// Copyright 2014 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. // This file contains simple golden tests for various examples. // Besides validating the results when the implementation changes, // it provides a way to look at the generated code without having // to execute the print statements in one's head. package main import ( "strings" "testing" ) // Golden represents a test case. type Golden struct { name string input string // input; the package clause is provided when running the test. output string // exected output. } var golden = []Golden{ {"day", day_in, day_out}, {"offset", offset_in, offset_out}, {"gap", gap_in, gap_out}, {"num", num_in, num_out}, {"unum", unum_in, unum_out}, {"prime", prime_in, prime_out}, } var goldenJSON = []Golden{ {"prime", prime_json_in, prime_json_out}, } var goldenText = []Golden{ {"prime", prime_text_in, prime_text_out}, } var goldenYAML = []Golden{ {"prime", prime_yaml_in, prime_yaml_out}, } var goldenSQL = []Golden{ {"prime", prime_sql_in, prime_sql_out}, } var goldenJSONAndSQL = []Golden{ {"prime", prime_json_and_sql_in, prime_json_and_sql_out}, } var goldenPrefix = []Golden{ {"prefix", prefix_in, day_out}, } // Each example starts with "type XXX [u]int", with a single space separating them. // Simple test: enumeration of type int starting at 0. const day_in = `type Day int const ( Monday Day = iota Tuesday Wednesday Thursday Friday Saturday Sunday ) ` const day_out = ` const _DayName = "MondayTuesdayWednesdayThursdayFridaySaturdaySunday" var _DayIndex = [...]uint8{0, 6, 13, 22, 30, 36, 44, 50} func (i Day) String() string { if i < 0 || i >= Day(len(_DayIndex)-1) { return fmt.Sprintf("Day(%d)", i) } return _DayName[_DayIndex[i]:_DayIndex[i+1]] } var _DayValues = []Day{0, 1, 2, 3, 4, 5, 6} var _DayNameToValueMap = map[string]Day{ _DayName[0:6]: 0, _DayName[6:13]: 1, _DayName[13:22]: 2, _DayName[22:30]: 3, _DayName[30:36]: 4, _DayName[36:44]: 5, _DayName[44:50]: 6, } // DayString retrieves an enum value from the enum constants string name. // Throws an error if the param is not part of the enum. func DayString(s string) (Day, error) { if val, ok := _DayNameToValueMap[s]; ok { return val, nil } return 0, fmt.Errorf("%s does not belong to Day values", s) } // DayValues returns all values of the enum func DayValues() []Day { return _DayValues } // belongsToDay returns "true" if the value is listed in the enum definition. "false" otherwise func (i Day) belongsToDay() bool { for _, v := range _DayValues { if i == v { return true } } return false } ` // Enumeration with an offset. // Also includes a duplicate. const offset_in = `type Number int const ( _ Number = iota One Two Three AnotherOne = One // Duplicate; note that AnotherOne doesn't appear below. ) ` const offset_out = ` const _NumberName = "OneTwoThree" var _NumberIndex = [...]uint8{0, 3, 6, 11} func (i Number) String() string { i -= 1 if i < 0 || i >= Number(len(_NumberIndex)-1) { return fmt.Sprintf("Number(%d)", i+1) } return _NumberName[_NumberIndex[i]:_NumberIndex[i+1]] } var _NumberValues = []Number{1, 2, 3} var _NumberNameToValueMap = map[string]Number{ _NumberName[0:3]: 1, _NumberName[3:6]: 2, _NumberName[6:11]: 3, } // NumberString retrieves an enum value from the enum constants string name. // Throws an error if the param is not part of the enum. func NumberString(s string) (Number, error) { if val, ok := _NumberNameToValueMap[s]; ok { return val, nil } return 0, fmt.Errorf("%s does not belong to Number values", s) } // NumberValues returns all values of the enum func NumberValues() []Number { return _NumberValues } // belongsToNumber returns "true" if the value is listed in the enum definition. "false" otherwise func (i Number) belongsToNumber() bool { for _, v := range _NumberValues { if i == v { return true } } return false } ` // Gaps and an offset. const gap_in = `type Gap int const ( Two Gap = 2 Three Gap = 3 Five Gap = 5 Six Gap = 6 Seven Gap = 7 Eight Gap = 8 Nine Gap = 9 Eleven Gap = 11 ) ` const gap_out = ` const ( _GapName_0 = "TwoThree" _GapName_1 = "FiveSixSevenEightNine" _GapName_2 = "Eleven" ) var ( _GapIndex_0 = [...]uint8{0, 3, 8} _GapIndex_1 = [...]uint8{0, 4, 7, 12, 17, 21} _GapIndex_2 = [...]uint8{0, 6} ) func (i Gap) String() string { switch { case 2 <= i && i <= 3: i -= 2 return _GapName_0[_GapIndex_0[i]:_GapIndex_0[i+1]] case 5 <= i && i <= 9: i -= 5 return _GapName_1[_GapIndex_1[i]:_GapIndex_1[i+1]] case i == 11: return _GapName_2 default: return fmt.Sprintf("Gap(%d)", i) } } var _GapValues = []Gap{2, 3, 5, 6, 7, 8, 9, 11} var _GapNameToValueMap = map[string]Gap{ _GapName_0[0:3]: 2, _GapName_0[3:8]: 3, _GapName_1[0:4]: 5, _GapName_1[4:7]: 6, _GapName_1[7:12]: 7, _GapName_1[12:17]: 8, _GapName_1[17:21]: 9, _GapName_2[0:6]: 11, } // GapString retrieves an enum value from the enum constants string name. // Throws an error if the param is not part of the enum. func GapString(s string) (Gap, error) { if val, ok := _GapNameToValueMap[s]; ok { return val, nil } return 0, fmt.Errorf("%s does not belong to Gap values", s) } // GapValues returns all values of the enum func GapValues() []Gap { return _GapValues } // belongsToGap returns "true" if the value is listed in the enum definition. "false" otherwise func (i Gap) belongsToGap() bool { for _, v := range _GapValues { if i == v { return true } } return false } ` // Signed integers spanning zero. const num_in = `type Num int const ( m_2 Num = -2 + iota m_1 m0 m1 m2 ) ` const num_out = ` const _NumName = "m_2m_1m0m1m2" var _NumIndex = [...]uint8{0, 3, 6, 8, 10, 12} func (i Num) String() string { i -= -2 if i < 0 || i >= Num(len(_NumIndex)-1) { return fmt.Sprintf("Num(%d)", i+-2) } return _NumName[_NumIndex[i]:_NumIndex[i+1]] } var _NumValues = []Num{-2, -1, 0, 1, 2} var _NumNameToValueMap = map[string]Num{ _NumName[0:3]: -2, _NumName[3:6]: -1, _NumName[6:8]: 0, _NumName[8:10]: 1, _NumName[10:12]: 2, } // NumString retrieves an enum value from the enum constants string name. // Throws an error if the param is not part of the enum. func NumString(s string) (Num, error) { if val, ok := _NumNameToValueMap[s]; ok { return val, nil } return 0, fmt.Errorf("%s does not belong to Num values", s) } // NumValues returns all values of the enum func NumValues() []Num { return _NumValues } // belongsToNum returns "true" if the value is listed in the enum definition. "false" otherwise func (i Num) belongsToNum() bool { for _, v := range _NumValues { if i == v { return true } } return false } ` // Unsigned integers spanning zero. const unum_in = `type Unum uint const ( m_2 Unum = iota + 253 m_1 ) const ( m0 Unum = iota m1 m2 ) ` const unum_out = ` const ( _UnumName_0 = "m0m1m2" _UnumName_1 = "m_2m_1" ) var ( _UnumIndex_0 = [...]uint8{0, 2, 4, 6} _UnumIndex_1 = [...]uint8{0, 3, 6} ) func (i Unum) String() string { switch { case 0 <= i && i <= 2: return _UnumName_0[_UnumIndex_0[i]:_UnumIndex_0[i+1]] case 253 <= i && i <= 254: i -= 253 return _UnumName_1[_UnumIndex_1[i]:_UnumIndex_1[i+1]] default: return fmt.Sprintf("Unum(%d)", i) } } var _UnumValues = []Unum{0, 1, 2, 253, 254} var _UnumNameToValueMap = map[string]Unum{ _UnumName_0[0:2]: 0, _UnumName_0[2:4]: 1, _UnumName_0[4:6]: 2, _UnumName_1[0:3]: 253, _UnumName_1[3:6]: 254, } // UnumString retrieves an enum value from the enum constants string name. // Throws an error if the param is not part of the enum. func UnumString(s string) (Unum, error) { if val, ok := _UnumNameToValueMap[s]; ok { return val, nil } return 0, fmt.Errorf("%s does not belong to Unum values", s) } // UnumValues returns all values of the enum func UnumValues() []Unum { return _UnumValues } // belongsToUnum returns "true" if the value is listed in the enum definition. "false" otherwise func (i Unum) belongsToUnum() bool { for _, v := range _UnumValues { if i == v { return true } } return false } ` // Enough gaps to trigger a map implementation of the method. // Also includes a duplicate to test that it doesn't cause problems const prime_in = `type Prime int const ( p2 Prime = 2 p3 Prime = 3 p5 Prime = 5 p7 Prime = 7 p77 Prime = 7 // Duplicate; note that p77 doesn't appear below. p11 Prime = 11 p13 Prime = 13 p17 Prime = 17 p19 Prime = 19 p23 Prime = 23 p29 Prime = 29 p37 Prime = 31 p41 Prime = 41 p43 Prime = 43 ) ` const prime_out = ` const _PrimeName = "p2p3p5p7p11p13p17p19p23p29p37p41p43" var _PrimeMap = map[Prime]string{ 2: _PrimeName[0:2], 3: _PrimeName[2:4], 5: _PrimeName[4:6], 7: _PrimeName[6:8], 11: _PrimeName[8:11], 13: _PrimeName[11:14], 17: _PrimeName[14:17], 19: _PrimeName[17:20], 23: _PrimeName[20:23], 29: _PrimeName[23:26], 31: _PrimeName[26:29], 41: _PrimeName[29:32], 43: _PrimeName[32:35], } func (i Prime) String() string { if str, ok := _PrimeMap[i]; ok { return str } return fmt.Sprintf("Prime(%d)", i) } var _PrimeNameToValueMap = map[string]Prime{ _PrimeName[0:2]: 2, _PrimeName[2:4]: 3, _PrimeName[4:6]: 5, _PrimeName[6:8]: 7, _PrimeName[8:11]: 11, _PrimeName[11:14]: 13, _PrimeName[14:17]: 17, _PrimeName[17:20]: 19, _PrimeName[20:23]: 23, _PrimeName[23:26]: 29, _PrimeName[26:29]: 31, _PrimeName[29:32]: 41, _PrimeName[32:35]: 43, } // PrimeString retrieves an enum value from the enum constants string name. // Throws an error if the param is not part of the enum. func PrimeString(s string) (Prime, error) { if val, ok := _PrimeNameToValueMap[s]; ok { return val, nil } return 0, fmt.Errorf("%s does not belong to Prime values", s) } ` const prime_json_in = `type Prime int const ( p2 Prime = 2 p3 Prime = 3 p5 Prime = 5 p7 Prime = 7 p77 Prime = 7 // Duplicate; note that p77 doesn't appear below. p11 Prime = 11 p13 Prime = 13 p17 Prime = 17 p19 Prime = 19 p23 Prime = 23 p29 Prime = 29 p37 Prime = 31 p41 Prime = 41 p43 Prime = 43 ) ` const prime_json_out = ` const _PrimeName = "p2p3p5p7p11p13p17p19p23p29p37p41p43" var _PrimeMap = map[Prime]string{ 2: _PrimeName[0:2], 3: _PrimeName[2:4], 5: _PrimeName[4:6], 7: _PrimeName[6:8], 11: _PrimeName[8:11], 13: _PrimeName[11:14], 17: _PrimeName[14:17], 19: _PrimeName[17:20], 23: _PrimeName[20:23], 29: _PrimeName[23:26], 31: _PrimeName[26:29], 41: _PrimeName[29:32], 43: _PrimeName[32:35], } func (i Prime) String() string { if str, ok := _PrimeMap[i]; ok { return str } return fmt.Sprintf("Prime(%d)", i) } var _PrimeNameToValueMap = map[string]Prime{ _PrimeName[0:2]: 2, _PrimeName[2:4]: 3, _PrimeName[4:6]: 5, _PrimeName[6:8]: 7, _PrimeName[8:11]: 11, _PrimeName[11:14]: 13, _PrimeName[14:17]: 17, _PrimeName[17:20]: 19, _PrimeName[20:23]: 23, _PrimeName[23:26]: 29, _PrimeName[26:29]: 31, _PrimeName[29:32]: 41, _PrimeName[32:35]: 43, } // PrimeString retrieves an enum value from the enum constants string name. // Throws an error if the param is not part of the enum. func PrimeString(s string) (Prime, error) { if val, ok := _PrimeNameToValueMap[s]; ok { return val, nil } return 0, fmt.Errorf("%s does not belong to Prime values", s) } // MarshalJSON implements the json.Marshaler interface for Prime func (i Prime) MarshalJSON() ([]byte, error) { return json.Marshal(i.String()) } // UnmarshalJSON implements the json.Unmarshaler interface for Prime func (i *Prime) UnmarshalJSON(data []byte) error { var s string if err := json.Unmarshal(data, &s); err != nil { return fmt.Errorf("Prime should be a string, got %s", data) } var err error *i, err = PrimeString(s) return err } ` const prime_text_in = `type Prime int const ( p2 Prime = 2 p3 Prime = 3 p5 Prime = 5 p7 Prime = 7 p77 Prime = 7 // Duplicate; note that p77 doesn't appear below. p11 Prime = 11 p13 Prime = 13 p17 Prime = 17 p19 Prime = 19 p23 Prime = 23 p29 Prime = 29 p37 Prime = 31 p41 Prime = 41 p43 Prime = 43 ) ` const prime_text_out = ` const _PrimeName = "p2p3p5p7p11p13p17p19p23p29p37p41p43" var _PrimeMap = map[Prime]string{ 2: _PrimeName[0:2], 3: _PrimeName[2:4], 5: _PrimeName[4:6], 7: _PrimeName[6:8], 11: _PrimeName[8:11], 13: _PrimeName[11:14], 17: _PrimeName[14:17], 19: _PrimeName[17:20], 23: _PrimeName[20:23], 29: _PrimeName[23:26], 31: _PrimeName[26:29], 41: _PrimeName[29:32], 43: _PrimeName[32:35], } func (i Prime) String() string { if str, ok := _PrimeMap[i]; ok { return str } return fmt.Sprintf("Prime(%d)", i) } var _PrimeNameToValueMap = map[string]Prime{ _PrimeName[0:2]: 2, _PrimeName[2:4]: 3, _PrimeName[4:6]: 5, _PrimeName[6:8]: 7, _PrimeName[8:11]: 11, _PrimeName[11:14]: 13, _PrimeName[14:17]: 17, _PrimeName[17:20]: 19, _PrimeName[20:23]: 23, _PrimeName[23:26]: 29, _PrimeName[26:29]: 31, _PrimeName[29:32]: 41, _PrimeName[32:35]: 43, } // PrimeString retrieves an enum value from the enum constants string name. // Throws an error if the param is not part of the enum. func PrimeString(s string) (Prime, error) { if val, ok := _PrimeNameToValueMap[s]; ok { return val, nil } return 0, fmt.Errorf("%s does not belong to Prime values", s) } // MarshalText implements the encoding.TextMarshaler interface for Prime func (i Prime) MarshalText() ([]byte, error) { return []byte(i.String()), nil } // MarshalText implements the encoding.TextUnmarshaler interface for Prime func (i *Prime) UnmarshalText(text []byte) error { var err error *i, err = PrimeString(string(text)) return err } ` const prime_yaml_in = `type Prime int const ( p2 Prime = 2 p3 Prime = 3 p5 Prime = 5 p7 Prime = 7 p77 Prime = 7 // Duplicate; note that p77 doesn't appear below. p11 Prime = 11 p13 Prime = 13 p17 Prime = 17 p19 Prime = 19 p23 Prime = 23 p29 Prime = 29 p37 Prime = 31 p41 Prime = 41 p43 Prime = 43 ) ` const prime_yaml_out = ` const _PrimeName = "p2p3p5p7p11p13p17p19p23p29p37p41p43" var _PrimeMap = map[Prime]string{ 2: _PrimeName[0:2], 3: _PrimeName[2:4], 5: _PrimeName[4:6], 7: _PrimeName[6:8], 11: _PrimeName[8:11], 13: _PrimeName[11:14], 17: _PrimeName[14:17], 19: _PrimeName[17:20], 23: _PrimeName[20:23], 29: _PrimeName[23:26], 31: _PrimeName[26:29], 41: _PrimeName[29:32], 43: _PrimeName[32:35], } func (i Prime) String() string { if str, ok := _PrimeMap[i]; ok { return str } return fmt.Sprintf("Prime(%d)", i) } var _PrimeNameToValueMap = map[string]Prime{ _PrimeName[0:2]: 2, _PrimeName[2:4]: 3, _PrimeName[4:6]: 5, _PrimeName[6:8]: 7, _PrimeName[8:11]: 11, _PrimeName[11:14]: 13, _PrimeName[14:17]: 17, _PrimeName[17:20]: 19, _PrimeName[20:23]: 23, _PrimeName[23:26]: 29, _PrimeName[26:29]: 31, _PrimeName[29:32]: 41, _PrimeName[32:35]: 43, } // PrimeString retrieves an enum value from the enum constants string name. // Throws an error if the param is not part of the enum. func PrimeString(s string) (Prime, error) { if val, ok := _PrimeNameToValueMap[s]; ok { return val, nil } return 0, fmt.Errorf("%s does not belong to Prime values", s) } // MarshalYAML implements a YAML Marshaler for Prime func (i Prime) MarshalYAML() (interface{}, error) { return i.String(), nil } // UnmarshalYAML implements a YAML Unmarshaler for Prime func (i *Prime) UnmarshalYAML(unmarshal func(interface{}) error) error { var s string if err := unmarshal(&s); err != nil { return err } var err error *i, err = PrimeString(s) return err } ` const prime_sql_in = `type Prime int const ( p2 Prime = 2 p3 Prime = 3 p5 Prime = 5 p7 Prime = 7 p77 Prime = 7 // Duplicate; note that p77 doesn't appear below. p11 Prime = 11 p13 Prime = 13 p17 Prime = 17 p19 Prime = 19 p23 Prime = 23 p29 Prime = 29 p37 Prime = 31 p41 Prime = 41 p43 Prime = 43 ) ` const prime_sql_out = ` const _PrimeName = "p2p3p5p7p11p13p17p19p23p29p37p41p43" var _PrimeMap = map[Prime]string{ 2: _PrimeName[0:2], 3: _PrimeName[2:4], 5: _PrimeName[4:6], 7: _PrimeName[6:8], 11: _PrimeName[8:11], 13: _PrimeName[11:14], 17: _PrimeName[14:17], 19: _PrimeName[17:20], 23: _PrimeName[20:23], 29: _PrimeName[23:26], 31: _PrimeName[26:29], 41: _PrimeName[29:32], 43: _PrimeName[32:35], } func (i Prime) String() string { if str, ok := _PrimeMap[i]; ok { return str } return fmt.Sprintf("Prime(%d)", i) } var _PrimeNameToValueMap = map[string]Prime{ _PrimeName[0:2]: 2, _PrimeName[2:4]: 3, _PrimeName[4:6]: 5, _PrimeName[6:8]: 7, _PrimeName[8:11]: 11, _PrimeName[11:14]: 13, _PrimeName[14:17]: 17, _PrimeName[17:20]: 19, _PrimeName[20:23]: 23, _PrimeName[23:26]: 29, _PrimeName[26:29]: 31, _PrimeName[29:32]: 41, _PrimeName[32:35]: 43, } // PrimeString retrieves an enum value from the enum constants string name. // Throws an error if the param is not part of the enum. func PrimeString(s string) (Prime, error) { if val, ok := _PrimeNameToValueMap[s]; ok { return val, nil } return 0, fmt.Errorf("%s does not belong to Prime values", s) } func (i Prime) Value() (driver.Value, error) { return i.String(), nil } func (i *Prime) Scan(value interface{}) error { if value == nil { return nil } str, ok := value.(string) if !ok { bytes, ok := value.([]byte) if !ok { return fmt.Errorf("value is not a byte slice") } str = string(bytes[:]) } val, err := PrimeString(str) if err != nil { return err } *i = val return nil } ` const prime_json_and_sql_in = `type Prime int const ( p2 Prime = 2 p3 Prime = 3 p5 Prime = 5 p7 Prime = 7 p77 Prime = 7 // Duplicate; note that p77 doesn't appear below. p11 Prime = 11 p13 Prime = 13 p17 Prime = 17 p19 Prime = 19 p23 Prime = 23 p29 Prime = 29 p37 Prime = 31 p41 Prime = 41 p43 Prime = 43 ) ` const prime_json_and_sql_out = ` const _PrimeName = "p2p3p5p7p11p13p17p19p23p29p37p41p43" var _PrimeMap = map[Prime]string{ 2: _PrimeName[0:2], 3: _PrimeName[2:4], 5: _PrimeName[4:6], 7: _PrimeName[6:8], 11: _PrimeName[8:11], 13: _PrimeName[11:14], 17: _PrimeName[14:17], 19: _PrimeName[17:20], 23: _PrimeName[20:23], 29: _PrimeName[23:26], 31: _PrimeName[26:29], 41: _PrimeName[29:32], 43: _PrimeName[32:35], } func (i Prime) String() string { if str, ok := _PrimeMap[i]; ok { return str } return fmt.Sprintf("Prime(%d)", i) } var _PrimeNameToValueMap = map[string]Prime{ _PrimeName[0:2]: 2, _PrimeName[2:4]: 3, _PrimeName[4:6]: 5, _PrimeName[6:8]: 7, _PrimeName[8:11]: 11, _PrimeName[11:14]: 13, _PrimeName[14:17]: 17, _PrimeName[17:20]: 19, _PrimeName[20:23]: 23, _PrimeName[23:26]: 29, _PrimeName[26:29]: 31, _PrimeName[29:32]: 41, _PrimeName[32:35]: 43, } // PrimeString retrieves an enum value from the enum constants string name. // Throws an error if the param is not part of the enum. func PrimeString(s string) (Prime, error) { if val, ok := _PrimeNameToValueMap[s]; ok { return val, nil } return 0, fmt.Errorf("%s does not belong to Prime values", s) } // MarshalJSON implements the json.Marshaler interface for Prime func (i Prime) MarshalJSON() ([]byte, error) { return json.Marshal(i.String()) } // UnmarshalJSON implements the json.Unmarshaler interface for Prime func (i *Prime) UnmarshalJSON(data []byte) error { var s string if err := json.Unmarshal(data, &s); err != nil { return fmt.Errorf("Prime should be a string, got %s", data) } var err error *i, err = PrimeString(s) return err } func (i Prime) Value() (driver.Value, error) { return i.String(), nil } func (i *Prime) Scan(value interface{}) error { if value == nil { return nil } str, ok := value.(string) if !ok { bytes, ok := value.([]byte) if !ok { return fmt.Errorf("value is not a byte slice") } str = string(bytes[:]) } val, err := PrimeString(str) if err != nil { return err } *i = val return nil } ` const prefix_in = `type Day int const ( DayMonday Day = iota DayTuesday DayWednesday DayThursday DayFriday DaySaturday DaySunday ) ` func TestGolden(t *testing.T) { for _, test := range golden { runGoldenTest(t, test, false, false, false, false, "") } for _, test := range goldenJSON { runGoldenTest(t, test, true, false, false, false, "") } for _, test := range goldenText { runGoldenTest(t, test, false, false, false, true, "") } for _, test := range goldenYAML { runGoldenTest(t, test, false, true, false, false, "") } for _, test := range goldenSQL { runGoldenTest(t, test, false, false, true, false, "") } for _, test := range goldenJSONAndSQL { runGoldenTest(t, test, true, false, true, false, "") } for _, test := range goldenPrefix { runGoldenTest(t, test, false, false, false, false, "Day") } } func runGoldenTest(t *testing.T, test Golden, generateJSON, generateYAML, generateSQL, generateText bool, prefix string) { var g Generator input := "package test\n" + test.input file := test.name + ".go" g.parsePackage(".", []string{file}, input) // Extract the name and type of the constant from the first line. tokens := strings.SplitN(test.input, " ", 3) if len(tokens) != 3 { t.Fatalf("%s: need type declaration on first line", test.name) } g.generate(tokens[1], generateJSON, generateYAML, generateSQL, generateText, "noop", prefix) got := string(g.format()) if got != test.output { t.Errorf("%s: got\n====\n%s====\nexpected\n====%s", test.name, got, test.output) } }