source/opt/scalar_analysis.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_SCALAR_ANALYSIS_H_
 #define SOURCE_OPT_SCALAR_ANALYSIS_H_

 #include <algorithm>
 #include <cstdint>
 #include <map>
 #include <memory>
 #include <unordered_set>
 #include <utility>
 #include <vector>

 #include "source/opt/basic_block.h"
 #include "source/opt/instruction.h"
 #include "source/opt/scalar_analysis_nodes.h"

 namespace spvtools {
 namespace opt {

 class IRContext;
 class Loop;

 // Manager for the Scalar Evolution analysis. Creates and maintains a DAG of
 // scalar operations generated from analysing the use def graph from incoming
 // instructions. Each node is hashed as it is added so like node (for instance,
 // two induction variables i=0,i++ and j=0,j++) become the same node. After
 // creating a DAG with AnalyzeInstruction it can the be simplified into a more
 // usable form with SimplifyExpression.
 class ScalarEvolutionAnalysis {
  public:
   explicit ScalarEvolutionAnalysis(IRContext* context);

   // Create a unary negative node on |operand|.
   SENode* CreateNegation(SENode* operand);

   // Creates a subtraction between the two operands by adding |operand_1| to the
   // negation of |operand_2|.
   SENode* CreateSubtraction(SENode* operand_1, SENode* operand_2);

   // Create an addition node between two operands. The |simplify| when set will
   // allow the function to return an SEConstant instead of an addition if the
   // two input operands are also constant.
   SENode* CreateAddNode(SENode* operand_1, SENode* operand_2);

   // Create a multiply node between two operands.
   SENode* CreateMultiplyNode(SENode* operand_1, SENode* operand_2);

   // Create a node representing a constant integer.
   SENode* CreateConstant(int64_t integer);

   // Create a value unknown node, such as a load.
   SENode* CreateValueUnknownNode(const Instruction* inst);

   // Create a CantComputeNode. Used to exit out of analysis.
   SENode* CreateCantComputeNode();

   // Create a new recurrent node with |offset| and |coefficient|, with respect
   // to |loop|.
   SENode* CreateRecurrentExpression(const Loop* loop, SENode* offset,
                                     SENode* coefficient);

   // Construct the DAG by traversing use def chain of |inst|.
   SENode* AnalyzeInstruction(const Instruction* inst);

   // Simplify the |node| by grouping like terms or if contains a recurrent
   // expression, rewrite the graph so the whole DAG (from |node| down) is in
   // terms of that recurrent expression.
   //
   // For example.
   // Induction variable i=0, i++ would produce Rec(0,1) so i+1 could be
   // transformed into Rec(1,1).
   //
   // X+X*2+Y-Y+34-17 would be transformed into 3*X + 17, where X and Y are
   // ValueUnknown nodes (such as a load instruction).
   SENode* SimplifyExpression(SENode* node);

   // Add |prospective_node| into the cache and return a raw pointer to it. If
   // |prospective_node| is already in the cache just return the raw pointer.
   SENode* GetCachedOrAdd(std::unique_ptr<SENode> prospective_node);

   // Checks that the graph starting from |node| is invariant to the |loop|.
   bool IsLoopInvariant(const Loop* loop, const SENode* node) const;

   // Sets |is_gt_zero| to true if |node| represent a value always strictly
   // greater than 0. The result of |is_gt_zero| is valid only if the function
   // returns true.
   bool IsAlwaysGreaterThanZero(SENode* node, bool* is_gt_zero) const;

   // Sets |is_ge_zero| to true if |node| represent a value greater or equals to
   // 0. The result of |is_ge_zero| is valid only if the function returns true.
   bool IsAlwaysGreaterOrEqualToZero(SENode* node, bool* is_ge_zero) const;

   // Find the recurrent term belonging to |loop| in the graph starting from
   // |node| and return the coefficient of that recurrent term. Constant zero
   // will be returned if no recurrent could be found. |node| should be in
   // simplest form.
   SENode* GetCoefficientFromRecurrentTerm(SENode* node, const Loop* loop);

   // Return a rebuilt graph starting from |node| with the recurrent expression
   // belonging to |loop| being zeroed out. Returned node will be simplified.
   SENode* BuildGraphWithoutRecurrentTerm(SENode* node, const Loop* loop);

   // Return the recurrent term belonging to |loop| if it appears in the graph
   // starting at |node| or null if it doesn't.
   SERecurrentNode* GetRecurrentTerm(SENode* node, const Loop* loop);

   SENode* UpdateChildNode(SENode* parent, SENode* child, SENode* new_child);

   // The loops in |loop_pair| will be considered the same when constructing
   // SERecurrentNode objects. This enables analysing dependencies that will be
   // created during loop fusion.
   void AddLoopsToPretendAreTheSame(
       const std::pair<const Loop*, const Loop*>& loop_pair) {
     pretend_equal_[std::get<1>(loop_pair)] = std::get<0>(loop_pair);
   }

  private:
   SENode* AnalyzeConstant(const Instruction* inst);

   // Handles both addition and subtraction. If the |instruction| is OpISub
   // then the resulting node will be op1+(-op2) otherwise if it is OpIAdd then
   // the result will be op1+op2. |instruction| must be OpIAdd or OpISub.
   SENode* AnalyzeAddOp(const Instruction* instruction);

   SENode* AnalyzeMultiplyOp(const Instruction* multiply);

   SENode* AnalyzePhiInstruction(const Instruction* phi);

   IRContext* context_;

   // A map of instructions to SENodes. This is used to track recurrent
   // expressions as they are added when analyzing instructions. Recurrent
   // expressions come from phi nodes which by nature can include recursion so we
   // check if nodes have already been built when analyzing instructions.
   std::map<const Instruction*, SENode*> recurrent_node_map_;

   // On creation we create and cache the CantCompute node so we not need to
   // perform a needless create step.
   SENode* cached_cant_compute_;

   // Helper functor to allow two unique_ptr to nodes to be compare. Only
   // needed
   // for the unordered_set implementation.
   struct NodePointersEquality {
     bool operator()(const std::unique_ptr<SENode>& lhs,
                     const std::unique_ptr<SENode>& rhs) const {
       return *lhs == *rhs;
     }
   };

   // Cache of nodes. All pointers to the nodes are references to the memory
   // managed by they set.
   std::unordered_set<std::unique_ptr<SENode>, SENodeHash, NodePointersEquality>
       node_cache_;

   // Loops that should be considered the same for performing analysis for loop
   // fusion.
   std::map<const Loop*, const Loop*> pretend_equal_;
 };

 // Wrapping class to manipulate SENode pointer using + - * / operators.
 class SExpression {
  public:
   // Implicit on purpose !
   SExpression(SENode* node)
       : node_(node->GetParentAnalysis()->SimplifyExpression(node)),
         scev_(node->GetParentAnalysis()) {}

   inline operator SENode*() const { return node_; }
   inline SENode* operator->() const { return node_; }
   const SENode& operator*() const { return *node_; }

   inline ScalarEvolutionAnalysis* GetScalarEvolutionAnalysis() const {
     return scev_;
   }

   inline SExpression operator+(SENode* rhs) const;
   template <typename T,
             typename std::enable_if<std::is_integral<T>::value, int>::type = 0>
   inline SExpression operator+(T integer) const;
   inline SExpression operator+(SExpression rhs) const;

   inline SExpression operator-() const;
   inline SExpression operator-(SENode* rhs) const;
   template <typename T,
             typename std::enable_if<std::is_integral<T>::value, int>::type = 0>
   inline SExpression operator-(T integer) const;
   inline SExpression operator-(SExpression rhs) const;

   inline SExpression operator*(SENode* rhs) const;
   template <typename T,
             typename std::enable_if<std::is_integral<T>::value, int>::type = 0>
   inline SExpression operator*(T integer) const;
   inline SExpression operator*(SExpression rhs) const;

   template <typename T,
             typename std::enable_if<std::is_integral<T>::value, int>::type = 0>
   inline std::pair<SExpression, int64_t> operator/(T integer) const;
   // Try to perform a division. Returns the pair <this.node_ / rhs, division
   // remainder>. If it fails to simplify it, the function returns a
   // CanNotCompute node.
   std::pair<SExpression, int64_t> operator/(SExpression rhs) const;

  private:
   SENode* node_;
   ScalarEvolutionAnalysis* scev_;
 };

 inline SExpression SExpression::operator+(SENode* rhs) const {
   return scev_->CreateAddNode(node_, rhs);
 }

 template <typename T,
           typename std::enable_if<std::is_integral<T>::value, int>::type>
 inline SExpression SExpression::operator+(T integer) const {
   return *this + scev_->CreateConstant(integer);
 }

 inline SExpression SExpression::operator+(SExpression rhs) const {
   return *this + rhs.node_;
 }

 inline SExpression SExpression::operator-() const {
   return scev_->CreateNegation(node_);
 }

 inline SExpression SExpression::operator-(SENode* rhs) const {
   return *this + scev_->CreateNegation(rhs);
 }

 template <typename T,
           typename std::enable_if<std::is_integral<T>::value, int>::type>
 inline SExpression SExpression::operator-(T integer) const {
   return *this - scev_->CreateConstant(integer);
 }

 inline SExpression SExpression::operator-(SExpression rhs) const {
   return *this - rhs.node_;
 }

 inline SExpression SExpression::operator*(SENode* rhs) const {
   return scev_->CreateMultiplyNode(node_, rhs);
 }

 template <typename T,
           typename std::enable_if<std::is_integral<T>::value, int>::type>
 inline SExpression SExpression::operator*(T integer) const {
   return *this * scev_->CreateConstant(integer);
 }

 inline SExpression SExpression::operator*(SExpression rhs) const {
   return *this * rhs.node_;
 }

 template <typename T,
           typename std::enable_if<std::is_integral<T>::value, int>::type>
 inline std::pair<SExpression, int64_t> SExpression::operator/(T integer) const {
   return *this / scev_->CreateConstant(integer);
 }

 template <typename T,
           typename std::enable_if<std::is_integral<T>::value, int>::type>
 inline SExpression operator+(T lhs, SExpression rhs) {
   return rhs + lhs;
 }
 inline SExpression operator+(SENode* lhs, SExpression rhs) { return rhs + lhs; }

 template <typename T,
           typename std::enable_if<std::is_integral<T>::value, int>::type>
 inline SExpression operator-(T lhs, SExpression rhs) {
   // NOLINTNEXTLINE(whitespace/braces)
   return SExpression{rhs.GetScalarEvolutionAnalysis()->CreateConstant(lhs)} -
          rhs;
 }
 inline SExpression operator-(SENode* lhs, SExpression rhs) {
   // NOLINTNEXTLINE(whitespace/braces)
   return SExpression{lhs} - rhs;
 }

 template <typename T,
           typename std::enable_if<std::is_integral<T>::value, int>::type>
 inline SExpression operator*(T lhs, SExpression rhs) {
   return rhs * lhs;
 }
 inline SExpression operator*(SENode* lhs, SExpression rhs) { return rhs * lhs; }

 template <typename T,
           typename std::enable_if<std::is_integral<T>::value, int>::type>
 inline std::pair<SExpression, int64_t> operator/(T lhs, SExpression rhs) {
   // NOLINTNEXTLINE(whitespace/braces)
   return SExpression{rhs.GetScalarEvolutionAnalysis()->CreateConstant(lhs)} /
          rhs;
 }
 inline std::pair<SExpression, int64_t> operator/(SENode* lhs, SExpression rhs) {
   // NOLINTNEXTLINE(whitespace/braces)
   return SExpression{lhs} / rhs;
 }

 }  // namespace opt
 }  // namespace spvtools
 #endif  // SOURCE_OPT_SCALAR_ANALYSIS_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_SCALAR_ANALYSIS_H_
	#define SOURCE_OPT_SCALAR_ANALYSIS_H_

	#include <algorithm>
	#include <cstdint>
	#include <map>
	#include <memory>
	#include <unordered_set>
	#include <utility>
	#include <vector>

	#include "source/opt/basic_block.h"
	#include "source/opt/instruction.h"
	#include "source/opt/scalar_analysis_nodes.h"

	namespace spvtools {
	namespace opt {

	class IRContext;
	class Loop;

	// Manager for the Scalar Evolution analysis. Creates and maintains a DAG of
	// scalar operations generated from analysing the use def graph from incoming
	// instructions. Each node is hashed as it is added so like node (for instance,
	// two induction variables i=0,i++ and j=0,j++) become the same node. After
	// creating a DAG with AnalyzeInstruction it can the be simplified into a more
	// usable form with SimplifyExpression.
	class ScalarEvolutionAnalysis {
	public:
	explicit ScalarEvolutionAnalysis(IRContext* context);

	// Create a unary negative node on \|operand\|.
	SENode* CreateNegation(SENode* operand);

	// Creates a subtraction between the two operands by adding \|operand_1\| to the
	// negation of \|operand_2\|.
	SENode* CreateSubtraction(SENode* operand_1, SENode* operand_2);

	// Create an addition node between two operands. The \|simplify\| when set will
	// allow the function to return an SEConstant instead of an addition if the
	// two input operands are also constant.
	SENode* CreateAddNode(SENode* operand_1, SENode* operand_2);

	// Create a multiply node between two operands.
	SENode* CreateMultiplyNode(SENode* operand_1, SENode* operand_2);

	// Create a node representing a constant integer.
	SENode* CreateConstant(int64_t integer);

	// Create a value unknown node, such as a load.
	SENode* CreateValueUnknownNode(const Instruction* inst);

	// Create a CantComputeNode. Used to exit out of analysis.
	SENode* CreateCantComputeNode();

	// Create a new recurrent node with \|offset\| and \|coefficient\|, with respect
	// to \|loop\|.
	SENode* CreateRecurrentExpression(const Loop* loop, SENode* offset,
	SENode* coefficient);

	// Construct the DAG by traversing use def chain of \|inst\|.
	SENode* AnalyzeInstruction(const Instruction* inst);

	// Simplify the \|node\| by grouping like terms or if contains a recurrent
	// expression, rewrite the graph so the whole DAG (from \|node\| down) is in
	// terms of that recurrent expression.
	//
	// For example.
	// Induction variable i=0, i++ would produce Rec(0,1) so i+1 could be
	// transformed into Rec(1,1).
	//
	// X+X2+Y-Y+34-17 would be transformed into 3X + 17, where X and Y are
	// ValueUnknown nodes (such as a load instruction).
	SENode* SimplifyExpression(SENode* node);

	// Add \|prospective_node\| into the cache and return a raw pointer to it. If
	// \|prospective_node\| is already in the cache just return the raw pointer.
	SENode* GetCachedOrAdd(std::unique_ptr<SENode> prospective_node);

	// Checks that the graph starting from \|node\| is invariant to the \|loop\|.
	bool IsLoopInvariant(const Loop* loop, const SENode* node) const;

	// Sets \|is_gt_zero\| to true if \|node\| represent a value always strictly
	// greater than 0. The result of \|is_gt_zero\| is valid only if the function
	// returns true.
	bool IsAlwaysGreaterThanZero(SENode* node, bool* is_gt_zero) const;

	// Sets \|is_ge_zero\| to true if \|node\| represent a value greater or equals to
	// 0. The result of \|is_ge_zero\| is valid only if the function returns true.
	bool IsAlwaysGreaterOrEqualToZero(SENode* node, bool* is_ge_zero) const;

	// Find the recurrent term belonging to \|loop\| in the graph starting from
	// \|node\| and return the coefficient of that recurrent term. Constant zero
	// will be returned if no recurrent could be found. \|node\| should be in
	// simplest form.
	SENode* GetCoefficientFromRecurrentTerm(SENode* node, const Loop* loop);

	// Return a rebuilt graph starting from \|node\| with the recurrent expression
	// belonging to \|loop\| being zeroed out. Returned node will be simplified.
	SENode* BuildGraphWithoutRecurrentTerm(SENode* node, const Loop* loop);

	// Return the recurrent term belonging to \|loop\| if it appears in the graph
	// starting at \|node\| or null if it doesn't.
	SERecurrentNode* GetRecurrentTerm(SENode* node, const Loop* loop);

	SENode* UpdateChildNode(SENode* parent, SENode* child, SENode* new_child);

	// The loops in \|loop_pair\| will be considered the same when constructing
	// SERecurrentNode objects. This enables analysing dependencies that will be
	// created during loop fusion.
	void AddLoopsToPretendAreTheSame(
	const std::pair<const Loop, const Loop>& loop_pair) {
	pretend_equal_[std::get<1>(loop_pair)] = std::get<0>(loop_pair);
	}

	private:
	SENode* AnalyzeConstant(const Instruction* inst);

	// Handles both addition and subtraction. If the \|instruction\| is OpISub
	// then the resulting node will be op1+(-op2) otherwise if it is OpIAdd then
	// the result will be op1+op2. \|instruction\| must be OpIAdd or OpISub.
	SENode* AnalyzeAddOp(const Instruction* instruction);

	SENode* AnalyzeMultiplyOp(const Instruction* multiply);

	SENode* AnalyzePhiInstruction(const Instruction* phi);

	IRContext* context_;

	// A map of instructions to SENodes. This is used to track recurrent
	// expressions as they are added when analyzing instructions. Recurrent
	// expressions come from phi nodes which by nature can include recursion so we
	// check if nodes have already been built when analyzing instructions.
	std::map<const Instruction, SENode> recurrent_node_map_;

	// On creation we create and cache the CantCompute node so we not need to
	// perform a needless create step.
	SENode* cached_cant_compute_;

	// Helper functor to allow two unique_ptr to nodes to be compare. Only
	// needed
	// for the unordered_set implementation.
	struct NodePointersEquality {
	bool operator()(const std::unique_ptr<SENode>& lhs,
	const std::unique_ptr<SENode>& rhs) const {
	return lhs == rhs;
	}
	};

	// Cache of nodes. All pointers to the nodes are references to the memory
	// managed by they set.
	std::unordered_set<std::unique_ptr<SENode>, SENodeHash, NodePointersEquality>
	node_cache_;

	// Loops that should be considered the same for performing analysis for loop
	// fusion.
	std::map<const Loop, const Loop> pretend_equal_;
	};

	// Wrapping class to manipulate SENode pointer using + - * / operators.
	class SExpression {
	public:
	// Implicit on purpose !
	SExpression(SENode* node)
	: node_(node->GetParentAnalysis()->SimplifyExpression(node)),
	scev_(node->GetParentAnalysis()) {}

	inline operator SENode*() const { return node_; }
	inline SENode* operator->() const { return node_; }
	const SENode& operator() const { return node_; }

	inline ScalarEvolutionAnalysis* GetScalarEvolutionAnalysis() const {
	return scev_;
	}

	inline SExpression operator+(SENode* rhs) const;
	template <typename T,
	typename std::enable_if<std::is_integral<T>::value, int>::type = 0>
	inline SExpression operator+(T integer) const;
	inline SExpression operator+(SExpression rhs) const;

	inline SExpression operator-() const;
	inline SExpression operator-(SENode* rhs) const;
	template <typename T,
	typename std::enable_if<std::is_integral<T>::value, int>::type = 0>
	inline SExpression operator-(T integer) const;
	inline SExpression operator-(SExpression rhs) const;

	inline SExpression operator(SENode rhs) const;
	template <typename T,
	typename std::enable_if<std::is_integral<T>::value, int>::type = 0>
	inline SExpression operator*(T integer) const;
	inline SExpression operator*(SExpression rhs) const;

	template <typename T,
	typename std::enable_if<std::is_integral<T>::value, int>::type = 0>
	inline std::pair<SExpression, int64_t> operator/(T integer) const;
	// Try to perform a division. Returns the pair <this.node_ / rhs, division
	// remainder>. If it fails to simplify it, the function returns a
	// CanNotCompute node.
	std::pair<SExpression, int64_t> operator/(SExpression rhs) const;

	private:
	SENode* node_;
	ScalarEvolutionAnalysis* scev_;
	};

	inline SExpression SExpression::operator+(SENode* rhs) const {
	return scev_->CreateAddNode(node_, rhs);
	}

	template <typename T,
	typename std::enable_if<std::is_integral<T>::value, int>::type>
	inline SExpression SExpression::operator+(T integer) const {
	return *this + scev_->CreateConstant(integer);
	}

	inline SExpression SExpression::operator+(SExpression rhs) const {
	return *this + rhs.node_;
	}

	inline SExpression SExpression::operator-() const {
	return scev_->CreateNegation(node_);
	}

	inline SExpression SExpression::operator-(SENode* rhs) const {
	return *this + scev_->CreateNegation(rhs);
	}

	template <typename T,
	typename std::enable_if<std::is_integral<T>::value, int>::type>
	inline SExpression SExpression::operator-(T integer) const {
	return *this - scev_->CreateConstant(integer);
	}

	inline SExpression SExpression::operator-(SExpression rhs) const {
	return *this - rhs.node_;
	}

	inline SExpression SExpression::operator(SENode rhs) const {
	return scev_->CreateMultiplyNode(node_, rhs);
	}

	template <typename T,
	typename std::enable_if<std::is_integral<T>::value, int>::type>
	inline SExpression SExpression::operator*(T integer) const {
	return this scev_->CreateConstant(integer);
	}

	inline SExpression SExpression::operator*(SExpression rhs) const {
	return this rhs.node_;
	}

	template <typename T,
	typename std::enable_if<std::is_integral<T>::value, int>::type>
	inline std::pair<SExpression, int64_t> SExpression::operator/(T integer) const {
	return *this / scev_->CreateConstant(integer);
	}

	template <typename T,
	typename std::enable_if<std::is_integral<T>::value, int>::type>
	inline SExpression operator+(T lhs, SExpression rhs) {
	return rhs + lhs;
	}
	inline SExpression operator+(SENode* lhs, SExpression rhs) { return rhs + lhs; }

	template <typename T,
	typename std::enable_if<std::is_integral<T>::value, int>::type>
	inline SExpression operator-(T lhs, SExpression rhs) {
	// NOLINTNEXTLINE(whitespace/braces)
	return SExpression{rhs.GetScalarEvolutionAnalysis()->CreateConstant(lhs)} -
	rhs;
	}
	inline SExpression operator-(SENode* lhs, SExpression rhs) {
	// NOLINTNEXTLINE(whitespace/braces)
	return SExpression{lhs} - rhs;
	}

	template <typename T,
	typename std::enable_if<std::is_integral<T>::value, int>::type>
	inline SExpression operator*(T lhs, SExpression rhs) {
	return rhs * lhs;
	}
	inline SExpression operator(SENode lhs, SExpression rhs) { return rhs * lhs; }

	template <typename T,
	typename std::enable_if<std::is_integral<T>::value, int>::type>
	inline std::pair<SExpression, int64_t> operator/(T lhs, SExpression rhs) {
	// NOLINTNEXTLINE(whitespace/braces)
	return SExpression{rhs.GetScalarEvolutionAnalysis()->CreateConstant(lhs)} /
	rhs;
	}
	inline std::pair<SExpression, int64_t> operator/(SENode* lhs, SExpression rhs) {
	// NOLINTNEXTLINE(whitespace/braces)
	return SExpression{lhs} / rhs;
	}

	} // namespace opt
	} // namespace spvtools
	#endif // SOURCE_OPT_SCALAR_ANALYSIS_H_