//
// Cforall Version 1.0.0 Copyright (C) 2015 University of Waterloo
//
// The contents of this file are covered under the licence agreement in the
// file "LICENCE" distributed with Cforall.
//
// StatementNode.cc --
//
// Author           : Rodolfo G. Esteves
// Created On       : Sat May 16 14:59:41 2015
// Last Modified By : Peter A. Buhr
// Last Modified On : Thu Aug 17 16:01:31 2017
// Update Count     : 345
//

#include <cassert>                 // for assert, safe_dynamic_cast, assertf
#include <list>                    // for list
#include <memory>                  // for unique_ptr
#include <string>                  // for string

#include "Common/SemanticError.h"  // for SemanticError
#include "Common/utility.h"        // for maybeMoveBuild, maybeBuild
#include "ParseNode.h"             // for StatementNode, ExpressionNode, bui...
#include "SynTree/Expression.h"    // for Expression, ConstantExpr
#include "SynTree/Label.h"         // for Label, noLabels
#include "SynTree/Declaration.h"
#include "SynTree/Statement.h"     // for Statement, BranchStmt, CaseStmt
#include "parserutility.h"         // for notZeroExpr

class Declaration;

using namespace std;


StatementNode::StatementNode( DeclarationNode *decl ) {
	assert( decl );
	DeclarationNode *agg = decl->extractAggregate();
	if ( agg ) {
		StatementNode *nextStmt = new StatementNode( new DeclStmt( noLabels, maybeBuild< Declaration >( decl ) ) );
		set_next( nextStmt );
		if ( decl->get_next() ) {
			get_next()->set_next( new StatementNode( dynamic_cast< DeclarationNode * >(decl->get_next()) ) );
			decl->set_next( 0 );
		} // if
	} else {
		if ( decl->get_next() ) {
			set_next( new StatementNode( dynamic_cast< DeclarationNode * >( decl->get_next() ) ) );
			decl->set_next( 0 );
		} // if
		agg = decl;
	} // if
	stmt.reset( new DeclStmt( noLabels, maybeMoveBuild< Declaration >(agg) ) );
} // StatementNode::StatementNode

StatementNode *StatementNode::append_last_case( StatementNode *stmt ) {
	StatementNode *prev = this;
	// find end of list and maintain previous pointer
	for ( StatementNode * curr = prev; curr != nullptr; curr = (StatementNode *)curr->get_next() ) {
		StatementNode *node = safe_dynamic_cast< StatementNode * >(curr);
		assert( dynamic_cast< CaseStmt * >(node->stmt.get()) );
		prev = curr;
	} // for
	// convert from StatementNode list to Statement list
	StatementNode *node = dynamic_cast< StatementNode * >(prev);
	std::list< Statement * > stmts;
	buildMoveList( stmt, stmts );
	// splice any new Statements to end of current Statements
	CaseStmt * caseStmt = dynamic_cast< CaseStmt * >(node->stmt.get());
	caseStmt->get_statements().splice( caseStmt->get_statements().end(), stmts );
	return this;
}

Statement *build_expr( ExpressionNode *ctl ) {
	Expression *e = maybeMoveBuild< Expression >( ctl );

	if ( e )
		return new ExprStmt( noLabels, e );
	else
		return new NullStmt( noLabels );
}

Statement *build_if( IfCtl * ctl, StatementNode *then_stmt, StatementNode *else_stmt ) {
	Statement *thenb, *elseb = 0;
	std::list< Statement * > branches;
	buildMoveList< Statement, StatementNode >( then_stmt, branches );
	assert( branches.size() == 1 );
	thenb = branches.front();

	if ( else_stmt ) {
		std::list< Statement * > branches;
		buildMoveList< Statement, StatementNode >( else_stmt, branches );
		assert( branches.size() == 1 );
		elseb = branches.front();
	} // if

	std::list< Statement * > init;
	if ( ctl->init != 0 ) {
		buildMoveList( ctl->init, init );
	} // if

	Expression * cond = nullptr;
	if ( ctl->condition ) {
		// compare the provided condition against 0
		cond =  notZeroExpr( maybeMoveBuild< Expression >(ctl->condition) );
	} else {
		for ( Statement * stmt : init ) {
			// build the && of all of the declared variables compared against 0
			DeclStmt * declStmt = safe_dynamic_cast< DeclStmt * >( stmt );
			DeclarationWithType * dwt = safe_dynamic_cast< DeclarationWithType * >( declStmt->decl );
			Expression * nze = notZeroExpr( new VariableExpr( dwt ) );
			cond = cond ? new LogicalExpr( cond, nze, true ) : nze;
		}
	}
	delete ctl;
	return new IfStmt( noLabels, cond, thenb, elseb, init );
}

Statement *build_switch( ExpressionNode *ctl, StatementNode *stmt ) {
	std::list< Statement * > branches;
	buildMoveList< Statement, StatementNode >( stmt, branches );
	// branches.size() == 0 for switch (...) {}, i.e., no declaration or statements
	return new SwitchStmt( noLabels, maybeMoveBuild< Expression >(ctl), branches );
}
Statement *build_case( ExpressionNode *ctl ) {
	std::list< Statement * > branches;
	return new CaseStmt( noLabels, maybeMoveBuild< Expression >(ctl), branches );
}
Statement *build_default() {
	std::list< Statement * > branches;
	return new CaseStmt( noLabels, nullptr, branches, true );
}

Statement *build_while( ExpressionNode *ctl, StatementNode *stmt, bool kind ) {
	std::list< Statement * > branches;
	buildMoveList< Statement, StatementNode >( stmt, branches );
	assert( branches.size() == 1 );
	return new WhileStmt( noLabels, notZeroExpr( maybeMoveBuild< Expression >(ctl) ), branches.front(), kind );
}

Statement *build_for( ForCtl *forctl, StatementNode *stmt ) {
	std::list< Statement * > branches;
	buildMoveList< Statement, StatementNode >( stmt, branches );
	assert( branches.size() == 1 );

	std::list< Statement * > init;
	if ( forctl->init != 0 ) {
		buildMoveList( forctl->init, init );
	} // if

	Expression *cond = 0;
	if ( forctl->condition != 0 )
		cond = notZeroExpr( maybeMoveBuild< Expression >(forctl->condition) );

	Expression *incr = 0;
	if ( forctl->change != 0 )
		incr = maybeMoveBuild< Expression >(forctl->change);

	delete forctl;
	return new ForStmt( noLabels, init, cond, incr, branches.front() );
}

Statement *build_branch( BranchStmt::Type kind ) {
	Statement * ret = new BranchStmt( noLabels, "", kind );
	return ret;
}
Statement *build_branch( std::string *identifier, BranchStmt::Type kind ) {
	Statement * ret = new BranchStmt( noLabels, *identifier, kind );
	delete identifier; 									// allocated by lexer
	return ret;
}
Statement *build_computedgoto( ExpressionNode *ctl ) {
	return new BranchStmt( noLabels, maybeMoveBuild< Expression >(ctl), BranchStmt::Goto );
}

Statement *build_return( ExpressionNode *ctl ) {
	std::list< Expression * > exps;
	buildMoveList( ctl, exps );
	return new ReturnStmt( noLabels, exps.size() > 0 ? exps.back() : nullptr );
}

Statement *build_throw( ExpressionNode *ctl ) {
	std::list< Expression * > exps;
	buildMoveList( ctl, exps );
	assertf( exps.size() < 2, "This means we are leaking memory");
	return new ThrowStmt( noLabels, ThrowStmt::Terminate, !exps.empty() ? exps.back() : nullptr );
}

Statement *build_resume( ExpressionNode *ctl ) {
	std::list< Expression * > exps;
	buildMoveList( ctl, exps );
	assertf( exps.size() < 2, "This means we are leaking memory");
	return new ThrowStmt( noLabels, ThrowStmt::Resume, !exps.empty() ? exps.back() : nullptr );
}

Statement *build_resume_at( ExpressionNode *ctl, ExpressionNode *target ) {
	(void)ctl;
	(void)target;
	assertf( false, "resume at (non-local throw) is not yet supported," );
}

Statement *build_try( StatementNode *try_stmt, StatementNode *catch_stmt, StatementNode *finally_stmt ) {
	std::list< CatchStmt * > branches;
	buildMoveList< CatchStmt, StatementNode >( catch_stmt, branches );
	CompoundStmt *tryBlock = safe_dynamic_cast< CompoundStmt * >(maybeMoveBuild< Statement >(try_stmt));
	FinallyStmt *finallyBlock = dynamic_cast< FinallyStmt * >(maybeMoveBuild< Statement >(finally_stmt) );
	return new TryStmt( noLabels, tryBlock, branches, finallyBlock );
}
Statement *build_catch( CatchStmt::Kind kind, DeclarationNode *decl, ExpressionNode *cond, StatementNode *body ) {
	std::list< Statement * > branches;
	buildMoveList< Statement, StatementNode >( body, branches );
	assert( branches.size() == 1 );
	return new CatchStmt( noLabels, kind, maybeMoveBuild< Declaration >(decl), maybeMoveBuild< Expression >(cond), branches.front() );
}
Statement *build_finally( StatementNode *stmt ) {
	std::list< Statement * > branches;
	buildMoveList< Statement, StatementNode >( stmt, branches );
	assert( branches.size() == 1 );
	return new FinallyStmt( noLabels, dynamic_cast< CompoundStmt * >( branches.front() ) );
}

WaitForStmt * build_waitfor( ExpressionNode * targetExpr, StatementNode * stmt, ExpressionNode * when ) {
	auto node = new WaitForStmt();

	WaitForStmt::Target target;
	target.function = maybeBuild<Expression>( targetExpr );

	ExpressionNode * next = dynamic_cast<ExpressionNode *>( targetExpr->get_next() );
	targetExpr->set_next( nullptr );
	buildMoveList< Expression >( next, target.arguments );

	delete targetExpr;

	node->clauses.push_back( WaitForStmt::Clause{
		target,
		maybeMoveBuild<Statement >( stmt ),
		maybeMoveBuild<Expression>( when )
	});

	return node;
}

WaitForStmt * build_waitfor( ExpressionNode * targetExpr, StatementNode * stmt, ExpressionNode * when, WaitForStmt * node ) {
	WaitForStmt::Target target;
	target.function = maybeBuild<Expression>( targetExpr );

	ExpressionNode * next = dynamic_cast<ExpressionNode *>( targetExpr->get_next() );
	targetExpr->set_next( nullptr );
	buildMoveList< Expression >( next, target.arguments );

	delete targetExpr;

	node->clauses.push_back( WaitForStmt::Clause{
		std::move( target ),
		maybeMoveBuild<Statement >( stmt ),
		maybeMoveBuild<Expression>( when )
	});

	return node;
}

WaitForStmt * build_waitfor_timeout( ExpressionNode * timeout, StatementNode * stmt, ExpressionNode * when ) {
	auto node = new WaitForStmt();

	if( timeout ) {
		node->timeout.time      = maybeMoveBuild<Expression>( timeout );
		node->timeout.statement = maybeMoveBuild<Statement >( stmt    );
		node->timeout.condition = maybeMoveBuild<Expression>( when    );
	}
	else {
		node->orelse.statement  = maybeMoveBuild<Statement >( stmt    );
		node->orelse.condition  = maybeMoveBuild<Expression>( when    );
	}

	return node;
}

WaitForStmt * build_waitfor_timeout( ExpressionNode * timeout, StatementNode * stmt, ExpressionNode * when,  StatementNode * else_stmt, ExpressionNode * else_when ) {
	auto node = new WaitForStmt();

	node->timeout.time      = maybeMoveBuild<Expression>( timeout );
	node->timeout.statement = maybeMoveBuild<Statement >( stmt    );
	node->timeout.condition = maybeMoveBuild<Expression>( when    );

	node->orelse.statement = maybeMoveBuild<Statement >( else_stmt );
	node->orelse.condition = maybeMoveBuild<Expression>( else_when );

	return node;
}

// WaitForStmt::Target build_waitfor( const std::string * name, ExpressionNode * arguments ) {
// 	 return WaitForStmt::Clause{

// 	 };
// }

Statement *build_compound( StatementNode *first ) {
	CompoundStmt *cs = new CompoundStmt( noLabels );
	buildMoveList( first, cs->get_kids() );
	return cs;
}

Statement *build_asmstmt( bool voltile, ConstantExpr *instruction, ExpressionNode *output, ExpressionNode *input, ExpressionNode *clobber, LabelNode *gotolabels ) {
	std::list< Expression * > out, in;
	std::list< ConstantExpr * > clob;

	buildMoveList( output, out );
	buildMoveList( input, in );
	buildMoveList( clobber, clob );
	return new AsmStmt( noLabels, voltile, instruction, out, in, clob, gotolabels ? gotolabels->labels : noLabels );
}

// Local Variables: //
// tab-width: 4 //
// mode: c++ //
// compile-command: "make install" //
// End: //