GopherLua is a Lua5.1 VM and compiler written in Go. GopherLua has a same goal with Lua: Be a scripting language with extensible semantics . It provides Go APIs that allow you to easily embed a scripting language to your Go host programs.
Contents
GopherLua is not fast but not too slow, I think.
GopherLua has almost equivalent ( or little bit better ) performance as Python3 on micro benchmarks.
There are some benchmarks on the wiki page .
go get github.com/yuin/gopher-lua
GopherLua supports >= Go1.9.
GopherLua APIs perform in much the same way as Lua, but the stack is used only for passing arguments and receiving returned values.
GopherLua supports channel operations. See "Goroutines" section.
Import a package.
import (
"github.com/yuin/gopher-lua"
)
Run scripts in the VM.
L := lua.NewState()
defer L.Close()
if err := L.DoString(`print("hello")`); err != nil {
panic(err)
}
L := lua.NewState()
defer L.Close()
if err := L.DoFile("hello.lua"); err != nil {
panic(err)
}
Refer to Lua Reference Manual and Go doc for further information.
Note that elements that are not commented in Go doc equivalent to Lua Reference Manual , except GopherLua uses objects instead of Lua stack indices.
All data in a GopherLua program is an LValue
. LValue
is an interface
type that has following methods.
String() string
Type() LValueType
Objects implement an LValue interface are
Type name | Go type | Type() value | Constants |
---|---|---|---|
LNilType |
(constants) | LTNil |
LNil |
LBool |
(constants) | LTBool |
LTrue , LFalse
|
LNumber |
float64 | LTNumber |
- |
LString |
string | LTString |
- |
LFunction |
struct pointer | LTFunction |
- |
LUserData |
struct pointer | LTUserData |
- |
LState |
struct pointer | LTThread |
- |
LTable |
struct pointer | LTTable |
- |
LChannel |
chan LValue | LTChannel |
- |
You can test an object type in Go way(type assertion) or using a Type()
value.
lv := L.Get(-1) // get the value at the top of the stack
if str, ok := lv.(lua.LString); ok {
// lv is LString
fmt.Println(string(str))
}
if lv.Type() != lua.LTString {
panic("string required.")
}
lv := L.Get(-1) // get the value at the top of the stack
if tbl, ok := lv.(*lua.LTable); ok {
// lv is LTable
fmt.Println(L.ObjLen(tbl))
}
Note that LBool
, LNumber
, LString
is not a pointer.
To test LNilType
and LBool
, You must use pre-defined constants.
lv := L.Get(-1) // get the value at the top of the stack
if lv == lua.LTrue { // correct
}
if bl, ok := lv.(lua.LBool); ok && bool(bl) { // wrong
}
In Lua, both nil
and false
make a condition false. LVIsFalse
and LVAsBool
implement this specification.
lv := L.Get(-1) // get the value at the top of the stack
if lua.LVIsFalse(lv) { // lv is nil or false
}
if lua.LVAsBool(lv) { // lv is neither nil nor false
}
Objects that based on go structs(LFunction
. LUserData
, LTable
)
have some public methods and fields. You can use these methods and fields for
performance and debugging, but there are some limitations.
The size of an LState
's callstack controls the maximum call depth for Lua functions within a script (Go function calls do not count).
The registry of an LState
implements stack storage for calling functions (both Lua and Go functions) and also for temporary variables in expressions. Its storage requirements will increase with callstack usage and also with code complexity.
Both the registry and the callstack can be set to either a fixed size or to auto size.
When you have a large number of LStates
instantiated in a process, it's worth taking the time to tune the registry and callstack options.
The registry can have an initial size, a maximum size and a step size configured on a per LState
basis. This will allow the registry to grow as needed. It will not shrink again after growing.
L := lua.NewState(lua.Options{
RegistrySize: 1024 * 20, // this is the initial size of the registry
RegistryMaxSize: 1024 * 80, // this is the maximum size that the registry can grow to. If set to `0` (the default) then the registry will not auto grow
RegistryGrowStep: 32, // this is how much to step up the registry by each time it runs out of space. The default is `32`.
})
defer L.Close()
A registry which is too small for a given script will ultimately result in a panic. A registry which is too big will waste memory (which can be significant if many LStates
are instantiated).
Auto growing registries incur a small performance hit at the point they are resized but will not otherwise affect performance.
The callstack can operate in two different modes, fixed or auto size.
A fixed size callstack has the highest performance and has a fixed memory overhead.
An auto sizing callstack will allocate and release callstack pages on demand which will ensure the minimum amount of memory is in use at any time. The downside is it will incur a small performance impact every time a new page of callframes is allocated.
By default an LState
will allocate and free callstack frames in pages of 8, so the allocation overhead is not incurred on every function call. It is very likely that the performance impact of an auto resizing callstack will be negligible for most use cases.
L := lua.NewState(lua.Options{
CallStackSize: 120, // this is the maximum callstack size of this LState
MinimizeStackMemory: true, // Defaults to `false` if not specified. If set, the callstack will auto grow and shrink as needed up to a max of `CallStackSize`. If not set, the callstack will be fixed at `CallStackSize`.
})
defer L.Close()
The above examples show how to customize the callstack and registry size on a per LState
basis. You can also adjust some defaults for when options are not specified by altering the values of lua.RegistrySize
, lua.RegistryGrowStep
and lua.CallStackSize
.
An LState
object that has been created by *LState#NewThread()
inherits the callstack & registry size from the parent LState
object.
true
.true
.Refer to Lua Reference Manual and Go doc(LState methods) for further information.
func Double(L *lua.LState) int {
lv := L.ToInt(1) /* get argument */
L.Push(lua.LNumber(lv * 2)) /* push result */
return 1 /* number of results */
}
func main() {
L := lua.NewState()
defer L.Close()
L.SetGlobal("double", L.NewFunction(Double)) /* Original lua_setglobal uses stack... */
}
print(double(20)) -- > "40"
Any function registered with GopherLua is a lua.LGFunction
, defined in value.go
type LGFunction func(*LState) int
Working with coroutines.
co, _ := L.NewThread() /* create a new thread */
fn := L.GetGlobal("coro").(*lua.LFunction) /* get function from lua */
for {
st, err, values := L.Resume(co, fn)
if st == lua.ResumeError {
fmt.Println("yield break(error)")
fmt.Println(err.Error())
break
}
for i, lv := range values {
fmt.Printf("%v : %v\n", i, lv)
}
if st == lua.ResumeOK {
fmt.Println("yield break(ok)")
break
}
}
The following demonstrates how to open a subset of the built-in modules in Lua, say for example to avoid enabling modules with access to local files or system calls.
main.go
func main() {
L := lua.NewState(lua.Options{SkipOpenLibs: true})
defer L.Close()
for _, pair := range []struct {
n string
f lua.LGFunction
}{
{lua.LoadLibName, lua.OpenPackage}, // Must be first
{lua.BaseLibName, lua.OpenBase},
{lua.TabLibName, lua.OpenTable},
} {
if err := L.CallByParam(lua.P{
Fn: L.NewFunction(pair.f),
NRet: 0,
Protect: true,
}, lua.LString(pair.n)); err != nil {
panic(err)
}
}
if err := L.DoFile("main.lua"); err != nil {
panic(err)
}
}
mymodule.go
package mymodule
import (
"github.com/yuin/gopher-lua"
)
func Loader(L *lua.LState) int {
// register functions to the table
mod := L.SetFuncs(L.NewTable(), exports)
// register other stuff
L.SetField(mod, "name", lua.LString("value"))
// returns the module
L.Push(mod)
return 1
}
var exports = map[string]lua.LGFunction{
"myfunc": myfunc,
}
func myfunc(L *lua.LState) int {
return 0
}
mymain.go
package main
import (
"./mymodule"
"github.com/yuin/gopher-lua"
)
func main() {
L := lua.NewState()
defer L.Close()
L.PreloadModule("mymodule", mymodule.Loader)
if err := L.DoFile("main.lua"); err != nil {
panic(err)
}
}
main.lua
local m = require("mymodule")
m.myfunc()
print(m.name)
L := lua.NewState()
defer L.Close()
if err := L.DoFile("double.lua"); err != nil {
panic(err)
}
if err := L.CallByParam(lua.P{
Fn: L.GetGlobal("double"),
NRet: 1,
Protect: true,
}, lua.LNumber(10)); err != nil {
panic(err)
}
ret := L.Get(-1) // returned value
L.Pop(1) // remove received value
If Protect
is false, GopherLua will panic instead of returning an error
value.
You can extend GopherLua with new types written in Go.
LUserData
is provided for this purpose.
type Person struct {
Name string
}
const luaPersonTypeName = "person"
// Registers my person type to given L.
func registerPersonType(L *lua.LState) {
mt := L.NewTypeMetatable(luaPersonTypeName)
L.SetGlobal("person", mt)
// static attributes
L.SetField(mt, "new", L.NewFunction(newPerson))
// methods
L.SetField(mt, "__index", L.SetFuncs(L.NewTable(), personMethods))
}
// Constructor
func newPerson(L *lua.LState) int {
person := &Person{L.CheckString(1)}
ud := L.NewUserData()
ud.Value = person
L.SetMetatable(ud, L.GetTypeMetatable(luaPersonTypeName))
L.Push(ud)
return 1
}
// Checks whether the first lua argument is a *LUserData with *Person and returns this *Person.
func checkPerson(L *lua.LState) *Person {
ud := L.CheckUserData(1)
if v, ok := ud.Value.(*Person); ok {
return v
}
L.ArgError(1, "person expected")
return nil
}
var personMethods = map[string]lua.LGFunction{
"name": personGetSetName,
}
// Getter and setter for the Person#Name
func personGetSetName(L *lua.LState) int {
p := checkPerson(L)
if L.GetTop() == 2 {
p.Name = L.CheckString(2)
return 0
}
L.Push(lua.LString(p.Name))
return 1
}
func main() {
L := lua.NewState()
defer L.Close()
registerPersonType(L)
if err := L.DoString(`
p = person.new("Steeve")
print(p:name()) -- "Steeve"
p:name("Alice")
print(p:name()) -- "Alice"
`); err != nil {
panic(err)
}
}
GopherLua supports the Go Concurrency Patterns: Context .
L := lua.NewState()
defer L.Close()
ctx, cancel := context.WithTimeout(context.Background(), 1*time.Second)
defer cancel()
// set the context to our LState
L.SetContext(ctx)
err := L.DoString(`
local clock = os.clock
function sleep(n) -- seconds
local t0 = clock()
while clock() - t0 <= n do end
end
sleep(3)
`)
// err.Error() contains "context deadline exceeded"
With coroutines
L := lua.NewState()
defer L.Close()
ctx, cancel := context.WithCancel(context.Background())
L.SetContext(ctx)
defer cancel()
L.DoString(`
function coro()
local i = 0
while true do
coroutine.yield(i)
i = i+1
end
return i
end
`)
co, cocancel := L.NewThread()
defer cocancel()
fn := L.GetGlobal("coro").(*LFunction)
_, err, values := L.Resume(co, fn) // err is nil
cancel() // cancel the parent context
_, err, values = L.Resume(co, fn) // err is NOT nil : child context was canceled
Note that using a context causes performance degradation.
time ./glua-with-context.exe fib.lua 9227465 0.01s user 0.11s system 1% cpu 7.505 total time ./glua-without-context.exe fib.lua 9227465 0.01s user 0.01s system 0% cpu 5.306 total
Calling DoFile
will load a Lua script, compile it to byte code and run the byte code in a LState
.
If you have multiple LStates
which are all required to run the same script, you can share the byte code between them,
which will save on memory.
Sharing byte code is safe as it is read only and cannot be altered by lua scripts.
// CompileLua reads the passed lua file from disk and compiles it.
func CompileLua(filePath string) (*lua.FunctionProto, error) {
file, err := os.Open(filePath)
defer file.Close()
if err != nil {
return nil, err
}
reader := bufio.NewReader(file)
chunk, err := parse.Parse(reader, filePath)
if err != nil {
return nil, err
}
proto, err := lua.Compile(chunk, filePath)
if err != nil {
return nil, err
}
return proto, nil
}
// DoCompiledFile takes a FunctionProto, as returned by CompileLua, and runs it in the LState. It is equivalent
// to calling DoFile on the LState with the original source file.
func DoCompiledFile(L *lua.LState, proto *lua.FunctionProto) error {
lfunc := L.NewFunctionFromProto(proto)
L.Push(lfunc)
return L.PCall(0, lua.MultRet, nil)
}
// Example shows how to share the compiled byte code from a lua script between multiple VMs.
func Example() {
codeToShare := CompileLua("mylua.lua")
a := lua.NewState()
b := lua.NewState()
c := lua.NewState()
DoCompiledFile(a, codeToShare)
DoCompiledFile(b, codeToShare)
DoCompiledFile(c, codeToShare)
}
The LState
is not goroutine-safe. It is recommended to use one LState per goroutine and communicate between goroutines by using channels.
Channels are represented by channel
objects in GopherLua. And a channel
table provides functions for performing channel operations.
Some objects can not be sent over channels due to having non-goroutine-safe objects inside itself.
You must not send these objects from Go APIs to channels.
func receiver(ch, quit chan lua.LValue) {
L := lua.NewState()
defer L.Close()
L.SetGlobal("ch", lua.LChannel(ch))
L.SetGlobal("quit", lua.LChannel(quit))
if err := L.DoString(`
local exit = false
while not exit do
channel.select(
{"|<-", ch, function(ok, v)
if not ok then
print("channel closed")
exit = true
else
print("received:", v)
end
end},
{"|<-", quit, function(ok, v)
print("quit")
exit = true
end}
)
end
`); err != nil {
panic(err)
}
}
func sender(ch, quit chan lua.LValue) {
L := lua.NewState()
defer L.Close()
L.SetGlobal("ch", lua.LChannel(ch))
L.SetGlobal("quit", lua.LChannel(quit))
if err := L.DoString(`
ch:send("1")
ch:send("2")
`); err != nil {
panic(err)
}
ch <- lua.LString("3")
quit <- lua.LTrue
}
func main() {
ch := make(chan lua.LValue)
quit := make(chan lua.LValue)
go receiver(ch, quit)
go sender(ch, quit)
time.Sleep(3 * time.Second)
}
ToChannel
, CheckChannel
, OptChannel
are available.
Refer to Go doc(LState methods) for further information.
buf
. By default, buf
is 0.select
statement in Go. It returns the index of the chosen case and, if that
case was a receive operation, the value received and a boolean indicating whether the channel has been closed.case
is a table that outlined below.channel.select
examples:
local idx, recv, ok = channel.select(
{"|<-", ch1},
{"|<-", ch2}
)
if not ok then
print("closed")
elseif idx == 1 then -- received from ch1
print(recv)
elseif idx == 2 then -- received from ch2
print(recv)
end
channel.select(
{"|<-", ch1, function(ok, data)
print(ok, data)
end},
{"<-|", ch2, "value", function(data)
print(data)
end},
{"default", function()
print("default action")
end}
)
data
over the channel.To create per-thread LState instances, You can use the sync.Pool
like mechanism.
type lStatePool struct {
m sync.Mutex
saved []*lua.LState
}
func (pl *lStatePool) Get() *lua.LState {
pl.m.Lock()
defer pl.m.Unlock()
n := len(pl.saved)
if n == 0 {
return pl.New()
}
x := pl.saved[n-1]
pl.saved = pl.saved[0 : n-1]
return x
}
func (pl *lStatePool) New() *lua.LState {
L := lua.NewState()
// setting the L up here.
// load scripts, set global variables, share channels, etc...
return L
}
func (pl *lStatePool) Put(L *lua.LState) {
pl.m.Lock()
defer pl.m.Unlock()
pl.saved = append(pl.saved, L)
}
func (pl *lStatePool) Shutdown() {
for _, L := range pl.saved {
L.Close()
}
}
// Global LState pool
var luaPool = &lStatePool{
saved: make([]*lua.LState, 0, 4),
}
Now, you can get per-thread LState objects from the luaPool
.
func MyWorker() {
L := luaPool.Get()
defer luaPool.Put(L)
/* your code here */
}
func main() {
defer luaPool.Shutdown()
go MyWorker()
go MyWorker()
/* etc... */
}
channel
.channel
table provides functions for performing channel operations.string.dump
os.setlocale
lua_Debug.namewhat
package.loadlib
collectgarbage
does not take any arguments and runs the garbage collector for the entire Go program.file:setvbuf
does not support a line buffering.os.setenv(name, value)
Lua has an interpreter called lua
. GopherLua has an interpreter called glua
.
go get github.com/yuin/gopher-lua/cmd/glua
glua
has same options as lua
.
See Guidlines for contributors .
BTC: 1NEDSyUmo4SMTDP83JJQSWi1MvQUGGNMZB
MIT
Yusuke Inuzuka
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