << endl;
}
return false;
}
} // namespace rift