// Copyright © 2014 Steve Francia . // // Licensed under the Simple Public License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // http://opensource.org/licenses/Simple-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. package helpers import ( "bytes" "crypto/md5" "encoding/hex" "errors" "fmt" "io" "net" "path/filepath" "reflect" "strings" "sync" "unicode" "unicode/utf8" "github.com/spf13/cast" bp "github.com/spf13/hugo/bufferpool" jww "github.com/spf13/jwalterweatherman" "github.com/spf13/pflag" "github.com/spf13/viper" ) // Filepath separator defined by os.Separator. const FilePathSeparator = string(filepath.Separator) // FindAvailablePort returns an available and valid TCP port. func FindAvailablePort() (*net.TCPAddr, error) { l, err := net.Listen("tcp", ":0") if err == nil { defer l.Close() addr := l.Addr() if a, ok := addr.(*net.TCPAddr); ok { return a, nil } return nil, fmt.Errorf("Unable to obtain a valid tcp port. %v", addr) } return nil, err } // InStringArray checks if a string is an element of a slice of strings // and returns a boolean value. func InStringArray(arr []string, el string) bool { for _, v := range arr { if v == el { return true } } return false } // GuessType attempts to guess the type of file from a given string. func GuessType(in string) string { switch strings.ToLower(in) { case "md", "markdown", "mdown": return "markdown" case "asciidoc", "adoc", "ad": return "asciidoc" case "mmark": return "mmark" case "rst": return "rst" case "html", "htm": return "html" } return "unknown" } // FirstUpper returns a string with the first character as upper case. func FirstUpper(s string) string { if s == "" { return "" } r, n := utf8.DecodeRuneInString(s) return string(unicode.ToUpper(r)) + s[n:] } // ReaderToBytes takes an io.Reader argument, reads from it // and returns bytes. func ReaderToBytes(lines io.Reader) []byte { if lines == nil { return []byte{} } b := bp.GetBuffer() defer bp.PutBuffer(b) b.ReadFrom(lines) bc := make([]byte, b.Len(), b.Len()) copy(bc, b.Bytes()) return bc } // ReaderToString is the same as ReaderToBytes, but returns a string. func ReaderToString(lines io.Reader) string { if lines == nil { return "" } b := bp.GetBuffer() defer bp.PutBuffer(b) b.ReadFrom(lines) return b.String() } // StringToReader does the opposite of ReaderToString. func StringToReader(in string) io.Reader { return strings.NewReader(in) } // BytesToReader does the opposite of ReaderToBytes. func BytesToReader(in []byte) io.Reader { return bytes.NewReader(in) } // ReaderContains reports whether subslice is within r. func ReaderContains(r io.Reader, subslice []byte) bool { if r == nil || len(subslice) == 0 { return false } bufflen := len(subslice) * 4 halflen := bufflen / 2 buff := make([]byte, bufflen) var err error var n, i int for { i++ if i == 1 { n, err = io.ReadAtLeast(r, buff[:halflen], halflen) } else { if i != 2 { // shift left to catch overlapping matches copy(buff[:], buff[halflen:]) } n, err = io.ReadAtLeast(r, buff[halflen:], halflen) } if n > 0 && bytes.Contains(buff, subslice) { return true } if err != nil { break } } return false } // ThemeSet checks whether a theme is in use or not. func ThemeSet() bool { return viper.GetString("theme") != "" } // DistinctErrorLogger ignores duplicate log statements. type DistinctErrorLogger struct { sync.RWMutex m map[string]bool } // Printf will ERROR log the string returned from fmt.Sprintf given the arguments, // but not if it has been logged before. func (l *DistinctErrorLogger) Printf(format string, v ...interface{}) { logStatement := fmt.Sprintf(format, v...) l.RLock() if l.m[logStatement] { l.RUnlock() return } l.RUnlock() l.Lock() if !l.m[logStatement] { jww.ERROR.Print(logStatement) l.m[logStatement] = true } l.Unlock() } // NewDistinctErrorLogger creates a new DistinctErrorLogger func NewDistinctErrorLogger() *DistinctErrorLogger { return &DistinctErrorLogger{m: make(map[string]bool)} } // Avoid spamming the logs with errors var DistinctErrorLog = NewDistinctErrorLogger() // Deprecated logs ERROR logs about a deprecation, but only once for a given set of arguments' values. func Deprecated(object, item, alternative string) { // deprecatedLogger.Printf("%s's %s is deprecated and will be removed in Hugo %s. Use %s instead.", object, item, NextHugoReleaseVersion(), alternative) DistinctErrorLog.Printf("%s's %s is deprecated and will be removed VERY SOON. Use %s instead.", object, item, alternative) } // SliceToLower goes through the source slice and lowers all values. func SliceToLower(s []string) []string { if s == nil { return nil } l := make([]string, len(s)) for i, v := range s { l[i] = strings.ToLower(v) } return l } // Md5String takes a string and returns its MD5 hash. func Md5String(f string) string { h := md5.New() h.Write([]byte(f)) return hex.EncodeToString(h.Sum([]byte{})) } // IsWhitespace determines if the given rune is whitespace. func IsWhitespace(r rune) bool { return r == ' ' || r == '\t' || r == '\n' || r == '\r' } // Seq creates a sequence of integers. // It's named and used as GNU's seq. // Examples: // 3 => 1, 2, 3 // 1 2 4 => 1, 3 // -3 => -1, -2, -3 // 1 4 => 1, 2, 3, 4 // 1 -2 => 1, 0, -1, -2 func Seq(args ...interface{}) ([]int, error) { if len(args) < 1 || len(args) > 3 { return nil, errors.New("Seq, invalid number of args: 'first' 'increment' (optional) 'last' (optional)") } intArgs := cast.ToIntSlice(args) if len(intArgs) < 1 || len(intArgs) > 3 { return nil, errors.New("Invalid argument(s) to Seq") } var inc = 1 var last int var first = intArgs[0] if len(intArgs) == 1 { last = first if last == 0 { return []int{}, nil } else if last > 0 { first = 1 } else { first = -1 inc = -1 } } else if len(intArgs) == 2 { last = intArgs[1] if last < first { inc = -1 } } else { inc = intArgs[1] last = intArgs[2] if inc == 0 { return nil, errors.New("'increment' must not be 0") } if first < last && inc < 0 { return nil, errors.New("'increment' must be > 0") } if first > last && inc > 0 { return nil, errors.New("'increment' must be < 0") } } // sanity check if last < -100000 { return nil, errors.New("size of result exeeds limit") } size := int(((last - first) / inc) + 1) // sanity check if size <= 0 || size > 2000 { return nil, errors.New("size of result exeeds limit") } seq := make([]int, size) val := first for i := 0; ; i++ { seq[i] = val val += inc if (inc < 0 && val < last) || (inc > 0 && val > last) { break } } return seq, nil } // DoArithmetic performs arithmetic operations (+,-,*,/) using reflection to // determine the type of the two terms. func DoArithmetic(a, b interface{}, op rune) (interface{}, error) { av := reflect.ValueOf(a) bv := reflect.ValueOf(b) var ai, bi int64 var af, bf float64 var au, bu uint64 switch av.Kind() { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: ai = av.Int() switch bv.Kind() { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: bi = bv.Int() case reflect.Float32, reflect.Float64: af = float64(ai) // may overflow ai = 0 bf = bv.Float() case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64: bu = bv.Uint() if ai >= 0 { au = uint64(ai) ai = 0 } else { bi = int64(bu) // may overflow bu = 0 } default: return nil, errors.New("Can't apply the operator to the values") } case reflect.Float32, reflect.Float64: af = av.Float() switch bv.Kind() { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: bf = float64(bv.Int()) // may overflow case reflect.Float32, reflect.Float64: bf = bv.Float() case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64: bf = float64(bv.Uint()) // may overflow default: return nil, errors.New("Can't apply the operator to the values") } case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64: au = av.Uint() switch bv.Kind() { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: bi = bv.Int() if bi >= 0 { bu = uint64(bi) bi = 0 } else { ai = int64(au) // may overflow au = 0 } case reflect.Float32, reflect.Float64: af = float64(au) // may overflow au = 0 bf = bv.Float() case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64: bu = bv.Uint() default: return nil, errors.New("Can't apply the operator to the values") } case reflect.String: as := av.String() if bv.Kind() == reflect.String && op == '+' { bs := bv.String() return as + bs, nil } return nil, errors.New("Can't apply the operator to the values") default: return nil, errors.New("Can't apply the operator to the values") } switch op { case '+': if ai != 0 || bi != 0 { return ai + bi, nil } else if af != 0 || bf != 0 { return af + bf, nil } else if au != 0 || bu != 0 { return au + bu, nil } else { return 0, nil } case '-': if ai != 0 || bi != 0 { return ai - bi, nil } else if af != 0 || bf != 0 { return af - bf, nil } else if au != 0 || bu != 0 { return au - bu, nil } else { return 0, nil } case '*': if ai != 0 || bi != 0 { return ai * bi, nil } else if af != 0 || bf != 0 { return af * bf, nil } else if au != 0 || bu != 0 { return au * bu, nil } else { return 0, nil } case '/': if bi != 0 { return ai / bi, nil } else if bf != 0 { return af / bf, nil } else if bu != 0 { return au / bu, nil } else { return nil, errors.New("Can't divide the value by 0") } default: return nil, errors.New("There is no such an operation") } } // NormalizeHugoFlagsFunc facilitates transitions of Hugo command-line flags, // e.g. --baseUrl to --baseURL, --uglyUrls to --uglyURLs func NormalizeHugoFlags(f *pflag.FlagSet, name string) pflag.NormalizedName { switch name { case "baseUrl": name = "baseURL" break case "uglyUrls": name = "uglyURLs" break } return pflag.NormalizedName(name) }