Esempio n. 1
0
func TestSchemaParser_SimpleFieldWithArgWithDefaultValue(t *testing.T) {
	body := `
type Hello {
  world(flag: Boolean = true): String
}`
	astDoc := parse(t, body)
	expected := ast.NewDocument(&ast.Document{
		Loc: testLoc(1, 53),
		Definitions: []ast.Node{
			ast.NewObjectDefinition(&ast.ObjectDefinition{
				Loc: testLoc(1, 53),
				Name: ast.NewName(&ast.Name{
					Value: "Hello",
					Loc:   testLoc(6, 11),
				}),
				Interfaces: []*ast.Named{},
				Fields: []*ast.FieldDefinition{
					ast.NewFieldDefinition(&ast.FieldDefinition{
						Loc: testLoc(16, 51),
						Name: ast.NewName(&ast.Name{
							Value: "world",
							Loc:   testLoc(16, 21),
						}),
						Arguments: []*ast.InputValueDefinition{
							ast.NewInputValueDefinition(&ast.InputValueDefinition{
								Loc: testLoc(22, 42),
								Name: ast.NewName(&ast.Name{
									Value: "flag",
									Loc:   testLoc(22, 26),
								}),
								Type: ast.NewNamed(&ast.Named{
									Loc: testLoc(28, 35),
									Name: ast.NewName(&ast.Name{
										Value: "Boolean",
										Loc:   testLoc(28, 35),
									}),
								}),
								DefaultValue: ast.NewBooleanValue(&ast.BooleanValue{
									Value: true,
									Loc:   testLoc(38, 42),
								}),
							}),
						},
						Type: ast.NewNamed(&ast.Named{
							Loc: testLoc(45, 51),
							Name: ast.NewName(&ast.Name{
								Value: "String",
								Loc:   testLoc(45, 51),
							}),
						}),
					}),
				},
			}),
		},
	})
	if !reflect.DeepEqual(astDoc, expected) {
		t.Fatalf("unexpected document, expected: %v, got: %v", expected, astDoc)
	}
}
Esempio n. 2
0
func parseValueLiteral(parser *Parser, isConst bool) (ast.Value, error) {
	token := parser.Token
	switch token.Kind {
	case lexer.TokenKind[lexer.BRACKET_L]:
		return parseList(parser, isConst)
	case lexer.TokenKind[lexer.BRACE_L]:
		return parseObject(parser, isConst)
	case lexer.TokenKind[lexer.INT]:
		advance(parser)
		return ast.NewIntValue(&ast.IntValue{
			Value: token.Value,
			Loc:   loc(parser, token.Start),
		}), nil
	case lexer.TokenKind[lexer.FLOAT]:
		advance(parser)
		return ast.NewFloatValue(&ast.FloatValue{
			Value: token.Value,
			Loc:   loc(parser, token.Start),
		}), nil
	case lexer.TokenKind[lexer.STRING]:
		advance(parser)
		return ast.NewStringValue(&ast.StringValue{
			Value: token.Value,
			Loc:   loc(parser, token.Start),
		}), nil
	case lexer.TokenKind[lexer.NAME]:
		if token.Value == "true" || token.Value == "false" {
			advance(parser)
			value := true
			if token.Value == "false" {
				value = false
			}
			return ast.NewBooleanValue(&ast.BooleanValue{
				Value: value,
				Loc:   loc(parser, token.Start),
			}), nil
		} else if token.Value != "null" {
			advance(parser)
			return ast.NewEnumValue(&ast.EnumValue{
				Value: token.Value,
				Loc:   loc(parser, token.Start),
			}), nil
		}
	case lexer.TokenKind[lexer.DOLLAR]:
		if !isConst {
			return parseVariable(parser)
		}
	}
	if err := unexpected(parser, lexer.Token{}); err != nil {
		return nil, err
	}
	return nil, nil
}
Esempio n. 3
0
/**
 * Produces a GraphQL Value AST given a Golang value.
 *
 * Optionally, a GraphQL type may be provided, which will be used to
 * disambiguate between value primitives.
 *
 * | JSON Value    | GraphQL Value        |
 * | ------------- | -------------------- |
 * | Object        | Input Object         |
 * | Array         | List                 |
 * | Boolean       | Boolean              |
 * | String        | String / Enum Value  |
 * | Number        | Int / Float          |
 *
 */
func astFromValue(value interface{}, ttype Type) ast.Value {

	if ttype, ok := ttype.(*NonNull); ok {
		// Note: we're not checking that the result is non-null.
		// This function is not responsible for validating the input value.
		val := astFromValue(value, ttype.OfType)
		return val
	}
	if isNullish(value) {
		return nil
	}
	valueVal := reflect.ValueOf(value)
	if !valueVal.IsValid() {
		return nil
	}
	if valueVal.Type().Kind() == reflect.Ptr {
		valueVal = valueVal.Elem()
	}
	if !valueVal.IsValid() {
		return nil
	}

	// Convert Golang slice to GraphQL list. If the Type is a list, but
	// the value is not an array, convert the value using the list's item type.
	if ttype, ok := ttype.(*List); ok {
		if valueVal.Type().Kind() == reflect.Slice {
			itemType := ttype.OfType
			values := []ast.Value{}
			for i := 0; i < valueVal.Len(); i++ {
				item := valueVal.Index(i).Interface()
				itemAST := astFromValue(item, itemType)
				if itemAST != nil {
					values = append(values, itemAST)
				}
			}
			return ast.NewListValue(&ast.ListValue{
				Values: values,
			})
		} else {
			// Because GraphQL will accept single values as a "list of one" when
			// expecting a list, if there's a non-array value and an expected list type,
			// create an AST using the list's item type.
			val := astFromValue(value, ttype.OfType)
			return val
		}
	}

	if valueVal.Type().Kind() == reflect.Map {
		// TODO: implement astFromValue from Map to Value
	}

	if value, ok := value.(bool); ok {
		return ast.NewBooleanValue(&ast.BooleanValue{
			Value: value,
		})
	}
	if value, ok := value.(int); ok {
		if ttype == Float {
			return ast.NewIntValue(&ast.IntValue{
				Value: fmt.Sprintf("%v.0", value),
			})
		}
		return ast.NewIntValue(&ast.IntValue{
			Value: fmt.Sprintf("%v", value),
		})
	}
	if value, ok := value.(float32); ok {
		return ast.NewFloatValue(&ast.FloatValue{
			Value: fmt.Sprintf("%v", value),
		})
	}
	if value, ok := value.(float64); ok {
		return ast.NewFloatValue(&ast.FloatValue{
			Value: fmt.Sprintf("%v", value),
		})
	}

	if value, ok := value.(string); ok {
		if _, ok := ttype.(*Enum); ok {
			return ast.NewEnumValue(&ast.EnumValue{
				Value: fmt.Sprintf("%v", value),
			})
		}
		return ast.NewStringValue(&ast.StringValue{
			Value: fmt.Sprintf("%v", value),
		})
	}

	// fallback, treat as string
	return ast.NewStringValue(&ast.StringValue{
		Value: fmt.Sprintf("%v", value),
	})
}