#include "externals.hh" #include "c-opcomp.hh" #include "c-opopt.hh" #include "c-ops.hh" #include "c-sync.hh" using namespace ebcl; using namespace opast; using namespace opopt; /*= T_OptData ================================================================*/ void T_OptData::findInputDecls( T_OpsParserOutput& program ) noexcept { if ( inputDecls ) { return; } inputDecls = T_KeyValueTable< T_String , T_Array< T_InputDecl > >{ }; visitor.visit( program.root , [this]( A_Node& node , const bool exit ) { if ( exit && node.type( ) == A_Node::OP_INPUT ) { auto& input{ (T_InputInstrNode&) node }; auto* da{ inputDecls->get( input.id( ) ) }; if ( !da ) { inputDecls->add( input.id( ) , T_Array< T_InputDecl >{ } ); da = inputDecls->get( input.id( ) ); } da->add( T_InputDecl{ input.location( ) , input.defValue( ) } ); } return true; } ); } /*= CONSTANT FOLDING =========================================================*/ namespace { struct T_ConstantFolder_ { T_ConstantFolder_( T_OptData& data ) noexcept : oData{ data } {} // Result bool didFold{ false }; bool operator()( A_Node& node , bool exit ) noexcept; private: T_OptData& oData; template< typename T > void handleParentNode( A_Node& node , std::function< A_ExpressionNode&( T& ) > get , std::function< void( T& , P_ExpressionNode ) > set ) noexcept; P_ExpressionNode checkExpression( A_ExpressionNode& node ) noexcept; // Handle identifiers. If the size is fixed and the identifier is // either width or height, replace it with the appropriate value. P_ExpressionNode doIdExpr( T_IdentifierExprNode& node ) noexcept; // Handle reads from inputs. If there's a curve and it is a constant, // or if there's no curve and only one default value, then the // expression is constant. P_ExpressionNode doInputExpr( T_InputExprNode& node ) noexcept; // Transform an unary operator applied to a constant into a constant. P_ExpressionNode doUnaryOp( T_UnaryOperatorNode& node , double value ) const noexcept; // Transform a binary operator applied to a constant into a constant. P_ExpressionNode doBinaryOp( T_BinaryOperatorNode& node , double left , double right ) const noexcept; }; /*----------------------------------------------------------------------------*/ bool T_ConstantFolder_::operator()( A_Node& node , const bool exit ) noexcept { if ( exit ) { return true; } switch ( node.type( ) ) { case A_Node::TN_ARG: handleParentNode< T_ArgumentNode >( node , []( auto& n ) -> A_ExpressionNode& { return n.expression( ); } , []( auto& n , P_ExpressionNode e ) { n.expression( std::move( e ) ); } ); return false; case A_Node::TN_CONDITION: handleParentNode< T_CondInstrNode::T_Expression >( node , []( auto& n ) -> A_ExpressionNode& { return n.expression( ); } , []( auto& n , P_ExpressionNode e ) { n.expression( std::move( e ) ); } ); return false; case A_Node::OP_SET: handleParentNode< T_SetInstrNode >( node , []( auto& n ) -> A_ExpressionNode& { return n.expression( ); } , []( auto& n , P_ExpressionNode e ) { n.setExpression( std::move( e ) ); } ); return false; default: return true; } } /*----------------------------------------------------------------------------*/ template< typename T > void T_ConstantFolder_::handleParentNode( A_Node& n , std::function< A_ExpressionNode&( T& ) > get , std::function< void( T& , P_ExpressionNode ) > set ) noexcept { auto& node{ (T&) n }; auto r{ checkExpression( get( node ) ) }; if ( r ) { r->location( ) = node.location( ); set( node , std::move( r ) ); didFold = true; } } P_ExpressionNode T_ConstantFolder_::checkExpression( A_ExpressionNode& node ) noexcept { // Already a constant if ( node.type( ) == A_Node::EXPR_CONST ) { return {}; } // Replace $width/$height with value if fixedSize if ( node.type( ) == A_Node::EXPR_ID ) { return doIdExpr( (T_IdentifierExprNode&) node ); } // Replace inputs with value if no curve/constant curve if ( node.type( ) == A_Node::EXPR_INPUT ) { return doInputExpr( (T_InputExprNode&) node ); } // Replace UnOp( Cnst ) with result auto* const asUnary{ dynamic_cast< T_UnaryOperatorNode* >( &node ) }; if ( asUnary ) { handleParentNode< T_UnaryOperatorNode >( *asUnary , []( auto& n ) -> A_ExpressionNode& { return n.argument( ); } , []( auto& n , P_ExpressionNode e ) { n.setArgument( std::move( e ) ); } ); if ( asUnary->argument( ).type( ) == A_Node::EXPR_CONST ) { auto const& cn{ (T_ConstantExprNode const&) asUnary->argument( ) }; return doUnaryOp( *asUnary , cn.floatValue( ) ); } return {}; } // Replace BinOp( Cnst , Cnst ) with result auto* const asBinary{ dynamic_cast< T_BinaryOperatorNode* >( &node ) }; assert( asBinary && "Missing support for some expr subtype" ); handleParentNode< T_BinaryOperatorNode >( *asBinary , []( auto& n ) -> A_ExpressionNode& { return n.left( ); } , []( auto& n , P_ExpressionNode e ) { n.setLeft( std::move( e ) ); } ); handleParentNode< T_BinaryOperatorNode >( *asBinary , []( auto& n ) -> A_ExpressionNode& { return n.right( ); } , []( auto& n , P_ExpressionNode e ) { n.setRight( std::move( e ) ); } ); if ( asBinary->left( ).type( ) == A_Node::EXPR_CONST && asBinary->right( ).type( ) == A_Node::EXPR_CONST ) { auto const& l{ (T_ConstantExprNode const&) asBinary->left( ) }; auto const& r{ (T_ConstantExprNode const&) asBinary->right( ) }; return doBinaryOp( *asBinary , l.floatValue( ) , r.floatValue( ) ); } return {}; } /*----------------------------------------------------------------------------*/ P_ExpressionNode T_ConstantFolder_::doInputExpr( T_InputExprNode& node ) noexcept { if ( !oData.curves ) { return {}; } auto const* const curve{ oData.curves->curves.get( node.id( ) ) }; if ( curve ) { // Curve present, check if it's constant const auto cval{ curve->isConstant( ) }; if ( !cval ) { return {}; } return NewOwned< T_ConstantExprNode >( node.parent( ) , *cval ); } assert( oData.inputDecls ); auto const* const dva{ oData.inputDecls->get( node.id( ) ) }; assert( dva ); if ( dva->size( ) == 1 ) { // If there's only one default value, that's a constant. return NewOwned< T_ConstantExprNode >( node.parent( ) , (*dva)[ 0 ].value ); } return {}; } P_ExpressionNode T_ConstantFolder_::doIdExpr( T_IdentifierExprNode& node ) noexcept { if ( !oData.fixedSize ) { return {}; } if ( node.id( ) == "width" ) { return NewOwned< T_ConstantExprNode >( node.parent( ) , double( oData.fixedSize->first ) ); } if ( node.id( ) == "height" ) { return NewOwned< T_ConstantExprNode >( node.parent( ) , float( oData.fixedSize->second ) ); } return {}; } P_ExpressionNode T_ConstantFolder_::doUnaryOp( T_UnaryOperatorNode& node , const double value ) const noexcept { const double rVal{ [this]( auto& node , const auto value ) { switch ( node.op( ) ) { case T_UnaryOperatorNode::NEG: return -value; case T_UnaryOperatorNode::NOT: return value ? 0. : 1.; case T_UnaryOperatorNode::INV: if ( value == 0 ) { oData.errors.addNew( "math - 1/x, x=0" , node.location( ) ); return 0.; } return 1. / value; case T_UnaryOperatorNode::COS: return cos( value ); case T_UnaryOperatorNode::SIN: return sin( value ); case T_UnaryOperatorNode::TAN: if ( fabs( value - M_PI / 2 ) <= 1e-6 ) { oData.errors.addNew( "math - tan(x), x=~PI/2" , node.location( ) , E_SRDErrorType::WARNING ); } return tan( value ); case T_UnaryOperatorNode::SQRT: if ( value < 0 ) { oData.errors.addNew( "math - sqrt(x), x<0" , node.location( ) ); return 0.; } return sqrt( value ); case T_UnaryOperatorNode::LN: if ( value <= 0 ) { oData.errors.addNew( "math - ln(x), x<=0" , node.location( ) ); return 0.; } return log( value ); case T_UnaryOperatorNode::EXP: return exp( value ); } fprintf( stderr , "invalid operator %d\n" , int( node.op( ) ) ); std::abort( ); }( node , value ) }; return NewOwned< T_ConstantExprNode >( node.parent( ) , rVal ); } P_ExpressionNode T_ConstantFolder_::doBinaryOp( T_BinaryOperatorNode& node , const double left , const double right ) const noexcept { const double rVal{ [this]( auto& node , const auto l , const auto r ) { switch ( node.op( ) ) { case T_BinaryOperatorNode::ADD: return l + r; case T_BinaryOperatorNode::SUB: return l - r; case T_BinaryOperatorNode::MUL: return l * r; case T_BinaryOperatorNode::DIV: if ( r == 0 ) { oData.errors.addNew( "math - l/r, r=0" , node.location( ) ); return 0.; } return l / r; case T_BinaryOperatorNode::POW: if ( l == 0 && r == 0 ) { oData.errors.addNew( "math - l^r, l=r=0" , node.location( ) ); return 0.; } if ( l == 0 && r < 0 ) { oData.errors.addNew( "math - l^r, l=0, r<0" , node.location( ) ); return 0.; } if ( l < 0 && fmod( r , 1. ) != 0. ) { oData.errors.addNew( "math - l^r, l<0, r not integer" , node.location( ) ); return 0.; } return pow( l , r ); case T_BinaryOperatorNode::CMP_EQ: return ( l == r ) ? 1. : 0.; case T_BinaryOperatorNode::CMP_NE: return ( l != r ) ? 1. : 0.; case T_BinaryOperatorNode::CMP_GT: return ( l > r ) ? 1. : 0.; case T_BinaryOperatorNode::CMP_GE: return ( l >= r ) ? 1. : 0.; case T_BinaryOperatorNode::CMP_LT: return ( l < r ) ? 1. : 0.; case T_BinaryOperatorNode::CMP_LE: return ( l <= r ) ? 1. : 0.; } fprintf( stderr , "invalid operator %d\n" , int( node.op( ) ) ); std::abort( ); }( node , left , right ) }; return NewOwned< T_ConstantExprNode >( node.parent( ) , rVal ); } } // namespace /*----------------------------------------------------------------------------*/ bool opopt::FoldConstants( T_OpsParserOutput& program , T_OptData& oData ) noexcept { T_ConstantFolder_ folder{ oData }; if ( oData.curves ) { oData.findInputDecls( program ); } oData.visitor.visit( program.root , folder ); return folder.didFold; } /*= DEAD CODE REMOVAL ========================================================*/ bool opopt::RemoveDeadCode( T_OpsParserOutput& program , T_OptData& oData ) noexcept { return false; }