func (this *NNF) VisitFunction(expr expression.Function) (interface{}, error) {
var exp expression.Expression = expr
switch expr := expr.(type) {
case *expression.IsBoolean:
exp = expression.NewLE(expr.Operand(), expression.TRUE_EXPR)
case *expression.IsNumber:
exp = expression.NewAnd(
expression.NewGT(expr.Operand(), expression.TRUE_EXPR),
expression.NewLT(expr.Operand(), expression.EMPTY_STRING_EXPR))
case *expression.IsString:
exp = expression.NewAnd(
expression.NewGE(expr.Operand(), expression.EMPTY_STRING_EXPR),
expression.NewLT(expr.Operand(), expression.EMPTY_ARRAY_EXPR))
case *expression.IsArray:
exp = expression.NewAnd(
expression.NewGE(expr.Operand(), expression.EMPTY_ARRAY_EXPR),
expression.NewLT(expr.Operand(), _EMPTY_OBJECT_EXPR))
case *expression.IsObject:
// Not equivalent to IS OBJECT. Includes BINARY values.
exp = expression.NewGE(expr.Operand(), _EMPTY_OBJECT_EXPR)
}
return exp, exp.MapChildren(this)
}
func newSubsetLike(expr expression.BinaryFunction, re *regexp.Regexp) expression.Visitor {
if re == nil {
// Pattern is not a constant
return newSubsetDefault(expr)
}
prefix, complete := re.LiteralPrefix()
if complete {
eq := expression.NewEq(expr.First(), expression.NewConstant(prefix))
return newSubsetEq(eq.(*expression.Eq))
}
if prefix == "" {
return newSubsetDefault(expr)
}
var and expression.Expression
le := expression.NewLE(expression.NewConstant(prefix), expr.First())
last := len(prefix) - 1
if prefix[last] < math.MaxUint8 {
bytes := []byte(prefix)
bytes[last]++
and = expression.NewAnd(le, expression.NewLT(
expr.First(),
expression.NewConstant(string(bytes))))
} else {
and = expression.NewAnd(le, expression.NewLT(
expr.First(),
expression.EMPTY_ARRAY_EXPR))
}
return newSubsetAnd(and.(*expression.And))
}
func (this *NNF) VisitNot(expr *expression.Not) (interface{}, error) {
err := expr.MapChildren(this)
if err != nil {
return nil, err
}
var exp expression.Expression = expr
switch operand := expr.Operand().(type) {
case *expression.Not:
exp = operand.Operand()
case *expression.And:
operands := make(expression.Expressions, len(operand.Operands()))
for i, op := range operand.Operands() {
operands[i] = expression.NewNot(op)
}
exp = expression.NewOr(operands...)
case *expression.Or:
operands := make(expression.Expressions, len(operand.Operands()))
for i, op := range operand.Operands() {
operands[i] = expression.NewNot(op)
}
exp = expression.NewAnd(operands...)
case *expression.Eq:
exp = expression.NewOr(expression.NewLT(operand.First(), operand.Second()),
expression.NewLT(operand.Second(), operand.First()))
case *expression.LT:
exp = expression.NewLE(operand.Second(), operand.First())
case *expression.LE:
exp = expression.NewLT(operand.Second(), operand.First())
}
return exp, exp.MapChildren(this)
}
func TestConverter(t *testing.T) {
s1 := NewJSConverter().Visit(
expression.NewLT(constant("a"), constant("b")))
s2 := "(\"a\" < \"b\")"
if s1 != s2 {
t.Errorf(" mismatch s1 %s s2 %s", s1, s2)
}
s1 = NewJSConverter().Visit(
expression.NewBetween(constant("a"),
constant("b"),
constant("c")))
s2 = "(\"a\" > \"b\" && \"a\" < \"c\")"
if s1 != s2 {
t.Errorf(" mismatch s1 %s s2 %s", s1, s2)
}
s1 = NewJSConverter().Visit(expression.NewAdd(
expression.NewSub(constant("a"), constant("b")),
expression.NewDiv(constant("a"), constant("b"))))
s2 = "((\"a\" - \"b\") + (\"a\" / \"b\"))"
if s1 != s2 {
t.Errorf(" mismatch s1 %s s2 %s", s1, s2)
}
s1 = NewJSConverter().Visit(expression.NewLength(constant("abc")))
s2 = "(\"abc\".length)"
if s1 != s2 {
t.Errorf(" mismatch s1 %s s2 %s", s1, s2)
}
s1 = NewJSConverter().Visit(expression.NewUpper(constant("abc")))
s2 = "(\"abc\".toUpperCase())"
if s1 != s2 {
t.Errorf(" mismatch s1 %s s2 %s", s1, s2)
}
s1 = NewJSConverter().Visit(expression.NewStrToMillis(constant("Wed, 09 Aug 1995 00:00:00")))
s2 = "(Date.parse(\"Wed, 09 Aug 1995 00:00:00\"))"
if s1 != s2 {
t.Errorf(" mismatch s1 %s s2 %s", s1, s2)
}
s1 = NewJSConverter().Visit(expression.NewContains(constant("dfgabc"), constant("abc")))
s2 = "(\"dfgabc\".indexOf(\"abc\"))"
if s1 != s2 {
t.Errorf(" mismatch s1 %s s2 %s", s1, s2)
}
s1 = NewJSConverter().Visit(expression.NewSubstr(constant("dfgabc"), constant(1), constant(4)))
s2 = "(\"dfgabc\".substring(1,4))"
if s1 != s2 {
t.Errorf(" mismatch s1 %s s2 %s", s1, s2)
}
s1 = NewJSConverter().Visit(expression.NewAdd(expression.NewContains(constant("dfgabc"), constant("abc")), expression.NewSubstr(constant("dfgabc"), constant(1), constant(4))))
s2 = "((\"dfgabc\".indexOf(\"abc\")) + (\"dfgabc\".substring(1,4)))"
if s1 != s2 {
t.Errorf(" mismatch s1 %s s2 %s", s1, s2)
}
doc := expression.NewIdentifier("bucket")
m1 := expression.NewField(doc, expression.NewFieldName("id"))
m2 := expression.NewField(doc, expression.NewFieldName("type"))
s1 = NewJSConverter().Visit(expression.NewOr(
expression.NewUpper(m1), expression.NewLower(m2)))
s2 = "((`bucket`.`id`.toUpperCase()) || (`bucket`.`type`.toLowerCase()))"
if s1 != s2 {
t.Errorf(" mismatch s1 %s s2 %s", s1, s2)
}
doc = expression.NewIdentifier("bucket")
m1 = expression.NewField(doc, expression.NewFieldName("geo"))
m2 = expression.NewField(m1, expression.NewFieldName("accuracy"))
s1 = NewJSConverter().Visit(m2)
s2 = "`bucket`.`geo`.`accuracy`"
if s1 != s2 {
t.Errorf(" mismatch s1 %s s2 %s", s1, s2)
}
doc = expression.NewIdentifier("bucket")
m1 = expression.NewField(doc, expression.NewElement(expression.NewFieldName("address"), constant(0)))
s1 = NewJSConverter().Visit(m1)
s2 = "`bucket`.`address`[0]"
if s1 != s2 {
t.Errorf(" mismatch s1 %s s2 %s", s1, s2)
}
s1 = NewJSConverter().Visit(expression.NewLength(expression.NewElement(doc, expression.NewFieldName("type"))))
s2 = "(`bucket`[`type`].length)"
if s1 != s2 {
t.Errorf(" mismatch s1 %s s2 %s", s1, s2)
}
}
