renamed package/directory

client.go

@@ -1,4 +1,4 @@
-package botclient
+package client
 
 import (
 	"encoding/gob"
@@ -7,7 +7,7 @@ import (
 	"fmt"
 	"log"
 
-	"bitbucket.org/hackerbots/botserv"
+	hbserver "bitbucket.org/hackerbots/server"
 	"code.google.com/p/go.net/websocket"
 )
 
@@ -26,12 +26,12 @@ type Client struct {
 	Name      string
 	Port      int
 	Server    string
-	StatsReq  botserv.StatsRequest
+	StatsReq  hbserver.StatsRequest
 	Verbose   bool
 	Player    Player
-	Game      botserv.GameParam
+	Game      hbserver.GameParam
 
-	boardstate botserv.Boardstate
+	boardstate hbserver.Boardstate
 	enc        encoder
 	dec        decoder
 	ws         *websocket.Conn
@@ -114,9 +114,9 @@ func (c *Client) Negociate() (err error) {
 		c.dec = gob.NewDecoder(c.ws)
 	}
 
-	conf := botserv.ClientConfig{
+	conf := hbserver.ClientConfig{
 		ID: c.GameId,
-		Stats: map[string]botserv.StatsRequest{
+		Stats: map[string]hbserver.StatsRequest{
 			c.Name: c.StatsReq,
 		},
 	}
@@ -127,7 +127,7 @@ func (c *Client) Negociate() (err error) {
 		Id      string `json:"id"`
 		Success bool   `json:"success"`
 		Type    string `json:"type"`
-		botserv.Failure
+		hbserver.Failure
 	}
 	websocket.JSON.Receive(c.ws, &handshake)
 	if !handshake.Success {
@@ -140,7 +140,7 @@ func (c *Client) Negociate() (err error) {
 	// we don't do anything useful with dstats, but could be interesting to
 	// pass along to the player?
 	dstats := struct {
-		Stats map[string]botserv.Stats `json:"stats"`
+		Stats map[string]hbserver.Stats `json:"stats"`
 		Type  string                    `json:"type"`
 	}{}
 	err = websocket.JSON.Receive(c.ws, &dstats)
@@ -151,7 +151,7 @@ func (c *Client) Negociate() (err error) {
 	return nil
 }
 
-// Play contains the main game run loop. It gets a botserv.Boardstate from the
+// Play contains the main game run loop. It gets a hbserver.Boardstate from the
 // server, and passes this along to the embedded Player. Following this it
 // sends the server the Player's instruction.
 func (c *Client) Play() error {

doc.go

@@ -1,2 +1,2 @@
-// botclient is a package used to connect to and interact with a hackebots game.
+// client is a package used to connect to and interact with a hackebots game.
-package botclient
+package client

gobot/main.go

@@ -6,8 +6,8 @@ import (
 	"math/rand"
 	"time"
 
-	"bitbucket.org/hackerbots/botclient"
+	hbclient "bitbucket.org/hackerbots/client"
-	"bitbucket.org/hackerbots/botserv"
+	hbserver "bitbucket.org/hackerbots/server"
 )
 
 var hp = flag.Int("hp", 50, "")
@@ -39,13 +39,13 @@ func main() {
 		gameId = flag.Arg(0)
 	}
 
-	c := &botclient.Client{
+	c := &hbclient.Client{
 		Server: *server,
 		Port:   *port,
 		Name:   *botname,
 		GameId: gameId,
 		// XXX: update with missing fields
-		StatsReq: botserv.StatsRequest{
+		StatsReq: hbserver.StatsRequest{
 			Hp:            *hp,
 			Speed:         *speed,
 			Acceleration:  *acceleration,
@@ -65,7 +65,7 @@ func main() {
 		log.Printf("%s: failed to negociate: %s", c.Name, err)
 	}
 
-	c.Player = botclient.NewSimplePlayer(
+	c.Player = hbclient.NewSimplePlayer(
 		c.Game.BoardSize.Width,
 		c.Game.BoardSize.Height,
 	)

player.go

@@ -1,11 +1,11 @@
-package botclient
+package client
 
 import (
 	"fmt"
 	"math"
 	"math/rand"
 
-	"bitbucket.org/hackerbots/botserv"
+	hbserver "bitbucket.org/hackerbots/server"
 	"bitbucket.org/hackerbots/vector"
 )
 
@@ -15,19 +15,19 @@ import (
 // The general case will be to implement a Player type that contains the magic
 // required to slay other robots quickly while staying alive for a long time.
 type Player interface {
-	Recv(bs *botserv.Boardstate)
+	Recv(bs *hbserver.Boardstate)
-	Instruction() map[string]botserv.Instruction
+	Instruction() map[string]hbserver.Instruction
 }
 
 // SimplePlayer is our default player and stands as a starting point for your
 // own Player implementations.
 type SimplePlayer struct {
-	me             botserv.Robot
+	me             hbserver.Robot
 	width, height  float32
-	knownObstacles map[string]botserv.Obstacle
+	knownObstacles map[string]hbserver.Obstacle
-	nearestEnemy   *botserv.OtherRobot
+	nearestEnemy   *hbserver.OtherRobot
-	fireat         *govector.Point2d
+	fireat         *vector.Point2d
-	moveto         *govector.Point2d
+	moveto         *vector.Point2d
 	speed          float32
 	maxSpeed       float32
 	safeDistance   float32
@@ -36,7 +36,7 @@ type SimplePlayer struct {
 // NewSimplePlayer simply returns a populated, usable *SimplePlayer
 func NewSimplePlayer(width, height float32) *SimplePlayer {
 	return &SimplePlayer{
-		knownObstacles: make(map[string]botserv.Obstacle),
+		knownObstacles: make(map[string]hbserver.Obstacle),
 		width:          width,
 		height:         height,
 		maxSpeed:       100,
@@ -44,8 +44,8 @@ func NewSimplePlayer(width, height float32) *SimplePlayer {
 	}
 }
 
-// Recv is our implementation of receiving a botserv.Boardstate from the server
+// Recv is our implementation of receiving a hbserver.Boardstate from the server
-func (p *SimplePlayer) Recv(bs *botserv.Boardstate) {
+func (p *SimplePlayer) Recv(bs *hbserver.Boardstate) {
 	p.speed = p.maxSpeed
 	if len(bs.MyRobots) > 0 {
 		p.me = bs.MyRobots[0]
@@ -81,7 +81,7 @@ func (p *SimplePlayer) navigate() {
 	}
 }
 
-func (p *SimplePlayer) recon(bs *botserv.Boardstate) {
+func (p *SimplePlayer) recon(bs *hbserver.Boardstate) {
 	for _, o := range bs.Objects {
 		obj := MiniObstacle(o)
 		if _, ok := p.knownObstacles[obj.Id()]; !ok {
@@ -109,8 +109,8 @@ func (p *SimplePlayer) recon(bs *botserv.Boardstate) {
 
 // Instruction is our default implementation of preparing a map of information
 // to be sent to server.
-func (p *SimplePlayer) Instruction() map[string]botserv.Instruction {
+func (p *SimplePlayer) Instruction() map[string]hbserver.Instruction {
-	return map[string]botserv.Instruction{
+	return map[string]hbserver.Instruction{
 		p.me.Id: {
 			MoveTo:      p.moveto,
 			TargetSpeed: &p.speed,
@@ -119,18 +119,18 @@ func (p *SimplePlayer) Instruction() map[string]botserv.Instruction {
 	}
 }
 
-func (p *SimplePlayer) randomDirection() *govector.Point2d {
+func (p *SimplePlayer) randomDirection() *vector.Point2d {
-	pt := govector.Vector2d{
+	pt := vector.Vector2d{
 		X: rand.Float32() * p.width,
 		Y: rand.Float32() * p.height,
 	}.ToPoint()
 	return &pt
 }
 
-func (p *SimplePlayer) probe(destination govector.Point2d) bool {
+func (p *SimplePlayer) probe(destination vector.Point2d) bool {
 	// XXX: make test for this
 	for _, v := range p.knownObstacles {
-		collided, _, _ := govector.RectIntersection(
+		collided, _, _ := vector.RectIntersection(
 			v.Bounds,
 			p.me.Position,
 			destination.Sub(p.me.Position),
@@ -142,7 +142,7 @@ func (p *SimplePlayer) probe(destination govector.Point2d) bool {
 	return true
 }
 
-// MiniObstacle is a convenient way to encode/decode between the [4]int -> botserv.Obstacle
+// MiniObstacle is a convenient way to encode/decode between the [4]int -> hbserver.Obstacle
 type MiniObstacle [4]int
 
 // id is used to calculate a key for use in maps
@@ -161,11 +161,11 @@ func (mo MiniObstacle) String() string {
 }
 
 // ToObstacle is where the conversion magic happens
-func (mo *MiniObstacle) ToObstacle() botserv.Obstacle {
+func (mo *MiniObstacle) ToObstacle() hbserver.Obstacle {
-	return botserv.Obstacle{
+	return hbserver.Obstacle{
-		Bounds: govector.AABB2d{
+		Bounds: vector.AABB2d{
-			A: govector.Point2d{float32(mo[0]), float32(mo[1])},
+			A: vector.Point2d{float32(mo[0]), float32(mo[1])},
-			B: govector.Point2d{float32(mo[2]), float32(mo[3])},
+			B: vector.Point2d{float32(mo[2]), float32(mo[3])},
 		},
 	}
 }