A codewalk through a simple program that illustrates several aspects of Go functions: function objects, higher-order functions, variadic functions, tail recursion, etc. The example program simulates the game of Pig, a dice game with simple rules but a nontrivial solution.

R=adg, rsc, iant2, r CC=golang-dev https://golang.org/cl/4306045
2024-11-21 14:34:41 -07:00 · 2011-04-07 18:05:15 -07:00 · 2011-04-07 18:05:15 -07:00 · 4ffee801ce
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 <codewalk title="First-Class Functions in Go">
 <step title="Introduction" src="doc/codewalk/pig.go">
 	Go supports first class functions, higher-order functions, user-defined
 	function types, function literals, closures, and multiple return values.
  <br/><br/>
 	This rich feature set supports a functional programming style in a strongly
 	typed language.
 	<br/><br/>
 	In this codewalk we will look at a simple program that simulates a dice game
 	called <a href="http://en.wikipedia.org/wiki/Pig_(dice)">Pig</a> and evaluates
 	basic strategies.
 </step>
 <step title="Game overview" src="doc/codewalk/pig.go:/\/\/ A score/,/thisTurn int\n}/">
  Pig is a two-player game played with a 6-sided die.  Each turn, you may roll or stay.
 	<ul>
 		<li> If you roll a 1, you lose all points for your turn and play passes to
 			your opponent.  Any other roll adds its value to your turn score.  </li>
 		<li> If you stay, your turn score is added to your total score, and play passes
 			to your opponent.  </li>
 	</ul>
 	The first person to reach 100 total points wins.
 	<br/><br/>
 	The <code>score</code> type stores the scores of the current and opposing
 	players, in addition to the points accumulated during the current turn.
 </step>
 <step title="User-defined function types" src="doc/codewalk/pig.go:/\/\/ An action/,/bool\)/">
 	In Go, functions can be passed around just like any other value. A function's
 	type signature describes the types of its arguments and return values.
 	<br/><br/>
 	The <code>action</code> type is a function that takes a <code>score</code>
 	and returns the resulting <code>score</code> and whether the current turn is
 	over.
 	<br/><br/>
  If the turn is over, the <code>player</code> and <code>opponent</code> fields
  in the resulting <code>score</code> should be swapped, as it is now the other player's
  turn.
 </step>
 <step title="Multiple return values" src="doc/codewalk/pig.go:/\/\/ roll returns/,/stay.*true\n}/">
 	Go functions can return multiple values.  
 	<br/><br/>
 	The functions <code>roll</code> and <code>stay</code> each return a pair of
 	values.  They also match the <code>action</code> type signature.  These
 	<code>action</code> functions define the rules of Pig.
 </step>
 <step title="Higher-order functions" src="doc/codewalk/pig.go:/\/\/ A strategy/,/action\n/">
 	A function can use other functions as arguments and return values.
 	<br/><br/>
  A <code>strategy</code> is a function that takes a <code>score</code> as input
  and returns an <code>action</code> to perform.  <br/>
  (Remember, an <code>action</code> is itself a function.)
 </step>
 <step title="Function literals and closures" src="doc/codewalk/pig.go:/return func/,/return roll\n\t}/">
 	Anonymous functions can be declared in Go, as in this example.  Function
 	literals are closures: they inherit the scope of the function in which they
 	are declared.
 	<br/><br/>
 	One basic strategy in Pig is to continue rolling until you have accumulated at
 	least k points in a turn, and then stay.  The argument <code>k</code> is
 	enclosed by this function literal, which matches the <code>strategy</code> type
 	signature.
 </step>
 <step title="Simulating games" src="doc/codewalk/pig.go:/\/\/ play/,/currentPlayer\n}/">
  We simulate a game of Pig by calling an <code>action</code> to update the
  <code>score</code> until one player reaches 100 points.  Each
  <code>action</code> is selected by calling the <code>strategy</code> function
  associated with the current player.
 </step>
 <step title="Comparing functions" src="doc/codewalk/pig.go:/if action/,/currentPlayer\)\)\n\t\t}/">
 	Functions can be compared for equality in Go.  From the 
 	<a href="http://golang.org/doc/go_spec.html#Comparison_operators">language specification</a>:
  Function values are equal if they refer to the same function or if both are <code>nil</code>.
 	<br/><br/>
  We enforce that a <code>strategy</code> function can only return a legal
  <code>action</code>: either <code>roll</code> or <code>stay</code>.
 </step>
 <step title="Simulating a tournament" src="doc/codewalk/pig.go:/\/\/ roundRobin/,/gamesPerStrategy\n}/">
 	The <code>roundRobin</code> function simulates a tournament and tallies wins.
 	Each strategy plays each other strategy <code>gamesPerSeries</code> times.
 </step>
 <step title="Variadic function declarations" src="doc/codewalk/pig.go:/\/\/ ratioS/,/string {/">
 	Variadic functions like <code>ratioString</code> take a variable number of
 	arguments.  These arguments are available as a slice inside the function.
 </step>
 <step title="Simulation results" src="doc/codewalk/pig.go:/func main/,/\n}/">
 	The <code>main</code> function defines 100 basic strategies, simulates a round
 	robin tournament, and then prints the win/loss record of each strategy.
 	<br/><br/>
 	Among these strategies, staying at 25 is best, but the <a
 	href="http://www.google.com/search?q=optimal+play+pig">optimal strategy for
 	Pig</a> is much more complex.
 </step>
 </codewalk>
--- a/doc/codewalk/pig.go
+++ b/doc/codewalk/pig.go
@ -0,0 +1,124 @@
 // Copyright 2011 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.
 package main
 import (
 	"fmt"
 	"rand"
 )
 const (
 	win            = 100 // The winning score in a game of Pig
 	gamesPerSeries = 10  // The number of games per series to simulate
 )
 // A score includes scores accumulated in previous turns for each player,
 // as well as the points scored by the current player in this turn.
 type score struct {
 	player, opponent, thisTurn int
 }
 // An action transitions stochastically to a resulting score.
 type action func(current score) (result score, turnIsOver bool)
 // roll returns the (result, turnIsOver) outcome of simulating a die roll. 
 // If the roll value is 1, then thisTurn score is abandoned, and the players'
 // roles swap.  Otherwise, the roll value is added to thisTurn.
 func roll(s score) (score, bool) {
 	outcome := rand.Intn(6) + 1 // A random int in [1, 6]
 	if outcome == 1 {
 		return score{s.opponent, s.player, 0}, true
 	}
 	return score{s.player, s.opponent, outcome + s.thisTurn}, false
 }
 // stay returns the (result, turnIsOver) outcome of staying.
 // thisTurn score is added to the player's score, and the players' roles swap.
 func stay(s score) (score, bool) {
 	return score{s.opponent, s.player + s.thisTurn, 0}, true
 }
 // A strategy chooses an action for any given score.
 type strategy func(score) action
 // stayAtK returns a strategy that rolls until thisTurn is at least k, then stays.
 func stayAtK(k int) strategy {
 	return func(s score) action {
 		if s.thisTurn >= k {
 			return stay
 		}
 		return roll
 	}
 }
 // play simulates a Pig game and returns the winner (0 or 1).
 func play(strategy0, strategy1 strategy) int {
 	strategies := []strategy{strategy0, strategy1}
 	var s score
 	var turnIsOver bool
 	currentPlayer := rand.Intn(2) // Randomly decide who plays first
 	for s.player+s.thisTurn < win {
 		action := strategies[currentPlayer](s)
 		if action != roll && action != stay {
 			panic(fmt.Sprintf("Player %d is cheating", currentPlayer))
 		}
 		s, turnIsOver = action(s)
 		if turnIsOver {
 			currentPlayer = (currentPlayer + 1) % 2
 		}
 	}
 	return currentPlayer
 }
 // roundRobin simulates a series of games between every pair of strategies.
 func roundRobin(strategies []strategy) ([]int, int) {
 	wins := make([]int, len(strategies))
 	for i := 0; i < len(strategies); i++ {
 		for j := i + 1; j < len(strategies); j++ {
 			for k := 0; k < gamesPerSeries; k++ {
 				winner := play(strategies[i], strategies[j])
 				if winner == 0 {
 					wins[i]++
 				} else {
 					wins[j]++
 				}
 			}
 		}
 	}
 	gamesPerStrategy := gamesPerSeries * (len(strategies) - 1) // no self play
 	return wins, gamesPerStrategy
 }
 // ratioString takes a list of integer values and returns a string that lists
 // each value and its percentage of the sum of all values.
 // e.g., ratios(1, 2, 3) = "1/6 (16.7%), 2/6 (33.3%), 3/6 (50.0%)"
 func ratioString(vals ...int) string {
 	total := 0
 	for _, val := range vals {
 		total += val
 	}
 	s := ""
 	for _, val := range vals {
 		if s != "" {
 			s += ", "
 		}
 		pct := 100 * float64(val) / float64(total)
 		s += fmt.Sprintf("%d/%d (%0.1f%%)", val, total, pct)
 	}
 	return s
 }
 func main() {
 	strategies := make([]strategy, win)
 	for k := range strategies {
 		strategies[k] = stayAtK(k + 1)
 	}
 	wins, games := roundRobin(strategies)
 	for k := range strategies {
 		fmt.Printf("Wins, losses staying at k =% 4d: %s\n",
 			k+1, ratioString(wins[k], games-wins[k]))
 	}
 }