package lua const defaultArrayCap = 32 const defaultHashCap = 32 type lValueArraySorter struct { L *LState Fn *LFunction Values []LValue } func (lv lValueArraySorter) Len() int { return len(lv.Values) } func (lv lValueArraySorter) Swap(i, j int) { lv.Values[i], lv.Values[j] = lv.Values[j], lv.Values[i] } func (lv lValueArraySorter) Less(i, j int) bool { if lv.Fn != nil { lv.L.Push(lv.Fn) lv.L.Push(lv.Values[i]) lv.L.Push(lv.Values[j]) lv.L.Call(2, 1) return LVAsBool(lv.L.reg.Pop()) } return lessThan(lv.L, lv.Values[i], lv.Values[j]) } func newLTable(acap int, hcap int) *LTable { if acap < 0 { acap = 0 } if hcap < 0 { hcap = 0 } tb := <able{} tb.Metatable = LNil if acap != 0 { tb.array = make([]LValue, 0, acap) } if hcap != 0 { tb.strdict = make(map[string]LValue, hcap) } return tb } // Len returns length of this LTable. func (tb *LTable) Len() int { if tb.array == nil { return 0 } var prev LValue = LNil for i := len(tb.array) - 1; i >= 0; i-- { v := tb.array[i] if prev == LNil && v != LNil { return i + 1 } prev = v } return 0 } // Append appends a given LValue to this LTable. func (tb *LTable) Append(value LValue) { if tb.array == nil { tb.array = make([]LValue, 0, defaultArrayCap) } tb.array = append(tb.array, value) } // Insert inserts a given LValue at position `i` in this table. func (tb *LTable) Insert(i int, value LValue) { if tb.array == nil { tb.array = make([]LValue, 0, defaultArrayCap) } if i > len(tb.array) { tb.RawSetInt(i, value) return } if i <= 0 { tb.RawSet(LNumber(i), value) return } i -= 1 tb.array = append(tb.array, LNil) copy(tb.array[i+1:], tb.array[i:]) tb.array[i] = value } // MaxN returns a maximum number key that nil value does not exist before it. func (tb *LTable) MaxN() int { if tb.array == nil { return 0 } for i := len(tb.array) - 1; i >= 0; i-- { if tb.array[i] != LNil { return i + 1 } } return 0 } // Remove removes from this table the element at a given position. func (tb *LTable) Remove(pos int) LValue { if tb.array == nil { return LNil } i := pos - 1 larray := len(tb.array) oldval := LNil switch { case i >= larray: // nothing to do case i == larray-1 || i < 0: oldval = tb.array[larray-1] tb.array = tb.array[:larray-1] default: oldval = tb.array[i] copy(tb.array[i:], tb.array[i+1:]) tb.array[larray-1] = nil tb.array = tb.array[:larray-1] } return oldval } // RawSet sets a given LValue to a given index without the __newindex metamethod. // It is recommended to use `RawSetString` or `RawSetInt` for performance // if you already know the given LValue is a string or number. func (tb *LTable) RawSet(key LValue, value LValue) { switch v := key.(type) { case LNumber: if isArrayKey(v) { if tb.array == nil { tb.array = make([]LValue, 0, defaultArrayCap) } index := int(v) - 1 alen := len(tb.array) switch { case index == alen: tb.array = append(tb.array, value) case index > alen: for i := 0; i < (index - alen); i++ { tb.array = append(tb.array, LNil) } tb.array = append(tb.array, value) case index < alen: tb.array[index] = value } return } case LString: tb.RawSetString(string(v), value) return } tb.RawSetH(key, value) } // RawSetInt sets a given LValue at a position `key` without the __newindex metamethod. func (tb *LTable) RawSetInt(key int, value LValue) { if key < 1 || key >= MaxArrayIndex { tb.RawSetH(LNumber(key), value) return } if tb.array == nil { tb.array = make([]LValue, 0, 32) } index := key - 1 alen := len(tb.array) switch { case index == alen: tb.array = append(tb.array, value) case index > alen: for i := 0; i < (index - alen); i++ { tb.array = append(tb.array, LNil) } tb.array = append(tb.array, value) case index < alen: tb.array[index] = value } } // RawSetString sets a given LValue to a given string index without the __newindex metamethod. func (tb *LTable) RawSetString(key string, value LValue) { if tb.strdict == nil { tb.strdict = make(map[string]LValue, defaultHashCap) } if tb.keys == nil { tb.keys = []LValue{} tb.k2i = map[LValue]int{} } if value == LNil { // TODO tb.keys and tb.k2i should also be removed delete(tb.strdict, key) } else { tb.strdict[key] = value lkey := LString(key) if _, ok := tb.k2i[lkey]; !ok { tb.k2i[lkey] = len(tb.keys) tb.keys = append(tb.keys, lkey) } } } // RawSetH sets a given LValue to a given index without the __newindex metamethod. func (tb *LTable) RawSetH(key LValue, value LValue) { if s, ok := key.(LString); ok { tb.RawSetString(string(s), value) return } if tb.dict == nil { tb.dict = make(map[LValue]LValue, len(tb.strdict)) } if tb.keys == nil { tb.keys = []LValue{} tb.k2i = map[LValue]int{} } if value == LNil { // TODO tb.keys and tb.k2i should also be removed delete(tb.dict, key) } else { tb.dict[key] = value if _, ok := tb.k2i[key]; !ok { tb.k2i[key] = len(tb.keys) tb.keys = append(tb.keys, key) } } } // RawGet returns an LValue associated with a given key without __index metamethod. func (tb *LTable) RawGet(key LValue) LValue { switch v := key.(type) { case LNumber: if isArrayKey(v) { if tb.array == nil { return LNil } index := int(v) - 1 if index >= len(tb.array) { return LNil } return tb.array[index] } case LString: if tb.strdict == nil { return LNil } if ret, ok := tb.strdict[string(v)]; ok { return ret } return LNil } if tb.dict == nil { return LNil } if v, ok := tb.dict[key]; ok { return v } return LNil } // RawGetInt returns an LValue at position `key` without __index metamethod. func (tb *LTable) RawGetInt(key int) LValue { if tb.array == nil { return LNil } index := int(key) - 1 if index >= len(tb.array) || index < 0 { return LNil } return tb.array[index] } // RawGet returns an LValue associated with a given key without __index metamethod. func (tb *LTable) RawGetH(key LValue) LValue { if s, sok := key.(LString); sok { if tb.strdict == nil { return LNil } if v, vok := tb.strdict[string(s)]; vok { return v } return LNil } if tb.dict == nil { return LNil } if v, ok := tb.dict[key]; ok { return v } return LNil } // RawGetString returns an LValue associated with a given key without __index metamethod. func (tb *LTable) RawGetString(key string) LValue { if tb.strdict == nil { return LNil } if v, vok := tb.strdict[string(key)]; vok { return v } return LNil } // ForEach iterates over this table of elements, yielding each in turn to a given function. func (tb *LTable) ForEach(cb func(LValue, LValue)) { if tb.array != nil { for i, v := range tb.array { if v != LNil { cb(LNumber(i+1), v) } } } if tb.strdict != nil { for k, v := range tb.strdict { if v != LNil { cb(LString(k), v) } } } if tb.dict != nil { for k, v := range tb.dict { if v != LNil { cb(k, v) } } } } // This function is equivalent to lua_next ( http://www.lua.org/manual/5.1/manual.html#lua_next ). func (tb *LTable) Next(key LValue) (LValue, LValue) { init := false if key == LNil { key = LNumber(0) init = true } if init || key != LNumber(0) { if kv, ok := key.(LNumber); ok && isInteger(kv) && int(kv) >= 0 && kv < LNumber(MaxArrayIndex) { index := int(kv) if tb.array != nil { for ; index < len(tb.array); index++ { if v := tb.array[index]; v != LNil { return LNumber(index + 1), v } } } if tb.array == nil || index == len(tb.array) { if (tb.dict == nil || len(tb.dict) == 0) && (tb.strdict == nil || len(tb.strdict) == 0) { return LNil, LNil } key = tb.keys[0] if v := tb.RawGetH(key); v != LNil { return key, v } } } } for i := tb.k2i[key] + 1; i < len(tb.keys); i++ { key := tb.keys[i] if v := tb.RawGetH(key); v != LNil { return key, v } } return LNil, LNil }