src/sksl/SkSLCFGGenerator.h - skia - Git at Google

 /*
  * Copyright 2016 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SKSL_CFGGENERATOR
 #define SKSL_CFGGENERATOR

 #include "ir/SkSLExpression.h"
 #include "ir/SkSLFunctionDefinition.h"

 #include <set>
 #include <stack>

 namespace SkSL {

 // index of a block within CFG.fBlocks
 typedef size_t BlockId;

 struct BasicBlock {
     struct Node {
         enum Kind {
             kStatement_Kind,
             kExpression_Kind
         };

         Node(Kind kind, bool constantPropagation, std::unique_ptr<Expression>* expression,
              std::unique_ptr<Statement>* statement)
         : fKind(kind)
         , fConstantPropagation(constantPropagation)
         , fExpression(expression)
         , fStatement(statement) {}

         std::unique_ptr<Expression>* expression() const {
             ASSERT(fKind == kExpression_Kind);
             return fExpression;
         }

         void setExpression(std::unique_ptr<Expression> expr) {
             ASSERT(fKind == kExpression_Kind);
             *fExpression = std::move(expr);
         }

         std::unique_ptr<Statement>* statement() const {
             ASSERT(fKind == kStatement_Kind);
             return fStatement;
         }

         void setStatement(std::unique_ptr<Statement> stmt) {
             ASSERT(fKind == kStatement_Kind);
             *fStatement = std::move(stmt);
         }

         String description() const {
             if (fKind == kStatement_Kind) {
                 return (*fStatement)->description();
             } else {
                 ASSERT(fKind == kExpression_Kind);
                 return (*fExpression)->description();
             }
         }

         Kind fKind;
         // if false, this node should not be subject to constant propagation. This happens with
         // compound assignment (i.e. x *= 2), in which the value x is used as an rvalue for
         // multiplication by 2 and then as an lvalue for assignment purposes. Since there is only
         // one "x" node, replacing it with a constant would break the assignment and we suppress
         // it. Down the road, we should handle this more elegantly by substituting a regular
         // assignment if the target is constant (i.e. x = 1; x *= 2; should become x = 1; x = 1 * 2;
         // and then collapse down to a simple x = 2;).
         bool fConstantPropagation;

     private:
         // we store pointers to the unique_ptrs so that we can replace expressions or statements
         // during optimization without having to regenerate the entire tree
         std::unique_ptr<Expression>* fExpression;
         std::unique_ptr<Statement>* fStatement;
     };

     /**
      * Attempts to remove the expression (and its subexpressions) pointed to by the iterator. If the
      * expression can be cleanly removed, returns true and updates the iterator to point to the
      * expression after the deleted expression. Otherwise returns false (and the CFG will need to be
      * regenerated).
      */
     bool tryRemoveExpression(std::vector<BasicBlock::Node>::iterator* iter);

     /**
      * Locates and attempts remove an expression occurring before the expression pointed to by iter.
      * If the expression can be cleanly removed, returns true and resets iter to a valid iterator
      * pointing to the same expression it did initially. Otherwise returns false (and the CFG will
      * need to be regenerated).
      */
     bool tryRemoveExpressionBefore(std::vector<BasicBlock::Node>::iterator* iter, Expression* e);

     /**
      * As tryRemoveExpressionBefore, but for lvalues. As lvalues are at most partially evaluated
      * (for instance, x[i] = 0 evaluates i but not x) this will only look for the parts of the
      * lvalue that are actually evaluated.
      */
     bool tryRemoveLValueBefore(std::vector<BasicBlock::Node>::iterator* iter, Expression* lvalue);

     /**
      * Attempts to inserts a new expression before the node pointed to by iter. If the
      * expression can be cleanly inserted, returns true and updates the iterator to point to the
      * newly inserted expression. Otherwise returns false (and the CFG will need to be regenerated).
      */
     bool tryInsertExpression(std::vector<BasicBlock::Node>::iterator* iter,
                              std::unique_ptr<Expression>* expr);

     std::vector<Node> fNodes;
     std::set<BlockId> fEntrances;
     std::set<BlockId> fExits;
     // variable definitions upon entering this basic block (null expression = undefined)
     DefinitionMap fBefore;
 };

 struct CFG {
     BlockId fStart;
     BlockId fExit;
     std::vector<BasicBlock> fBlocks;

     void dump();

 private:
     BlockId fCurrent;

     // Adds a new block, adds an exit* from the current block to the new block, then marks the new
     // block as the current block
     // *see note in addExit()
     BlockId newBlock();

     // Adds a new block, but does not mark it current or add an exit from the current block
     BlockId newIsolatedBlock();

     // Adds an exit from the 'from' block to the 'to' block
     // Note that we skip adding the exit if the 'from' block is itself unreachable; this means that
     // we don't actually have to trace the tree to see if a particular block is unreachable, we can
     // just check to see if it has any entrances. This does require a bit of care in the order in
     // which we set the CFG up.
     void addExit(BlockId from, BlockId to);

     friend class CFGGenerator;
 };

 /**
  * Converts functions into control flow graphs.
  */
 class CFGGenerator {
 public:
     CFGGenerator() {}

     CFG getCFG(FunctionDefinition& f);

 private:
     void addStatement(CFG& cfg, std::unique_ptr<Statement>* s);

     void addExpression(CFG& cfg, std::unique_ptr<Expression>* e, bool constantPropagate);

     void addLValue(CFG& cfg, std::unique_ptr<Expression>* e);

     std::stack<BlockId> fLoopContinues;
     std::stack<BlockId> fLoopExits;
 };

 }

 #endif
	/*
	* Copyright 2016 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SKSL_CFGGENERATOR
	#define SKSL_CFGGENERATOR

	#include "ir/SkSLExpression.h"
	#include "ir/SkSLFunctionDefinition.h"

	#include <set>
	#include <stack>

	namespace SkSL {

	// index of a block within CFG.fBlocks
	typedef size_t BlockId;

	struct BasicBlock {
	struct Node {
	enum Kind {
	kStatement_Kind,
	kExpression_Kind
	};

	Node(Kind kind, bool constantPropagation, std::unique_ptr<Expression>* expression,
	std::unique_ptr<Statement>* statement)
	: fKind(kind)
	, fConstantPropagation(constantPropagation)
	, fExpression(expression)
	, fStatement(statement) {}

	std::unique_ptr<Expression>* expression() const {
	ASSERT(fKind == kExpression_Kind);
	return fExpression;
	}

	void setExpression(std::unique_ptr<Expression> expr) {
	ASSERT(fKind == kExpression_Kind);
	*fExpression = std::move(expr);
	}

	std::unique_ptr<Statement>* statement() const {
	ASSERT(fKind == kStatement_Kind);
	return fStatement;
	}

	void setStatement(std::unique_ptr<Statement> stmt) {
	ASSERT(fKind == kStatement_Kind);
	*fStatement = std::move(stmt);
	}

	String description() const {
	if (fKind == kStatement_Kind) {
	return (*fStatement)->description();
	} else {
	ASSERT(fKind == kExpression_Kind);
	return (*fExpression)->description();
	}
	}

	Kind fKind;
	// if false, this node should not be subject to constant propagation. This happens with
	// compound assignment (i.e. x *= 2), in which the value x is used as an rvalue for
	// multiplication by 2 and then as an lvalue for assignment purposes. Since there is only
	// one "x" node, replacing it with a constant would break the assignment and we suppress
	// it. Down the road, we should handle this more elegantly by substituting a regular
	// assignment if the target is constant (i.e. x = 1; x = 2; should become x = 1; x = 1 2;
	// and then collapse down to a simple x = 2;).
	bool fConstantPropagation;

	private:
	// we store pointers to the unique_ptrs so that we can replace expressions or statements
	// during optimization without having to regenerate the entire tree
	std::unique_ptr<Expression>* fExpression;
	std::unique_ptr<Statement>* fStatement;
	};

	/**
	* Attempts to remove the expression (and its subexpressions) pointed to by the iterator. If the
	* expression can be cleanly removed, returns true and updates the iterator to point to the
	* expression after the deleted expression. Otherwise returns false (and the CFG will need to be
	* regenerated).
	*/
	bool tryRemoveExpression(std::vector<BasicBlock::Node>::iterator* iter);

	/**
	* Locates and attempts remove an expression occurring before the expression pointed to by iter.
	* If the expression can be cleanly removed, returns true and resets iter to a valid iterator
	* pointing to the same expression it did initially. Otherwise returns false (and the CFG will
	* need to be regenerated).
	*/
	bool tryRemoveExpressionBefore(std::vector<BasicBlock::Node>::iterator* iter, Expression* e);

	/**
	* As tryRemoveExpressionBefore, but for lvalues. As lvalues are at most partially evaluated
	* (for instance, x[i] = 0 evaluates i but not x) this will only look for the parts of the
	* lvalue that are actually evaluated.
	*/
	bool tryRemoveLValueBefore(std::vector<BasicBlock::Node>::iterator* iter, Expression* lvalue);

	/**
	* Attempts to inserts a new expression before the node pointed to by iter. If the
	* expression can be cleanly inserted, returns true and updates the iterator to point to the
	* newly inserted expression. Otherwise returns false (and the CFG will need to be regenerated).
	*/
	bool tryInsertExpression(std::vector<BasicBlock::Node>::iterator* iter,
	std::unique_ptr<Expression>* expr);

	std::vector<Node> fNodes;
	std::set<BlockId> fEntrances;
	std::set<BlockId> fExits;
	// variable definitions upon entering this basic block (null expression = undefined)
	DefinitionMap fBefore;
	};

	struct CFG {
	BlockId fStart;
	BlockId fExit;
	std::vector<BasicBlock> fBlocks;

	void dump();

	private:
	BlockId fCurrent;

	// Adds a new block, adds an exit* from the current block to the new block, then marks the new
	// block as the current block
	// *see note in addExit()
	BlockId newBlock();

	// Adds a new block, but does not mark it current or add an exit from the current block
	BlockId newIsolatedBlock();

	// Adds an exit from the 'from' block to the 'to' block
	// Note that we skip adding the exit if the 'from' block is itself unreachable; this means that
	// we don't actually have to trace the tree to see if a particular block is unreachable, we can
	// just check to see if it has any entrances. This does require a bit of care in the order in
	// which we set the CFG up.
	void addExit(BlockId from, BlockId to);

	friend class CFGGenerator;
	};

	/**
	* Converts functions into control flow graphs.
	*/
	class CFGGenerator {
	public:
	CFGGenerator() {}

	CFG getCFG(FunctionDefinition& f);

	private:
	void addStatement(CFG& cfg, std::unique_ptr<Statement>* s);

	void addExpression(CFG& cfg, std::unique_ptr<Expression>* e, bool constantPropagate);

	void addLValue(CFG& cfg, std::unique_ptr<Expression>* e);

	std::stack<BlockId> fLoopContinues;
	std::stack<BlockId> fLoopExits;
	};

	}

	#endif