// Copyright (c) 2017 Google Inc. // // 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_SCALAR_REPLACEMENT_PASS_H_ #define SOURCE_OPT_SCALAR_REPLACEMENT_PASS_H_ #include #include #include #include #include #include #include "source/opt/function.h" #include "source/opt/pass.h" #include "source/opt/type_manager.h" namespace spvtools { namespace opt { // Documented in optimizer.hpp class ScalarReplacementPass : public Pass { private: static const uint32_t kDefaultLimit = 100; public: ScalarReplacementPass(uint32_t limit = kDefaultLimit) : max_num_elements_(limit) { name_[0] = '\0'; strcat(name_, "scalar-replacement="); sprintf(&name_[strlen(name_)], "%d", max_num_elements_); } const char* name() const override { return name_; } // Attempts to scalarize all appropriate function scope variables. Returns // SuccessWithChange if any change is made. Status Process() override; IRContext::Analysis GetPreservedAnalyses() override { return IRContext::kAnalysisDefUse | IRContext::kAnalysisInstrToBlockMapping | IRContext::kAnalysisDecorations | IRContext::kAnalysisCombinators | IRContext::kAnalysisCFG | IRContext::kAnalysisNameMap; } private: // Small container for tracking statistics about variables. // // TODO(alanbaker): Develop some useful heuristics to tune this pass. struct VariableStats { uint32_t num_partial_accesses; uint32_t num_full_accesses; }; // Attempts to scalarize all appropriate function scope variables in // |function|. Returns SuccessWithChange if any changes are mode. Status ProcessFunction(Function* function); // Returns true if |varInst| can be scalarized. // // Examines the use chain of |varInst| to verify all uses are valid for // scalarization. bool CanReplaceVariable(const Instruction* varInst) const; // Returns true if |typeInst| is an acceptable type to scalarize. // // Allows all aggregate types except runtime arrays. Additionally, checks the // that the number of elements that would be scalarized is within bounds. bool CheckType(const Instruction* typeInst) const; // Returns true if all the decorations for |varInst| are acceptable for // scalarization. bool CheckAnnotations(const Instruction* varInst) const; // Returns true if all the decorations for |typeInst| are acceptable for // scalarization. bool CheckTypeAnnotations(const Instruction* typeInst) const; // Returns true if the uses of |inst| are acceptable for scalarization. // // Recursively checks all the uses of |inst|. For |inst| specifically, only // allows SpvOpAccessChain, SpvOpInBoundsAccessChain, SpvOpLoad and // SpvOpStore. Access chains must have the first index be a compile-time // constant. Subsequent uses of access chains (including other access chains) // are checked in a more relaxed manner. bool CheckUses(const Instruction* inst) const; // Helper function for the above |CheckUses|. // // This version tracks some stats about the current OpVariable. These stats // are used to drive heuristics about when to scalarize. bool CheckUses(const Instruction* inst, VariableStats* stats) const; // Relaxed helper function for |CheckUses|. bool CheckUsesRelaxed(const Instruction* inst) const; // Transfers appropriate decorations from |source| to |replacements|. void TransferAnnotations(const Instruction* source, std::vector* replacements); // Scalarizes |inst| and updates its uses. // // |inst| must be an OpVariable. It is replaced with an OpVariable for each // for element of the composite type. Uses of |inst| are updated as // appropriate. If the replacement variables are themselves scalarizable, they // get added to |worklist| for further processing. If any replacement // variable ends up with no uses it is erased. Returns false if any // subsequent access chain is out of bounds. bool ReplaceVariable(Instruction* inst, std::queue* worklist); // Returns the underlying storage type for |inst|. // // |inst| must be an OpVariable. Returns the type that is pointed to by // |inst|. Instruction* GetStorageType(const Instruction* inst) const; // Returns true if the load can be scalarized. // // |inst| must be an OpLoad. Returns true if |index| is the pointer operand of // |inst| and the load is not from volatile memory. bool CheckLoad(const Instruction* inst, uint32_t index) const; // Returns true if the store can be scalarized. // // |inst| must be an OpStore. Returns true if |index| is the pointer operand // of |inst| and the store is not to volatile memory. bool CheckStore(const Instruction* inst, uint32_t index) const; // Creates a variable of type |typeId| from the |index|'th element of // |varInst|. The new variable is added to |replacements|. void CreateVariable(uint32_t typeId, Instruction* varInst, uint32_t index, std::vector* replacements); // Populates |replacements| with a new OpVariable for each element of |inst|. // // |inst| must be an OpVariable of a composite type. New variables are // initialized the same as the corresponding index in |inst|. |replacements| // will contain a variable for each element of the composite with matching // indexes (i.e. the 0'th element of |inst| is the 0'th entry of // |replacements|). void CreateReplacementVariables(Instruction* inst, std::vector* replacements); // Returns the value of an OpConstant of integer type. // // |constant| must use two or fewer words to generate the value. size_t GetConstantInteger(const Instruction* constant) const; // Returns the integer literal for |op|. size_t GetIntegerLiteral(const Operand& op) const; // Returns the array length for |arrayInst|. size_t GetArrayLength(const Instruction* arrayInst) const; // Returns the number of elements in |type|. // // |type| must be a vector or matrix type. size_t GetNumElements(const Instruction* type) const; // Returns an id for a pointer to |id|. uint32_t GetOrCreatePointerType(uint32_t id); // Creates the initial value for the |index| element of |source| in |newVar|. // // If there is an initial value for |source| for element |index|, it is // appended as an operand on |newVar|. If the initial value is OpUndef, no // initial value is added to |newVar|. void GetOrCreateInitialValue(Instruction* source, uint32_t index, Instruction* newVar); // Replaces the load to the entire composite. // // Generates a load for each replacement variable and then creates a new // composite by combining all of the loads. // // |load| must be a load. void ReplaceWholeLoad(Instruction* load, const std::vector& replacements); // Replaces the store to the entire composite. // // Generates a composite extract and store for each element in the scalarized // variable from the original store data input. void ReplaceWholeStore(Instruction* store, const std::vector& replacements); // Replaces an access chain to the composite variable with either a direct use // of the appropriate replacement variable or another access chain with the // replacement variable as the base and one fewer indexes. Returns false if // the chain has an out of bounds access. bool ReplaceAccessChain(Instruction* chain, const std::vector& replacements); // Returns a set containing the which components of the result of |inst| are // potentially used. If the return value is |nullptr|, then every components // is possibly used. std::unique_ptr> GetUsedComponents( Instruction* inst); // Returns an instruction defining a null constant with type |type_id|. If // one already exists, it is returned. Otherwise a new one is created. Instruction* CreateNullConstant(uint32_t type_id); // Maps storage type to a pointer type enclosing that type. std::unordered_map pointee_to_pointer_; // Maps type id to OpConstantNull for that type. std::unordered_map type_to_null_; // Limit on the number of members in an object that will be replaced. // 0 means there is no limit. uint32_t max_num_elements_; bool IsLargerThanSizeLimit(size_t length) const; char name_[55]; }; } // namespace opt } // namespace spvtools #endif // SOURCE_OPT_SCALAR_REPLACEMENT_PASS_H_