Linter Demo Errors: 11Warnings: 64File: /home/fstrocco/Dart/dart/benchmark/compiler/lib/src/ssa/invoke_dynamic_specializers.dart // Copyright (c) 2013, the Dart 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. part of ssa; /** * [InvokeDynamicSpecializer] and its subclasses are helpers to * optimize intercepted dynamic calls. It knows what input types * would be beneficial for performance, and how to change a invoke * dynamic to a builtin instruction (e.g. HIndex, HBitNot). */ class InvokeDynamicSpecializer { const InvokeDynamicSpecializer(); TypeMask computeTypeFromInputTypes(HInvokeDynamic instruction, Compiler compiler) { Selector selector = instruction.selector; return TypeMaskFactory.inferredTypeForSelector(selector, compiler); } HInstruction tryConvertToBuiltin(HInvokeDynamic instruction, Compiler compiler) { return null; } Operation operation(ConstantSystem constantSystem) => null; static InvokeDynamicSpecializer lookupSpecializer(Selector selector) { if (selector.kind == SelectorKind.INDEX) { return selector.name == '[]' ? const IndexSpecializer() : const IndexAssignSpecializer(); } else if (selector.kind == SelectorKind.OPERATOR) { if (selector.name == 'unary-') { return const UnaryNegateSpecializer(); } else if (selector.name == '~') { return const BitNotSpecializer(); } else if (selector.name == '+') { return const AddSpecializer(); } else if (selector.name == '-') { return const SubtractSpecializer(); } else if (selector.name == '*') { return const MultiplySpecializer(); } else if (selector.name == '/') { return const DivideSpecializer(); } else if (selector.name == '~/') { return const TruncatingDivideSpecializer(); } else if (selector.name == '%') { return const ModuloSpecializer(); } else if (selector.name == '>>') { return const ShiftRightSpecializer(); } else if (selector.name == '<<') { return const ShiftLeftSpecializer(); } else if (selector.name == '&') { return const BitAndSpecializer(); } else if (selector.name == '|') { return const BitOrSpecializer(); } else if (selector.name == '^') { return const BitXorSpecializer(); } else if (selector.name == '==') { return const EqualsSpecializer(); } else if (selector.name == '<') { return const LessSpecializer(); } else if (selector.name == '<=') { return const LessEqualSpecializer(); } else if (selector.name == '>') { return const GreaterSpecializer(); } else if (selector.name == '>=') { return const GreaterEqualSpecializer(); } } else if (selector.kind == SelectorKind.CALL) { if (selector.argumentCount == 1 && selector.namedArguments.length == 0) { if (selector.name == 'codeUnitAt') { return const CodeUnitAtSpecializer(); } } } return const InvokeDynamicSpecializer(); } } class IndexAssignSpecializer extends InvokeDynamicSpecializer { const IndexAssignSpecializer(); HInstruction tryConvertToBuiltin(HInvokeDynamic instruction, Compiler compiler) { if (instruction.inputs[1].isMutableIndexable(compiler)) { if (!instruction.inputs[2].isInteger(compiler) && compiler.enableTypeAssertions) { // We want the right checked mode error. return null; } return new HIndexAssign(instruction.inputs[1], instruction.inputs[2], instruction.inputs[3], instruction.selector); } return null; } } class IndexSpecializer extends InvokeDynamicSpecializer { const IndexSpecializer(); HInstruction tryConvertToBuiltin(HInvokeDynamic instruction, Compiler compiler) { if (!instruction.inputs[1].isIndexablePrimitive(compiler)) return null; if (!instruction.inputs[2].isInteger(compiler) && compiler.enableTypeAssertions) { // We want the right checked mode error. return null; } TypeMask receiverType = instruction.getDartReceiver(compiler).instructionType; Selector refined = new TypedSelector(receiverType, instruction.selector, compiler.world); TypeMask type = TypeMaskFactory.inferredTypeForSelector(refined, compiler); return new HIndex( instruction.inputs[1], instruction.inputs[2], instruction.selector, type); } } class BitNotSpecializer extends InvokeDynamicSpecializer { const BitNotSpecializer(); UnaryOperation operation(ConstantSystem constantSystem) { return constantSystem.bitNot; } TypeMask computeTypeFromInputTypes(HInvokeDynamic instruction, Compiler compiler) { // All bitwise operations on primitive types either produce an // integer or throw an error. JavaScriptBackend backend = compiler.backend; if (instruction.inputs[1].isPrimitiveOrNull(compiler)) { return backend.uint32Type; } return super.computeTypeFromInputTypes(instruction, compiler); } HInstruction tryConvertToBuiltin(HInvokeDynamic instruction, Compiler compiler) { JavaScriptBackend backend = compiler.backend; HInstruction input = instruction.inputs[1]; if (input.isNumber(compiler)) { return new HBitNot(input, instruction.selector, computeTypeFromInputTypes(instruction, compiler)); } return null; } } class UnaryNegateSpecializer extends InvokeDynamicSpecializer { const UnaryNegateSpecializer(); UnaryOperation operation(ConstantSystem constantSystem) { return constantSystem.negate; } TypeMask computeTypeFromInputTypes(HInvokeDynamic instruction, Compiler compiler) { TypeMask operandType = instruction.inputs[1].instructionType; if (instruction.inputs[1].isNumberOrNull(compiler)) return operandType; return super.computeTypeFromInputTypes(instruction, compiler); } HInstruction tryConvertToBuiltin(HInvokeDynamic instruction, Compiler compiler) { HInstruction input = instruction.inputs[1]; if (input.isNumber(compiler)) { return new HNegate(input, instruction.selector, input.instructionType); } return null; } } abstract class BinaryArithmeticSpecializer extends InvokeDynamicSpecializer { const BinaryArithmeticSpecializer(); TypeMask computeTypeFromInputTypes(HInvokeDynamic instruction, Compiler compiler) { HInstruction left = instruction.inputs[1]; HInstruction right = instruction.inputs[2]; JavaScriptBackend backend = compiler.backend; if (left.isIntegerOrNull(compiler) && right.isIntegerOrNull(compiler)) { return backend.intType; } if (left.isNumberOrNull(compiler)) { if (left.isDoubleOrNull(compiler) || right.isDoubleOrNull(compiler)) { return backend.doubleType; } return backend.numType; } return super.computeTypeFromInputTypes(instruction, compiler); } bool isBuiltin(HInvokeDynamic instruction, Compiler compiler) { return instruction.inputs[1].isNumber(compiler) && instruction.inputs[2].isNumber(compiler); } HInstruction tryConvertToBuiltin(HInvokeDynamic instruction, Compiler compiler) { if (isBuiltin(instruction, compiler)) { HInstruction builtin = newBuiltinVariant(instruction, compiler); if (builtin != null) return builtin; // Even if there is no builtin equivalent instruction, we know // the instruction does not have any side effect, and that it // can be GVN'ed. clearAllSideEffects(instruction); } return null; } void clearAllSideEffects(HInstruction instruction) { instruction.sideEffects.clearAllSideEffects(); instruction.sideEffects.clearAllDependencies(); instruction.setUseGvn(); } bool inputsArePositiveIntegers(HInstruction instruction, Compiler compiler) { HInstruction left = instruction.inputs[1]; HInstruction right = instruction.inputs[2]; JavaScriptBackend backend = compiler.backend; return left.isPositiveIntegerOrNull(compiler) && right.isPositiveIntegerOrNull(compiler); } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler); Selector renameToOptimizedSelector(String name, Selector selector, Compiler compiler) { if (selector.name == name) return selector; JavaScriptBackend backend = compiler.backend; Selector newSelector = new Selector( SelectorKind.CALL, new Name(name, backend.interceptorsLibrary), new CallStructure(selector.argumentCount)); return selector.mask == null ? newSelector : new TypedSelector(selector.mask, newSelector, compiler.world); } } class AddSpecializer extends BinaryArithmeticSpecializer { const AddSpecializer(); TypeMask computeTypeFromInputTypes(HInvokeDynamic instruction, Compiler compiler) { if (inputsArePositiveIntegers(instruction, compiler)) { JavaScriptBackend backend = compiler.backend; return backend.positiveIntType; } return super.computeTypeFromInputTypes(instruction, compiler); } BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.add; } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler) { return new HAdd( instruction.inputs[1], instruction.inputs[2], instruction.selector, computeTypeFromInputTypes(instruction, compiler)); } } class DivideSpecializer extends BinaryArithmeticSpecializer { const DivideSpecializer(); BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.divide; } TypeMask computeTypeFromInputTypes(HInstruction instruction, Compiler compiler) { HInstruction left = instruction.inputs[1]; JavaScriptBackend backend = compiler.backend; if (left.isNumberOrNull(compiler)) { return backend.doubleType; } return super.computeTypeFromInputTypes(instruction, compiler); } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler) { JavaScriptBackend backend = compiler.backend; return new HDivide( instruction.inputs[1], instruction.inputs[2], instruction.selector, backend.doubleType); } } class ModuloSpecializer extends BinaryArithmeticSpecializer { const ModuloSpecializer(); TypeMask computeTypeFromInputTypes(HInvokeDynamic instruction, Compiler compiler) { if (inputsArePositiveIntegers(instruction, compiler)) { JavaScriptBackend backend = compiler.backend; return backend.positiveIntType; } return super.computeTypeFromInputTypes(instruction, compiler); } BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.modulo; } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler) { // Modulo cannot be mapped to the native operator (different semantics). return null; } } class MultiplySpecializer extends BinaryArithmeticSpecializer { const MultiplySpecializer(); BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.multiply; } TypeMask computeTypeFromInputTypes(HInvokeDynamic instruction, Compiler compiler) { if (inputsArePositiveIntegers(instruction, compiler)) { JavaScriptBackend backend = compiler.backend; return backend.positiveIntType; } return super.computeTypeFromInputTypes(instruction, compiler); } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler) { return new HMultiply( instruction.inputs[1], instruction.inputs[2], instruction.selector, computeTypeFromInputTypes(instruction, compiler)); } } class SubtractSpecializer extends BinaryArithmeticSpecializer { const SubtractSpecializer(); BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.subtract; } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler) { return new HSubtract( instruction.inputs[1], instruction.inputs[2], instruction.selector, computeTypeFromInputTypes(instruction, compiler)); } } class TruncatingDivideSpecializer extends BinaryArithmeticSpecializer { const TruncatingDivideSpecializer(); BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.truncatingDivide; } TypeMask computeTypeFromInputTypes(HInvokeDynamic instruction, Compiler compiler) { if (inputsArePositiveIntegers(instruction, compiler)) { JavaScriptBackend backend = compiler.backend; return backend.positiveIntType; } return super.computeTypeFromInputTypes(instruction, compiler); } bool isNotZero(HInstruction instruction, Compiler compiler) { if (!instruction.isConstantInteger()) return false; HConstant rightConstant = instruction; IntConstantValue intConstant = rightConstant.constant; int count = intConstant.primitiveValue; return count != 0; } HInstruction tryConvertToBuiltin(HInvokeDynamic instruction, Compiler compiler) { HInstruction left = instruction.inputs[1]; HInstruction right = instruction.inputs[2]; if (isBuiltin(instruction, compiler)) { if (right.isPositiveInteger(compiler) && isNotZero(right, compiler)) { if (left.isUInt31(compiler)) { return newBuiltinVariant(instruction, compiler); } // We can call _tdivFast because the rhs is a 32bit integer // and not 0, nor -1. instruction.selector = renameToOptimizedSelector( '_tdivFast', instruction.selector, compiler); } clearAllSideEffects(instruction); } return null; } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler) { return new HTruncatingDivide( instruction.inputs[1], instruction.inputs[2], instruction.selector, computeTypeFromInputTypes(instruction, compiler)); } } abstract class BinaryBitOpSpecializer extends BinaryArithmeticSpecializer { const BinaryBitOpSpecializer(); TypeMask computeTypeFromInputTypes(HInvokeDynamic instruction, Compiler compiler) { // All bitwise operations on primitive types either produce an // integer or throw an error. HInstruction left = instruction.inputs[1]; JavaScriptBackend backend = compiler.backend; if (left.isPrimitiveOrNull(compiler)) { return backend.uint32Type; } return super.computeTypeFromInputTypes(instruction, compiler); } bool argumentLessThan32(HInstruction instruction) { if (!instruction.isConstantInteger()) return false; HConstant rightConstant = instruction; IntConstantValue intConstant = rightConstant.constant; int count = intConstant.primitiveValue; return count >= 0 && count <= 31; } bool isPositive(HInstruction instruction, Compiler compiler) { // TODO: We should use the value range analysis. Currently, ranges // are discarded just after the analysis. return instruction.isPositiveInteger(compiler); } } class ShiftLeftSpecializer extends BinaryBitOpSpecializer { const ShiftLeftSpecializer(); BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.shiftLeft; } HInstruction tryConvertToBuiltin(HInvokeDynamic instruction, Compiler compiler) { HInstruction left = instruction.inputs[1]; HInstruction right = instruction.inputs[2]; if (left.isNumber(compiler)) { if (argumentLessThan32(right)) { return newBuiltinVariant(instruction, compiler); } // Even if there is no builtin equivalent instruction, we know // the instruction does not have any side effect, and that it // can be GVN'ed. clearAllSideEffects(instruction); Selector selector = instruction.selector; if (isPositive(right, compiler)) { instruction.selector = renameToOptimizedSelector( '_shlPositive', instruction.selector, compiler); } } return null; } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler) { JavaScriptBackend backend = compiler.backend; return new HShiftLeft( instruction.inputs[1], instruction.inputs[2], instruction.selector, computeTypeFromInputTypes(instruction, compiler)); } } class ShiftRightSpecializer extends BinaryBitOpSpecializer { const ShiftRightSpecializer(); TypeMask computeTypeFromInputTypes(HInvokeDynamic instruction, Compiler compiler) { HInstruction left = instruction.inputs[1]; HInstruction right = instruction.inputs[2]; JavaScriptBackend backend = compiler.backend; if (left.isUInt32(compiler)) return left.instructionType; return super.computeTypeFromInputTypes(instruction, compiler); } HInstruction tryConvertToBuiltin(HInvokeDynamic instruction, Compiler compiler) { HInstruction left = instruction.inputs[1]; HInstruction right = instruction.inputs[2]; if (left.isNumber(compiler)) { if (argumentLessThan32(right) && isPositive(left, compiler)) { return newBuiltinVariant(instruction, compiler); } // Even if there is no builtin equivalent instruction, we know // the instruction does not have any side effect, and that it // can be GVN'ed. clearAllSideEffects(instruction); if (isPositive(right, compiler) && isPositive(left, compiler)) { instruction.selector = renameToOptimizedSelector( '_shrBothPositive', instruction.selector, compiler); } else if (isPositive(left, compiler) && right.isNumber(compiler)) { instruction.selector = renameToOptimizedSelector( '_shrReceiverPositive', instruction.selector, compiler); } else if (isPositive(right, compiler)) { instruction.selector = renameToOptimizedSelector( '_shrOtherPositive', instruction.selector, compiler); } } return null; } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler) { JavaScriptBackend backend = compiler.backend; return new HShiftRight( instruction.inputs[1], instruction.inputs[2], instruction.selector, computeTypeFromInputTypes(instruction, compiler)); } BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.shiftRight; } } class BitOrSpecializer extends BinaryBitOpSpecializer { const BitOrSpecializer(); BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.bitOr; } TypeMask computeTypeFromInputTypes(HInvokeDynamic instruction, Compiler compiler) { HInstruction left = instruction.inputs[1]; HInstruction right = instruction.inputs[2]; JavaScriptBackend backend = compiler.backend; if (left.isUInt31(compiler) && right.isUInt31(compiler)) { return backend.uint31Type; } return super.computeTypeFromInputTypes(instruction, compiler); } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler) { JavaScriptBackend backend = compiler.backend; return new HBitOr( instruction.inputs[1], instruction.inputs[2], instruction.selector, computeTypeFromInputTypes(instruction, compiler)); } } class BitAndSpecializer extends BinaryBitOpSpecializer { const BitAndSpecializer(); BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.bitAnd; } TypeMask computeTypeFromInputTypes(HInvokeDynamic instruction, Compiler compiler) { HInstruction left = instruction.inputs[1]; HInstruction right = instruction.inputs[2]; JavaScriptBackend backend = compiler.backend; if (left.isPrimitiveOrNull(compiler) && (left.isUInt31(compiler) || right.isUInt31(compiler))) { return backend.uint31Type; } return super.computeTypeFromInputTypes(instruction, compiler); } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler) { JavaScriptBackend backend = compiler.backend; return new HBitAnd( instruction.inputs[1], instruction.inputs[2], instruction.selector, computeTypeFromInputTypes(instruction, compiler)); } } class BitXorSpecializer extends BinaryBitOpSpecializer { const BitXorSpecializer(); BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.bitXor; } TypeMask computeTypeFromInputTypes(HInvokeDynamic instruction, Compiler compiler) { HInstruction left = instruction.inputs[1]; HInstruction right = instruction.inputs[2]; JavaScriptBackend backend = compiler.backend; if (left.isUInt31(compiler) && right.isUInt31(compiler)) { return backend.uint31Type; } return super.computeTypeFromInputTypes(instruction, compiler); } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler) { JavaScriptBackend backend = compiler.backend; return new HBitXor( instruction.inputs[1], instruction.inputs[2], instruction.selector, computeTypeFromInputTypes(instruction, compiler)); } } abstract class RelationalSpecializer extends InvokeDynamicSpecializer { const RelationalSpecializer(); TypeMask computeTypeFromInputTypes(HInvokeDynamic instruction, Compiler compiler) { JavaScriptBackend backend = compiler.backend; if (instruction.inputs[1].isPrimitiveOrNull(compiler)) { return backend.boolType; } return super.computeTypeFromInputTypes(instruction, compiler); } HInstruction tryConvertToBuiltin(HInvokeDynamic instruction, Compiler compiler) { HInstruction left = instruction.inputs[1]; HInstruction right = instruction.inputs[2]; if (left.isNumber(compiler) && right.isNumber(compiler)) { return newBuiltinVariant(instruction, compiler); } return null; } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler); } class EqualsSpecializer extends RelationalSpecializer { const EqualsSpecializer(); HInstruction tryConvertToBuiltin(HInvokeDynamic instruction, Compiler compiler) { HInstruction left = instruction.inputs[1]; HInstruction right = instruction.inputs[2]; TypeMask instructionType = left.instructionType; if (right.isConstantNull() || left.isPrimitiveOrNull(compiler)) { return newBuiltinVariant(instruction, compiler); } World world = compiler.world; Selector selector = new TypedSelector(instructionType, instruction.selector, world); JavaScriptBackend backend = compiler.backend; Iterable matches = world.allFunctions.filter(selector); // This test relies the on `Object.==` and `Interceptor.==` always being // implemented because if the selector matches by subtype, it still will be // a regular object or an interceptor. if (matches.every(backend.isDefaultEqualityImplementation)) { return newBuiltinVariant(instruction, compiler); } return null; } BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.equal; } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler) { JavaScriptBackend backend = compiler.backend; return new HIdentity( instruction.inputs[1], instruction.inputs[2], instruction.selector, backend.boolType); } } class LessSpecializer extends RelationalSpecializer { const LessSpecializer(); BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.less; } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler) { JavaScriptBackend backend = compiler.backend; return new HLess( instruction.inputs[1], instruction.inputs[2], instruction.selector, backend.boolType); } } class GreaterSpecializer extends RelationalSpecializer { const GreaterSpecializer(); BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.greater; } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler) { JavaScriptBackend backend = compiler.backend; return new HGreater( instruction.inputs[1], instruction.inputs[2], instruction.selector, backend.boolType); } } class GreaterEqualSpecializer extends RelationalSpecializer { const GreaterEqualSpecializer(); BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.greaterEqual; } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler) { JavaScriptBackend backend = compiler.backend; return new HGreaterEqual( instruction.inputs[1], instruction.inputs[2], instruction.selector, backend.boolType); } } class LessEqualSpecializer extends RelationalSpecializer { const LessEqualSpecializer(); BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.lessEqual; } HInstruction newBuiltinVariant(HInvokeDynamic instruction, Compiler compiler) { JavaScriptBackend backend = compiler.backend; return new HLessEqual( instruction.inputs[1], instruction.inputs[2], instruction.selector, backend.boolType); } } class CodeUnitAtSpecializer extends InvokeDynamicSpecializer { const CodeUnitAtSpecializer(); BinaryOperation operation(ConstantSystem constantSystem) { return constantSystem.codeUnitAt; } HInstruction tryConvertToBuiltin(HInvokeDynamic instruction, Compiler compiler) { // TODO(sra): Implement a builtin HCodeUnitAt instruction and the same index // bounds checking optimizations as for HIndex. return null; } }