src/main/java/com/android/tools/r8/ir/code/InvokeMultiNewArray.java - r8 - Git at Google

 // Copyright (c) 2018, the R8 project authors. Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.
 package com.android.tools.r8.ir.code;

 import static com.android.tools.r8.optimize.MemberRebindingAnalysis.isClassTypeVisibleFromContext;

 import com.android.tools.r8.cf.LoadStoreHelper;
 import com.android.tools.r8.cf.TypeVerificationHelper;
 import com.android.tools.r8.cf.code.CfMultiANewArray;
 import com.android.tools.r8.errors.Unreachable;
 import com.android.tools.r8.graph.AppView;
 import com.android.tools.r8.graph.DexClass;
 import com.android.tools.r8.graph.DexType;
 import com.android.tools.r8.ir.analysis.AbstractError;
 import com.android.tools.r8.ir.analysis.type.Nullability;
 import com.android.tools.r8.ir.analysis.type.TypeElement;
 import com.android.tools.r8.ir.conversion.CfBuilder;
 import com.android.tools.r8.ir.conversion.DexBuilder;
 import com.android.tools.r8.ir.optimize.Inliner.ConstraintWithTarget;
 import com.android.tools.r8.ir.optimize.InliningConstraints;
 import com.android.tools.r8.utils.LongInterval;
 import java.util.List;

 public class InvokeMultiNewArray extends Invoke {

   private final DexType type;

   public InvokeMultiNewArray(DexType type, Value result, List<Value> arguments) {
     super(result, arguments);
     this.type = type;
   }

   @Override
   public int opcode() {
     return Opcodes.INVOKE_MULTI_NEW_ARRAY;
   }

   @Override
   public <T> T accept(InstructionVisitor<T> visitor) {
     return visitor.visit(this);
   }

   @Override
   public boolean isInvokeMultiNewArray() {
     return true;
   }

   @Override
   public InvokeMultiNewArray asInvokeMultiNewArray() {
     return this;
   }

   @Override
   public Type getType() {
     return Type.MULTI_NEW_ARRAY;
   }

   public DexType getArrayType() {
     return type;
   }

   @Override
   public DexType getReturnType() {
     return getArrayType();
   }

   @Override
   protected String getTypeString() {
     return "MultiNewArray";
   }

   @Override
   public boolean identicalNonValueNonPositionParts(Instruction other) {
     return other.isInvokeMultiNewArray() && type == other.asInvokeMultiNewArray().type;
   }

   @Override
   public ConstraintWithTarget inliningConstraint(
       InliningConstraints inliningConstraints, DexType invocationContext) {
     return inliningConstraints.forInvokeMultiNewArray(type, invocationContext);
   }

   @Override
   public TypeElement evaluate(AppView<?> appView) {
     return TypeElement.fromDexType(type, Nullability.definitelyNotNull(), appView);
   }

   @Override
   public boolean hasInvariantOutType() {
     return true;
   }

   @Override
   public DexType computeVerificationType(AppView<?> appView, TypeVerificationHelper helper) {
     return type;
   }

   @Override
   public void insertLoadAndStores(InstructionListIterator it, LoadStoreHelper helper) {
     helper.loadInValues(this, it);
     helper.storeOutValue(this, it);
   }

   @Override
   public void buildCf(CfBuilder builder) {
     builder.add(new CfMultiANewArray(type, arguments().size()));
   }

   @Override
   public void buildDex(DexBuilder builder) {
     throw new Unreachable("InvokeNewArray (non-empty) not supported when compiling to dex files.");
   }

   @Override
   public AbstractError instructionInstanceCanThrow(AppView<?> appView, DexType context) {
     DexType baseType = type.isArrayType() ? type.toBaseType(appView.dexItemFactory()) : type;
     if (baseType.isPrimitiveType()) {
       // Primitives types are known to be present and accessible.
       assert !type.isWideType() : "The array's contents must be single-word";
       return instructionInstanceCanThrowNegativeArraySizeException();
     }

     assert baseType.isReferenceType();

     if (baseType == context) {
       // The enclosing type is known to be present and accessible.
       return instructionInstanceCanThrowNegativeArraySizeException();
     }

     if (!appView.enableWholeProgramOptimizations()) {
       // Conservatively bail-out in D8, because we require whole program knowledge to determine if
       // the type is present and accessible.
       return AbstractError.top();
     }

     // Check if the type is guaranteed to be present.
     DexClass clazz = appView.definitionFor(baseType);
     if (clazz == null) {
       return AbstractError.top();
     }

     if (clazz.isLibraryClass()
         && !appView.dexItemFactory().libraryTypesAssumedToBePresent.contains(baseType)) {
       return AbstractError.top();
     }

     // Check if the type is guaranteed to be accessible.
     if (!isClassTypeVisibleFromContext(appView, context, clazz)) {
       return AbstractError.top();
     }

     // The type is known to be present and accessible.
     return instructionInstanceCanThrowNegativeArraySizeException();
   }

   private AbstractError instructionInstanceCanThrowNegativeArraySizeException() {
     boolean mayHaveNegativeArraySize = false;
     for (Value value : arguments()) {
       if (!value.hasValueRange()) {
         mayHaveNegativeArraySize = true;
         break;
       }
       LongInterval valueRange = value.getValueRange();
       if (valueRange.getMin() < 0) {
         mayHaveNegativeArraySize = true;
         break;
       }
     }
     return mayHaveNegativeArraySize ? AbstractError.top() : AbstractError.bottom();
   }

   @Override
   public boolean instructionMayHaveSideEffects(
       AppView<?> appView, DexType context, SideEffectAssumption assumption) {
     // Check if the instruction has a side effect on the locals environment.
     if (hasOutValue() && outValue().hasLocalInfo()) {
       assert appView.options().debug;
       return true;
     }

     return instructionInstanceCanThrow(appView, context).isThrowing();
   }

   @Override
   public boolean canBeDeadCode(AppView<?> appView, IRCode code) {
     return !instructionMayHaveSideEffects(appView, code.method.method.holder);
   }

   @Override
   public boolean instructionMayTriggerMethodInvocation(AppView<?> appView, DexType context) {
     return false;
   }
 }
	// Copyright (c) 2018, the R8 project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.
	package com.android.tools.r8.ir.code;

	import static com.android.tools.r8.optimize.MemberRebindingAnalysis.isClassTypeVisibleFromContext;

	import com.android.tools.r8.cf.LoadStoreHelper;
	import com.android.tools.r8.cf.TypeVerificationHelper;
	import com.android.tools.r8.cf.code.CfMultiANewArray;
	import com.android.tools.r8.errors.Unreachable;
	import com.android.tools.r8.graph.AppView;
	import com.android.tools.r8.graph.DexClass;
	import com.android.tools.r8.graph.DexType;
	import com.android.tools.r8.ir.analysis.AbstractError;
	import com.android.tools.r8.ir.analysis.type.Nullability;
	import com.android.tools.r8.ir.analysis.type.TypeElement;
	import com.android.tools.r8.ir.conversion.CfBuilder;
	import com.android.tools.r8.ir.conversion.DexBuilder;
	import com.android.tools.r8.ir.optimize.Inliner.ConstraintWithTarget;
	import com.android.tools.r8.ir.optimize.InliningConstraints;
	import com.android.tools.r8.utils.LongInterval;
	import java.util.List;

	public class InvokeMultiNewArray extends Invoke {

	private final DexType type;

	public InvokeMultiNewArray(DexType type, Value result, List<Value> arguments) {
	super(result, arguments);
	this.type = type;
	}

	@Override
	public int opcode() {
	return Opcodes.INVOKE_MULTI_NEW_ARRAY;
	}

	@Override
	public <T> T accept(InstructionVisitor<T> visitor) {
	return visitor.visit(this);
	}

	@Override
	public boolean isInvokeMultiNewArray() {
	return true;
	}

	@Override
	public InvokeMultiNewArray asInvokeMultiNewArray() {
	return this;
	}

	@Override
	public Type getType() {
	return Type.MULTI_NEW_ARRAY;
	}

	public DexType getArrayType() {
	return type;
	}

	@Override
	public DexType getReturnType() {
	return getArrayType();
	}

	@Override
	protected String getTypeString() {
	return "MultiNewArray";
	}

	@Override
	public boolean identicalNonValueNonPositionParts(Instruction other) {
	return other.isInvokeMultiNewArray() && type == other.asInvokeMultiNewArray().type;
	}

	@Override
	public ConstraintWithTarget inliningConstraint(
	InliningConstraints inliningConstraints, DexType invocationContext) {
	return inliningConstraints.forInvokeMultiNewArray(type, invocationContext);
	}

	@Override
	public TypeElement evaluate(AppView<?> appView) {
	return TypeElement.fromDexType(type, Nullability.definitelyNotNull(), appView);
	}

	@Override
	public boolean hasInvariantOutType() {
	return true;
	}

	@Override
	public DexType computeVerificationType(AppView<?> appView, TypeVerificationHelper helper) {
	return type;
	}

	@Override
	public void insertLoadAndStores(InstructionListIterator it, LoadStoreHelper helper) {
	helper.loadInValues(this, it);
	helper.storeOutValue(this, it);
	}

	@Override
	public void buildCf(CfBuilder builder) {
	builder.add(new CfMultiANewArray(type, arguments().size()));
	}

	@Override
	public void buildDex(DexBuilder builder) {
	throw new Unreachable("InvokeNewArray (non-empty) not supported when compiling to dex files.");
	}

	@Override
	public AbstractError instructionInstanceCanThrow(AppView<?> appView, DexType context) {
	DexType baseType = type.isArrayType() ? type.toBaseType(appView.dexItemFactory()) : type;
	if (baseType.isPrimitiveType()) {
	// Primitives types are known to be present and accessible.
	assert !type.isWideType() : "The array's contents must be single-word";
	return instructionInstanceCanThrowNegativeArraySizeException();
	}

	assert baseType.isReferenceType();

	if (baseType == context) {
	// The enclosing type is known to be present and accessible.
	return instructionInstanceCanThrowNegativeArraySizeException();
	}

	if (!appView.enableWholeProgramOptimizations()) {
	// Conservatively bail-out in D8, because we require whole program knowledge to determine if
	// the type is present and accessible.
	return AbstractError.top();
	}

	// Check if the type is guaranteed to be present.
	DexClass clazz = appView.definitionFor(baseType);
	if (clazz == null) {
	return AbstractError.top();
	}

	if (clazz.isLibraryClass()
	&& !appView.dexItemFactory().libraryTypesAssumedToBePresent.contains(baseType)) {
	return AbstractError.top();
	}

	// Check if the type is guaranteed to be accessible.
	if (!isClassTypeVisibleFromContext(appView, context, clazz)) {
	return AbstractError.top();
	}

	// The type is known to be present and accessible.
	return instructionInstanceCanThrowNegativeArraySizeException();
	}

	private AbstractError instructionInstanceCanThrowNegativeArraySizeException() {
	boolean mayHaveNegativeArraySize = false;
	for (Value value : arguments()) {
	if (!value.hasValueRange()) {
	mayHaveNegativeArraySize = true;
	break;
	}
	LongInterval valueRange = value.getValueRange();
	if (valueRange.getMin() < 0) {
	mayHaveNegativeArraySize = true;
	break;
	}
	}
	return mayHaveNegativeArraySize ? AbstractError.top() : AbstractError.bottom();
	}

	@Override
	public boolean instructionMayHaveSideEffects(
	AppView<?> appView, DexType context, SideEffectAssumption assumption) {
	// Check if the instruction has a side effect on the locals environment.
	if (hasOutValue() && outValue().hasLocalInfo()) {
	assert appView.options().debug;
	return true;
	}

	return instructionInstanceCanThrow(appView, context).isThrowing();
	}

	@Override
	public boolean canBeDeadCode(AppView<?> appView, IRCode code) {
	return !instructionMayHaveSideEffects(appView, code.method.method.holder);
	}

	@Override
	public boolean instructionMayTriggerMethodInvocation(AppView<?> appView, DexType context) {
	return false;
	}
	}