/* Real-time Online/Offline Charging System (OCS) for Telecom & ISP environments Copyright (C) ITsysCOM GmbH This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see */ package utils import ( "archive/zip" "bytes" "crypto/aes" "crypto/cipher" "crypto/rand" "crypto/sha1" "encoding/gob" "encoding/hex" "encoding/json" "errors" "fmt" "io" "math" math_rand "math/rand" "os" "path/filepath" "regexp" "slices" "strconv" "strings" "sync" "time" "golang.org/x/crypto/bcrypt" ) var ( boolGenerator *boolGen rfc3339Rule = regexp.MustCompile(`^\d{4}-\d{2}-\d{2}T\d{2}:\d{2}:\d{2}.+$`) sqlRule = regexp.MustCompile(`^\d{4}-\d{2}-\d{2}\s\d{2}:\d{2}:\d{2}$`) utcFormat = regexp.MustCompile(`^\d{4}-\d{2}-\d{2}[T]\d{2}:\d{2}:\d{2}$`) gotimeRule = regexp.MustCompile(`^\d{4}-\d{2}-\d{2}\s\d{2}:\d{2}:\d{2}\.?\d*\s[+,-]\d+\s\w+$`) gotimeRule2 = regexp.MustCompile(`^\d{4}-\d{2}-\d{2}\s\d{2}:\d{2}:\d{2}\.?\d*\s[+,-]\d+\s[+,-]\d+$`) fsTimestamp = regexp.MustCompile(`^\d{16}$`) astTimestamp = regexp.MustCompile(`^\d{4}-\d{2}-\d{2}T\d{2}:\d{2}:\d{2}\.\d*[+,-]\d+$`) unixTimestampRule = regexp.MustCompile(`^\d{10}$`) unixTimestampMilisecondsRule = regexp.MustCompile(`^\d{13}$`) unixTimestampNanosecondsRule = regexp.MustCompile(`^\d{19}$`) oneLineTimestampRule = regexp.MustCompile(`^\d{14}$`) oneSpaceTimestampRule = regexp.MustCompile(`^\d{2}\.\d{2}.\d{4}\s{1}\d{2}:\d{2}:\d{2}$`) eamonTimestampRule = regexp.MustCompile(`^\d{2}/\d{2}/\d{4}\s{1}\d{2}:\d{2}:\d{2}$`) broadsoftTimestampRule = regexp.MustCompile(`^\d{14}\.\d{3}`) ) func init() { boolGenerator = newBoolGen() } // BoolGenerator return the boolean generator func BoolGenerator() *boolGen { return boolGenerator } func NewCounter(start, limit int64) *Counter { return &Counter{ value: start, limit: limit, } } type Counter struct { value, limit int64 sync.Mutex } func (c *Counter) Next() int64 { c.Lock() defer c.Unlock() c.value += 1 if c.limit > 0 && c.value > c.limit { c.value = 0 } return c.value } func (c *Counter) Value() int64 { c.Lock() defer c.Unlock() return c.value } // Returns first non empty string out of vals. Useful to extract defaults func FirstNonEmpty(vals ...string) string { for _, val := range vals { if len(val) != 0 { return val } } return EmptyString } func FirstIntNonEmpty(vals ...int) int { for _, val := range vals { if val != 0 { return val } } return 0 } func FirstDurationNonEmpty(vals ...time.Duration) time.Duration { for _, val := range vals { if val != 0 { return val } } return 0 } // Sha1 generate the SHA1 hash from any string // the order of string matters func Sha1(attrs ...string) string { hasher := sha1.New() for _, attr := range attrs { hasher.Write([]byte(attr)) } return fmt.Sprintf("%x", hasher.Sum(nil)) } // helper function for uuid generation func GenUUID() string { b := make([]byte, 16) io.ReadFull(rand.Reader, b) b[6] = (b[6] & 0x0F) | 0x40 b[8] = (b[8] &^ 0x40) | 0x80 return fmt.Sprintf("%x-%x-%x-%x-%x", b[:4], b[4:6], b[6:8], b[8:10], b[10:]) } // UUIDSha1Prefix generates a prefix of the sha1 applied to an UUID // prefix 8 is chosen since the probability of colision starts being minimal after 7 characters (see git commits) func UUIDSha1Prefix() string { return Sha1(GenUUID())[:7] } // Round return rounded version of x with prec precision. // // Special cases are: // // Round(±0) = ±0 // Round(±Inf) = ±Inf // Round(NaN) = NaN func Round(x float64, prec int, method string) float64 { var rounder float64 maxPrec := 7 // define a max precision to cut float errors if maxPrec < prec { maxPrec = prec } pow := math.Pow(10, float64(prec)) intermed := x * pow _, frac := math.Modf(intermed) switch method { case MetaRoundingUp: if frac >= math.Pow10(-maxPrec) { // Max precision we go, rest is float chaos rounder = math.Ceil(intermed) } else { rounder = math.Floor(intermed) } case MetaRoundingDown: rounder = math.Floor(intermed) case MetaRoundingMiddle: if frac >= 0.5 { rounder = math.Ceil(intermed) } else { rounder = math.Floor(intermed) } default: rounder = intermed } return rounder / pow } // RoundStatDuration is used in engine package for stat metrics that has duration (e.g acd metric, tcd metric, etc...) func RoundStatDuration(x time.Duration, prec int) time.Duration { return x.Round(time.Duration(math.Pow10(9 - prec))) } func getAddDuration(tmStr string) (addDur time.Duration, err error) { eDurIdx := strings.Index(tmStr, "+") if eDurIdx == -1 { return } return time.ParseDuration(tmStr[eDurIdx+1:]) } // ParseTimeDetectLayout returns the time from string func ParseTimeDetectLayout(tmStr string, timezone string) (time.Time, error) { tmStr = strings.TrimSpace(tmStr) var nilTime time.Time if len(tmStr) == 0 || tmStr == MetaUnlimited { return nilTime, nil } loc, err := time.LoadLocation(timezone) if err != nil { return nilTime, err } switch { case tmStr == MetaUnlimited || tmStr == "": // leave it at zero case tmStr == MetaDaily: return time.Now().AddDate(0, 0, 1), nil // add one day case tmStr == MetaMonthly: return time.Now().AddDate(0, 1, 0), nil // add one month case tmStr == MetaMonthlyEstimated: return monthlyEstimated(time.Now()) case tmStr == MetaYearly: return time.Now().AddDate(1, 0, 0), nil // add one year case strings.HasPrefix(tmStr, "*month_end"): expDate := GetEndOfMonth(time.Now()) extraDur, err := getAddDuration(tmStr) if err != nil { return nilTime, err } expDate = expDate.Add(extraDur) return expDate, nil case strings.HasPrefix(tmStr, "*mo"): // add one month and extra duration extraDur, err := getAddDuration(tmStr) if err != nil { return nilTime, err } return time.Now().AddDate(0, 1, 0).Add(extraDur), nil case astTimestamp.MatchString(tmStr): return time.Parse("2006-01-02T15:04:05.999999999-0700", tmStr) case rfc3339Rule.MatchString(tmStr): return time.Parse(time.RFC3339, tmStr) case gotimeRule.MatchString(tmStr): return time.Parse("2006-01-02 15:04:05.999999999 -0700 MST", tmStr) case gotimeRule2.MatchString(tmStr): return time.Parse("2006-01-02 15:04:05.999999999 -0700 -0700", tmStr) case sqlRule.MatchString(tmStr): return time.ParseInLocation("2006-01-02 15:04:05", tmStr, loc) case fsTimestamp.MatchString(tmStr): if tmstmp, err := strconv.ParseInt(tmStr+"000", 10, 64); err != nil { return nilTime, err } else { return time.Unix(0, tmstmp).In(loc), nil } case unixTimestampRule.MatchString(tmStr): //error never happens because of regex tmstmp, _ := strconv.ParseInt(tmStr, 10, 64) return time.Unix(tmstmp, 0).In(loc), nil case unixTimestampMilisecondsRule.MatchString(tmStr): //error never happens because of regex tmstmp, _ := strconv.ParseInt(tmStr, 10, 64) return time.Unix(0, tmstmp*int64(time.Millisecond)).In(loc), nil case unixTimestampNanosecondsRule.MatchString(tmStr): if tmstmp, err := strconv.ParseInt(tmStr, 10, 64); err != nil { return nilTime, err } else { return time.Unix(0, tmstmp).In(loc), nil } case tmStr == "0" || len(tmStr) == 0: // Time probably missing from request return nilTime, nil case oneLineTimestampRule.MatchString(tmStr): return time.ParseInLocation("20060102150405", tmStr, loc) case oneSpaceTimestampRule.MatchString(tmStr): return time.ParseInLocation("02.01.2006 15:04:05", tmStr, loc) case eamonTimestampRule.MatchString(tmStr): return time.ParseInLocation("02/01/2006 15:04:05", tmStr, loc) case broadsoftTimestampRule.MatchString(tmStr): return time.ParseInLocation("20060102150405.999", tmStr, loc) case tmStr == MetaNow: return time.Now(), nil case strings.HasPrefix(tmStr, "+"): tmStr = strings.TrimPrefix(tmStr, "+") if tmStrTmp, err := time.ParseDuration(tmStr); err != nil { return nilTime, err } else { return time.Now().Add(tmStrTmp), nil } case strings.HasPrefix(tmStr, "-"): tmStr = strings.TrimPrefix(tmStr, "-") if tmStrTmp, err := time.ParseDuration(tmStr); err != nil { return nilTime, err } else { return time.Now().Add(-tmStrTmp), nil } case utcFormat.MatchString(tmStr): return time.ParseInLocation("2006-01-02T15:04:05", tmStr, loc) } return nilTime, errors.New("Unsupported time format") } // monthlyEstimated calculates the next month's estimated end date by adjusting for month-end variations // and handling edge cases like different month lengths and leap years func monthlyEstimated(t1 time.Time) (time.Time, error) { initialMnt := t1.Month() tAfter := t1.AddDate(0, 1, 0) for tAfter.Month()-initialMnt > 1 { tAfter = tAfter.AddDate(0, 0, -1) } return tAfter, nil } // RoundDuration returns a number equal or larger than the amount that exactly // is divisible to whole func RoundDuration(whole, amount time.Duration) time.Duration { a, w := float64(amount), float64(whole) if math.Mod(a, w) == 0 { return amount } return time.Duration((w - math.Mod(a, w)) + a) } func SplitPrefix(prefix string, minLength int) []string { length := int(math.Max(float64(len(prefix)-(minLength-1)), 0)) subs := make([]string, length) max := len(prefix) for i := 0; i < length; i++ { subs[i] = prefix[:max-i] } return subs } func SplitSuffix(suffix string) []string { length := len(suffix) subs := make([]string, length) max := len(suffix) - 1 for i := 0; i < length; i++ { subs[i] = suffix[max-i:] } return subs } func CopyHour(src, dest time.Time) time.Time { if src.Hour() == 0 && src.Minute() == 0 && src.Second() == 0 { return src } return time.Date(dest.Year(), dest.Month(), dest.Day(), src.Hour(), src.Minute(), src.Second(), src.Nanosecond(), src.Location()) } // Parses duration, considers s as time unit if not provided, seconds as float to specify subunits func ParseDurationWithSecs(durStr string) (d time.Duration, err error) { if durStr == "" { return } if _, err = strconv.ParseFloat(durStr, 64); err == nil { // Seconds format considered durStr += "s" } return time.ParseDuration(durStr) } // Parses duration, considers s as time unit if not provided, seconds as float to specify subunits func ParseDurationWithNanosecs(durStr string) (d time.Duration, err error) { if durStr == "" { return } if durStr == MetaUnlimited { durStr = "-1" } if _, err = strconv.ParseFloat(durStr, 64); err == nil { // Seconds format considered durStr += "ns" } return time.ParseDuration(durStr) } // returns the minimum duration between the two func MinDuration(d1, d2 time.Duration) time.Duration { if d1 < d2 { return d1 } return d2 } // ParseZeroRatingSubject will parse the subject in the balance // returns duration if able to extract it from subject // returns error if not able to parse duration (ie: if ratingSubject is standard one) func ParseZeroRatingSubject(tor, rateSubj string, defaultRateSubj map[string]string, isUnitBal bool) (time.Duration, error) { rateSubj = strings.TrimSpace(rateSubj) if !isUnitBal && rateSubj == EmptyString { return 0, errors.New("no rating subject for monetary") } if rateSubj == EmptyString || rateSubj == MetaAny { var hasToR bool if rateSubj, hasToR = defaultRateSubj[tor]; !hasToR { rateSubj = defaultRateSubj[MetaAny] } } if !strings.HasPrefix(rateSubj, MetaRatingSubjectPrefix) { return 0, errors.New("malformed rating subject: " + rateSubj) } durStr := rateSubj[len(MetaRatingSubjectPrefix):] if val, err := strconv.ParseFloat(durStr, 64); err == nil { // No time unit, postpend return time.Duration(val), nil // just return the float value converted(this should be faster than reparsing the string) } return time.ParseDuration(durStr) } func ConcatenatedKey(keyVals ...string) string { return strings.Join(keyVals, ConcatenatedKeySep) } func SplitConcatenatedKey(key string) []string { return strings.Split(key, ConcatenatedKeySep) } func InfieldJoin(vals ...string) string { return strings.Join(vals, InfieldSep) } func InfieldSplit(val string) []string { return strings.Split(val, InfieldSep) } // Splited Unzip in small functions to have better coverage func Unzip(src, dest string) error { r, err := zip.OpenReader(src) if err != nil { return err } defer r.Close() for _, f := range r.File { path := filepath.Join(dest, f.Name) if f.FileInfo().IsDir() { os.MkdirAll(path, f.Mode()) continue } err = unzipFile(f, path, f.Mode()) if err != nil { return err } } return err } type zipFile interface { Open() (io.ReadCloser, error) } func unzipFile(f zipFile, path string, fm os.FileMode) (err error) { rc, err := f.Open() if err != nil { return err } err = copyFile(rc, path, fm) rc.Close() if err != nil { return err } return nil } func copyFile(rc io.ReadCloser, path string, fm os.FileMode) (err error) { f, err := os.OpenFile( path, os.O_WRONLY|os.O_CREATE|os.O_TRUNC, fm) if err != nil { return err } defer f.Close() _, err = io.Copy(f, rc) return } // Fib returns successive Fibonacci numbers. func Fib() func() int { a, b := 0, 1 return func() int { a, b = b, a+b // Prevent int overflow by keeping b as the maximum valid Fibonacci number. if b < a { b = a } return a } } // FibDuration returns successive Fibonacci numbers as time.Duration with the // unit specified by durationUnit or maxDuration if it is exceeded func FibDuration(durationUnit, maxDuration time.Duration) func() time.Duration { fib := Fib() return func() time.Duration { fibNrAsDuration := time.Duration(fib()) // Handle potential overflow when multiplying by durationUnit. if fibNrAsDuration > (math.MaxInt / durationUnit) { fibNrAsDuration = math.MaxInt } else { fibNrAsDuration *= durationUnit } // Cap the duration to maxDuration if specified. if maxDuration > 0 && maxDuration < fibNrAsDuration { return maxDuration } return fibNrAsDuration } } // Utilities to provide pointers where we need to define ad-hoc func StringPointer(str string) *string { if str == MetaZero { str = EmptyString return &str } return &str } func IntPointer(i int) *int { return &i } func Int64Pointer(i int64) *int64 { return &i } func Float64Pointer(f float64) *float64 { return &f } func BoolPointer(b bool) *bool { return &b } func StringMapPointer(sm StringMap) *StringMap { return &sm } func MapStringStringPointer(mp map[string]string) *map[string]string { return &mp } func MapStringSlicePointer(mp map[string][]string) *map[string][]string { return &mp } func TimePointer(t time.Time) *time.Time { return &t } func DurationPointer(d time.Duration) *time.Duration { return &d } func SliceStringPointer(d []string) *[]string { return &d } func ToIJSON(v any) string { b, _ := json.MarshalIndent(v, "", " ") return string(b) } func ToJSON(v any) string { b, _ := json.Marshal(v) return string(b) } // Simple object cloner, b should be a pointer towards a value into which we want to decode func Clone(a, b any) error { buff := new(bytes.Buffer) enc := gob.NewEncoder(buff) dec := gob.NewDecoder(buff) if err := enc.Encode(a); err != nil { return err } return dec.Decode(b) } // Used as generic function logic for various fields // Attributes // // source - the base source // width - the field width // strip - if present it will specify the strip strategy, when missing strip will not be allowed // padding - if present it will specify the padding strategy to use, left, right, zeroleft, zeroright func FmtFieldWidth(fieldID, source string, width int, strip, padding string, mandatory bool) (string, error) { if mandatory && len(source) == 0 { return "", fmt.Errorf("Empty source value for fieldID: <%s>", fieldID) } if width == 0 { // Disable width processing if not defined return source, nil } if len(source) == width { // the source is exactly the maximum length return source, nil } if len(source) > width { //the source is bigger than allowed if len(strip) == 0 { return "", fmt.Errorf("Source %s is bigger than the width %d, no strip defied, fieldID: <%s>", source, width, fieldID) } if strip == MetaRight { return source[:width], nil } else if strip == MetaXRight { return source[:width-1] + "x", nil // Suffix with x to mark prefix } else if strip == MetaLeft { diffIndx := len(source) - width return source[diffIndx:], nil } else if strip == MetaXLeft { // Prefix one x to mark stripping diffIndx := len(source) - width return "x" + source[diffIndx+1:], nil } } else { //the source is smaller as the maximum allowed if len(padding) == 0 { return "", fmt.Errorf("Source %s is smaller than the width %d, no padding defined, fieldID: <%s>", source, width, fieldID) } var paddingFmt string switch padding { case MetaRight: paddingFmt = fmt.Sprintf("%%-%ds", width) case MetaLeft: paddingFmt = fmt.Sprintf("%%%ds", width) case MetaZeroLeft: paddingFmt = fmt.Sprintf("%%0%ds", width) } if len(paddingFmt) != 0 { return fmt.Sprintf(paddingFmt, source), nil } } return source, nil } func GetEndOfMonth(ref time.Time) time.Time { if ref.IsZero() { return time.Now() } year, month, _ := ref.Date() if month == time.December { year++ month = time.January } else { month++ } eom := time.Date(year, month, 1, 0, 0, 0, 0, ref.Location()) return eom.Add(-time.Second) } // formats number in K,M,G, etc. func SizeFmt(num float64, suffix string) string { if suffix == EmptyString { suffix = "B" } for _, unit := range []string{"", "Ki", "Mi", "Gi", "Ti", "Pi", "Ei", "Zi"} { if math.Abs(num) < 1024.0 { return fmt.Sprintf("%3.1f%s%s", num, unit, suffix) } num /= 1024.0 } return fmt.Sprintf("%.1f%s%s", num, "Yi", suffix) } func TimeIs0h(t time.Time) bool { return t.Hour() == 0 && t.Minute() == 0 && t.Second() == 0 } func ParseHierarchyPath(path string, sep string) HierarchyPath { if path == EmptyString { return nil } if sep == EmptyString { for _, sep = range []string{"/", NestingSep} { if strings.Contains(path, sep) { break } } } path = strings.Trim(path, sep) // Need to strip if prefix of suffiy (eg: paths with /) so we can properly split return HierarchyPath(strings.Split(path, sep)) } // HierarchyPath is used in various places to represent various path hierarchies (eg: in Diameter groups, XML trees) type HierarchyPath []string // AsString converts HierarchyPath to a string. func (hP HierarchyPath) AsString(sep string, isAbsolute bool) string { var strHP strings.Builder // If isAbsolute is true and the HierarchyPath slice is empty, sep will be returned. // This will indicate the start of the absolute path. if isAbsolute { strHP.WriteString(sep) } if len(hP) == 0 { // If isAbsolute is false and HierarchyPath is empty, return '.' to represent the current directory in a relative path. // This convention avoids errors (e.g., "expr expression is nil") when retrieving elements from an empty path. if !isAbsolute { return "." } return strHP.String() } for i, elem := range hP { if i != 0 { strHP.WriteString(sep) } strHP.WriteString(elem) } return strHP.String() } // Clone returns a deep copy of HierarchyPath func (h HierarchyPath) Clone() (cln HierarchyPath) { if h == nil { return } return slices.Clone(h) } // Mask a number of characters in the suffix of the destination func MaskSuffix(dest string, maskLen int) string { destLen := len(dest) if maskLen < 0 { return dest } else if maskLen > destLen { maskLen = destLen } dest = dest[:destLen-maskLen] for i := 0; i < maskLen; i++ { dest += MaskChar } return dest } // Sortable Int64Slice type Int64Slice []int64 func (slc Int64Slice) Len() int { return len(slc) } func (slc Int64Slice) Swap(i, j int) { slc[i], slc[j] = slc[j], slc[i] } func (slc Int64Slice) Less(i, j int) bool { return slc[i] < slc[j] } func GetCGRVersion() (vers string, err error) { vers = fmt.Sprintf("%s@%s", CGRateS, Version) if GitCommitDate == "" || GitCommitHash == "" { return vers, nil } var matched bool /* Git v2.45 relevant release note: * The output format for dates "iso-strict" has been tweaked to show a time in the Zulu timezone with "Z" suffix, instead of "+00:00". */ // Parse the git commit date, which might be in different formats depending on the git version trimmedCommitDate := strings.TrimSpace(GitCommitDate) commitDate, err := time.Parse("2006-01-02T15:04:05Z", trimmedCommitDate) if err != nil { // Failed to parse iso-strict date format for git version 2.45+. Try to parse with the previous format. var fallbackErr error commitDate, fallbackErr = time.Parse("2006-01-02T15:04:05-07:00", trimmedCommitDate) if fallbackErr != nil { // Both parsing attempts failed, group the errors together. err = fmt.Errorf( "failed to parse date:\ngit2.45+ iso-strict format: %w\nprevious iso-strict format: %w", err, fallbackErr) } else { err = nil // successfully parsed with fallback format } } if err != nil && GitCommitDate != "%cI" { // ignore error for old git versions where %cI is not defined return vers, fmt.Errorf("version build error: %w", err) } matched, err = regexp.MatchString("^[0-9a-f]{12,}$", GitCommitHash) if err != nil { return vers, fmt.Errorf("version build error: commit hash compilation failed: %v", err) } else if !matched { return vers, fmt.Errorf("version build error: commit hash does not match expected format") } commitHash := GitCommitHash //CGRateS@v0.10.1~dev-20200110075344-7572e7b11e00 return fmt.Sprintf("%s@%s-%s-%s", CGRateS, Version, commitDate.UTC().Format("20060102150405"), commitHash[:12]), nil } // NewTenantID parses a string in the format of "tenant:ID" and returns // a TenantID struct. If the separator is not found, the entire string // is treated as the ID. func NewTenantID(input string) *TenantID { tenant, id, sepFound := strings.Cut(input, ConcatenatedKeySep) if !sepFound { return &TenantID{ID: input} } return &TenantID{Tenant: tenant, ID: id} } type PaginatorWithTenant struct { Tenant string Paginator } type TenantWithAPIOpts struct { Tenant string APIOpts map[string]any } type TenantID struct { Tenant string ID string } type TenantIDWithAPIOpts struct { *TenantID APIOpts map[string]any } func (tID *TenantID) TenantID() string { return ConcatenatedKey(tID.Tenant, tID.ID) } func (tID *TenantIDWithAPIOpts) TenantIDConcatenated() string { return ConcatenatedKey(tID.Tenant, tID.ID) } // CachedRPCResponse is used to cache a RPC response type CachedRPCResponse struct { Result any Error error } func ReverseString(s string) string { r := []rune(s) for i, j := 0, len(r)-1; i < len(r)/2; i, j = i+1, j-1 { r[i], r[j] = r[j], r[i] } return string(r) } func GetUrlRawArguments(dialURL string) (out map[string]string) { out = make(map[string]string) idx := strings.IndexRune(dialURL, '?') if idx == -1 { return } strParams := dialURL[idx+1:] if len(strParams) == 0 { return } vecParams := strings.Split(strParams, "&") for _, paramPair := range vecParams { idx := strings.IndexRune(paramPair, '=') if idx == -1 { continue } out[paramPair[:idx]] = paramPair[idx+1:] } return } // WarnExecTime is used when we need to meassure the execution of specific functions // and warn when the total duration is higher than expected // should be usually called with defer, ie: defer WarnExecTime(time.Now(), "MyTestFunc", 2*time.Second) func WarnExecTime(startTime time.Time, logID string, maxDur time.Duration) { totalDur := time.Since(startTime) if totalDur > maxDur { Logger.Warning(fmt.Sprintf("<%s> execution took: <%s>", logID, totalDur)) } } // endchan := LongExecTimeDetector("mesaj", 5*time.Second) // defer func() { close(endchan) }() func LongExecTimeDetector(logID string, maxDur time.Duration) (endchan chan struct{}) { endchan = make(chan struct{}, 1) go func() { select { case <-time.After(maxDur): Logger.Warning(fmt.Sprintf("<%s> execution more than: <%s>", logID, maxDur)) case <-endchan: } }() return } type StringWithAPIOpts struct { APIOpts map[string]any Tenant string Arg string } func CastRPCErr(err error) error { if err != nil { if _, has := ErrMap[err.Error()]; has { return ErrMap[err.Error()] } } return err } // RandomInteger returns a random 64-bit integer between min and max values func RandomInteger(min, max int64) int64 { return math_rand.Int63n(max-min) + min } type LoadIDsWithAPIOpts struct { LoadIDs map[string]int64 Tenant string APIOpts map[string]any } // IsURL returns if the path is an URL func IsURL(path string) bool { return strings.HasPrefix(path, "https://") || strings.HasPrefix(path, "http://") } // GetIndexesArg the API argumets to specify an index type GetIndexesArg struct { IdxItmType string TntCtx string IdxKey string Tenant string APIOpts map[string]any } // SetIndexesArg the API arguments needed for seting an index type SetIndexesArg struct { IdxItmType string TntCtx string Indexes map[string]StringSet Tenant string APIOpts map[string]any } type DurationArgs struct { Duration time.Duration APIOpts map[string]any Tenant string } type DirectoryArgs struct { DirPath string APIOpts map[string]any Tenant string } // AESEncrypt will encrypt the provided txt using the encKey and AES algorithm func AESEncrypt(txt, encKey string) (encrypted string, err error) { key, _ := hex.DecodeString(encKey) var blk cipher.Block if blk, err = aes.NewCipher(key); err != nil { return } var aesGCM cipher.AEAD aesGCM, _ = cipher.NewGCM(blk) nonce := make([]byte, aesGCM.NonceSize()) io.ReadFull(rand.Reader, nonce) return fmt.Sprintf("%x", aesGCM.Seal(nonce, nonce, []byte(txt), nil)), nil } // AESDecrypt will decrypt the provided encrypted txt using the encKey and AES algorithm func AESDecrypt(encrypted string, encKey string) (txt string, err error) { key, _ := hex.DecodeString(encKey) enc, _ := hex.DecodeString(encrypted) var blk cipher.Block if blk, err = aes.NewCipher(key); err != nil { return } var aesGCM cipher.AEAD aesGCM, _ = cipher.NewGCM(blk) nonceSize := aesGCM.NonceSize() nonce, ciphertext := enc[:nonceSize], enc[nonceSize:] var plaintext []byte plaintext, err = aesGCM.Open(nil, nonce, ciphertext, nil) return string(plaintext), err } // Hash generates the hash text func ComputeHash(dataKeys ...string) (lns string, err error) { var hashByts []byte hashByts, err = bcrypt.GenerateFromPassword( []byte(ConcatenatedKey(dataKeys...)), bcrypt.MinCost) return string(hashByts), err } // VerifyHash matches the data hash with the dataKeys ha func VerifyHash(hash string, dataKeys ...string) bool { err := bcrypt.CompareHashAndPassword([]byte(hash), []byte(ConcatenatedKey(dataKeys...))) return err == nil } // newBoolGen initialize an efficient boolean generator func newBoolGen() *boolGen { return &boolGen{src: math_rand.NewSource(time.Now().UnixNano())} } // boolGen is an efficient boolean generator type boolGen struct { src math_rand.Source cache int64 remaining int } // RandomBool generate a random boolean func (b *boolGen) RandomBool() bool { if b.remaining == 0 { b.cache, b.remaining = b.src.Int63(), 63 } result := b.cache&0x01 == 1 b.cache >>= 1 b.remaining-- return result } // GenerateDBItemOpts will create the options for DB replication // if they are empty they should be omitted func GenerateDBItemOpts(apiKey, routeID, cache, rmtHost string) (mp map[string]any) { mp = make(map[string]any) if apiKey != EmptyString { mp[OptsAPIKey] = apiKey } if routeID != EmptyString { mp[OptsRouteID] = routeID } if cache != EmptyString { mp[CacheOpt] = cache } if rmtHost != EmptyString { mp[RemoteHostOpt] = rmtHost } return } // SplitPath splits filter rules based on the specified separator func SplitPath(rule string, sep byte, n int) []string { var nest, pos int if n <= 0 { n = bytes.Count([]byte(rule), []byte{sep}) + 1 } if n == 1 { return []string{rule} } splt := make([]string, 0, n) shouldBreak := false for i, b := range rule { switch byte(b) { case sep: if nest != 0 { continue // skip separators inside nested structures } splt = append(splt, rule[pos:i]) pos = i + 1 if len(splt) == n-1 { shouldBreak = true } case IdxStart[0]: nest++ // entering nested structure case IdxEnd[0]: nest-- // exiting nested structure case HashtagSep[0]: if sep == NestingSep[0] { shouldBreak = true } } if shouldBreak { break } } splt = append(splt, rule[pos:]) // add last element return splt } type PanicMessageArgs struct { Tenant string APIOpts map[string]any Message string }