/* * Copyright (C) 2016 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifndef ART_COMPILER_OPTIMIZING_ESCAPE_H_ #define ART_COMPILER_OPTIMIZING_ESCAPE_H_ #include "base/macros.h" namespace art HIDDEN { class HInstruction; /* * Methods related to escape analysis, i.e. determining whether an object * allocation is visible outside ('escapes') its immediate method context. */ // A visitor for seeing all instructions escape analysis considers escaping. // Called with each user of the reference passed to 'VisitEscapes'. Return true // to continue iteration and false to stop. class EscapeVisitor { public: virtual ~EscapeVisitor() {} virtual bool Visit(HInstruction* escape) = 0; bool operator()(HInstruction* user) { return Visit(user); } }; // An explicit EscapeVisitor for lambdas template class LambdaEscapeVisitor final : public EscapeVisitor { public: explicit LambdaEscapeVisitor(F f) : func_(f) {} bool Visit(HInstruction* escape) override { return func_(escape); } private: F func_; }; // This functor is used with the escape-checking functions. If the NoEscape // function returns true escape analysis will consider 'user' to not have // escaped 'reference'. This allows clients with additional information to // supplement the escape-analysis. If the NoEscape function returns false then // the normal escape-checking code will be used to determine whether or not // 'reference' escapes. class NoEscapeCheck { public: virtual ~NoEscapeCheck() {} virtual bool NoEscape(HInstruction* reference, HInstruction* user) = 0; bool operator()(HInstruction* ref, HInstruction* user) { return NoEscape(ref, user); } }; // An explicit NoEscapeCheck for use with c++ lambdas. template class LambdaNoEscapeCheck final : public NoEscapeCheck { public: explicit LambdaNoEscapeCheck(F f) : func_(f) {} bool NoEscape(HInstruction* ref, HInstruction* user) override { return func_(ref, user); } private: F func_; }; /* * Performs escape analysis on the given instruction, typically a reference to an * allocation. The method assigns true to parameter 'is_singleton' if the reference * is the only name that can refer to its value during the lifetime of the method, * meaning that the reference is not aliased with something else, is not stored to * heap memory, and not passed to another method. In addition, the method assigns * true to parameter 'is_singleton_and_not_returned' if the reference is a singleton * and not returned to the caller and to parameter 'is_singleton_and_not_deopt_visible' * if the reference is a singleton and not used as an environment local of an * HDeoptimize instruction (clients of the final value must run after BCE to ensure * all such instructions have been introduced already). * * Note that being visible to a HDeoptimize instruction does not count for ordinary * escape analysis, since switching between compiled code and interpreted code keeps * non escaping references restricted to the lifetime of the method and the thread * executing it. This property only concerns optimizations that are interested in * escape analysis with respect to the *compiled* code (such as LSE). * * When set, the no_escape function is applied to any use of the allocation instruction * prior to any built-in escape analysis. This allows clients to define better escape * analysis in certain case-specific circumstances. If 'no_escape(reference, user)' * returns true, the user is assumed *not* to cause any escape right away. The return * value false means the client cannot provide a definite answer and built-in escape * analysis is applied to the user instead. */ void CalculateEscape(HInstruction* reference, NoEscapeCheck& no_escape, /*out*/ bool* is_singleton, /*out*/ bool* is_singleton_and_not_returned, /*out*/ bool* is_singleton_and_not_deopt_visible); inline void CalculateEscape(HInstruction* reference, bool (*no_escape_fn)(HInstruction*, HInstruction*), /*out*/ bool* is_singleton, /*out*/ bool* is_singleton_and_not_returned, /*out*/ bool* is_singleton_and_not_deopt_visible) { LambdaNoEscapeCheck esc(no_escape_fn); LambdaNoEscapeCheck noop_esc([](HInstruction*, HInstruction*) { return false; }); CalculateEscape(reference, no_escape_fn == nullptr ? static_cast(noop_esc) : esc, is_singleton, is_singleton_and_not_returned, is_singleton_and_not_deopt_visible); } /* * Performs escape analysis and visits each escape of the reference. Does not try to calculate any * overall information about the method. Escapes are calculated in the same way as CalculateEscape. * * The escape_visitor should return true to continue visiting, false otherwise. */ void VisitEscapes(HInstruction* reference, EscapeVisitor& escape_visitor); /* * Convenience method for testing the singleton and not returned properties at once. * Callers should be aware that this method invokes the full analysis at each call. */ bool DoesNotEscape(HInstruction* reference, NoEscapeCheck& no_escape); inline bool DoesNotEscape(HInstruction* reference, bool (*no_escape_fn)(HInstruction*, HInstruction*)) { LambdaNoEscapeCheck esc(no_escape_fn); return DoesNotEscape(reference, esc); } } // namespace art #endif // ART_COMPILER_OPTIMIZING_ESCAPE_H_