source/opt/copy_prop_arrays.h - external/github.com/KhronosGroup/SPIRV-Tools - Git at Google

 // Copyright (c) 2018 Google LLC.
 //
 // 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 SOURCE_OPT_COPY_PROP_ARRAYS_H_
 #define SOURCE_OPT_COPY_PROP_ARRAYS_H_

 #include <memory>
 #include <vector>

 #include "source/opt/mem_pass.h"

 namespace spvtools {
 namespace opt {

 // This pass implements a simple array copy propagation.  It does not do a full
 // array data flow.  It looks for simple cases that meet the following
 // conditions:
 //
 // 1) The source must never be stored to.
 // 2) The target must be stored to exactly once.
 // 3) The store to the target must be a store to the entire array, and be a
 // copy of the entire source.
 // 4) All loads of the target must be dominated by the store.
 //
 // The hard part is keeping all of the types correct.  We do not want to
 // have to do too large a search to update everything, which may not be
 // possible, do we give up if we see any instruction that might be hard to
 // update.

 class CopyPropagateArrays : public MemPass {
  public:
   const char* name() const override { return "copy-propagate-arrays"; }
   Status Process() override;

   IRContext::Analysis GetPreservedAnalyses() override {
     return IRContext::kAnalysisDefUse | IRContext::kAnalysisCFG |
            IRContext::kAnalysisInstrToBlockMapping |
            IRContext::kAnalysisLoopAnalysis | IRContext::kAnalysisDecorations |
            IRContext::kAnalysisDominatorAnalysis | IRContext::kAnalysisNameMap |
            IRContext::kAnalysisConstants | IRContext::kAnalysisTypes;
   }

  private:
   // The class used to identify a particular memory object.  This memory object
   // will be owned by a particular variable, meaning that the memory is part of
   // that variable.  It could be the entire variable or a member of the
   // variable.
   class MemoryObject {
    public:
     // Construction a memory object that is owned by |var_inst|.  The iterator
     // |begin| and |end| traverse a container of integers that identify which
     // member of |var_inst| this memory object will represent.  These integers
     // are interpreted the same way they would be in an |OpAccessChain|
     // instruction.
     template <class iterator>
     MemoryObject(Instruction* var_inst, iterator begin, iterator end);

     // Change |this| to now point to the member identified by |access_chain|
     // (starting from the current member).  The elements in |access_chain| are
     // interpreted the same as the indices in the |OpAccessChain|
     // instruction.
     void GetMember(const std::vector<uint32_t>& access_chain);

     // Change |this| to now represent the first enclosing object to which it
     // belongs.  (Remove the last element off the access_chain). It is invalid
     // to call this function if |this| does not represent a member of its owner.
     void GetParent() {
       assert(IsMember());
       access_chain_.pop_back();
     }

     // Returns true if |this| represents a member of its owner, and not the
     // entire variable.
     bool IsMember() const { return !access_chain_.empty(); }

     // Returns the number of members in the object represented by |this|.  If
     // |this| does not represent a composite type, the return value will be 0.
     uint32_t GetNumberOfMembers();

     // Returns the owning variable that the memory object is contained in.
     Instruction* GetVariable() const { return variable_inst_; }

     // Returns a vector of integers that can be used to access the specific
     // member that |this| represents starting from the owning variable.  These
     // values are to be interpreted the same way the indices are in an
     // |OpAccessChain| instruction.
     const std::vector<uint32_t>& AccessChain() const { return access_chain_; }

     // Returns the type id of the pointer type that can be used to point to this
     // memory object.
     uint32_t GetPointerTypeId(const CopyPropagateArrays* pass) const {
       analysis::DefUseManager* def_use_mgr =
           GetVariable()->context()->get_def_use_mgr();
       analysis::TypeManager* type_mgr =
           GetVariable()->context()->get_type_mgr();

       Instruction* var_pointer_inst =
           def_use_mgr->GetDef(GetVariable()->type_id());

       uint32_t member_type_id = pass->GetMemberTypeId(
           var_pointer_inst->GetSingleWordInOperand(1), GetAccessIds());

       uint32_t member_pointer_type_id = type_mgr->FindPointerToType(
           member_type_id, static_cast<SpvStorageClass>(
                               var_pointer_inst->GetSingleWordInOperand(0)));
       return member_pointer_type_id;
     }

     // Returns the storage class of the memory object.
     SpvStorageClass GetStorageClass() const {
       analysis::TypeManager* type_mgr =
           GetVariable()->context()->get_type_mgr();
       const analysis::Pointer* pointer_type =
           type_mgr->GetType(GetVariable()->type_id())->AsPointer();
       return pointer_type->storage_class();
     }

     // Returns true if |other| represents memory that is contains inside of the
     // memory represented by |this|.
     bool Contains(MemoryObject* other);

    private:
     // The variable that owns this memory object.
     Instruction* variable_inst_;

     // The access chain to reach the particular member the memory object
     // represents.  It should be interpreted the same way the indices in an
     // |OpAccessChain| are interpreted.
     std::vector<uint32_t> access_chain_;
     std::vector<uint32_t> GetAccessIds() const;
   };

   // Returns the memory object being stored to |var_inst| in the store
   // instruction |store_inst|, if one exists, that can be used in place of
   // |var_inst| in all of the loads of |var_inst|.  This code is conservative
   // and only identifies very simple cases.  If no such memory object can be
   // found, the return value is |nullptr|.
   std::unique_ptr<CopyPropagateArrays::MemoryObject> FindSourceObjectIfPossible(
       Instruction* var_inst, Instruction* store_inst);

   // Replaces all loads of |var_inst| with a load from |source| instead.
   // |insertion_pos| is a position where it is possible to construct the
   // address of |source| and also dominates all of the loads of |var_inst|.
   void PropagateObject(Instruction* var_inst, MemoryObject* source,
                        Instruction* insertion_pos);

   // Returns true if all of the references to |ptr_inst| can be rewritten and
   // are dominated by |store_inst|.
   bool HasValidReferencesOnly(Instruction* ptr_inst, Instruction* store_inst);

   // Returns a memory object that at one time was equivalent to the value in
   // |result|.  If no such memory object exists, the return value is |nullptr|.
   std::unique_ptr<MemoryObject> GetSourceObjectIfAny(uint32_t result);

   // Returns the memory object that is loaded by |load_inst|.  If a memory
   // object cannot be identified, the return value is |nullptr|.  The opcode of
   // |load_inst| must be |OpLoad|.
   std::unique_ptr<MemoryObject> BuildMemoryObjectFromLoad(
       Instruction* load_inst);

   // Returns the memory object that at some point was equivalent to the result
   // of |extract_inst|.  If a memory object cannot be identified, the return
   // value is |nullptr|.  The opcode of |extract_inst| must be
   // |OpCompositeExtract|.
   std::unique_ptr<MemoryObject> BuildMemoryObjectFromExtract(
       Instruction* extract_inst);

   // Returns the memory object that at some point was equivalent to the result
   // of |construct_inst|.  If a memory object cannot be identified, the return
   // value is |nullptr|.  The opcode of |constuct_inst| must be
   // |OpCompositeConstruct|.
   std::unique_ptr<MemoryObject> BuildMemoryObjectFromCompositeConstruct(
       Instruction* conststruct_inst);

   // Returns the memory object that at some point was equivalent to the result
   // of |insert_inst|.  If a memory object cannot be identified, the return
   // value is |nullptr\.  The opcode of |insert_inst| must be
   // |OpCompositeInsert|.  This function looks for a series of
   // |OpCompositeInsert| instructions that insert the elements one at a time in
   // order from beginning to end.
   std::unique_ptr<MemoryObject> BuildMemoryObjectFromInsert(
       Instruction* insert_inst);

   // Return true if |type_id| is a pointer type whose pointee type is an array.
   bool IsPointerToArrayType(uint32_t type_id);

   // Returns true of there are not stores using |ptr_inst| or something derived
   // from it.
   bool HasNoStores(Instruction* ptr_inst);

   // Creates an |OpAccessChain| instruction whose result is a pointer the memory
   // represented by |source|.  The new instruction will be placed before
   // |insertion_point|.  |insertion_point| must be part of a function.  Returns
   // the new instruction.
   Instruction* BuildNewAccessChain(Instruction* insertion_point,
                                    MemoryObject* source) const;

   // Rewrites all uses of |original_ptr| to use |new_pointer_inst| updating
   // types of other instructions as needed.  This function should not be called
   // if |CanUpdateUses(original_ptr_inst, new_pointer_inst->type_id())| returns
   // false.
   void UpdateUses(Instruction* original_ptr_inst,
                   Instruction* new_pointer_inst);

   // Return true if |UpdateUses| is able to change all of the uses of
   // |original_ptr_inst| to |type_id| and still have valid code.
   bool CanUpdateUses(Instruction* original_ptr_inst, uint32_t type_id);

   // Returns a store to |var_inst| that writes to the entire variable, and is
   // the only store that does so.  Note it does not look through OpAccessChain
   // instruction, so partial stores are not considered.
   Instruction* FindStoreInstruction(const Instruction* var_inst) const;

   // Return the type id of the member of the type |id| access using
   // |access_chain|. The elements of |access_chain| are to be interpreted the
   // same way the indexes are used in an |OpCompositeExtract| instruction.
   uint32_t GetMemberTypeId(uint32_t id,
                            const std::vector<uint32_t>& access_chain) const;
 };

 }  // namespace opt
 }  // namespace spvtools

 #endif  // SOURCE_OPT_COPY_PROP_ARRAYS_H_
	// Copyright (c) 2018 Google LLC.
	//
	// 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 SOURCE_OPT_COPY_PROP_ARRAYS_H_
	#define SOURCE_OPT_COPY_PROP_ARRAYS_H_

	#include <memory>
	#include <vector>

	#include "source/opt/mem_pass.h"

	namespace spvtools {
	namespace opt {

	// This pass implements a simple array copy propagation. It does not do a full
	// array data flow. It looks for simple cases that meet the following
	// conditions:
	//
	// 1) The source must never be stored to.
	// 2) The target must be stored to exactly once.
	// 3) The store to the target must be a store to the entire array, and be a
	// copy of the entire source.
	// 4) All loads of the target must be dominated by the store.
	//
	// The hard part is keeping all of the types correct. We do not want to
	// have to do too large a search to update everything, which may not be
	// possible, do we give up if we see any instruction that might be hard to
	// update.

	class CopyPropagateArrays : public MemPass {
	public:
	const char* name() const override { return "copy-propagate-arrays"; }
	Status Process() override;

	IRContext::Analysis GetPreservedAnalyses() override {
	return IRContext::kAnalysisDefUse \| IRContext::kAnalysisCFG \|
	IRContext::kAnalysisInstrToBlockMapping \|
	IRContext::kAnalysisLoopAnalysis \| IRContext::kAnalysisDecorations \|
	IRContext::kAnalysisDominatorAnalysis \| IRContext::kAnalysisNameMap \|
	IRContext::kAnalysisConstants \| IRContext::kAnalysisTypes;
	}

	private:
	// The class used to identify a particular memory object. This memory object
	// will be owned by a particular variable, meaning that the memory is part of
	// that variable. It could be the entire variable or a member of the
	// variable.
	class MemoryObject {
	public:
	// Construction a memory object that is owned by \|var_inst\|. The iterator
	// \|begin\| and \|end\| traverse a container of integers that identify which
	// member of \|var_inst\| this memory object will represent. These integers
	// are interpreted the same way they would be in an \|OpAccessChain\|
	// instruction.
	template <class iterator>
	MemoryObject(Instruction* var_inst, iterator begin, iterator end);

	// Change \|this\| to now point to the member identified by \|access_chain\|
	// (starting from the current member). The elements in \|access_chain\| are
	// interpreted the same as the indices in the \|OpAccessChain\|
	// instruction.
	void GetMember(const std::vector<uint32_t>& access_chain);

	// Change \|this\| to now represent the first enclosing object to which it
	// belongs. (Remove the last element off the access_chain). It is invalid
	// to call this function if \|this\| does not represent a member of its owner.
	void GetParent() {
	assert(IsMember());
	access_chain_.pop_back();
	}

	// Returns true if \|this\| represents a member of its owner, and not the
	// entire variable.
	bool IsMember() const { return !access_chain_.empty(); }

	// Returns the number of members in the object represented by \|this\|. If
	// \|this\| does not represent a composite type, the return value will be 0.
	uint32_t GetNumberOfMembers();

	// Returns the owning variable that the memory object is contained in.
	Instruction* GetVariable() const { return variable_inst_; }

	// Returns a vector of integers that can be used to access the specific
	// member that \|this\| represents starting from the owning variable. These
	// values are to be interpreted the same way the indices are in an
	// \|OpAccessChain\| instruction.
	const std::vector<uint32_t>& AccessChain() const { return access_chain_; }

	// Returns the type id of the pointer type that can be used to point to this
	// memory object.
	uint32_t GetPointerTypeId(const CopyPropagateArrays* pass) const {
	analysis::DefUseManager* def_use_mgr =
	GetVariable()->context()->get_def_use_mgr();
	analysis::TypeManager* type_mgr =
	GetVariable()->context()->get_type_mgr();

	Instruction* var_pointer_inst =
	def_use_mgr->GetDef(GetVariable()->type_id());

	uint32_t member_type_id = pass->GetMemberTypeId(
	var_pointer_inst->GetSingleWordInOperand(1), GetAccessIds());

	uint32_t member_pointer_type_id = type_mgr->FindPointerToType(
	member_type_id, static_cast<SpvStorageClass>(
	var_pointer_inst->GetSingleWordInOperand(0)));
	return member_pointer_type_id;
	}

	// Returns the storage class of the memory object.
	SpvStorageClass GetStorageClass() const {
	analysis::TypeManager* type_mgr =
	GetVariable()->context()->get_type_mgr();
	const analysis::Pointer* pointer_type =
	type_mgr->GetType(GetVariable()->type_id())->AsPointer();
	return pointer_type->storage_class();
	}

	// Returns true if \|other\| represents memory that is contains inside of the
	// memory represented by \|this\|.
	bool Contains(MemoryObject* other);

	private:
	// The variable that owns this memory object.
	Instruction* variable_inst_;

	// The access chain to reach the particular member the memory object
	// represents. It should be interpreted the same way the indices in an
	// \|OpAccessChain\| are interpreted.
	std::vector<uint32_t> access_chain_;
	std::vector<uint32_t> GetAccessIds() const;
	};

	// Returns the memory object being stored to \|var_inst\| in the store
	// instruction \|store_inst\|, if one exists, that can be used in place of
	// \|var_inst\| in all of the loads of \|var_inst\|. This code is conservative
	// and only identifies very simple cases. If no such memory object can be
	// found, the return value is \|nullptr\|.
	std::unique_ptr<CopyPropagateArrays::MemoryObject> FindSourceObjectIfPossible(
	Instruction* var_inst, Instruction* store_inst);

	// Replaces all loads of \|var_inst\| with a load from \|source\| instead.
	// \|insertion_pos\| is a position where it is possible to construct the
	// address of \|source\| and also dominates all of the loads of \|var_inst\|.
	void PropagateObject(Instruction* var_inst, MemoryObject* source,
	Instruction* insertion_pos);

	// Returns true if all of the references to \|ptr_inst\| can be rewritten and
	// are dominated by \|store_inst\|.
	bool HasValidReferencesOnly(Instruction* ptr_inst, Instruction* store_inst);

	// Returns a memory object that at one time was equivalent to the value in
	// \|result\|. If no such memory object exists, the return value is \|nullptr\|.
	std::unique_ptr<MemoryObject> GetSourceObjectIfAny(uint32_t result);

	// Returns the memory object that is loaded by \|load_inst\|. If a memory
	// object cannot be identified, the return value is \|nullptr\|. The opcode of
	// \|load_inst\| must be \|OpLoad\|.
	std::unique_ptr<MemoryObject> BuildMemoryObjectFromLoad(
	Instruction* load_inst);

	// Returns the memory object that at some point was equivalent to the result
	// of \|extract_inst\|. If a memory object cannot be identified, the return
	// value is \|nullptr\|. The opcode of \|extract_inst\| must be
	// \|OpCompositeExtract\|.
	std::unique_ptr<MemoryObject> BuildMemoryObjectFromExtract(
	Instruction* extract_inst);

	// Returns the memory object that at some point was equivalent to the result
	// of \|construct_inst\|. If a memory object cannot be identified, the return
	// value is \|nullptr\|. The opcode of \|constuct_inst\| must be
	// \|OpCompositeConstruct\|.
	std::unique_ptr<MemoryObject> BuildMemoryObjectFromCompositeConstruct(
	Instruction* conststruct_inst);

	// Returns the memory object that at some point was equivalent to the result
	// of \|insert_inst\|. If a memory object cannot be identified, the return
	// value is \|nullptr\. The opcode of \|insert_inst\| must be
	// \|OpCompositeInsert\|. This function looks for a series of
	// \|OpCompositeInsert\| instructions that insert the elements one at a time in
	// order from beginning to end.
	std::unique_ptr<MemoryObject> BuildMemoryObjectFromInsert(
	Instruction* insert_inst);

	// Return true if \|type_id\| is a pointer type whose pointee type is an array.
	bool IsPointerToArrayType(uint32_t type_id);

	// Returns true of there are not stores using \|ptr_inst\| or something derived
	// from it.
	bool HasNoStores(Instruction* ptr_inst);

	// Creates an \|OpAccessChain\| instruction whose result is a pointer the memory
	// represented by \|source\|. The new instruction will be placed before
	// \|insertion_point\|. \|insertion_point\| must be part of a function. Returns
	// the new instruction.
	Instruction* BuildNewAccessChain(Instruction* insertion_point,
	MemoryObject* source) const;

	// Rewrites all uses of \|original_ptr\| to use \|new_pointer_inst\| updating
	// types of other instructions as needed. This function should not be called
	// if \|CanUpdateUses(original_ptr_inst, new_pointer_inst->type_id())\| returns
	// false.
	void UpdateUses(Instruction* original_ptr_inst,
	Instruction* new_pointer_inst);

	// Return true if \|UpdateUses\| is able to change all of the uses of
	// \|original_ptr_inst\| to \|type_id\| and still have valid code.
	bool CanUpdateUses(Instruction* original_ptr_inst, uint32_t type_id);

	// Returns a store to \|var_inst\| that writes to the entire variable, and is
	// the only store that does so. Note it does not look through OpAccessChain
	// instruction, so partial stores are not considered.
	Instruction* FindStoreInstruction(const Instruction* var_inst) const;

	// Return the type id of the member of the type \|id\| access using
	// \|access_chain\|. The elements of \|access_chain\| are to be interpreted the
	// same way the indexes are used in an \|OpCompositeExtract\| instruction.
	uint32_t GetMemberTypeId(uint32_t id,
	const std::vector<uint32_t>& access_chain) const;
	};

	} // namespace opt
	} // namespace spvtools

	#endif // SOURCE_OPT_COPY_PROP_ARRAYS_H_