compiler/optimizing/escape.cc - LeafOS-Project/android_art - Gitiles

 /*
  * 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.
  */

 #include "escape.h"

 #include "nodes.h"

 namespace art HIDDEN {

 void VisitEscapes(HInstruction* reference, EscapeVisitor& escape_visitor) {
   // References not allocated in the method are intrinsically escaped.
   // Finalizable references are always escaping since they end up in FinalizerQueues.
   if ((!reference->IsNewInstance() && !reference->IsNewArray()) ||
       (reference->IsNewInstance() && reference->AsNewInstance()->IsFinalizable())) {
     if (!escape_visitor(reference)) {
       return;
     }
   }

   // Visit all uses to determine if this reference can escape into the heap,
   // a method call, an alias, etc.
   for (const HUseListNode<HInstruction*>& use : reference->GetUses()) {
     HInstruction* user = use.GetUser();
     if (user->IsBoundType() || user->IsNullCheck()) {
       // BoundType shouldn't normally be necessary for an allocation. Just be conservative
       // for the uncommon cases. Similarly, null checks are eventually eliminated for explicit
       // allocations, but if we see one before it is simplified, assume an alias.
       if (!escape_visitor(user)) {
         return;
       }
     } else if (user->IsCheckCast() || user->IsInstanceOf()) {
       // TODO Currently we'll just be conservative for Partial LSE and avoid
       // optimizing check-cast things since we'd need to add blocks otherwise.
       // Normally the simplifier should be able to just get rid of them
       if (!escape_visitor(user)) {
         return;
       }
     } else if (user->IsPhi() ||
                user->IsSelect() ||
                (user->IsInvoke() && user->GetSideEffects().DoesAnyWrite()) ||
                (user->IsInstanceFieldSet() && (reference == user->InputAt(1))) ||
                (user->IsUnresolvedInstanceFieldSet() && (reference == user->InputAt(1))) ||
                (user->IsStaticFieldSet() && (reference == user->InputAt(1))) ||
                (user->IsUnresolvedStaticFieldSet() && (reference == user->InputAt(0))) ||
                (user->IsArraySet() && (reference == user->InputAt(2)))) {
       // The reference is merged to HPhi/HSelect, passed to a callee, or stored to heap.
       // Hence, the reference is no longer the only name that can refer to its value.
       if (!escape_visitor(user)) {
         return;
       }
     } else if ((user->IsUnresolvedInstanceFieldGet() && (reference == user->InputAt(0))) ||
                (user->IsUnresolvedInstanceFieldSet() && (reference == user->InputAt(0)))) {
       // The field is accessed in an unresolved way. We mark the object as a non-singleton.
       // Note that we could optimize this case and still perform some optimizations until
       // we hit the unresolved access, but the conservative assumption is the simplest.
       if (!escape_visitor(user)) {
         return;
       }
     } else if (user->IsReturn()) {
       if (!escape_visitor(user)) {
         return;
       }
     }
   }

   // Look at the environment uses if it's for HDeoptimize. Other environment uses are fine,
   // as long as client optimizations that rely on this information are disabled for debuggable.
   for (const HUseListNode<HEnvironment*>& use : reference->GetEnvUses()) {
     HEnvironment* user = use.GetUser();
     if (user->GetHolder()->IsDeoptimize()) {
       if (!escape_visitor(user->GetHolder())) {
         return;
       }
     }
   }
 }

 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) {
   // For references not allocated in the method, don't assume anything.
   if (!reference->IsNewInstance() && !reference->IsNewArray()) {
     *is_singleton = false;
     *is_singleton_and_not_returned = false;
     *is_singleton_and_not_deopt_visible = false;
     return;
   }
   // Assume the best until proven otherwise.
   *is_singleton = true;
   *is_singleton_and_not_returned = true;
   *is_singleton_and_not_deopt_visible = true;

   if (reference->IsNewInstance() && reference->AsNewInstance()->IsFinalizable()) {
     // Finalizable reference is treated as being returned in the end.
     *is_singleton_and_not_returned = false;
   }

   LambdaEscapeVisitor visitor([&](HInstruction* escape) -> bool {
     if (escape == reference || no_escape(reference, escape)) {
       // Ignore already known inherent escapes and escapes client supplied
       // analysis knows is safe. Continue on.
       return true;
     } else if (escape->IsInstanceOf() || escape->IsCheckCast()) {
       // Ignore since these are not relevant for regular LSE.
       return true;
     } else if (escape->IsReturn()) {
       // value is returned but might still be singleton. Continue on.
       *is_singleton_and_not_returned = false;
       return true;
     } else if (escape->IsDeoptimize()) {
       // value escapes through deopt but might still be singleton. Continue on.
       *is_singleton_and_not_deopt_visible = false;
       return true;
     } else {
       // Real escape. All knowledge about what happens to the value lost. We can
       // stop here.
       *is_singleton = false;
       *is_singleton_and_not_returned = false;
       *is_singleton_and_not_deopt_visible = false;
       return false;
     }
   });
   VisitEscapes(reference, visitor);
 }

 bool DoesNotEscape(HInstruction* reference, NoEscapeCheck& no_escape) {
   bool is_singleton = false;
   bool is_singleton_and_not_returned = false;
   bool is_singleton_and_not_deopt_visible = false;  // not relevant for escape
   CalculateEscape(reference,
                   no_escape,
                   &is_singleton,
                   &is_singleton_and_not_returned,
                   &is_singleton_and_not_deopt_visible);
   return is_singleton_and_not_returned;
 }

 }  // namespace art
	/*
	* 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.
	*/

	#include "escape.h"

	#include "nodes.h"

	namespace art HIDDEN {

	void VisitEscapes(HInstruction* reference, EscapeVisitor& escape_visitor) {
	// References not allocated in the method are intrinsically escaped.
	// Finalizable references are always escaping since they end up in FinalizerQueues.
	if ((!reference->IsNewInstance() && !reference->IsNewArray()) \|\|
	(reference->IsNewInstance() && reference->AsNewInstance()->IsFinalizable())) {
	if (!escape_visitor(reference)) {
	return;
	}
	}

	// Visit all uses to determine if this reference can escape into the heap,
	// a method call, an alias, etc.
	for (const HUseListNode<HInstruction*>& use : reference->GetUses()) {
	HInstruction* user = use.GetUser();
	if (user->IsBoundType() \|\| user->IsNullCheck()) {
	// BoundType shouldn't normally be necessary for an allocation. Just be conservative
	// for the uncommon cases. Similarly, null checks are eventually eliminated for explicit
	// allocations, but if we see one before it is simplified, assume an alias.
	if (!escape_visitor(user)) {
	return;
	}
	} else if (user->IsCheckCast() \|\| user->IsInstanceOf()) {
	// TODO Currently we'll just be conservative for Partial LSE and avoid
	// optimizing check-cast things since we'd need to add blocks otherwise.
	// Normally the simplifier should be able to just get rid of them
	if (!escape_visitor(user)) {
	return;
	}
	} else if (user->IsPhi() \|\|
	user->IsSelect() \|\|
	(user->IsInvoke() && user->GetSideEffects().DoesAnyWrite()) \|\|
	(user->IsInstanceFieldSet() && (reference == user->InputAt(1))) \|\|
	(user->IsUnresolvedInstanceFieldSet() && (reference == user->InputAt(1))) \|\|
	(user->IsStaticFieldSet() && (reference == user->InputAt(1))) \|\|
	(user->IsUnresolvedStaticFieldSet() && (reference == user->InputAt(0))) \|\|
	(user->IsArraySet() && (reference == user->InputAt(2)))) {
	// The reference is merged to HPhi/HSelect, passed to a callee, or stored to heap.
	// Hence, the reference is no longer the only name that can refer to its value.
	if (!escape_visitor(user)) {
	return;
	}
	} else if ((user->IsUnresolvedInstanceFieldGet() && (reference == user->InputAt(0))) \|\|
	(user->IsUnresolvedInstanceFieldSet() && (reference == user->InputAt(0)))) {
	// The field is accessed in an unresolved way. We mark the object as a non-singleton.
	// Note that we could optimize this case and still perform some optimizations until
	// we hit the unresolved access, but the conservative assumption is the simplest.
	if (!escape_visitor(user)) {
	return;
	}
	} else if (user->IsReturn()) {
	if (!escape_visitor(user)) {
	return;
	}
	}
	}

	// Look at the environment uses if it's for HDeoptimize. Other environment uses are fine,
	// as long as client optimizations that rely on this information are disabled for debuggable.
	for (const HUseListNode<HEnvironment*>& use : reference->GetEnvUses()) {
	HEnvironment* user = use.GetUser();
	if (user->GetHolder()->IsDeoptimize()) {
	if (!escape_visitor(user->GetHolder())) {
	return;
	}
	}
	}
	}

	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) {
	// For references not allocated in the method, don't assume anything.
	if (!reference->IsNewInstance() && !reference->IsNewArray()) {
	*is_singleton = false;
	*is_singleton_and_not_returned = false;
	*is_singleton_and_not_deopt_visible = false;
	return;
	}
	// Assume the best until proven otherwise.
	*is_singleton = true;
	*is_singleton_and_not_returned = true;
	*is_singleton_and_not_deopt_visible = true;

	if (reference->IsNewInstance() && reference->AsNewInstance()->IsFinalizable()) {
	// Finalizable reference is treated as being returned in the end.
	*is_singleton_and_not_returned = false;
	}

	LambdaEscapeVisitor visitor([&](HInstruction* escape) -> bool {
	if (escape == reference \|\| no_escape(reference, escape)) {
	// Ignore already known inherent escapes and escapes client supplied
	// analysis knows is safe. Continue on.
	return true;
	} else if (escape->IsInstanceOf() \|\| escape->IsCheckCast()) {
	// Ignore since these are not relevant for regular LSE.
	return true;
	} else if (escape->IsReturn()) {
	// value is returned but might still be singleton. Continue on.
	*is_singleton_and_not_returned = false;
	return true;
	} else if (escape->IsDeoptimize()) {
	// value escapes through deopt but might still be singleton. Continue on.
	*is_singleton_and_not_deopt_visible = false;
	return true;
	} else {
	// Real escape. All knowledge about what happens to the value lost. We can
	// stop here.
	*is_singleton = false;
	*is_singleton_and_not_returned = false;
	*is_singleton_and_not_deopt_visible = false;
	return false;
	}
	});
	VisitEscapes(reference, visitor);
	}

	bool DoesNotEscape(HInstruction* reference, NoEscapeCheck& no_escape) {
	bool is_singleton = false;
	bool is_singleton_and_not_returned = false;
	bool is_singleton_and_not_deopt_visible = false; // not relevant for escape
	CalculateEscape(reference,
	no_escape,
	&is_singleton,
	&is_singleton_and_not_returned,
	&is_singleton_and_not_deopt_visible);
	return is_singleton_and_not_returned;
	}

	} // namespace art