package oss import ( "bytes" "errors" "fmt" "hash/crc64" "net/http" "os" "os/exec" "runtime" "strconv" "strings" "time" ) // userAgent gets user agent // It has the SDK version information, OS information and GO version var userAgent = func() string { sys := getSysInfo() return fmt.Sprintf("aliyun-sdk-go/%s (%s/%s/%s;%s)", Version, sys.name, sys.release, sys.machine, runtime.Version()) }() type sysInfo struct { name string // OS name such as windows/Linux release string // OS version 2.6.32-220.23.2.ali1089.el5.x86_64 etc machine string // CPU type amd64/x86_64 } // getSysInfo gets system info // gets the OS information and CPU type func getSysInfo() sysInfo { name := runtime.GOOS release := "-" machine := runtime.GOARCH if out, err := exec.Command("uname", "-s").CombinedOutput(); err == nil { name = string(bytes.TrimSpace(out)) } if out, err := exec.Command("uname", "-r").CombinedOutput(); err == nil { release = string(bytes.TrimSpace(out)) } if out, err := exec.Command("uname", "-m").CombinedOutput(); err == nil { machine = string(bytes.TrimSpace(out)) } return sysInfo{name: name, release: release, machine: machine} } // unpackedRange type unpackedRange struct { hasStart bool // Flag indicates if the start point is specified hasEnd bool // Flag indicates if the end point is specified start int64 // Start point end int64 // End point } // invalidRangeError returns invalid range error func invalidRangeError(r string) error { return fmt.Errorf("InvalidRange %s", r) } // parseRange parse various styles of range such as bytes=M-N func parseRange(normalizedRange string) (*unpackedRange, error) { var err error hasStart := false hasEnd := false var start int64 var end int64 // Bytes==M-N or ranges=M-N nrSlice := strings.Split(normalizedRange, "=") if len(nrSlice) != 2 || nrSlice[0] != "bytes" { return nil, invalidRangeError(normalizedRange) } // Bytes=M-N,X-Y rSlice := strings.Split(nrSlice[1], ",") rStr := rSlice[0] if strings.HasSuffix(rStr, "-") { // M- startStr := rStr[:len(rStr)-1] start, err = strconv.ParseInt(startStr, 10, 64) if err != nil { return nil, invalidRangeError(normalizedRange) } hasStart = true } else if strings.HasPrefix(rStr, "-") { // -N len := rStr[1:] end, err = strconv.ParseInt(len, 10, 64) if err != nil { return nil, invalidRangeError(normalizedRange) } if end == 0 { // -0 return nil, invalidRangeError(normalizedRange) } hasEnd = true } else { // M-N valSlice := strings.Split(rStr, "-") if len(valSlice) != 2 { return nil, invalidRangeError(normalizedRange) } start, err = strconv.ParseInt(valSlice[0], 10, 64) if err != nil { return nil, invalidRangeError(normalizedRange) } hasStart = true end, err = strconv.ParseInt(valSlice[1], 10, 64) if err != nil { return nil, invalidRangeError(normalizedRange) } hasEnd = true } return &unpackedRange{hasStart, hasEnd, start, end}, nil } // adjustRange returns adjusted range, adjust the range according to the length of the file func adjustRange(ur *unpackedRange, size int64) (start, end int64) { if ur == nil { return 0, size } if ur.hasStart && ur.hasEnd { start = ur.start end = ur.end + 1 if ur.start < 0 || ur.start >= size || ur.end > size || ur.start > ur.end { start = 0 end = size } } else if ur.hasStart { start = ur.start end = size if ur.start < 0 || ur.start >= size { start = 0 } } else if ur.hasEnd { start = size - ur.end end = size if ur.end < 0 || ur.end > size { start = 0 end = size } } return } // GetNowSec returns Unix time, the number of seconds elapsed since January 1, 1970 UTC. // gets the current time in Unix time, in seconds. func GetNowSec() int64 { return time.Now().Unix() } // GetNowNanoSec returns t as a Unix time, the number of nanoseconds elapsed // since January 1, 1970 UTC. The result is undefined if the Unix time // in nanoseconds cannot be represented by an int64. Note that this // means the result of calling UnixNano on the zero Time is undefined. // gets the current time in Unix time, in nanoseconds. func GetNowNanoSec() int64 { return time.Now().UnixNano() } // GetNowGMT gets the current time in GMT format. func GetNowGMT() string { return time.Now().UTC().Format(http.TimeFormat) } // FileChunk is the file chunk definition type FileChunk struct { Number int // Chunk number Offset int64 // Chunk offset Size int64 // Chunk size. } // SplitFileByPartNum splits big file into parts by the num of parts. // Split the file with specified parts count, returns the split result when error is nil. func SplitFileByPartNum(fileName string, chunkNum int) ([]FileChunk, error) { if chunkNum <= 0 || chunkNum > 10000 { return nil, errors.New("chunkNum invalid") } file, err := os.Open(fileName) if err != nil { return nil, err } defer file.Close() stat, err := file.Stat() if err != nil { return nil, err } if int64(chunkNum) > stat.Size() { return nil, errors.New("oss: chunkNum invalid") } var chunks []FileChunk var chunk = FileChunk{} var chunkN = (int64)(chunkNum) for i := int64(0); i < chunkN; i++ { chunk.Number = int(i + 1) chunk.Offset = i * (stat.Size() / chunkN) if i == chunkN-1 { chunk.Size = stat.Size()/chunkN + stat.Size()%chunkN } else { chunk.Size = stat.Size() / chunkN } chunks = append(chunks, chunk) } return chunks, nil } // SplitFileByPartSize splits big file into parts by the size of parts. // Splits the file by the part size. Returns the FileChunk when error is nil. func SplitFileByPartSize(fileName string, chunkSize int64) ([]FileChunk, error) { if chunkSize <= 0 { return nil, errors.New("chunkSize invalid") } file, err := os.Open(fileName) if err != nil { return nil, err } defer file.Close() stat, err := file.Stat() if err != nil { return nil, err } var chunkN = stat.Size() / chunkSize if chunkN >= 10000 { return nil, errors.New("Too many parts, please increase part size") } var chunks []FileChunk var chunk = FileChunk{} for i := int64(0); i < chunkN; i++ { chunk.Number = int(i + 1) chunk.Offset = i * chunkSize chunk.Size = chunkSize chunks = append(chunks, chunk) } if stat.Size()%chunkSize > 0 { chunk.Number = len(chunks) + 1 chunk.Offset = int64(len(chunks)) * chunkSize chunk.Size = stat.Size() % chunkSize chunks = append(chunks, chunk) } return chunks, nil } // GetPartEnd calculates the end position func GetPartEnd(begin int64, total int64, per int64) int64 { if begin+per > total { return total - 1 } return begin + per - 1 } // crcTable returns the table constructed from the specified polynomial var crcTable = func() *crc64.Table { return crc64.MakeTable(crc64.ECMA) }