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/*
* Copyright (C) 2016 Yusuke Suzuki <utatane.tea@gmail.com>
* Copyright (C) 2016 Apple Inc. All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY APPLE INC. AND ITS CONTRIBUTORS ``AS IS''
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO,
* THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL APPLE INC. OR ITS CONTRIBUTORS
* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF
* THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "config.h"
#include "BytecodeGeneratorification.h"
#include "BytecodeLivenessAnalysisInlines.h"
#include "BytecodeRewriter.h"
#include "BytecodeUseDef.h"
#include "IdentifierInlines.h"
#include "InterpreterInlines.h"
#include "JSCInlines.h"
#include "JSCJSValueInlines.h"
#include "JSGeneratorFunction.h"
#include "StrongInlines.h"
#include "UnlinkedCodeBlock.h"
#include <wtf/Optional.h>
namespace JSC {
struct YieldData {
size_t point { 0 };
int argument { 0 };
FastBitVector liveness;
};
class BytecodeGeneratorification {
public:
typedef Vector<YieldData> Yields;
BytecodeGeneratorification(UnlinkedCodeBlock* codeBlock, UnlinkedCodeBlock::UnpackedInstructions& instructions, SymbolTable* generatorFrameSymbolTable, int generatorFrameSymbolTableIndex)
: m_graph(codeBlock, instructions)
, m_generatorFrameSymbolTable(*codeBlock->vm(), generatorFrameSymbolTable)
, m_generatorFrameSymbolTableIndex(generatorFrameSymbolTableIndex)
{
for (BytecodeBasicBlock* block : m_graph) {
for (unsigned bytecodeOffset : block->offsets()) {
const UnlinkedInstruction* pc = &m_graph.instructions()[bytecodeOffset];
switch (pc->u.opcode) {
case op_enter: {
m_enterPoint = bytecodeOffset;
break;
}
case op_yield: {
unsigned liveCalleeLocalsIndex = pc[2].u.index;
if (liveCalleeLocalsIndex >= m_yields.size())
m_yields.resize(liveCalleeLocalsIndex + 1);
YieldData& data = m_yields[liveCalleeLocalsIndex];
data.point = bytecodeOffset;
data.argument = pc[3].u.operand;
break;
}
default:
break;
}
}
}
}
struct Storage {
Identifier identifier;
unsigned identifierIndex;
ScopeOffset scopeOffset;
};
void run();
BytecodeGraph<UnlinkedCodeBlock>& graph() { return m_graph; }
const Yields& yields() const
{
return m_yields;
}
Yields& yields()
{
return m_yields;
}
unsigned enterPoint() const
{
return m_enterPoint;
}
private:
Storage storageForGeneratorLocal(unsigned index)
{
// We assign a symbol to a register. There is one-on-one corresponding between a register and a symbol.
// By doing so, we allocate the specific storage to save the given register.
// This allow us not to save all the live registers even if the registers are not overwritten from the previous resuming time.
// It means that, the register can be retrieved even if the immediate previous op_save does not save it.
if (m_storages.size() <= index)
m_storages.resize(index + 1);
if (std::optional<Storage> storage = m_storages[index])
return *storage;
UnlinkedCodeBlock* codeBlock = m_graph.codeBlock();
Identifier identifier = Identifier::fromUid(PrivateName());
unsigned identifierIndex = codeBlock->numberOfIdentifiers();
codeBlock->addIdentifier(identifier);
ScopeOffset scopeOffset = m_generatorFrameSymbolTable->takeNextScopeOffset(NoLockingNecessary);
m_generatorFrameSymbolTable->set(NoLockingNecessary, identifier.impl(), SymbolTableEntry(VarOffset(scopeOffset)));
Storage storage = {
identifier,
identifierIndex,
scopeOffset
};
m_storages[index] = storage;
return storage;
}
unsigned m_enterPoint { 0 };
BytecodeGraph<UnlinkedCodeBlock> m_graph;
Vector<std::optional<Storage>> m_storages;
Yields m_yields;
Strong<SymbolTable> m_generatorFrameSymbolTable;
int m_generatorFrameSymbolTableIndex;
};
class GeneratorLivenessAnalysis : public BytecodeLivenessPropagation<GeneratorLivenessAnalysis> {
public:
GeneratorLivenessAnalysis(BytecodeGeneratorification& generatorification)
: m_generatorification(generatorification)
{
}
template<typename Functor>
void computeDefsForBytecodeOffset(UnlinkedCodeBlock* codeBlock, OpcodeID opcodeID, UnlinkedInstruction* instruction, FastBitVector&, const Functor& functor)
{
JSC::computeDefsForBytecodeOffset(codeBlock, opcodeID, instruction, functor);
}
template<typename Functor>
void computeUsesForBytecodeOffset(UnlinkedCodeBlock* codeBlock, OpcodeID opcodeID, UnlinkedInstruction* instruction, FastBitVector&, const Functor& functor)
{
JSC::computeUsesForBytecodeOffset(codeBlock, opcodeID, instruction, functor);
}
void run()
{
// Perform modified liveness analysis to determine which locals are live at the merge points.
// This produces the conservative results for the question, "which variables should be saved and resumed?".
runLivenessFixpoint(m_generatorification.graph());
for (YieldData& data : m_generatorification.yields())
data.liveness = getLivenessInfoAtBytecodeOffset(m_generatorification.graph(), data.point + opcodeLength(op_yield));
}
private:
BytecodeGeneratorification& m_generatorification;
};
void BytecodeGeneratorification::run()
{
// We calculate the liveness at each merge point. This gives us the information which registers should be saved and resumed conservatively.
{
GeneratorLivenessAnalysis pass(*this);
pass.run();
}
UnlinkedCodeBlock* codeBlock = m_graph.codeBlock();
BytecodeRewriter rewriter(m_graph);
// Setup the global switch for the generator.
{
unsigned nextToEnterPoint = enterPoint() + opcodeLength(op_enter);
unsigned switchTableIndex = m_graph.codeBlock()->numberOfSwitchJumpTables();
VirtualRegister state = virtualRegisterForArgument(static_cast<int32_t>(JSGeneratorFunction::GeneratorArgument::State));
auto& jumpTable = m_graph.codeBlock()->addSwitchJumpTable();
jumpTable.min = 0;
jumpTable.branchOffsets.resize(m_yields.size() + 1);
jumpTable.branchOffsets.fill(0);
jumpTable.add(0, nextToEnterPoint);
for (unsigned i = 0; i < m_yields.size(); ++i)
jumpTable.add(i + 1, m_yields[i].point);
rewriter.insertFragmentBefore(nextToEnterPoint, [&](BytecodeRewriter::Fragment& fragment) {
fragment.appendInstruction(op_switch_imm, switchTableIndex, nextToEnterPoint, state.offset());
});
}
for (const YieldData& data : m_yields) {
VirtualRegister scope = virtualRegisterForArgument(static_cast<int32_t>(JSGeneratorFunction::GeneratorArgument::Frame));
// Emit save sequence.
rewriter.insertFragmentBefore(data.point, [&](BytecodeRewriter::Fragment& fragment) {
data.liveness.forEachSetBit([&](size_t index) {
VirtualRegister operand = virtualRegisterForLocal(index);
Storage storage = storageForGeneratorLocal(index);
fragment.appendInstruction(
op_put_to_scope,
scope.offset(), // scope
storage.identifierIndex, // identifier
operand.offset(), // value
GetPutInfo(DoNotThrowIfNotFound, LocalClosureVar, InitializationMode::NotInitialization).operand(), // info
m_generatorFrameSymbolTableIndex, // symbol table constant index
storage.scopeOffset.offset() // scope offset
);
});
// Insert op_ret just after save sequence.
fragment.appendInstruction(op_ret, data.argument);
});
// Emit resume sequence.
rewriter.insertFragmentAfter(data.point, [&](BytecodeRewriter::Fragment& fragment) {
data.liveness.forEachSetBit([&](size_t index) {
VirtualRegister operand = virtualRegisterForLocal(index);
Storage storage = storageForGeneratorLocal(index);
UnlinkedValueProfile profile = codeBlock->addValueProfile();
fragment.appendInstruction(
op_get_from_scope,
operand.offset(), // dst
scope.offset(), // scope
storage.identifierIndex, // identifier
GetPutInfo(DoNotThrowIfNotFound, LocalClosureVar, InitializationMode::NotInitialization).operand(), // info
0, // local scope depth
storage.scopeOffset.offset(), // scope offset
profile // profile
);
});
});
// Clip the unnecessary bytecodes.
rewriter.removeBytecode(data.point);
}
rewriter.execute();
}
void performGeneratorification(UnlinkedCodeBlock* codeBlock, UnlinkedCodeBlock::UnpackedInstructions& instructions, SymbolTable* generatorFrameSymbolTable, int generatorFrameSymbolTableIndex)
{
BytecodeGeneratorification pass(codeBlock, instructions, generatorFrameSymbolTable, generatorFrameSymbolTableIndex);
pass.run();
}
} // namespace JSC
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