package pongo2 import ( "fmt" "math" ) type Expression struct { // TODO: Add location token? expr1 IEvaluator expr2 IEvaluator opToken *Token } type relationalExpression struct { // TODO: Add location token? expr1 IEvaluator expr2 IEvaluator opToken *Token } type simpleExpression struct { negate bool negativeSign bool term1 IEvaluator term2 IEvaluator opToken *Token } type term struct { // TODO: Add location token? factor1 IEvaluator factor2 IEvaluator opToken *Token } type power struct { // TODO: Add location token? power1 IEvaluator power2 IEvaluator } func (expr *Expression) FilterApplied(name string) bool { return expr.expr1.FilterApplied(name) && (expr.expr2 == nil || (expr.expr2 != nil && expr.expr2.FilterApplied(name))) } func (expr *relationalExpression) FilterApplied(name string) bool { return expr.expr1.FilterApplied(name) && (expr.expr2 == nil || (expr.expr2 != nil && expr.expr2.FilterApplied(name))) } func (expr *simpleExpression) FilterApplied(name string) bool { return expr.term1.FilterApplied(name) && (expr.term2 == nil || (expr.term2 != nil && expr.term2.FilterApplied(name))) } func (expr *term) FilterApplied(name string) bool { return expr.factor1.FilterApplied(name) && (expr.factor2 == nil || (expr.factor2 != nil && expr.factor2.FilterApplied(name))) } func (expr *power) FilterApplied(name string) bool { return expr.power1.FilterApplied(name) && (expr.power2 == nil || (expr.power2 != nil && expr.power2.FilterApplied(name))) } func (expr *Expression) GetPositionToken() *Token { return expr.expr1.GetPositionToken() } func (expr *relationalExpression) GetPositionToken() *Token { return expr.expr1.GetPositionToken() } func (expr *simpleExpression) GetPositionToken() *Token { return expr.term1.GetPositionToken() } func (expr *term) GetPositionToken() *Token { return expr.factor1.GetPositionToken() } func (expr *power) GetPositionToken() *Token { return expr.power1.GetPositionToken() } func (expr *Expression) Execute(ctx *ExecutionContext, writer TemplateWriter) *Error { value, err := expr.Evaluate(ctx) if err != nil { return err } writer.WriteString(value.String()) return nil } func (expr *relationalExpression) Execute(ctx *ExecutionContext, writer TemplateWriter) *Error { value, err := expr.Evaluate(ctx) if err != nil { return err } writer.WriteString(value.String()) return nil } func (expr *simpleExpression) Execute(ctx *ExecutionContext, writer TemplateWriter) *Error { value, err := expr.Evaluate(ctx) if err != nil { return err } writer.WriteString(value.String()) return nil } func (expr *term) Execute(ctx *ExecutionContext, writer TemplateWriter) *Error { value, err := expr.Evaluate(ctx) if err != nil { return err } writer.WriteString(value.String()) return nil } func (expr *power) Execute(ctx *ExecutionContext, writer TemplateWriter) *Error { value, err := expr.Evaluate(ctx) if err != nil { return err } writer.WriteString(value.String()) return nil } func (expr *Expression) Evaluate(ctx *ExecutionContext) (*Value, *Error) { v1, err := expr.expr1.Evaluate(ctx) if err != nil { return nil, err } if expr.expr2 != nil { v2, err := expr.expr2.Evaluate(ctx) if err != nil { return nil, err } switch expr.opToken.Val { case "and", "&&": return AsValue(v1.IsTrue() && v2.IsTrue()), nil case "or", "||": return AsValue(v1.IsTrue() || v2.IsTrue()), nil default: return nil, ctx.Error(fmt.Sprintf("unimplemented: %s", expr.opToken.Val), expr.opToken) } } else { return v1, nil } } func (expr *relationalExpression) Evaluate(ctx *ExecutionContext) (*Value, *Error) { v1, err := expr.expr1.Evaluate(ctx) if err != nil { return nil, err } if expr.expr2 != nil { v2, err := expr.expr2.Evaluate(ctx) if err != nil { return nil, err } switch expr.opToken.Val { case "<=": if v1.IsFloat() || v2.IsFloat() { return AsValue(v1.Float() <= v2.Float()), nil } return AsValue(v1.Integer() <= v2.Integer()), nil case ">=": if v1.IsFloat() || v2.IsFloat() { return AsValue(v1.Float() >= v2.Float()), nil } return AsValue(v1.Integer() >= v2.Integer()), nil case "==": return AsValue(v1.EqualValueTo(v2)), nil case ">": if v1.IsFloat() || v2.IsFloat() { return AsValue(v1.Float() > v2.Float()), nil } return AsValue(v1.Integer() > v2.Integer()), nil case "<": if v1.IsFloat() || v2.IsFloat() { return AsValue(v1.Float() < v2.Float()), nil } return AsValue(v1.Integer() < v2.Integer()), nil case "!=", "<>": return AsValue(!v1.EqualValueTo(v2)), nil case "in": return AsValue(v2.Contains(v1)), nil default: return nil, ctx.Error(fmt.Sprintf("unimplemented: %s", expr.opToken.Val), expr.opToken) } } else { return v1, nil } } func (expr *simpleExpression) Evaluate(ctx *ExecutionContext) (*Value, *Error) { t1, err := expr.term1.Evaluate(ctx) if err != nil { return nil, err } result := t1 if expr.negate { result = result.Negate() } if expr.negativeSign { if result.IsNumber() { switch { case result.IsFloat(): result = AsValue(-1 * result.Float()) case result.IsInteger(): result = AsValue(-1 * result.Integer()) default: return nil, ctx.Error("Operation between a number and a non-(float/integer) is not possible", nil) } } else { return nil, ctx.Error("Negative sign on a non-number expression", expr.GetPositionToken()) } } if expr.term2 != nil { t2, err := expr.term2.Evaluate(ctx) if err != nil { return nil, err } switch expr.opToken.Val { case "+": if result.IsFloat() || t2.IsFloat() { // Result will be a float return AsValue(result.Float() + t2.Float()), nil } // Result will be an integer return AsValue(result.Integer() + t2.Integer()), nil case "-": if result.IsFloat() || t2.IsFloat() { // Result will be a float return AsValue(result.Float() - t2.Float()), nil } // Result will be an integer return AsValue(result.Integer() - t2.Integer()), nil default: return nil, ctx.Error("Unimplemented", expr.GetPositionToken()) } } return result, nil } func (expr *term) Evaluate(ctx *ExecutionContext) (*Value, *Error) { f1, err := expr.factor1.Evaluate(ctx) if err != nil { return nil, err } if expr.factor2 != nil { f2, err := expr.factor2.Evaluate(ctx) if err != nil { return nil, err } switch expr.opToken.Val { case "*": if f1.IsFloat() || f2.IsFloat() { // Result will be float return AsValue(f1.Float() * f2.Float()), nil } // Result will be int return AsValue(f1.Integer() * f2.Integer()), nil case "/": if f1.IsFloat() || f2.IsFloat() { // Result will be float return AsValue(f1.Float() / f2.Float()), nil } // Result will be int return AsValue(f1.Integer() / f2.Integer()), nil case "%": // Result will be int return AsValue(f1.Integer() % f2.Integer()), nil default: return nil, ctx.Error("unimplemented", expr.opToken) } } else { return f1, nil } } func (expr *power) Evaluate(ctx *ExecutionContext) (*Value, *Error) { p1, err := expr.power1.Evaluate(ctx) if err != nil { return nil, err } if expr.power2 != nil { p2, err := expr.power2.Evaluate(ctx) if err != nil { return nil, err } return AsValue(math.Pow(p1.Float(), p2.Float())), nil } return p1, nil } func (p *Parser) parseFactor() (IEvaluator, *Error) { if p.Match(TokenSymbol, "(") != nil { expr, err := p.ParseExpression() if err != nil { return nil, err } if p.Match(TokenSymbol, ")") == nil { return nil, p.Error("Closing bracket expected after expression", nil) } return expr, nil } return p.parseVariableOrLiteralWithFilter() } func (p *Parser) parsePower() (IEvaluator, *Error) { pw := new(power) power1, err := p.parseFactor() if err != nil { return nil, err } pw.power1 = power1 if p.Match(TokenSymbol, "^") != nil { power2, err := p.parsePower() if err != nil { return nil, err } pw.power2 = power2 } if pw.power2 == nil { // Shortcut for faster evaluation return pw.power1, nil } return pw, nil } func (p *Parser) parseTerm() (IEvaluator, *Error) { returnTerm := new(term) factor1, err := p.parsePower() if err != nil { return nil, err } returnTerm.factor1 = factor1 for p.PeekOne(TokenSymbol, "*", "/", "%") != nil { if returnTerm.opToken != nil { // Create new sub-term returnTerm = &term{ factor1: returnTerm, } } op := p.Current() p.Consume() factor2, err := p.parsePower() if err != nil { return nil, err } returnTerm.opToken = op returnTerm.factor2 = factor2 } if returnTerm.opToken == nil { // Shortcut for faster evaluation return returnTerm.factor1, nil } return returnTerm, nil } func (p *Parser) parseSimpleExpression() (IEvaluator, *Error) { expr := new(simpleExpression) if sign := p.MatchOne(TokenSymbol, "+", "-"); sign != nil { if sign.Val == "-" { expr.negativeSign = true } } if p.Match(TokenSymbol, "!") != nil || p.Match(TokenKeyword, "not") != nil { expr.negate = true } term1, err := p.parseTerm() if err != nil { return nil, err } expr.term1 = term1 for p.PeekOne(TokenSymbol, "+", "-") != nil { if expr.opToken != nil { // New sub expr expr = &simpleExpression{ term1: expr, } } op := p.Current() p.Consume() term2, err := p.parseTerm() if err != nil { return nil, err } expr.term2 = term2 expr.opToken = op } if expr.negate == false && expr.negativeSign == false && expr.term2 == nil { // Shortcut for faster evaluation return expr.term1, nil } return expr, nil } func (p *Parser) parseRelationalExpression() (IEvaluator, *Error) { expr1, err := p.parseSimpleExpression() if err != nil { return nil, err } expr := &relationalExpression{ expr1: expr1, } if t := p.MatchOne(TokenSymbol, "==", "<=", ">=", "!=", "<>", ">", "<"); t != nil { expr2, err := p.parseRelationalExpression() if err != nil { return nil, err } expr.opToken = t expr.expr2 = expr2 } else if t := p.MatchOne(TokenKeyword, "in"); t != nil { expr2, err := p.parseSimpleExpression() if err != nil { return nil, err } expr.opToken = t expr.expr2 = expr2 } if expr.expr2 == nil { // Shortcut for faster evaluation return expr.expr1, nil } return expr, nil } func (p *Parser) ParseExpression() (IEvaluator, *Error) { rexpr1, err := p.parseRelationalExpression() if err != nil { return nil, err } exp := &Expression{ expr1: rexpr1, } if p.PeekOne(TokenSymbol, "&&", "||") != nil || p.PeekOne(TokenKeyword, "and", "or") != nil { op := p.Current() p.Consume() expr2, err := p.ParseExpression() if err != nil { return nil, err } exp.expr2 = expr2 exp.opToken = op } if exp.expr2 == nil { // Shortcut for faster evaluation return exp.expr1, nil } return exp, nil }