Merge remote-tracking branch 'upstream/master'

2016-02-06 22:40:52 +01:00 · 2016-02-06 22:40:52 +01:00 · cd583bfe41
parent 5ecab372f9 e9e87a4508
commit cd583bfe41
4 changed files with 184 additions and 33 deletions
--- a/README.md
+++ b/README.md
@ -1,11 +1,18 @@
 #Enumer
-Enumer generates Go code to get string names from enum values and viceversa.
+Enumer is a tool to generate Go code that adds useful methods to Go enums (constants with a specific type).
-It is a fork of [Rob Pike’s Stringer tool](https://godoc.org/golang.org/x/tools/cmd/stringer) 
+It started as a fork of [Rob Pike’s Stringer tool](https://godoc.org/golang.org/x/tools/cmd/stringer).
 but adding a *"string to enum value"* method to the generated code.
-This is useful when you need to read enum values from the command line arguments, from a configuration file, 
+##Generated functions and methods
 When Enumer is applied to a type, it will generate three methods and one function:
 * A method `String()` that returns the string representation of the enum value. This makes the enum conform
 the `Stringer` interface, so whenever you print an enum value, you'll get the string name instead of a number.
 * A function `<Type>String(s string)` to get the enum value from its string representation. This is useful 
 when you need to read enum values from the command line arguments, from a configuration file, 
 from a REST API request... In short, from those places where using the real enum value (an integer) would 
-be almost meaningless or hard to trace or use by a human
+be almost meaningless or hard to trace or use by a human.
 * And two more methods, `MarshalJSON()` and `UnmarshalJSON()`, that makes the enum conform 
 the `json.Marshaler` and `json.Unmarshaler` interfaces. Very useful to use it in JSON APIs.
 For example, if we have an enum type called `Pill`,
 ```go
@ -19,7 +26,7 @@ const (
 	Acetaminophen = Paracetamol
 )
 ```
-executing `enumer -type=Pill` will generate a new file with two methods:
+executing `enumer -type=Pill` will generate a new file with four methods:
 ```go
 func (i Pill) String() string {
    //...
@ -28,6 +35,14 @@ func (i Pill) String() string {
 func PillString(s string) (Pill, error) {
    //...
 }
 func (i Pill) MarshalJSON() ([]byte, error) {
 	//...
 }
 func (i *Pill) UnmarshalJSON(data []byte) error {
 	//...
 }
 ```
 From now on, we can:
 ```go
@ -43,17 +58,26 @@ if err != nil {
    return
 }
 // Now pill == Ibuprofen
 // Marshal/unmarshal to/from json strings, either directly or automatically when
 // the enum is a field of a struct
 pillJSON := Aspirin.MarshalJSON()
 // Now pillJSON == `"Aspirin"`
 ```
-The generated code is exactly the same as the Stringer tool plus the `<Type>String` method, so you can use
+The generated code is exactly the same as the Stringer tool plus the mentioned additions, so you can use
 **Enumer** where you are already using **Stringer** without any code change.
 ## How to use
-The usage of Enumer is the same as Stringer, no changes were introduced.
+The usage of Enumer is the same as Stringer, so you can refer to the [Stringer docs](https://godoc.org/golang.org/x/tools/cmd/stringer)
-For more information please refer to the [Stringer docs](https://godoc.org/golang.org/x/tools/cmd/stringer) 
+for more information.
 There is only one flag added: `noJSON`. If this flag is set to true (i.e. `enumer -type=Pill -noJSON`), 
 the JSON related methods won't be generated.
 ## Additional functions of this fork
 This fork additionally implements the Scanner and Valuer interface to use a enum seamlessly in a database model.
-## TODO
+## Inspiring projects
- Add a flag to optionally generate implementation of Scanner und Valuer interface
+* [Stringer](https://godoc.org/golang.org/x/tools/cmd/stringer)
 * [jsonenums](https://github.com/campoy/jsonenums)
--- a/enumer.go
+++ b/enumer.go
@ -1,4 +1,5 @@
 package main
 import "fmt"
 // Arguments to format are:
@ -33,3 +34,26 @@ func (g *Generator) buildValueToNameMap(runs [][]Value, typeName string, runsThr
 	g.Printf("}\n\n")
 	g.Printf(stringValueToNameMap, typeName)
 }
 // Arguments to format are:
 //	[1]: type name
 const jsonMethods = `
 func (i %[1]s) MarshalJSON() ([]byte, error) {
 	return json.Marshal(i.String())
 }
 func (i *%[1]s) UnmarshalJSON(data []byte) error {
 	var s string
 	if err := json.Unmarshal(data, &s); err != nil {
 		return fmt.Errorf("%[1]s should be a string, got %%s", data)
 	}
 	var err error
 	*i, err = %[1]sString(s)
 	return err
 }
 `
 func (g *Generator) buildJSONMethods(runs [][]Value, typeName string, runsThreshold int) {
 	g.Printf(jsonMethods, typeName)
 }
--- a/golden_test.go
+++ b/golden_test.go
@ -30,6 +30,10 @@ var golden = []Golden{
 	{"prime", prime_in, prime_out},
 }
 var goldenJSON = []Golden {
 	{"prime", prime_json_in, prime_json_out},
 }
 // Each example starts with "type XXX [u]int", with a single space separating them.
 // Simple test: enumeration of type int starting at 0.
@ -338,9 +342,100 @@ func PrimeString(s string) (Prime, error) {
 	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 _Prime_name = "p2p3p5p7p11p13p17p19p23p29p37p41p43"
 var _Prime_map = map[Prime]string{
 	2:  _Prime_name[0:2],
 	3:  _Prime_name[2:4],
 	5:  _Prime_name[4:6],
 	7:  _Prime_name[6:8],
 	11: _Prime_name[8:11],
 	13: _Prime_name[11:14],
 	17: _Prime_name[14:17],
 	19: _Prime_name[17:20],
 	23: _Prime_name[20:23],
 	29: _Prime_name[23:26],
 	31: _Prime_name[26:29],
 	41: _Prime_name[29:32],
 	43: _Prime_name[32:35],
 }
 func (i Prime) String() string {
 	if str, ok := _Prime_map[i]; ok {
 		return str
 	}
 	return fmt.Sprintf("Prime(%d)", i)
 }
 var _PrimeNameToValue_map = map[string]Prime{
 	_Prime_name[0:2]:   2,
 	_Prime_name[2:4]:   3,
 	_Prime_name[4:6]:   5,
 	_Prime_name[6:8]:   7,
 	_Prime_name[8:11]:  11,
 	_Prime_name[11:14]: 13,
 	_Prime_name[14:17]: 17,
 	_Prime_name[17:20]: 19,
 	_Prime_name[20:23]: 23,
 	_Prime_name[23:26]: 29,
 	_Prime_name[26:29]: 31,
 	_Prime_name[29:32]: 41,
 	_Prime_name[32:35]: 43,
 }
 func PrimeString(s string) (Prime, error) {
 	if val, ok := _PrimeNameToValue_map[s]; ok {
 		return val, nil
 	}
 	return 0, fmt.Errorf("%s does not belong to Prime values", s)
 }
 func (i Prime) MarshalJSON() ([]byte, error) {
 	return json.Marshal(i.String())
 }
 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 TestGolden(t *testing.T) {
 	for _, test := range golden {
 		runGoldenTest(t, test, false)
 	}
 	for _, test := range goldenJSON {
 		runGoldenTest(t, test, true)
 	}
 }
 func runGoldenTest(t *testing.T, test Golden, generateJSON bool) {
 	var g Generator
 	input := "package test\n" + test.input
 	file := test.name + ".go"
@ -350,10 +445,9 @@ func TestGolden(t *testing.T) {
 	if len(tokens) != 3 {
 		t.Fatalf("%s: need type declaration on first line", test.name)
 	}
-		g.generate(tokens[1])
+	g.generate(tokens[1], generateJSON)
 	got := string(g.format())
 	if got != test.output {
 		t.Errorf("%s: got\n====\n%s====\nexpected\n====%s", test.name, got, test.output)
 	}
 }
 }
--- a/stringer.go
+++ b/stringer.go
@ -82,6 +82,7 @@ import (
 var (
 	typeNames = flag.String("type", "", "comma-separated list of type names; must be set")
 	noJSON    = flag.Bool("noJSON", false, "if true, json marshaling methods will NOT be included. Default: false")
 	output    = flag.String("output", "", "output file name; default srcdir/<type>_string.go")
 )
@ -98,7 +99,7 @@ func Usage() {
 func main() {
 	log.SetFlags(0)
-	log.SetPrefix("stringer: ")
+	log.SetPrefix("enumer: ")
 	flag.Usage = Usage
 	flag.Parse()
 	if len(*typeNames) == 0 {
@ -135,11 +136,14 @@ func main() {
 	g.Printf("import (\n")
 	g.Printf("\t\"fmt\"\n")
 	g.Printf("\t\"database/sql/driver\"\n")
 	if !*noJSON {
 		g.Printf("\t\"encoding/json\"\n")
 	}
 	g.Printf(")\n")
 	// Run generate for each type.
 	for _, typeName := range types {
-		g.generate(typeName)
+		g.generate(typeName, !*noJSON)
 	}
 	// Format the output.
@ -275,7 +279,7 @@ func (pkg *Package) check(fs *token.FileSet, astFiles []*ast.File) {
 }
 // generate produces the String method for the named type.
-func (g *Generator) generate(typeName string) {
+func (g *Generator) generate(typeName string, includeJSON bool) {
 	values := make([]Value, 0, 100)
 	for _, file := range g.pkg.files {
 		// Set the state for this run of the walker.
@ -303,16 +307,21 @@ func (g *Generator) generate(typeName string) {
 	// being necessary for any realistic example other than bitmasks
 	// is very low. And bitmasks probably deserve their own analysis,
 	// to be done some other day.
 	const runsThreshold = 10
 	switch {
 	case len(runs) == 1:
 		g.buildOneRun(runs, typeName)
-	case len(runs) <= 10:
+	case len(runs) <= runsThreshold:
 		g.buildMultipleRuns(runs, typeName)
 	default:
 		g.buildMap(runs, typeName)
 	}
-	// ENUMER: This is the only addition over the original stringer code. Everything else is in enumer.go
+
-	g.buildValueToNameMap(runs, typeName, 10)
+	// ENUMER part
 	g.buildValueToNameMap(runs, typeName, runsThreshold)
 	if includeJSON {
 		g.buildJSONMethods(runs, typeName, runsThreshold)
 	}
 	// SQL
 	g.addValueAndScanMethod(typeName)