mirror of
https://github.com/cheat/cheat.git
synced 2024-11-23 22:41:35 +01:00
3a6b6e58f0
`make vendor-update`
659 lines
20 KiB
Go
659 lines
20 KiB
Go
// Copyright 2014 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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// Stringer is a tool to automate the creation of methods that satisfy the fmt.Stringer
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// interface. Given the name of a (signed or unsigned) integer type T that has constants
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// defined, stringer will create a new self-contained Go source file implementing
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//
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// func (t T) String() string
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//
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// The file is created in the same package and directory as the package that defines T.
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// It has helpful defaults designed for use with go generate.
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//
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// Stringer works best with constants that are consecutive values such as created using iota,
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// but creates good code regardless. In the future it might also provide custom support for
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// constant sets that are bit patterns.
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//
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// For example, given this snippet,
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//
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// package painkiller
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//
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// type Pill int
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//
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// const (
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// Placebo Pill = iota
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// Aspirin
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// Ibuprofen
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// Paracetamol
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// Acetaminophen = Paracetamol
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// )
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//
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// running this command
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//
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// stringer -type=Pill
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//
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// in the same directory will create the file pill_string.go, in package painkiller,
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// containing a definition of
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//
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// func (Pill) String() string
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//
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// That method will translate the value of a Pill constant to the string representation
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// of the respective constant name, so that the call fmt.Print(painkiller.Aspirin) will
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// print the string "Aspirin".
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//
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// Typically this process would be run using go generate, like this:
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//
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// //go:generate stringer -type=Pill
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//
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// If multiple constants have the same value, the lexically first matching name will
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// be used (in the example, Acetaminophen will print as "Paracetamol").
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//
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// With no arguments, it processes the package in the current directory.
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// Otherwise, the arguments must name a single directory holding a Go package
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// or a set of Go source files that represent a single Go package.
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//
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// The -type flag accepts a comma-separated list of types so a single run can
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// generate methods for multiple types. The default output file is t_string.go,
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// where t is the lower-cased name of the first type listed. It can be overridden
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// with the -output flag.
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//
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// The -linecomment flag tells stringer to generate the text of any line comment, trimmed
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// of leading spaces, instead of the constant name. For instance, if the constants above had a
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// Pill prefix, one could write
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//
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// PillAspirin // Aspirin
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//
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// to suppress it in the output.
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package main // import "golang.org/x/tools/cmd/stringer"
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import (
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"bytes"
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"flag"
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"fmt"
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"go/ast"
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"go/constant"
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"go/format"
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"go/token"
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"go/types"
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"io/ioutil"
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"log"
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"os"
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"path/filepath"
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"sort"
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"strings"
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"golang.org/x/tools/go/packages"
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)
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var (
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typeNames = flag.String("type", "", "comma-separated list of type names; must be set")
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output = flag.String("output", "", "output file name; default srcdir/<type>_string.go")
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trimprefix = flag.String("trimprefix", "", "trim the `prefix` from the generated constant names")
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linecomment = flag.Bool("linecomment", false, "use line comment text as printed text when present")
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buildTags = flag.String("tags", "", "comma-separated list of build tags to apply")
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)
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// Usage is a replacement usage function for the flags package.
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func Usage() {
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fmt.Fprintf(os.Stderr, "Usage of stringer:\n")
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fmt.Fprintf(os.Stderr, "\tstringer [flags] -type T [directory]\n")
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fmt.Fprintf(os.Stderr, "\tstringer [flags] -type T files... # Must be a single package\n")
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fmt.Fprintf(os.Stderr, "For more information, see:\n")
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fmt.Fprintf(os.Stderr, "\thttps://pkg.go.dev/golang.org/x/tools/cmd/stringer\n")
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fmt.Fprintf(os.Stderr, "Flags:\n")
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flag.PrintDefaults()
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}
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func main() {
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log.SetFlags(0)
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log.SetPrefix("stringer: ")
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flag.Usage = Usage
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flag.Parse()
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if len(*typeNames) == 0 {
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flag.Usage()
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os.Exit(2)
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}
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types := strings.Split(*typeNames, ",")
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var tags []string
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if len(*buildTags) > 0 {
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tags = strings.Split(*buildTags, ",")
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}
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// We accept either one directory or a list of files. Which do we have?
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args := flag.Args()
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if len(args) == 0 {
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// Default: process whole package in current directory.
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args = []string{"."}
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}
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// Parse the package once.
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var dir string
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g := Generator{
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trimPrefix: *trimprefix,
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lineComment: *linecomment,
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}
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// TODO(suzmue): accept other patterns for packages (directories, list of files, import paths, etc).
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if len(args) == 1 && isDirectory(args[0]) {
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dir = args[0]
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} else {
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if len(tags) != 0 {
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log.Fatal("-tags option applies only to directories, not when files are specified")
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}
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dir = filepath.Dir(args[0])
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}
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g.parsePackage(args, tags)
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// Print the header and package clause.
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g.Printf("// Code generated by \"stringer %s\"; DO NOT EDIT.\n", strings.Join(os.Args[1:], " "))
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g.Printf("\n")
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g.Printf("package %s", g.pkg.name)
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g.Printf("\n")
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g.Printf("import \"strconv\"\n") // Used by all methods.
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// Run generate for each type.
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for _, typeName := range types {
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g.generate(typeName)
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}
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// Format the output.
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src := g.format()
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// Write to file.
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outputName := *output
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if outputName == "" {
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baseName := fmt.Sprintf("%s_string.go", types[0])
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outputName = filepath.Join(dir, strings.ToLower(baseName))
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}
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err := ioutil.WriteFile(outputName, src, 0644)
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if err != nil {
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log.Fatalf("writing output: %s", err)
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}
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}
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// isDirectory reports whether the named file is a directory.
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func isDirectory(name string) bool {
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info, err := os.Stat(name)
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if err != nil {
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log.Fatal(err)
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}
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return info.IsDir()
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}
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// Generator holds the state of the analysis. Primarily used to buffer
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// the output for format.Source.
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type Generator struct {
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buf bytes.Buffer // Accumulated output.
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pkg *Package // Package we are scanning.
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trimPrefix string
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lineComment bool
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}
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func (g *Generator) Printf(format string, args ...interface{}) {
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fmt.Fprintf(&g.buf, format, args...)
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}
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// File holds a single parsed file and associated data.
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type File struct {
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pkg *Package // Package to which this file belongs.
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file *ast.File // Parsed AST.
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// These fields are reset for each type being generated.
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typeName string // Name of the constant type.
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values []Value // Accumulator for constant values of that type.
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trimPrefix string
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lineComment bool
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}
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type Package struct {
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name string
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defs map[*ast.Ident]types.Object
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files []*File
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}
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// parsePackage analyzes the single package constructed from the patterns and tags.
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// parsePackage exits if there is an error.
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func (g *Generator) parsePackage(patterns []string, tags []string) {
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cfg := &packages.Config{
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Mode: packages.NeedName | packages.NeedTypes | packages.NeedTypesInfo | packages.NeedSyntax,
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// TODO: Need to think about constants in test files. Maybe write type_string_test.go
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// in a separate pass? For later.
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Tests: false,
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BuildFlags: []string{fmt.Sprintf("-tags=%s", strings.Join(tags, " "))},
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}
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pkgs, err := packages.Load(cfg, patterns...)
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if err != nil {
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log.Fatal(err)
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}
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if len(pkgs) != 1 {
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log.Fatalf("error: %d packages found", len(pkgs))
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}
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g.addPackage(pkgs[0])
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}
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// addPackage adds a type checked Package and its syntax files to the generator.
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func (g *Generator) addPackage(pkg *packages.Package) {
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g.pkg = &Package{
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name: pkg.Name,
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defs: pkg.TypesInfo.Defs,
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files: make([]*File, len(pkg.Syntax)),
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}
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for i, file := range pkg.Syntax {
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g.pkg.files[i] = &File{
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file: file,
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pkg: g.pkg,
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trimPrefix: g.trimPrefix,
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lineComment: g.lineComment,
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}
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}
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}
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// generate produces the String method for the named type.
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func (g *Generator) generate(typeName string) {
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values := make([]Value, 0, 100)
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for _, file := range g.pkg.files {
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// Set the state for this run of the walker.
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file.typeName = typeName
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file.values = nil
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if file.file != nil {
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ast.Inspect(file.file, file.genDecl)
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values = append(values, file.values...)
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}
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}
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if len(values) == 0 {
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log.Fatalf("no values defined for type %s", typeName)
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}
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// Generate code that will fail if the constants change value.
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g.Printf("func _() {\n")
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g.Printf("\t// An \"invalid array index\" compiler error signifies that the constant values have changed.\n")
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g.Printf("\t// Re-run the stringer command to generate them again.\n")
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g.Printf("\tvar x [1]struct{}\n")
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for _, v := range values {
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g.Printf("\t_ = x[%s - %s]\n", v.originalName, v.str)
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}
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g.Printf("}\n")
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runs := splitIntoRuns(values)
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// The decision of which pattern to use depends on the number of
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// runs in the numbers. If there's only one, it's easy. For more than
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// one, there's a tradeoff between complexity and size of the data
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// and code vs. the simplicity of a map. A map takes more space,
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// but so does the code. The decision here (crossover at 10) is
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// arbitrary, but considers that for large numbers of runs the cost
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// of the linear scan in the switch might become important, and
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// rather than use yet another algorithm such as binary search,
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// we punt and use a map. In any case, the likelihood of a map
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// being necessary for any realistic example other than bitmasks
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// is very low. And bitmasks probably deserve their own analysis,
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// to be done some other day.
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switch {
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case len(runs) == 1:
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g.buildOneRun(runs, typeName)
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case len(runs) <= 10:
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g.buildMultipleRuns(runs, typeName)
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default:
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g.buildMap(runs, typeName)
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}
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}
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// splitIntoRuns breaks the values into runs of contiguous sequences.
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// For example, given 1,2,3,5,6,7 it returns {1,2,3},{5,6,7}.
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// The input slice is known to be non-empty.
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func splitIntoRuns(values []Value) [][]Value {
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// We use stable sort so the lexically first name is chosen for equal elements.
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sort.Stable(byValue(values))
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// Remove duplicates. Stable sort has put the one we want to print first,
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// so use that one. The String method won't care about which named constant
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// was the argument, so the first name for the given value is the only one to keep.
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// We need to do this because identical values would cause the switch or map
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// to fail to compile.
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j := 1
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for i := 1; i < len(values); i++ {
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if values[i].value != values[i-1].value {
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values[j] = values[i]
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j++
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}
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}
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values = values[:j]
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runs := make([][]Value, 0, 10)
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for len(values) > 0 {
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// One contiguous sequence per outer loop.
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i := 1
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for i < len(values) && values[i].value == values[i-1].value+1 {
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i++
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}
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runs = append(runs, values[:i])
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values = values[i:]
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}
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return runs
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}
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// format returns the gofmt-ed contents of the Generator's buffer.
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func (g *Generator) format() []byte {
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src, err := format.Source(g.buf.Bytes())
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if err != nil {
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// Should never happen, but can arise when developing this code.
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// The user can compile the output to see the error.
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log.Printf("warning: internal error: invalid Go generated: %s", err)
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log.Printf("warning: compile the package to analyze the error")
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return g.buf.Bytes()
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}
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return src
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}
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// Value represents a declared constant.
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type Value struct {
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originalName string // The name of the constant.
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name string // The name with trimmed prefix.
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// The value is stored as a bit pattern alone. The boolean tells us
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// whether to interpret it as an int64 or a uint64; the only place
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// this matters is when sorting.
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// Much of the time the str field is all we need; it is printed
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// by Value.String.
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value uint64 // Will be converted to int64 when needed.
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signed bool // Whether the constant is a signed type.
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str string // The string representation given by the "go/constant" package.
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}
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func (v *Value) String() string {
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return v.str
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}
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// byValue lets us sort the constants into increasing order.
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// We take care in the Less method to sort in signed or unsigned order,
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// as appropriate.
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type byValue []Value
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func (b byValue) Len() int { return len(b) }
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func (b byValue) Swap(i, j int) { b[i], b[j] = b[j], b[i] }
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func (b byValue) Less(i, j int) bool {
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if b[i].signed {
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return int64(b[i].value) < int64(b[j].value)
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}
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return b[i].value < b[j].value
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}
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// genDecl processes one declaration clause.
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func (f *File) genDecl(node ast.Node) bool {
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decl, ok := node.(*ast.GenDecl)
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if !ok || decl.Tok != token.CONST {
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// We only care about const declarations.
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return true
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}
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// The name of the type of the constants we are declaring.
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// Can change if this is a multi-element declaration.
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typ := ""
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// Loop over the elements of the declaration. Each element is a ValueSpec:
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// a list of names possibly followed by a type, possibly followed by values.
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// If the type and value are both missing, we carry down the type (and value,
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// but the "go/types" package takes care of that).
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for _, spec := range decl.Specs {
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vspec := spec.(*ast.ValueSpec) // Guaranteed to succeed as this is CONST.
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if vspec.Type == nil && len(vspec.Values) > 0 {
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// "X = 1". With no type but a value. If the constant is untyped,
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// skip this vspec and reset the remembered type.
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typ = ""
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// If this is a simple type conversion, remember the type.
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// We don't mind if this is actually a call; a qualified call won't
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// be matched (that will be SelectorExpr, not Ident), and only unusual
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// situations will result in a function call that appears to be
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// a type conversion.
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ce, ok := vspec.Values[0].(*ast.CallExpr)
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if !ok {
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continue
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}
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id, ok := ce.Fun.(*ast.Ident)
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if !ok {
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continue
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}
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typ = id.Name
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}
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if vspec.Type != nil {
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// "X T". We have a type. Remember it.
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ident, ok := vspec.Type.(*ast.Ident)
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if !ok {
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continue
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}
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typ = ident.Name
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}
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if typ != f.typeName {
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// This is not the type we're looking for.
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continue
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}
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// We now have a list of names (from one line of source code) all being
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// declared with the desired type.
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// Grab their names and actual values and store them in f.values.
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for _, name := range vspec.Names {
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if name.Name == "_" {
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continue
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}
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// This dance lets the type checker find the values for us. It's a
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// bit tricky: look up the object declared by the name, find its
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// types.Const, and extract its value.
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obj, ok := f.pkg.defs[name]
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if !ok {
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log.Fatalf("no value for constant %s", name)
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}
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info := obj.Type().Underlying().(*types.Basic).Info()
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if info&types.IsInteger == 0 {
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log.Fatalf("can't handle non-integer constant type %s", typ)
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}
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value := obj.(*types.Const).Val() // Guaranteed to succeed as this is CONST.
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if value.Kind() != constant.Int {
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log.Fatalf("can't happen: constant is not an integer %s", name)
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}
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i64, isInt := constant.Int64Val(value)
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u64, isUint := constant.Uint64Val(value)
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if !isInt && !isUint {
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log.Fatalf("internal error: value of %s is not an integer: %s", name, value.String())
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}
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if !isInt {
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u64 = uint64(i64)
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}
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v := Value{
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originalName: name.Name,
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value: u64,
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signed: info&types.IsUnsigned == 0,
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str: value.String(),
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}
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if c := vspec.Comment; f.lineComment && c != nil && len(c.List) == 1 {
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v.name = strings.TrimSpace(c.Text())
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} else {
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v.name = strings.TrimPrefix(v.originalName, f.trimPrefix)
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}
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f.values = append(f.values, v)
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}
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}
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return false
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}
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// Helpers
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// usize returns the number of bits of the smallest unsigned integer
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// type that will hold n. Used to create the smallest possible slice of
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// integers to use as indexes into the concatenated strings.
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func usize(n int) int {
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switch {
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case n < 1<<8:
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return 8
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case n < 1<<16:
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return 16
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default:
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// 2^32 is enough constants for anyone.
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return 32
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}
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}
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// declareIndexAndNameVars declares the index slices and concatenated names
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// strings representing the runs of values.
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func (g *Generator) declareIndexAndNameVars(runs [][]Value, typeName string) {
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var indexes, names []string
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for i, run := range runs {
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index, name := g.createIndexAndNameDecl(run, typeName, fmt.Sprintf("_%d", i))
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|
if len(run) != 1 {
|
|
indexes = append(indexes, index)
|
|
}
|
|
names = append(names, name)
|
|
}
|
|
g.Printf("const (\n")
|
|
for _, name := range names {
|
|
g.Printf("\t%s\n", name)
|
|
}
|
|
g.Printf(")\n\n")
|
|
|
|
if len(indexes) > 0 {
|
|
g.Printf("var (")
|
|
for _, index := range indexes {
|
|
g.Printf("\t%s\n", index)
|
|
}
|
|
g.Printf(")\n\n")
|
|
}
|
|
}
|
|
|
|
// declareIndexAndNameVar is the single-run version of declareIndexAndNameVars
|
|
func (g *Generator) declareIndexAndNameVar(run []Value, typeName string) {
|
|
index, name := g.createIndexAndNameDecl(run, typeName, "")
|
|
g.Printf("const %s\n", name)
|
|
g.Printf("var %s\n", index)
|
|
}
|
|
|
|
// createIndexAndNameDecl returns the pair of declarations for the run. The caller will add "const" and "var".
|
|
func (g *Generator) createIndexAndNameDecl(run []Value, typeName string, suffix string) (string, string) {
|
|
b := new(bytes.Buffer)
|
|
indexes := make([]int, len(run))
|
|
for i := range run {
|
|
b.WriteString(run[i].name)
|
|
indexes[i] = b.Len()
|
|
}
|
|
nameConst := fmt.Sprintf("_%s_name%s = %q", typeName, suffix, b.String())
|
|
nameLen := b.Len()
|
|
b.Reset()
|
|
fmt.Fprintf(b, "_%s_index%s = [...]uint%d{0, ", typeName, suffix, usize(nameLen))
|
|
for i, v := range indexes {
|
|
if i > 0 {
|
|
fmt.Fprintf(b, ", ")
|
|
}
|
|
fmt.Fprintf(b, "%d", v)
|
|
}
|
|
fmt.Fprintf(b, "}")
|
|
return b.String(), nameConst
|
|
}
|
|
|
|
// declareNameVars declares the concatenated names string representing all the values in the runs.
|
|
func (g *Generator) declareNameVars(runs [][]Value, typeName string, suffix string) {
|
|
g.Printf("const _%s_name%s = \"", typeName, suffix)
|
|
for _, run := range runs {
|
|
for i := range run {
|
|
g.Printf("%s", run[i].name)
|
|
}
|
|
}
|
|
g.Printf("\"\n")
|
|
}
|
|
|
|
// buildOneRun generates the variables and String method for a single run of contiguous values.
|
|
func (g *Generator) buildOneRun(runs [][]Value, typeName string) {
|
|
values := runs[0]
|
|
g.Printf("\n")
|
|
g.declareIndexAndNameVar(values, typeName)
|
|
// The generated code is simple enough to write as a Printf format.
|
|
lessThanZero := ""
|
|
if values[0].signed {
|
|
lessThanZero = "i < 0 || "
|
|
}
|
|
if values[0].value == 0 { // Signed or unsigned, 0 is still 0.
|
|
g.Printf(stringOneRun, typeName, usize(len(values)), lessThanZero)
|
|
} else {
|
|
g.Printf(stringOneRunWithOffset, typeName, values[0].String(), usize(len(values)), lessThanZero)
|
|
}
|
|
}
|
|
|
|
// Arguments to format are:
|
|
//
|
|
// [1]: type name
|
|
// [2]: size of index element (8 for uint8 etc.)
|
|
// [3]: less than zero check (for signed types)
|
|
const stringOneRun = `func (i %[1]s) String() string {
|
|
if %[3]si >= %[1]s(len(_%[1]s_index)-1) {
|
|
return "%[1]s(" + strconv.FormatInt(int64(i), 10) + ")"
|
|
}
|
|
return _%[1]s_name[_%[1]s_index[i]:_%[1]s_index[i+1]]
|
|
}
|
|
`
|
|
|
|
// Arguments to format are:
|
|
// [1]: type name
|
|
// [2]: lowest defined value for type, as a string
|
|
// [3]: size of index element (8 for uint8 etc.)
|
|
// [4]: less than zero check (for signed types)
|
|
/*
|
|
*/
|
|
const stringOneRunWithOffset = `func (i %[1]s) String() string {
|
|
i -= %[2]s
|
|
if %[4]si >= %[1]s(len(_%[1]s_index)-1) {
|
|
return "%[1]s(" + strconv.FormatInt(int64(i + %[2]s), 10) + ")"
|
|
}
|
|
return _%[1]s_name[_%[1]s_index[i] : _%[1]s_index[i+1]]
|
|
}
|
|
`
|
|
|
|
// buildMultipleRuns generates the variables and String method for multiple runs of contiguous values.
|
|
// For this pattern, a single Printf format won't do.
|
|
func (g *Generator) buildMultipleRuns(runs [][]Value, typeName string) {
|
|
g.Printf("\n")
|
|
g.declareIndexAndNameVars(runs, typeName)
|
|
g.Printf("func (i %s) String() string {\n", typeName)
|
|
g.Printf("\tswitch {\n")
|
|
for i, values := range runs {
|
|
if len(values) == 1 {
|
|
g.Printf("\tcase i == %s:\n", &values[0])
|
|
g.Printf("\t\treturn _%s_name_%d\n", typeName, i)
|
|
continue
|
|
}
|
|
if values[0].value == 0 && !values[0].signed {
|
|
// For an unsigned lower bound of 0, "0 <= i" would be redundant.
|
|
g.Printf("\tcase i <= %s:\n", &values[len(values)-1])
|
|
} else {
|
|
g.Printf("\tcase %s <= i && i <= %s:\n", &values[0], &values[len(values)-1])
|
|
}
|
|
if values[0].value != 0 {
|
|
g.Printf("\t\ti -= %s\n", &values[0])
|
|
}
|
|
g.Printf("\t\treturn _%s_name_%d[_%s_index_%d[i]:_%s_index_%d[i+1]]\n",
|
|
typeName, i, typeName, i, typeName, i)
|
|
}
|
|
g.Printf("\tdefault:\n")
|
|
g.Printf("\t\treturn \"%s(\" + strconv.FormatInt(int64(i), 10) + \")\"\n", typeName)
|
|
g.Printf("\t}\n")
|
|
g.Printf("}\n")
|
|
}
|
|
|
|
// buildMap handles the case where the space is so sparse a map is a reasonable fallback.
|
|
// It's a rare situation but has simple code.
|
|
func (g *Generator) buildMap(runs [][]Value, typeName string) {
|
|
g.Printf("\n")
|
|
g.declareNameVars(runs, typeName, "")
|
|
g.Printf("\nvar _%s_map = map[%s]string{\n", typeName, typeName)
|
|
n := 0
|
|
for _, values := range runs {
|
|
for _, value := range values {
|
|
g.Printf("\t%s: _%s_name[%d:%d],\n", &value, typeName, n, n+len(value.name))
|
|
n += len(value.name)
|
|
}
|
|
}
|
|
g.Printf("}\n\n")
|
|
g.Printf(stringMap, typeName)
|
|
}
|
|
|
|
// Argument to format is the type name.
|
|
const stringMap = `func (i %[1]s) String() string {
|
|
if str, ok := _%[1]s_map[i]; ok {
|
|
return str
|
|
}
|
|
return "%[1]s(" + strconv.FormatInt(int64(i), 10) + ")"
|
|
}
|
|
`
|