Scalaz(22)- 泛函编程思维: Coerce Monadic Thinking
马上进入新的一年2016了,来点轻松点的内容吧。前面写过一篇关于用Reader实现依赖注入管理的博文(Scalaz(16)- Monad:依赖注入-Dependency Injection By Reader Monad)。刚好年底这几天抽空重审了一遍,这时才真正认识到让一个老资格OOP程序猿去编写一段FP程序时会发生什么事情:他会用FP语法和数据类型按照OOP的思维编写程序。其结果就是一段尴尬的代码,让人看得不知怎么去形容,更不用提FP程序的精简高雅了。我在前面博文的示范程序正是落入了这个OOP思维陷阱。
我们先把源代码搬过来看看:
package Exercises
import scalaz._
import Scalaz._
object reader3 {
trait OnOffDevice {
def on: String
def off: String
}
trait SensorDevice {
def isCoffeePresent: Boolean
}
trait PowerConfig {
def getPowerVolts(country: String): Int
def isUSStandard(volt: Int): Boolean
}
trait OnOffComponent {
def onOffDevice: OnOffDevice
}
trait SensorComponent {
def sensorDevice: SensorDevice
}
trait Device extends OnOffComponent with SensorComponent
trait DeviceComponent {
def onOffDevice: OnOffDevice
def sensorDevice: SensorDevice
}
trait PowerComponent {
def powerConfig: PowerConfig
}
trait Appliance extends DeviceComponent with PowerComponent
object Appliance {
val appliance = Reader[Appliance,Appliance](identity)
val onOffDevice = appliance map {_.onOffDevice}
val sensorDevice = appliance map {_.sensorDevice}
val powerConfig = appliance map {_.powerConfig}
}
object OnOffDevice {
import Appliance.onOffDevice
def on: Reader[Appliance,String] = onOffDevice map { _.on }
def off: Reader[Appliance,String] = onOffDevice map { _.off }
}
object SensorDevice {
import Appliance.sensorDevice
def isCoffeePresent: Reader[Appliance,Boolean] = sensorDevice map { _.isCoffeePresent }
}
object PowerConfig {
import Appliance.powerConfig
def getPowerVolts(country: String) = powerConfig map {_.getPowerVolts(country)}
def isUSStandard(volts: Int) = powerConfig map {_.isUSStandard(volts)}
}
object OnOffService {
def on = for {
ison <- OnOffDevice.on
} yield ison
def off = for {
isoff <- OnOffDevice.off
} yield isoff
}
object SensorService {
def isCoffeePresent = for {
hasCoffee <- SensorDevice.isCoffeePresent
} yield hasCoffee
}
object PowerService {
def isUSStandard(country: String) = for {
is110v <- PowerConfig.getPowerVolts(country)
isUSS <- PowerConfig.isUSStandard(is110v)
} yield isUSS
}
class OnOffDeviceImpl extends OnOffDevice {
def on = "SomeDevice.On"
def off = "SomeDevice.Off"
}
class SensorDeviceImpl extends SensorDevice {
def isCoffeePresent = true
}
class PowerConfigImpl extends PowerConfig {
def getPowerVolts(country: String) = country match {
case "USA" => 110
case "UK" => 220
case "HK" => 220
case "CHN" => 110
case _ => 0
}
def isUSStandard(volts: Int) = volts === 110
}
object MockOnOffDevice extends OnOffDeviceImpl
object MockSensorDevice extends SensorDeviceImpl
object MockPowerConfig extends PowerConfigImpl
trait OnOffFunctions extends OnOffComponent {
def onOffDevice = MockOnOffDevice
}
trait SensorFunctions extends SensorComponent {
def sensorDevice = MockSensorDevice
}
trait DeviceFunctions extends DeviceComponent {
def onOffDevice = MockOnOffDevice
def sensorDevice = MockSensorDevice
}
trait PowerFunctions extends PowerComponent {
def powerConfig = MockPowerConfig
}
object MockAppliance extends Appliance with DeviceFunctions with PowerFunctions
def trigger =
if ((PowerService.isUSStandard("CHN")(MockAppliance))
&& (SensorService.isCoffeePresent(MockAppliance)))
OnOffService.on(MockAppliance)
else
OnOffService.off(MockAppliance) //> trigger: => scalaz.Id.Id[String]
trigger //> res0: scalaz.Id.Id[String] = SomeDevice.On
}
这段代码前面用trait进行了功能需求描述,接着用Reader定义依赖,再接着通过Reader组合实现了依赖的层级式管理,直到形成最终的Reader组合:
object MockAppliance extends Appliance with DeviceFunctions with PowerFunctions
这些都没什么问题,也体现了函数式编程风格。问题就出在这个trigger函数定义里,我们来看看:
def trigger =
if ((PowerService.isUSStandard("CHN")(MockAppliance))
&& (SensorService.isCoffeePresent(MockAppliance)))
OnOffService.on(MockAppliance)
else
OnOffService.off(MockAppliance) //> trigger: => scalaz.Id.Id[String]
首先感觉代码很乱;每句都有个MockAppliance很笨拙(clumsy),感觉不到任何优雅的风格,也看不出与常用的OOP编程有什么分别。
回忆下当时是怎么想的呢?trigger的要求是:如果电源是US标准并且壶里能检测到有咖啡,那么就可以启动加热器,否则关停。
已经完成了电源标准和咖啡壶内容检测即加热器开关的组件(combinators)。都是细化了的独立功能函数,这点符合了函数式编程的基本要求。
当时的思路是这样的:
1、获取当前电源制式,判断是否US标准
2、获取咖啡壶检测数据,判断是否盛载咖啡
3、if 1 and 2 then OnoffService.on else OnOffService.off
但是为了获取1和2的Boolean结果就必须注入依赖:MockAppliance,所以在trigger函数定义里进行了依赖注入。现在看来这就是典型的OOP思想方式。
首先我们再次回想一下函数式编程的一些最基本要求:
1、纯代码(pure code):实现函数组合-这点在前面的功能函数组件编程中已经做到
2、无副作用(no-side-effect):尽量把副作用推到程序最外层,拖延到最后-trigger使用了依赖MockAppliance,产生了副作用
3、我经常提醒自己Monadic Programming就是F[A]:A是我们要运算的值,我们需要在一个壳子内(context)对A进行运算。
看看这个版本的trigger:因为直接获取了isUSStandard和isCoffeePresent的Boolean运算值所以需要立即注入依赖。首先的后果是trigger现在是有副作用的了。再者trigger和MockAppliance紧紧绑到了一起(tight coupling)- 如果我们再有个Reader组合,比如什么DeployAppliance的,那我们必须再搞另一个版本的trigger了。即使我们通过输入参数传入这个Reader组合依赖也会破坏了函数的可组合性(composibility),影响函数组件的重复利用。看来还是按照上面的要求把这个trigger重新编写:
object MockAppliance extends Appliance with DeviceFunctions with PowerFunctions
def trigger(cntry: String) = for {
isUS <- PowerService.isUSStandard(cntry)
hasCoffee <- SensorService.isCoffeePresent
onoff <- if (isUS && hasCoffee) OnOffService.on else OnOffService.off
} yield onoff //> trigger: (cntry: String)scalaz.Kleisli[scalaz.Id.Id,Exercises.Exercises.rea
//| derDI.Appliance,String]
trigger("CHN")(MockAppliance) //> res0: scalaz.Id.Id[String] = SomeDevice.On
trigger("HK")(MockAppliance) //> res1: scalaz.Id.Id[String] = SomeDevice.Off
现在这个版本的trigger是一段纯代码,并且是在for-comprehension内运算的,与依赖实现了松散耦合。假如这时再有另一个版本的依赖组合DeployAppliance,我们只需要改变trigger的注入依赖:
trigger("CHN")(DeployAppliance) //> res0: scalaz.Id.Id[String] = CoffeeMachine.On
trigger("HK")(DeployAppliance) //> res1: scalaz.Id.Id[String] = CoffeeMachine.Off
怎么样?这样看起来是不是简明高雅许多了?
噢,祝大家新年快乐!