// Copyright © 2013-14 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 tpl import ( "bitbucket.org/pkg/inflect" "bytes" "encoding/base64" "errors" "fmt" "html" "html/template" "os" "reflect" "sort" "strconv" "strings" "time" "github.com/spf13/cast" "github.com/spf13/hugo/helpers" jww "github.com/spf13/jwalterweatherman" ) var funcMap template.FuncMap func Eq(x, y interface{}) bool { normalize := func(v interface{}) interface{} { vv := reflect.ValueOf(v) switch vv.Kind() { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: return vv.Int() case reflect.Float32, reflect.Float64: return vv.Float() case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64: return vv.Uint() default: return v } } x = normalize(x) y = normalize(y) return reflect.DeepEqual(x, y) } func Ne(x, y interface{}) bool { return !Eq(x, y) } func Ge(a, b interface{}) bool { left, right := compareGetFloat(a, b) return left >= right } func Gt(a, b interface{}) bool { left, right := compareGetFloat(a, b) return left > right } func Le(a, b interface{}) bool { left, right := compareGetFloat(a, b) return left <= right } func Lt(a, b interface{}) bool { left, right := compareGetFloat(a, b) return left < right } func Dictionary(values ...interface{}) (map[string]interface{}, error) { if len(values)%2 != 0 { return nil, errors.New("invalid dict call") } dict := make(map[string]interface{}, len(values)/2) for i := 0; i < len(values); i += 2 { key, ok := values[i].(string) if !ok { return nil, errors.New("dict keys must be strings") } dict[key] = values[i+1] } return dict, nil } func compareGetFloat(a interface{}, b interface{}) (float64, float64) { var left, right float64 var leftStr, rightStr *string var err error av := reflect.ValueOf(a) switch av.Kind() { case reflect.Array, reflect.Chan, reflect.Map, reflect.Slice: left = float64(av.Len()) case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: left = float64(av.Int()) case reflect.Float32, reflect.Float64: left = av.Float() case reflect.String: left, err = strconv.ParseFloat(av.String(), 64) if err != nil { str := av.String() leftStr = &str } } bv := reflect.ValueOf(b) switch bv.Kind() { case reflect.Array, reflect.Chan, reflect.Map, reflect.Slice: right = float64(bv.Len()) case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: right = float64(bv.Int()) case reflect.Float32, reflect.Float64: right = bv.Float() case reflect.String: right, err = strconv.ParseFloat(bv.String(), 64) if err != nil { str := bv.String() rightStr = &str } } switch { case leftStr == nil || rightStr == nil: case *leftStr < *rightStr: return 0, 1 case *leftStr > *rightStr: return 1, 0 default: return 0, 0 } return left, right } // Slicing in Slicestr is done by specifying a half-open range with // two indices, start and end. 1 and 4 creates a slice including elements 1 through 3. // The end index can be omitted, it defaults to the string's length. func Slicestr(a interface{}, startEnd ...interface{}) (string, error) { aStr, err := cast.ToStringE(a) if err != nil { return "", err } var argStart, argEnd int argNum := len(startEnd) if argNum > 0 { if argStart, err = cast.ToIntE(startEnd[0]); err != nil { return "", errors.New("start argument must be integer") } } if argNum > 1 { if argEnd, err = cast.ToIntE(startEnd[1]); err != nil { return "", errors.New("end argument must be integer") } } if argNum > 2 { return "", errors.New("too many arguments") } asRunes := []rune(aStr) if argNum > 0 && (argStart < 0 || argStart >= len(asRunes)) { return "", errors.New("slice bounds out of range") } if argNum == 2 { if argEnd < 0 || argEnd > len(asRunes) { return "", errors.New("slice bounds out of range") } return string(asRunes[argStart:argEnd]), nil } else if argNum == 1 { return string(asRunes[argStart:]), nil } else { return string(asRunes[:]), nil } } // Substr extracts parts of a string, beginning at the character at the specified // position, and returns the specified number of characters. // // It normally takes two parameters: start and length. // It can also take one parameter: start, i.e. length is omitted, in which case // the substring starting from start until the end of the string will be returned. // // To extract characters from the end of the string, use a negative start number. // // In addition, borrowing from the extended behavior described at http://php.net/substr, // if length is given and is negative, then that many characters will be omitted from // the end of string. func Substr(a interface{}, nums ...interface{}) (string, error) { aStr, err := cast.ToStringE(a) if err != nil { return "", err } var start, length int asRunes := []rune(aStr) switch len(nums) { case 0: return "", errors.New("too less arguments") case 1: if start, err = cast.ToIntE(nums[0]); err != nil { return "", errors.New("start argument must be integer") } length = len(asRunes) case 2: if start, err = cast.ToIntE(nums[0]); err != nil { return "", errors.New("start argument must be integer") } if length, err = cast.ToIntE(nums[1]); err != nil { return "", errors.New("length argument must be integer") } default: return "", errors.New("too many arguments") } if start < -len(asRunes) { start = 0 } if start > len(asRunes) { return "", errors.New(fmt.Sprintf("start position out of bounds for %d-byte string", len(aStr))) } var s, e int if start >= 0 && length >= 0 { s = start e = start + length } else if start < 0 && length >= 0 { s = len(asRunes) + start - length + 1 e = len(asRunes) + start + 1 } else if start >= 0 && length < 0 { s = start e = len(asRunes) + length } else { s = len(asRunes) + start e = len(asRunes) + length } if s > e { return "", errors.New(fmt.Sprintf("calculated start position greater than end position: %d > %d", s, e)) } if e > len(asRunes) { e = len(asRunes) } return string(asRunes[s:e]), nil } func Split(a interface{}, delimiter string) ([]string, error) { aStr, err := cast.ToStringE(a) if err != nil { return []string{}, err } return strings.Split(aStr, delimiter), nil } func Intersect(l1, l2 interface{}) (interface{}, error) { if l1 == nil || l2 == nil { return make([]interface{}, 0), nil } l1v := reflect.ValueOf(l1) l2v := reflect.ValueOf(l2) switch l1v.Kind() { case reflect.Array, reflect.Slice: switch l2v.Kind() { case reflect.Array, reflect.Slice: r := reflect.MakeSlice(l1v.Type(), 0, 0) for i := 0; i < l1v.Len(); i++ { l1vv := l1v.Index(i) for j := 0; j < l2v.Len(); j++ { l2vv := l2v.Index(j) switch l1vv.Kind() { case reflect.String: if l1vv.Type() == l2vv.Type() && l1vv.String() == l2vv.String() && !In(r, l2vv) { r = reflect.Append(r, l2vv) } case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: switch l2vv.Kind() { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: if l1vv.Int() == l2vv.Int() && !In(r, l2vv) { r = reflect.Append(r, l2vv) } } case reflect.Float32, reflect.Float64: switch l2vv.Kind() { case reflect.Float32, reflect.Float64: if l1vv.Float() == l2vv.Float() && !In(r, l2vv) { r = reflect.Append(r, l2vv) } } } } } return r.Interface(), nil default: return nil, errors.New("can't iterate over " + reflect.ValueOf(l2).Type().String()) } default: return nil, errors.New("can't iterate over " + reflect.ValueOf(l1).Type().String()) } } func In(l interface{}, v interface{}) bool { lv := reflect.ValueOf(l) vv := reflect.ValueOf(v) switch lv.Kind() { case reflect.Array, reflect.Slice: for i := 0; i < lv.Len(); i++ { lvv := lv.Index(i) lvv, isNil := indirect(lvv) if isNil { continue } switch lvv.Kind() { case reflect.String: if vv.Type() == lvv.Type() && vv.String() == lvv.String() { return true } case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: switch vv.Kind() { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: if vv.Int() == lvv.Int() { return true } } case reflect.Float32, reflect.Float64: switch vv.Kind() { case reflect.Float32, reflect.Float64: if vv.Float() == lvv.Float() { return true } } } } case reflect.String: if vv.Type() == lv.Type() && strings.Contains(lv.String(), vv.String()) { return true } } return false } // indirect is taken from 'text/template/exec.go' func indirect(v reflect.Value) (rv reflect.Value, isNil bool) { for ; v.Kind() == reflect.Ptr || v.Kind() == reflect.Interface; v = v.Elem() { if v.IsNil() { return v, true } if v.Kind() == reflect.Interface && v.NumMethod() > 0 { break } } return v, false } // First is exposed to templates, to iterate over the first N items in a // rangeable list. func First(limit interface{}, seq interface{}) (interface{}, error) { if limit == nil || seq == nil { return nil, errors.New("both limit and seq must be provided") } limitv, err := cast.ToIntE(limit) if err != nil { return nil, err } if limitv < 1 { return nil, errors.New("can't return negative/empty count of items from sequence") } seqv := reflect.ValueOf(seq) seqv, isNil := indirect(seqv) if isNil { return nil, errors.New("can't iterate over a nil value") } switch seqv.Kind() { case reflect.Array, reflect.Slice, reflect.String: // okay default: return nil, errors.New("can't iterate over " + reflect.ValueOf(seq).Type().String()) } if limitv > seqv.Len() { limitv = seqv.Len() } return seqv.Slice(0, limitv).Interface(), nil } // Last is exposed to templates, to iterate over the last N items in a // rangeable list. func Last(limit interface{}, seq interface{}) (interface{}, error) { if limit == nil || seq == nil { return nil, errors.New("both limit and seq must be provided") } limitv, err := cast.ToIntE(limit) if err != nil { return nil, err } if limitv < 1 { return nil, errors.New("can't return negative/empty count of items from sequence") } seqv := reflect.ValueOf(seq) seqv, isNil := indirect(seqv) if isNil { return nil, errors.New("can't iterate over a nil value") } switch seqv.Kind() { case reflect.Array, reflect.Slice, reflect.String: // okay default: return nil, errors.New("can't iterate over " + reflect.ValueOf(seq).Type().String()) } if limitv > seqv.Len() { limitv = seqv.Len() } return seqv.Slice(seqv.Len()-limitv, seqv.Len()).Interface(), nil } // After is exposed to templates, to iterate over all the items after N in a // rangeable list. It's meant to accompany First func After(index interface{}, seq interface{}) (interface{}, error) { if index == nil || seq == nil { return nil, errors.New("both limit and seq must be provided") } indexv, err := cast.ToIntE(index) if err != nil { return nil, err } if indexv < 1 { return nil, errors.New("can't return negative/empty count of items from sequence") } seqv := reflect.ValueOf(seq) seqv, isNil := indirect(seqv) if isNil { return nil, errors.New("can't iterate over a nil value") } switch seqv.Kind() { case reflect.Array, reflect.Slice, reflect.String: // okay default: return nil, errors.New("can't iterate over " + reflect.ValueOf(seq).Type().String()) } if indexv >= seqv.Len() { return nil, errors.New("no items left") } return seqv.Slice(indexv, seqv.Len()).Interface(), nil } var ( zero reflect.Value errorType = reflect.TypeOf((*error)(nil)).Elem() timeType = reflect.TypeOf((*time.Time)(nil)).Elem() ) func timeUnix(v reflect.Value) int64 { if v.Type() != timeType { panic("coding error: argument must be time.Time type reflect Value") } return v.MethodByName("Unix").Call([]reflect.Value{})[0].Int() } func evaluateSubElem(obj reflect.Value, elemName string) (reflect.Value, error) { if !obj.IsValid() { return zero, errors.New("can't evaluate an invalid value") } typ := obj.Type() obj, isNil := indirect(obj) // first, check whether obj has a method. In this case, obj is // an interface, a struct or its pointer. If obj is a struct, // to check all T and *T method, use obj pointer type Value objPtr := obj if objPtr.Kind() != reflect.Interface && objPtr.CanAddr() { objPtr = objPtr.Addr() } mt, ok := objPtr.Type().MethodByName(elemName) if ok { if mt.PkgPath != "" { return zero, fmt.Errorf("%s is an unexported method of type %s", elemName, typ) } // struct pointer has one receiver argument and interface doesn't have an argument if mt.Type.NumIn() > 1 || mt.Type.NumOut() == 0 || mt.Type.NumOut() > 2 { return zero, fmt.Errorf("%s is a method of type %s but doesn't satisfy requirements", elemName, typ) } if mt.Type.NumOut() == 1 && mt.Type.Out(0).Implements(errorType) { return zero, fmt.Errorf("%s is a method of type %s but doesn't satisfy requirements", elemName, typ) } if mt.Type.NumOut() == 2 && !mt.Type.Out(1).Implements(errorType) { return zero, fmt.Errorf("%s is a method of type %s but doesn't satisfy requirements", elemName, typ) } res := objPtr.Method(mt.Index).Call([]reflect.Value{}) if len(res) == 2 && !res[1].IsNil() { return zero, fmt.Errorf("error at calling a method %s of type %s: %s", elemName, typ, res[1].Interface().(error)) } return res[0], nil } // elemName isn't a method so next start to check whether it is // a struct field or a map value. In both cases, it mustn't be // a nil value if isNil { return zero, fmt.Errorf("can't evaluate a nil pointer of type %s by a struct field or map key name %s", typ, elemName) } switch obj.Kind() { case reflect.Struct: ft, ok := obj.Type().FieldByName(elemName) if ok { if ft.PkgPath != "" { return zero, fmt.Errorf("%s is an unexported field of struct type %s", elemName, typ) } return obj.FieldByIndex(ft.Index), nil } return zero, fmt.Errorf("%s isn't a field of struct type %s", elemName, typ) case reflect.Map: kv := reflect.ValueOf(elemName) if kv.Type().AssignableTo(obj.Type().Key()) { return obj.MapIndex(kv), nil } return zero, fmt.Errorf("%s isn't a key of map type %s", elemName, typ) } return zero, fmt.Errorf("%s is neither a struct field, a method nor a map element of type %s", elemName, typ) } func checkCondition(v, mv reflect.Value, op string) (bool, error) { v, vIsNil := indirect(v) if !v.IsValid() { vIsNil = true } mv, mvIsNil := indirect(mv) if !mv.IsValid() { mvIsNil = true } if vIsNil || mvIsNil { switch op { case "", "=", "==", "eq": return vIsNil == mvIsNil, nil case "!=", "<>", "ne": return vIsNil != mvIsNil, nil } return false, nil } var ivp, imvp *int64 var svp, smvp *string var ima []int64 var sma []string if mv.Type() == v.Type() { switch v.Kind() { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: iv := v.Int() ivp = &iv imv := mv.Int() imvp = &imv case reflect.String: sv := v.String() svp = &sv smv := mv.String() smvp = &smv case reflect.Struct: switch v.Type() { case timeType: iv := timeUnix(v) ivp = &iv imv := timeUnix(mv) imvp = &imv } } } else { if mv.Kind() != reflect.Array && mv.Kind() != reflect.Slice { return false, nil } if mv.Type().Elem() != v.Type() { return false, nil } switch v.Kind() { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: iv := v.Int() ivp = &iv for i := 0; i < mv.Len(); i++ { ima = append(ima, mv.Index(i).Int()) } case reflect.String: sv := v.String() svp = &sv for i := 0; i < mv.Len(); i++ { sma = append(sma, mv.Index(i).String()) } case reflect.Struct: switch v.Type() { case timeType: iv := timeUnix(v) ivp = &iv for i := 0; i < mv.Len(); i++ { ima = append(ima, timeUnix(mv.Index(i))) } } } } switch op { case "", "=", "==", "eq": if ivp != nil && imvp != nil { return *ivp == *imvp, nil } else if svp != nil && smvp != nil { return *svp == *smvp, nil } case "!=", "<>", "ne": if ivp != nil && imvp != nil { return *ivp != *imvp, nil } else if svp != nil && smvp != nil { return *svp != *smvp, nil } case ">=", "ge": if ivp != nil && imvp != nil { return *ivp >= *imvp, nil } else if svp != nil && smvp != nil { return *svp >= *smvp, nil } case ">", "gt": if ivp != nil && imvp != nil { return *ivp > *imvp, nil } else if svp != nil && smvp != nil { return *svp > *smvp, nil } case "<=", "le": if ivp != nil && imvp != nil { return *ivp <= *imvp, nil } else if svp != nil && smvp != nil { return *svp <= *smvp, nil } case "<", "lt": if ivp != nil && imvp != nil { return *ivp < *imvp, nil } else if svp != nil && smvp != nil { return *svp < *smvp, nil } case "in", "not in": var r bool if ivp != nil && len(ima) > 0 { r = In(ima, *ivp) } else if svp != nil { if len(sma) > 0 { r = In(sma, *svp) } else if smvp != nil { r = In(*smvp, *svp) } } else { return false, nil } if op == "not in" { return !r, nil } else { return r, nil } default: return false, errors.New("no such an operator") } return false, nil } func Where(seq, key interface{}, args ...interface{}) (r interface{}, err error) { seqv := reflect.ValueOf(seq) kv := reflect.ValueOf(key) var mv reflect.Value var op string switch len(args) { case 1: mv = reflect.ValueOf(args[0]) case 2: var ok bool if op, ok = args[0].(string); !ok { return nil, errors.New("operator argument must be string type") } op = strings.TrimSpace(strings.ToLower(op)) mv = reflect.ValueOf(args[1]) default: return nil, errors.New("can't evaluate the array by no match argument or more than or equal to two arguments") } seqv, isNil := indirect(seqv) if isNil { return nil, errors.New("can't iterate over a nil value of type " + reflect.ValueOf(seq).Type().String()) } var path []string if kv.Kind() == reflect.String { path = strings.Split(strings.Trim(kv.String(), "."), ".") } switch seqv.Kind() { case reflect.Array, reflect.Slice: rv := reflect.MakeSlice(seqv.Type(), 0, 0) for i := 0; i < seqv.Len(); i++ { var vvv reflect.Value rvv := seqv.Index(i) if kv.Kind() == reflect.String { vvv = rvv for _, elemName := range path { vvv, err = evaluateSubElem(vvv, elemName) if err != nil { return nil, err } } } else { vv, _ := indirect(rvv) if vv.Kind() == reflect.Map && kv.Type().AssignableTo(vv.Type().Key()) { vvv = vv.MapIndex(kv) } } if ok, err := checkCondition(vvv, mv, op); ok { rv = reflect.Append(rv, rvv) } else if err != nil { return nil, err } } return rv.Interface(), nil default: return nil, errors.New("can't iterate over " + reflect.ValueOf(seq).Type().String()) } } // Apply, given a map, array, or slice, returns a new slice with the function fname applied over it. func Apply(seq interface{}, fname string, args ...interface{}) (interface{}, error) { if seq == nil { return make([]interface{}, 0), nil } if fname == "apply" { return nil, errors.New("can't apply myself (no turtles allowed)") } seqv := reflect.ValueOf(seq) seqv, isNil := indirect(seqv) if isNil { return nil, errors.New("can't iterate over a nil value") } fn, found := funcMap[fname] if !found { return nil, errors.New("can't find function " + fname) } fnv := reflect.ValueOf(fn) switch seqv.Kind() { case reflect.Array, reflect.Slice: r := make([]interface{}, seqv.Len()) for i := 0; i < seqv.Len(); i++ { vv := seqv.Index(i) vvv, err := applyFnToThis(fnv, vv, args...) if err != nil { return nil, err } r[i] = vvv.Interface() } return r, nil default: return nil, errors.New("can't apply over " + reflect.ValueOf(seq).Type().String()) } } func applyFnToThis(fn, this reflect.Value, args ...interface{}) (reflect.Value, error) { n := make([]reflect.Value, len(args)) for i, arg := range args { if arg == "." { n[i] = this } else { n[i] = reflect.ValueOf(arg) } } num := fn.Type().NumIn() if fn.Type().IsVariadic() { num-- } // TODO(bep) see #1098 - also see template_tests.go /*if len(args) < num { return reflect.ValueOf(nil), errors.New("Too few arguments") } else if len(args) > num { return reflect.ValueOf(nil), errors.New("Too many arguments") }*/ for i := 0; i < num; i++ { if xt, targ := n[i].Type(), fn.Type().In(i); !xt.AssignableTo(targ) { return reflect.ValueOf(nil), errors.New("called apply using " + xt.String() + " as type " + targ.String()) } } res := fn.Call(n) if len(res) == 1 || res[1].IsNil() { return res[0], nil } else { return reflect.ValueOf(nil), res[1].Interface().(error) } } func Delimit(seq, delimiter interface{}, last ...interface{}) (template.HTML, error) { d, err := cast.ToStringE(delimiter) if err != nil { return "", err } var dLast *string for _, l := range last { dStr, err := cast.ToStringE(l) if err != nil { dLast = nil } dLast = &dStr break } seqv := reflect.ValueOf(seq) seqv, isNil := indirect(seqv) if isNil { return "", errors.New("can't iterate over a nil value") } var str string switch seqv.Kind() { case reflect.Map: sortSeq, err := Sort(seq) if err != nil { return "", err } seqv = reflect.ValueOf(sortSeq) fallthrough case reflect.Array, reflect.Slice, reflect.String: for i := 0; i < seqv.Len(); i++ { val := seqv.Index(i).Interface() valStr, err := cast.ToStringE(val) if err != nil { continue } switch { case i == seqv.Len()-2 && dLast != nil: str += valStr + *dLast case i == seqv.Len()-1: str += valStr default: str += valStr + d } } default: return "", errors.New("can't iterate over " + reflect.ValueOf(seq).Type().String()) } return template.HTML(str), nil } func Sort(seq interface{}, args ...interface{}) (interface{}, error) { seqv := reflect.ValueOf(seq) seqv, isNil := indirect(seqv) if isNil { return nil, errors.New("can't iterate over a nil value") } switch seqv.Kind() { case reflect.Array, reflect.Slice, reflect.Map: // ok default: return nil, errors.New("can't sort " + reflect.ValueOf(seq).Type().String()) } // Create a list of pairs that will be used to do the sort p := pairList{SortAsc: true, SliceType: reflect.SliceOf(seqv.Type().Elem())} p.Pairs = make([]pair, seqv.Len()) var sortByField string for i, l := range args { dStr, err := cast.ToStringE(l) switch { case i == 0 && err != nil: sortByField = "" case i == 0 && err == nil: sortByField = dStr case i == 1 && err == nil && dStr == "desc": p.SortAsc = false case i == 1: p.SortAsc = true } } path := strings.Split(strings.Trim(sortByField, "."), ".") switch seqv.Kind() { case reflect.Array, reflect.Slice: for i := 0; i < seqv.Len(); i++ { p.Pairs[i].Key = reflect.ValueOf(i) p.Pairs[i].Value = seqv.Index(i) if sortByField == "" || sortByField == "value" { p.Pairs[i].SortByValue = p.Pairs[i].Value } else { v := p.Pairs[i].Value var err error for _, elemName := range path { v, err = evaluateSubElem(v, elemName) if err != nil { return nil, err } } p.Pairs[i].SortByValue = v } } case reflect.Map: keys := seqv.MapKeys() for i := 0; i < seqv.Len(); i++ { p.Pairs[i].Key = keys[i] p.Pairs[i].Value = seqv.MapIndex(keys[i]) if sortByField == "" { p.Pairs[i].SortByValue = p.Pairs[i].Key } else if sortByField == "value" { p.Pairs[i].SortByValue = p.Pairs[i].Value } else { v := p.Pairs[i].Value var err error for _, elemName := range path { v, err = evaluateSubElem(v, elemName) if err != nil { return nil, err } } p.Pairs[i].SortByValue = v } } } return p.sort(), nil } // Credit for pair sorting method goes to Andrew Gerrand // https://groups.google.com/forum/#!topic/golang-nuts/FT7cjmcL7gw // A data structure to hold a key/value pair. type pair struct { Key reflect.Value Value reflect.Value SortByValue reflect.Value } // A slice of pairs that implements sort.Interface to sort by Value. type pairList struct { Pairs []pair SortAsc bool SliceType reflect.Type } func (p pairList) Swap(i, j int) { p.Pairs[i], p.Pairs[j] = p.Pairs[j], p.Pairs[i] } func (p pairList) Len() int { return len(p.Pairs) } func (p pairList) Less(i, j int) bool { return Lt(p.Pairs[i].SortByValue.Interface(), p.Pairs[j].SortByValue.Interface()) } // sorts a pairList and returns a slice of sorted values func (p pairList) sort() interface{} { if p.SortAsc { sort.Sort(p) } else { sort.Sort(sort.Reverse(p)) } sorted := reflect.MakeSlice(p.SliceType, len(p.Pairs), len(p.Pairs)) for i, v := range p.Pairs { sorted.Index(i).Set(v.Value) } return sorted.Interface() } func IsSet(a interface{}, key interface{}) bool { av := reflect.ValueOf(a) kv := reflect.ValueOf(key) switch av.Kind() { case reflect.Array, reflect.Chan, reflect.Slice: if int64(av.Len()) > kv.Int() { return true } case reflect.Map: if kv.Type() == av.Type().Key() { return av.MapIndex(kv).IsValid() } } return false } func ReturnWhenSet(a, k interface{}) interface{} { av, isNil := indirect(reflect.ValueOf(a)) if isNil { return "" } var avv reflect.Value switch av.Kind() { case reflect.Array, reflect.Slice: index, ok := k.(int) if ok && av.Len() > index { avv = av.Index(index) } case reflect.Map: kv := reflect.ValueOf(k) if kv.Type().AssignableTo(av.Type().Key()) { avv = av.MapIndex(kv) } } if avv.IsValid() { switch avv.Kind() { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: return avv.Int() case reflect.Uint, reflect.Uint8, reflect.Uint16, reflect.Uint32, reflect.Uint64: return avv.Uint() case reflect.Float32, reflect.Float64: return avv.Float() case reflect.String: return avv.String() } } return "" } func Highlight(in interface{}, lang, opts string) template.HTML { var str string av := reflect.ValueOf(in) switch av.Kind() { case reflect.String: str = av.String() } return template.HTML(helpers.Highlight(html.UnescapeString(str), lang, opts)) } var markdownTrimPrefix = []byte("

") var markdownTrimSuffix = []byte("

\n") func Markdownify(text string) template.HTML { m := helpers.RenderBytes(&helpers.RenderingContext{Content: []byte(text), PageFmt: "markdown"}) m = bytes.TrimPrefix(m, markdownTrimPrefix) m = bytes.TrimSuffix(m, markdownTrimSuffix) return template.HTML(m) } func refPage(page interface{}, ref, methodName string) template.HTML { value := reflect.ValueOf(page) method := value.MethodByName(methodName) if method.IsValid() && method.Type().NumIn() == 1 && method.Type().NumOut() == 2 { result := method.Call([]reflect.Value{reflect.ValueOf(ref)}) url, err := result[0], result[1] if !err.IsNil() { jww.ERROR.Printf("%s", err.Interface()) return template.HTML(fmt.Sprintf("%s", err.Interface())) } if url.String() == "" { jww.ERROR.Printf("ref %s could not be found\n", ref) return template.HTML(ref) } return template.HTML(url.String()) } jww.ERROR.Printf("Can only create references from Page and Node objects.") return template.HTML(ref) } func Ref(page interface{}, ref string) template.HTML { return refPage(page, ref, "Ref") } func RelRef(page interface{}, ref string) template.HTML { return refPage(page, ref, "RelRef") } func Chomp(text interface{}) (string, error) { s, err := cast.ToStringE(text) if err != nil { return "", err } return strings.TrimRight(s, "\r\n"), nil } // Trim leading/trailing characters defined by b from a func Trim(a interface{}, b string) (string, error) { aStr, err := cast.ToStringE(a) if err != nil { return "", err } return strings.Trim(aStr, b), nil } // Replace all occurences of b with c in a func Replace(a, b, c interface{}) (string, error) { aStr, err := cast.ToStringE(a) if err != nil { return "", err } bStr, err := cast.ToStringE(b) if err != nil { return "", err } cStr, err := cast.ToStringE(c) if err != nil { return "", err } return strings.Replace(aStr, bStr, cStr, -1), nil } // DateFormat converts the textual representation of the datetime string into // the other form or returns it of the time.Time value. These are formatted // with the layout string func DateFormat(layout string, v interface{}) (string, error) { t, err := cast.ToTimeE(v) if err != nil { return "", err } return t.Format(layout), nil } // "safeHTMLAttr" is currently disabled, pending further discussion // on its use case. 2015-01-19 func SafeHTMLAttr(text string) template.HTMLAttr { return template.HTMLAttr(text) } func SafeCSS(text string) template.CSS { return template.CSS(text) } func SafeURL(text string) template.URL { return template.URL(text) } func SafeHTML(a string) template.HTML { return template.HTML(a) } 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 } else { 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") } } func Mod(a, b interface{}) (int64, error) { av := reflect.ValueOf(a) bv := reflect.ValueOf(b) var ai, bi int64 switch av.Kind() { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: ai = av.Int() default: return 0, errors.New("Modulo operator can't be used with non integer value") } switch bv.Kind() { case reflect.Int, reflect.Int8, reflect.Int16, reflect.Int32, reflect.Int64: bi = bv.Int() default: return 0, errors.New("Modulo operator can't be used with non integer value") } if bi == 0 { return 0, errors.New("The number can't be divided by zero at modulo operation") } return ai % bi, nil } func ModBool(a, b interface{}) (bool, error) { res, err := Mod(a, b) if err != nil { return false, err } return res == int64(0), nil } func Base64Decode(content interface{}) (string, error) { conv, err := cast.ToStringE(content) if err != nil { return "", err } dec, err := base64.StdEncoding.DecodeString(conv) if err != nil { return "", err } return string(dec), nil } func Base64Encode(content interface{}) (string, error) { conv, err := cast.ToStringE(content) if err != nil { return "", err } return base64.StdEncoding.EncodeToString([]byte(conv)), nil } func init() { funcMap = template.FuncMap{ "urlize": helpers.URLize, "sanitizeURL": helpers.SanitizeURL, "sanitizeurl": helpers.SanitizeURL, "eq": Eq, "ne": Ne, "gt": Gt, "ge": Ge, "lt": Lt, "le": Le, "dict": Dictionary, "in": In, "slicestr": Slicestr, "substr": Substr, "split": Split, "intersect": Intersect, "isSet": IsSet, "isset": IsSet, "echoParam": ReturnWhenSet, "safeHTML": SafeHTML, "safeCSS": SafeCSS, "safeURL": SafeURL, "absURL": func(a string) template.HTML { return template.HTML(helpers.AbsURL(a)) }, "relURL": func(a string) template.HTML { return template.HTML(helpers.RelURL(a)) }, "markdownify": Markdownify, "first": First, "last": Last, "after": After, "where": Where, "delimit": Delimit, "sort": Sort, "highlight": Highlight, "add": func(a, b interface{}) (interface{}, error) { return doArithmetic(a, b, '+') }, "sub": func(a, b interface{}) (interface{}, error) { return doArithmetic(a, b, '-') }, "div": func(a, b interface{}) (interface{}, error) { return doArithmetic(a, b, '/') }, "mod": Mod, "mul": func(a, b interface{}) (interface{}, error) { return doArithmetic(a, b, '*') }, "modBool": ModBool, "lower": func(a string) string { return strings.ToLower(a) }, "upper": func(a string) string { return strings.ToUpper(a) }, "title": func(a string) string { return strings.Title(a) }, "partial": Partial, "ref": Ref, "relref": RelRef, "apply": Apply, "chomp": Chomp, "replace": Replace, "trim": Trim, "dateFormat": DateFormat, "getJSON": GetJSON, "getCSV": GetCSV, "readDir": ReadDir, "seq": helpers.Seq, "getenv": func(varName string) string { return os.Getenv(varName) }, "base64Decode": Base64Decode, "base64Encode": Base64Encode, "pluralize": func(in interface{}) (string, error) { word, err := cast.ToStringE(in) if err != nil { return "", err } return inflect.Pluralize(word), nil }, "singularize": func(in interface{}) (string, error) { word, err := cast.ToStringE(in) if err != nil { return "", err } return inflect.Singularize(word), nil }, } }