src/cmd/godoc/dirtrees.go - go - Git at Google

 // Copyright 2010 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 the code dealing with package directory trees.

 package main

 import (
 	"bytes"
 	"go/doc"
 	"go/parser"
 	"go/token"
 	"log"
 	"path/filepath"
 	"strings"
 	"unicode"
 )

 type Directory struct {
 	Depth int
 	Path  string // includes Name
 	Name  string
 	Text  string       // package documentation, if any
 	Dirs  []*Directory // subdirectories
 }

 func isGoFile(fi FileInfo) bool {
 	name := fi.Name()
 	return fi.IsRegular() &&
 		len(name) > 0 && name[0] != '.' && // ignore .files
 		filepath.Ext(name) == ".go"
 }

 func isPkgFile(fi FileInfo) bool {
 	return isGoFile(fi) &&
 		!strings.HasSuffix(fi.Name(), "_test.go") // ignore test files
 }

 func isPkgDir(fi FileInfo) bool {
 	name := fi.Name()
 	return fi.IsDirectory() && len(name) > 0 &&
 		name[0] != '_' && name[0] != '.' // ignore _files and .files
 }

 func firstSentence(s string) string {
 	i := -1 // index+1 of first terminator (punctuation ending a sentence)
 	j := -1 // index+1 of first terminator followed by white space
 	prev := 'A'
 	for k, ch := range s {
 		k1 := k + 1
 		if ch == '.' || ch == '!' || ch == '?' {
 			if i < 0 {
 				i = k1 // first terminator
 			}
 			if k1 < len(s) && s[k1] <= ' ' {
 				if j < 0 {
 					j = k1 // first terminator followed by white space
 				}
 				if !unicode.IsUpper(prev) {
 					j = k1
 					break
 				}
 			}
 		}
 		prev = ch
 	}

 	if j < 0 {
 		// use the next best terminator
 		j = i
 		if j < 0 {
 			// no terminator at all, use the entire string
 			j = len(s)
 		}
 	}

 	return s[0:j]
 }

 type treeBuilder struct {
 	pathFilter func(string) bool
 	maxDepth   int
 }

 func (b *treeBuilder) newDirTree(fset *token.FileSet, path, name string, depth int) *Directory {
 	if b.pathFilter != nil && !b.pathFilter(path) {
 		return nil
 	}

 	if depth >= b.maxDepth {
 		// return a dummy directory so that the parent directory
 		// doesn't get discarded just because we reached the max
 		// directory depth
 		return &Directory{depth, path, name, "", nil}
 	}

 	list, err := fs.ReadDir(path)
 	if err != nil {
 		// newDirTree is called with a path that should be a package
 		// directory; errors here should not happen, but if they do,
 		// we want to know about them
 		log.Printf("ReadDir(%s): %s", path, err)
 	}

 	// determine number of subdirectories and if there are package files
 	ndirs := 0
 	hasPkgFiles := false
 	var synopses [4]string // prioritized package documentation (0 == highest priority)
 	for _, d := range list {
 		switch {
 		case isPkgDir(d):
 			ndirs++
 		case isPkgFile(d):
 			// looks like a package file, but may just be a file ending in ".go";
 			// don't just count it yet (otherwise we may end up with hasPkgFiles even
 			// though the directory doesn't contain any real package files - was bug)
 			if synopses[0] == "" {
 				// no "optimal" package synopsis yet; continue to collect synopses
 				file, err := parseFile(fset, filepath.Join(path, d.Name()),
 					parser.ParseComments|parser.PackageClauseOnly)
 				if err == nil {
 					hasPkgFiles = true
 					if file.Doc != nil {
 						// prioritize documentation
 						i := -1
 						switch file.Name.Name {
 						case name:
 							i = 0 // normal case: directory name matches package name
 						case fakePkgName:
 							i = 1 // synopses for commands
 						case "main":
 							i = 2 // directory contains a main package
 						default:
 							i = 3 // none of the above
 						}
 						if 0 <= i && i < len(synopses) && synopses[i] == "" {
 							synopses[i] = firstSentence(doc.CommentText(file.Doc))
 						}
 					}
 				}
 			}
 		}
 	}

 	// create subdirectory tree
 	var dirs []*Directory
 	if ndirs > 0 {
 		dirs = make([]*Directory, ndirs)
 		i := 0
 		for _, d := range list {
 			if isPkgDir(d) {
 				name := d.Name()
 				dd := b.newDirTree(fset, filepath.Join(path, name), name, depth+1)
 				if dd != nil {
 					dirs[i] = dd
 					i++
 				}
 			}
 		}
 		dirs = dirs[0:i]
 	}

 	// if there are no package files and no subdirectories
 	// containing package files, ignore the directory
 	if !hasPkgFiles && len(dirs) == 0 {
 		return nil
 	}

 	// select the highest-priority synopsis for the directory entry, if any
 	synopsis := ""
 	for _, synopsis = range synopses {
 		if synopsis != "" {
 			break
 		}
 	}

 	return &Directory{depth, path, name, synopsis, dirs}
 }

 // newDirectory creates a new package directory tree with at most maxDepth
 // levels, anchored at root. The result tree is pruned such that it only
 // contains directories that contain package files or that contain
 // subdirectories containing package files (transitively). If a non-nil
 // pathFilter is provided, directory paths additionally must be accepted
 // by the filter (i.e., pathFilter(path) must be true). If a value >= 0 is
 // provided for maxDepth, nodes at larger depths are pruned as well; they
 // are assumed to contain package files even if their contents are not known
 // (i.e., in this case the tree may contain directories w/o any package files).
 //
 func newDirectory(root string, pathFilter func(string) bool, maxDepth int) *Directory {
 	// The root could be a symbolic link so use Stat not Lstat.
 	d, err := fs.Stat(root)
 	// If we fail here, report detailed error messages; otherwise
 	// is is hard to see why a directory tree was not built.
 	switch {
 	case err != nil:
 		log.Printf("newDirectory(%s): %s", root, err)
 		return nil
 	case !isPkgDir(d):
 		log.Printf("newDirectory(%s): not a package directory", root)
 		return nil
 	}
 	if maxDepth < 0 {
 		maxDepth = 1e6 // "infinity"
 	}
 	b := treeBuilder{pathFilter, maxDepth}
 	// the file set provided is only for local parsing, no position
 	// information escapes and thus we don't need to save the set
 	return b.newDirTree(token.NewFileSet(), root, d.Name(), 0)
 }

 func (dir *Directory) writeLeafs(buf *bytes.Buffer) {
 	if dir != nil {
 		if len(dir.Dirs) == 0 {
 			buf.WriteString(dir.Path)
 			buf.WriteByte('\n')
 			return
 		}

 		for _, d := range dir.Dirs {
 			d.writeLeafs(buf)
 		}
 	}
 }

 func (dir *Directory) walk(c chan<- *Directory, skipRoot bool) {
 	if dir != nil {
 		if !skipRoot {
 			c <- dir
 		}
 		for _, d := range dir.Dirs {
 			d.walk(c, false)
 		}
 	}
 }

 func (dir *Directory) iter(skipRoot bool) <-chan *Directory {
 	c := make(chan *Directory)
 	go func() {
 		dir.walk(c, skipRoot)
 		close(c)
 	}()
 	return c
 }

 func (dir *Directory) lookupLocal(name string) *Directory {
 	for _, d := range dir.Dirs {
 		if d.Name == name {
 			return d
 		}
 	}
 	return nil
 }

 // lookup looks for the *Directory for a given path, relative to dir.
 func (dir *Directory) lookup(path string) *Directory {
 	d := strings.Split(dir.Path, string(filepath.Separator))
 	p := strings.Split(path, string(filepath.Separator))
 	i := 0
 	for i < len(d) {
 		if i >= len(p) || d[i] != p[i] {
 			return nil
 		}
 		i++
 	}
 	for dir != nil && i < len(p) {
 		dir = dir.lookupLocal(p[i])
 		i++
 	}
 	return dir
 }

 // DirEntry describes a directory entry. The Depth and Height values
 // are useful for presenting an entry in an indented fashion.
 //
 type DirEntry struct {
 	Depth    int    // >= 0
 	Height   int    // = DirList.MaxHeight - Depth, > 0
 	Path     string // includes Name, relative to DirList root
 	Name     string
 	Synopsis string
 }

 type DirList struct {
 	MaxHeight int // directory tree height, > 0
 	List      []DirEntry
 }

 // listing creates a (linear) directory listing from a directory tree.
 // If skipRoot is set, the root directory itself is excluded from the list.
 //
 func (root *Directory) listing(skipRoot bool) *DirList {
 	if root == nil {
 		return nil
 	}

 	// determine number of entries n and maximum height
 	n := 0
 	minDepth := 1 << 30 // infinity
 	maxDepth := 0
 	for d := range root.iter(skipRoot) {
 		n++
 		if minDepth > d.Depth {
 			minDepth = d.Depth
 		}
 		if maxDepth < d.Depth {
 			maxDepth = d.Depth
 		}
 	}
 	maxHeight := maxDepth - minDepth + 1

 	if n == 0 {
 		return nil
 	}

 	// create list
 	list := make([]DirEntry, n)
 	i := 0
 	for d := range root.iter(skipRoot) {
 		p := &list[i]
 		p.Depth = d.Depth - minDepth
 		p.Height = maxHeight - p.Depth
 		// the path is relative to root.Path - remove the root.Path
 		// prefix (the prefix should always be present but avoid
 		// crashes and check)
 		path := d.Path
 		if strings.HasPrefix(d.Path, root.Path) {
 			path = d.Path[len(root.Path):]
 		}
 		// remove trailing separator if any - path must be relative
 		if len(path) > 0 && path[0] == filepath.Separator {
 			path = path[1:]
 		}
 		p.Path = path
 		p.Name = d.Name
 		p.Synopsis = d.Text
 		i++
 	}

 	return &DirList{maxHeight, list}
 }
	// Copyright 2010 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 the code dealing with package directory trees.

	package main

	import (
	"bytes"
	"go/doc"
	"go/parser"
	"go/token"
	"log"
	"path/filepath"
	"strings"
	"unicode"
	)

	type Directory struct {
	Depth int
	Path string // includes Name
	Name string
	Text string // package documentation, if any
	Dirs []*Directory // subdirectories
	}

	func isGoFile(fi FileInfo) bool {
	name := fi.Name()
	return fi.IsRegular() &&
	len(name) > 0 && name[0] != '.' && // ignore .files
	filepath.Ext(name) == ".go"
	}

	func isPkgFile(fi FileInfo) bool {
	return isGoFile(fi) &&
	!strings.HasSuffix(fi.Name(), "_test.go") // ignore test files
	}

	func isPkgDir(fi FileInfo) bool {
	name := fi.Name()
	return fi.IsDirectory() && len(name) > 0 &&
	name[0] != '_' && name[0] != '.' // ignore _files and .files
	}

	func firstSentence(s string) string {
	i := -1 // index+1 of first terminator (punctuation ending a sentence)
	j := -1 // index+1 of first terminator followed by white space
	prev := 'A'
	for k, ch := range s {
	k1 := k + 1
	if ch == '.' \|\| ch == '!' \|\| ch == '?' {
	if i < 0 {
	i = k1 // first terminator
	}
	if k1 < len(s) && s[k1] <= ' ' {
	if j < 0 {
	j = k1 // first terminator followed by white space
	}
	if !unicode.IsUpper(prev) {
	j = k1
	break
	}
	}
	}
	prev = ch
	}

	if j < 0 {
	// use the next best terminator
	j = i
	if j < 0 {
	// no terminator at all, use the entire string
	j = len(s)
	}
	}

	return s[0:j]
	}

	type treeBuilder struct {
	pathFilter func(string) bool
	maxDepth int
	}

	func (b treeBuilder) newDirTree(fset token.FileSet, path, name string, depth int) *Directory {
	if b.pathFilter != nil && !b.pathFilter(path) {
	return nil
	}

	if depth >= b.maxDepth {
	// return a dummy directory so that the parent directory
	// doesn't get discarded just because we reached the max
	// directory depth
	return &Directory{depth, path, name, "", nil}
	}

	list, err := fs.ReadDir(path)
	if err != nil {
	// newDirTree is called with a path that should be a package
	// directory; errors here should not happen, but if they do,
	// we want to know about them
	log.Printf("ReadDir(%s): %s", path, err)
	}

	// determine number of subdirectories and if there are package files
	ndirs := 0
	hasPkgFiles := false
	var synopses [4]string // prioritized package documentation (0 == highest priority)
	for _, d := range list {
	switch {
	case isPkgDir(d):
	ndirs++
	case isPkgFile(d):
	// looks like a package file, but may just be a file ending in ".go";
	// don't just count it yet (otherwise we may end up with hasPkgFiles even
	// though the directory doesn't contain any real package files - was bug)
	if synopses[0] == "" {
	// no "optimal" package synopsis yet; continue to collect synopses
	file, err := parseFile(fset, filepath.Join(path, d.Name()),
	parser.ParseComments\|parser.PackageClauseOnly)
	if err == nil {
	hasPkgFiles = true
	if file.Doc != nil {
	// prioritize documentation
	i := -1
	switch file.Name.Name {
	case name:
	i = 0 // normal case: directory name matches package name
	case fakePkgName:
	i = 1 // synopses for commands
	case "main":
	i = 2 // directory contains a main package
	default:
	i = 3 // none of the above
	}
	if 0 <= i && i < len(synopses) && synopses[i] == "" {
	synopses[i] = firstSentence(doc.CommentText(file.Doc))
	}
	}
	}
	}
	}
	}

	// create subdirectory tree
	var dirs []*Directory
	if ndirs > 0 {
	dirs = make([]*Directory, ndirs)
	i := 0
	for _, d := range list {
	if isPkgDir(d) {
	name := d.Name()
	dd := b.newDirTree(fset, filepath.Join(path, name), name, depth+1)
	if dd != nil {
	dirs[i] = dd
	i++
	}
	}
	}
	dirs = dirs[0:i]
	}

	// if there are no package files and no subdirectories
	// containing package files, ignore the directory
	if !hasPkgFiles && len(dirs) == 0 {
	return nil
	}

	// select the highest-priority synopsis for the directory entry, if any
	synopsis := ""
	for _, synopsis = range synopses {
	if synopsis != "" {
	break
	}
	}

	return &Directory{depth, path, name, synopsis, dirs}
	}

	// newDirectory creates a new package directory tree with at most maxDepth
	// levels, anchored at root. The result tree is pruned such that it only
	// contains directories that contain package files or that contain
	// subdirectories containing package files (transitively). If a non-nil
	// pathFilter is provided, directory paths additionally must be accepted
	// by the filter (i.e., pathFilter(path) must be true). If a value >= 0 is
	// provided for maxDepth, nodes at larger depths are pruned as well; they
	// are assumed to contain package files even if their contents are not known
	// (i.e., in this case the tree may contain directories w/o any package files).
	//
	func newDirectory(root string, pathFilter func(string) bool, maxDepth int) *Directory {
	// The root could be a symbolic link so use Stat not Lstat.
	d, err := fs.Stat(root)
	// If we fail here, report detailed error messages; otherwise
	// is is hard to see why a directory tree was not built.
	switch {
	case err != nil:
	log.Printf("newDirectory(%s): %s", root, err)
	return nil
	case !isPkgDir(d):
	log.Printf("newDirectory(%s): not a package directory", root)
	return nil
	}
	if maxDepth < 0 {
	maxDepth = 1e6 // "infinity"
	}
	b := treeBuilder{pathFilter, maxDepth}
	// the file set provided is only for local parsing, no position
	// information escapes and thus we don't need to save the set
	return b.newDirTree(token.NewFileSet(), root, d.Name(), 0)
	}

	func (dir Directory) writeLeafs(buf bytes.Buffer) {
	if dir != nil {
	if len(dir.Dirs) == 0 {
	buf.WriteString(dir.Path)
	buf.WriteByte('\n')
	return
	}

	for _, d := range dir.Dirs {
	d.writeLeafs(buf)
	}
	}
	}

	func (dir Directory) walk(c chan<- Directory, skipRoot bool) {
	if dir != nil {
	if !skipRoot {
	c <- dir
	}
	for _, d := range dir.Dirs {
	d.walk(c, false)
	}
	}
	}

	func (dir Directory) iter(skipRoot bool) <-chan Directory {
	c := make(chan *Directory)
	go func() {
	dir.walk(c, skipRoot)
	close(c)
	}()
	return c
	}

	func (dir Directory) lookupLocal(name string) Directory {
	for _, d := range dir.Dirs {
	if d.Name == name {
	return d
	}
	}
	return nil
	}

	// lookup looks for the *Directory for a given path, relative to dir.
	func (dir Directory) lookup(path string) Directory {
	d := strings.Split(dir.Path, string(filepath.Separator))
	p := strings.Split(path, string(filepath.Separator))
	i := 0
	for i < len(d) {
	if i >= len(p) \|\| d[i] != p[i] {
	return nil
	}
	i++
	}
	for dir != nil && i < len(p) {
	dir = dir.lookupLocal(p[i])
	i++
	}
	return dir
	}

	// DirEntry describes a directory entry. The Depth and Height values
	// are useful for presenting an entry in an indented fashion.
	//
	type DirEntry struct {
	Depth int // >= 0
	Height int // = DirList.MaxHeight - Depth, > 0
	Path string // includes Name, relative to DirList root
	Name string
	Synopsis string
	}

	type DirList struct {
	MaxHeight int // directory tree height, > 0
	List []DirEntry
	}

	// listing creates a (linear) directory listing from a directory tree.
	// If skipRoot is set, the root directory itself is excluded from the list.
	//
	func (root Directory) listing(skipRoot bool) DirList {
	if root == nil {
	return nil
	}

	// determine number of entries n and maximum height
	n := 0
	minDepth := 1 << 30 // infinity
	maxDepth := 0
	for d := range root.iter(skipRoot) {
	n++
	if minDepth > d.Depth {
	minDepth = d.Depth
	}
	if maxDepth < d.Depth {
	maxDepth = d.Depth
	}
	}
	maxHeight := maxDepth - minDepth + 1

	if n == 0 {
	return nil
	}

	// create list
	list := make([]DirEntry, n)
	i := 0
	for d := range root.iter(skipRoot) {
	p := &list[i]
	p.Depth = d.Depth - minDepth
	p.Height = maxHeight - p.Depth
	// the path is relative to root.Path - remove the root.Path
	// prefix (the prefix should always be present but avoid
	// crashes and check)
	path := d.Path
	if strings.HasPrefix(d.Path, root.Path) {
	path = d.Path[len(root.Path):]
	}
	// remove trailing separator if any - path must be relative
	if len(path) > 0 && path[0] == filepath.Separator {
	path = path[1:]
	}
	p.Path = path
	p.Name = d.Name
	p.Synopsis = d.Text
	i++
	}

	return &DirList{maxHeight, list}
	}