title = "用go语言给lua写扩展"
slug = "extending-lua-with-go-language"
desc = "extending-lua-with-go-language"
date = "2018-11-27 00:14:21"
update_date = "2018-11-27 00:14:21"
author = ""
thumb = ""
draft = false
tags = ["tag"]最近的一个lua项目中需要解析wbxml,WBXML是XML的二进制表示形式,Exchange与手机端之间的通讯采用的就是该协议,我需要解析到手机端提交过来的数据,但lua没有现成的Wbxml解析库,从头撸一个势必要花费大量造轮子的时间,在网上查找了半天,发现有一个go语言版本的https://github.com/magicmonty/activesync-go,写了几行测试代码,确认该库可以正常解析出Exchange的wbxml数据内容,如下所示:
最初的方案打算用golang实现一个微服务,供openresty调用,该方案的特点是方便,能快速实现,但缺点也是非常明显的:
- 性能损耗大:openresty每接收到一个请求都需要调用golang的restful api,然后等待golang把wbxml解析完并返回,这中间有非常大的性能损耗
- 增加运维成本:golang微服务奔溃后,openresty将无法拿到想到的信息了,在运维时,除了要关注openresty本身外,还要时刻关注golang微服务的业务连续性、性能等指标
最佳的方案是提供一个lua的扩展,无缝集成到openresty中,这样可以完美地规避掉上述2个缺点。
关于用go语言扩展lua,github中已有现成的辅助库https://github.com/theganyo/lua2go可以使用,它的工作流程如下:
-
编写go模块,并导出需要给lua使用的函数:
//export add func add(operand1 int, operand2 int) int { return operand1 + operand2 }
-
将go模块编译为静态库:
go build -buildmode=c-shared -o example.so example.go
-
编写lua文件,加载自己的.so文件:
local lua2go = require('lua2go') local example = lua2go.Load('./example.so')
-
在lua文件与头文件模块中注册导出的函数:
lua2go.Externs[[ extern GoInt add(GoInt p0, GoInt p1); ]]
-
在lua文件中调用导出的函数并将结果转化为lua格式的数据:
local goAddResult = example.add(1, 1) local addResult = lua2go.ToLua(goAddResult) print('1 + 1 = ' .. addResult)
详细情况可以参考该项目的example
getDecodeResult函数可以将wbxml的二进制数据直接解析成xml格式的string
func getDecodeResult(data ...byte) string {
var result string
result, _ = Decode(bytes.NewBuffer(data), MakeCodeBook(PROTOCOL_VERSION_14_1))
return result
}但解析出来的xml的格式如下,多层嵌套且用了命名空间,虽然能看到明文的xml了,但是还是不能直接取到我们想要的数据
<?xml version="1.0" encoding="utf-8"?>
<O:Provision xmlns:O="Provision" xmlns:S="Settings">
<S:DeviceInformation>
<S:Set>
<S:Model>MIX 2</S:Model>
<S:IMEI>888833336669999</S:IMEI>
<S:FriendlyName>MIX 2</S:FriendlyName>
<S:OS>Android 8.0.0</S:OS>
<S:PhoneNumber>+8618599999999</S:PhoneNumber>
<S:UserAgent>Android/8.0.0-EAS-1.3</S:UserAgent>
<S:MobileOperator>**联通 (46001)</S:MobileOperator>
</S:Set>
</S:DeviceInformation>
<O:Policies>
<O:Policy>
<O:PolicyType>MS-EAS-Provisioning-WBXML</O:PolicyType>
</O:Policy>
</O:Policies>
</O:Provision>我们需要再对xml进行一次解析,解析到对应的struct中,就可以方便地获取想要的数据了,但是这个xml格式比较复杂,笔者试着手工定义了几次都失败了,干脆找了个自动化工具自动生成了,自动化工具的地址为https://github.com/miku/zek。
作者还提供了个Web版的在线工具,使用起来非常方便,地址为:https://www.onlinetool.io/xmltogo/
最后生成的Struct如下:
type Provision struct {
XMLName xml.Name `xml:"Provision"`
Text string `xml:",chardata"`
O string `xml:"O,attr"`
S string `xml:"S,attr"`
DeviceInformation struct {
Text string `xml:",chardata"`
Set struct {
Text string `xml:",chardata"`
Model string `xml:"Model"`
IMEI string `xml:"IMEI"`
FriendlyName string `xml:"FriendlyName"`
OS string `xml:"OS"`
PhoneNumber string `xml:"PhoneNumber"`
UserAgent string `xml:"UserAgent"`
MobileOperator string `xml:"MobileOperator"`
} `xml:"Set"`
} `xml:"DeviceInformation"`
Policies struct {
Text string `xml:",chardata"`
Policy struct {
Text string `xml:",chardata"`
PolicyType string `xml:"PolicyType"`
} `xml:"Policy"`
} `xml:"Policies"`
}最终我们自己导出的处理wbxml的函数如下(将需要关注的信息放到一个用||分割的字符串中返回):
//export parse
func parse(data []byte) (*C.char) {
result := make([]string, 0)
xmldata := getDecodeResult(data...)
fmt.Println(xmldata)
out := Provision{}
xml.Unmarshal([]byte(xmldata), &out)
//fmt.Printf("Model: %v\n", out.DeviceInformation.Set.Model)
//fmt.Printf("Imie: %v\n", out.DeviceInformation.Set.IMEI)
//fmt.Printf("FriendlyName: %v\n", out.DeviceInformation.Set.FriendlyName)
//fmt.Printf("PhoneNumber: %v\n", out.DeviceInformation.Set.PhoneNumber)
//fmt.Printf("MobileOperator: %v\n", out.DeviceInformation.Set.MobileOperator)
result = append(result, out.DeviceInformation.Set.Model)
result = append(result, out.DeviceInformation.Set.IMEI)
result = append(result, out.DeviceInformation.Set.FriendlyName)
result = append(result, out.DeviceInformation.Set.PhoneNumber)
result = append(result, out.DeviceInformation.Set.MobileOperator)
return C.CString(strings.Join(result, "||"))
}接下来分别在wbxml.h和xbxml/lua中导出这个函数,如下所示:
wbxml.h的内容:
#ifndef GO_CGO_PROLOGUE_H
#define GO_CGO_PROLOGUE_H
typedef signed char GoInt8;
typedef unsigned char GoUint8;
typedef short GoInt16;
typedef unsigned short GoUint16;
typedef int GoInt32;
typedef unsigned int GoUint32;
typedef long long GoInt64;
typedef unsigned long long GoUint64;
typedef GoInt64 GoInt;
typedef GoUint64 GoUint;
typedef __SIZE_TYPE__ GoUintptr;
typedef float GoFloat32;
typedef double GoFloat64;
typedef float _Complex GoComplex64;
typedef double _Complex GoComplex128;
/*
static assertion to make sure the file is being used on architecture
at least with matching size of GoInt.
*/
typedef char _check_for_64_bit_pointer_matching_GoInt[sizeof(void*)==64/8 ? 1:-1];
typedef struct { const char *p; GoInt n; } GoString;
typedef void *GoMap;
typedef void *GoChan;
typedef struct { void *t; void *v; } GoInterface;
typedef struct { void *data; GoInt len; GoInt cap; } GoSlice;
#endif
/* End of boilerplate cgo prologue. */
#ifdef __cplusplus
extern "C" {
#endif
extern char* parse(GoString data);
#ifdef __cplusplus
}
#endifwbxml的内容:
-- ensure the lua2go lib is on the LUA_PATH so it will load
-- normally, you'd just put it on the LUA_PATH
package.path = package.path .. ';../lua/?.lua'
-- load lua2go
local lua2go = require('lua2go')
-- load my Go library
local example = lua2go.Load('/data/code/golang/src/dewbxml/wbxml.so')
-- copy just the extern functions from benchmark.h into ffi.cdef structure below
-- (the boilerplate cgo prologue is already defined for you in lua2go)
-- this registers your Go functions to the ffi library..
lua2go.Externs[[
extern char* parse(GoString data);
]]
local filename = "/data/code/golang/src/dewbxml/file.bin"
local file = io.open(filename,"rb")
local data = file:read("*a")
local goResult = example.parse(lua2go.ToGo(data))
local Result = lua2go.ToLua(goResult)
print('Result: ' .. Result)最终的结果如下图所示:
造化弄人,在不经意间,还是造了一个轮子,项目地址为:https://github.com/netxfly/dewbxml
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