Update README.md

Merge pull request #43 from mdiluz/gameplay-improvements
Assorted gameplay improvements from play testing
2024-09-27 10:43:28 +01:00 · 2020-08-02 12:52:29 +01:00 · 2020-08-02 12:49:15 +01:00 · 2020-08-02 12:43:44 +01:00 · 2020-08-02 12:15:49 +01:00 · 2020-08-02 12:03:12 +01:00
58 changed files with 5178 additions and 5587 deletions
--- a/.vscode/launch.json
+++ b/.vscode/launch.json
@ -1,30 +0,0 @@
 {
    // Use IntelliSense to learn about possible attributes.
    // Hover to view descriptions of existing attributes.
    // For more information, visit: https://go.microsoft.com/fwlink/?linkid=830387
    "version": "0.2.0",
    "configurations": [
        {
            "name": "Launch Rove Server",
            "type": "go",
            "request": "launch",
            "mode": "auto",
            "program": "${workspaceFolder}/cmd/rove-server/main.go",
            "cwd": "${workspaceFolder}",
            "env": {
                "WORDS_FILE": "${workspaceFolder}/data/words_alpha.txt",
            },
            "args": [],            
        },
        {
            "name": "Launch Rove",
            "type": "go",
            "request": "launch",
            "mode": "auto",
            "program": "${workspaceFolder}/cmd/rove/main.go",
            "cwd": "${workspaceFolder}",
            "env": {},
            "args": ["radar"],            
        }
    ]
 }
--- a/.vscode/settings.json
+++ b/.vscode/settings.json
@ -1,5 +0,0 @@
 {
    "gopls": {
        "buildFlags": ["-tags=integration"]
      },
 }
--- a/1
+++ b/1
@ -8,7 +8,6 @@ RUN go mod download
 # Build the executables
 RUN go build -o rove -ldflags="-X 'github.com/mdiluz/rove/pkg/version.Version=$(git describe --always --long --dirty --tags)'" cmd/rove/main.go
 RUN go build -o rove-server -ldflags="-X 'github.com/mdiluz/rove/pkg/version.Version=$(git describe --always --long --dirty --tags)'" cmd/rove-server/main.go
 RUN go build -o rove-server-rest-proxy cmd/rove-server-rest-proxy/main.go
 CMD [ "./rove-server" ]
--- a/Dockerfile.docs
+++ b/Dockerfile.docs
@ -1,8 +0,0 @@
 FROM quay.io/goswagger/swagger:latest
 LABEL maintainer="Marc Di Luzio <marc.diluzio@gmail.com>"
 WORKDIR /app
 COPY . .
 CMD [ "serve", "pkg/rove/rove.swagger.json", "--no-open" ]
--- a/23
+++ b/23
@ -3,7 +3,7 @@ VERSION := $(shell git describe --always --long --dirty --tags)
 build:
 	@echo Running no-output build
 	go mod download
-	go build -ldflags="-X 'github.com/mdiluz/rove/pkg/version.Version=${VERSION}'" ./...
+	go build -ldflags="-X 'github.com/mdiluz/rove/cmd/version.Version=${VERSION}'" ./...
 install:
 	@echo Installing to GOPATH
@ -12,24 +12,15 @@ install:
 gen:
 	@echo Installing go dependencies
-	go install \
+	go install github.com/golang/protobuf/protoc-gen-go
 		github.com/grpc-ecosystem/grpc-gateway/protoc-gen-grpc-gateway \
 		github.com/grpc-ecosystem/grpc-gateway/protoc-gen-swagger \
 		github.com/golang/protobuf/protoc-gen-go
 	go mod download
-	@echo Generating rove server gRPC and gateway
+	@echo Generating rove server gRPC
-	protoc --proto_path proto --go_out=plugins=grpc,paths=source_relative:pkg/ proto/rove/rove.proto
+	protoc --proto_path proto --go_out=plugins=grpc,paths=source_relative:proto/ proto/roveapi/roveapi.proto
 	protoc --proto_path proto --grpc-gateway_out=paths=source_relative:pkg/ proto/rove/rove.proto
 	@echo Generating rove server swagger
 	protoc --proto_path proto --swagger_out=logtostderr=true:pkg/ proto/rove/rove.proto
 test:
-	@echo Unit tests
+	@echo Run unit and integration tests
-	go test -v ./...
+	docker-compose -f docker-compose-test.yml up --build --exit-code-from=rove-tests --abort-on-container-exit rove-tests
-
+	docker-compose -f docker-compose-test.yml down
 	@echo Integration tests
 	docker-compose up --build --exit-code-from=rove-tests --abort-on-container-exit rove-tests
 	docker-compose down
 	go tool cover -html=/tmp/coverage-data/c.out -o /tmp/coverage.html
 	@echo Done, coverage data can be found in /tmp/coverage.html
--- a/README.md
+++ b/README.md
@ -1,11 +1,8 @@
 Rove
 ====
 ![Tests](https://github.com/mdiluz/rove/workflows/Tests/badge.svg) ![Docker](https://github.com/mdiluz/rove/workflows/Docker/badge.svg) [![rove](https://snapcraft.io//rove/badge.svg)](https://snapcraft.io/rove)
-![Rove](https://github.com/mdiluz/rove/blob/master/data/icon.svg)
+![Rove](data/icon.svg)
 Rove is an asynchronous nomadic game about exploring as part of a loose community.
-This repository is a [living document](https://github.com/mdiluz/rove/tree/master/docs) of current game design, as well as source code for the `rove-server` deployment and the `rove` command line client.
+This repository contains the source code for the `rove-server` deployment and the `rove` command line client. See [mdiluz.github.io/rove](https://mdiluz.github.io/rove/) for game details, and [roveapi.proto](proto/roveapi/roveapi.proto) for the current server-client API.
 See [rove.proto](https://github.com/mdiluz/rove/blob/master/proto/rove/rove.proto) for the current server-client API.
--- a/cmd/rove-server-rest-proxy/http_test.go
+++ b/cmd/rove-server-rest-proxy/http_test.go
@ -1,150 +0,0 @@
 // +build integration
 package main
 import (
 	"bytes"
 	"encoding/json"
 	"fmt"
 	"io/ioutil"
 	"log"
 	"net/http"
 	"net/url"
 	"os"
 	"testing"
 	"github.com/google/uuid"
 	"github.com/mdiluz/rove/pkg/rove"
 	"github.com/stretchr/testify/assert"
 )
 // Server is a simple wrapper to a server path
 type Server string
 // Request performs a HTTP
 func (s Server) Request(method, path string, in, out interface{}) error {
 	u := url.URL{
 		Scheme: "http",
 		Host:   fmt.Sprintf("%s:8080", string(s)),
 		Path:   path,
 	}
 	client := &http.Client{}
 	// Marshal the input
 	marshalled, err := json.Marshal(in)
 	if err != nil {
 		return err
 	}
 	// Set up the request
 	req, err := http.NewRequest(method, u.String(), bytes.NewReader(marshalled))
 	if err != nil {
 		return err
 	}
 	// Do the POST
 	req.Header.Set("Content-Type", "application/json")
 	if resp, err := client.Do(req); err != nil {
 		return err
 	} else if resp.StatusCode != http.StatusOK {
 		body, err := ioutil.ReadAll(resp.Body)
 		if err != nil {
 			return fmt.Errorf("failed to read response body to code %d", resp.StatusCode)
 		}
 		return fmt.Errorf("http returned status %d: %s", resp.StatusCode, string(body))
 	} else {
 		return json.NewDecoder(resp.Body).Decode(out)
 	}
 }
 var serv = Server(os.Getenv("ROVE_HTTP"))
 func TestServer_ServerStatus(t *testing.T) {
 	req := &rove.ServerStatusRequest{}
 	resp := &rove.ServerStatusResponse{}
 	if err := serv.Request("GET", "server-status", req, resp); err != nil {
 		log.Fatal(err)
 	}
 }
 func TestServer_Register(t *testing.T) {
 	req := &rove.RegisterRequest{Name: uuid.New().String()}
 	resp := &rove.RegisterResponse{}
 	err := serv.Request("POST", "register", req, resp)
 	assert.NoError(t, err, "First register attempt should pass")
 	err = serv.Request("POST", "register", req, resp)
 	assert.Error(t, err, "Second identical register attempt should fail")
 }
 func TestServer_Command(t *testing.T) {
 	acc := uuid.New().String()
 	var resp rove.RegisterResponse
 	err := serv.Request("POST", "register", &rove.RegisterRequest{Name: acc}, &resp)
 	assert.NoError(t, err, "First register attempt should pass")
 	req := &rove.CommandRequest{
 		Account: &rove.Account{
 			Name: resp.Account.Name,
 		},
 		Commands: []*rove.Command{
 			{
 				Command: "move",
 				Bearing: "NE",
 			},
 		},
 	}
 	assert.Error(t, serv.Request("POST", "command", req, &rove.CommandResponse{}), "Commands should fail with no secret")
 	req.Account.Secret = resp.Account.Secret
 	assert.NoError(t, serv.Request("POST", "command", req, &rove.CommandResponse{}), "Commands should pass")
 }
 func TestServer_Radar(t *testing.T) {
 	acc := uuid.New().String()
 	var reg rove.RegisterResponse
 	err := serv.Request("POST", "register", &rove.RegisterRequest{Name: acc}, &reg)
 	assert.NoError(t, err, "First register attempt should pass")
 	resp := &rove.RadarResponse{}
 	req := &rove.RadarRequest{
 		Account: &rove.Account{
 			Name: reg.Account.Name,
 		},
 	}
 	assert.Error(t, serv.Request("POST", "radar", req, resp), "Radar should fail without secret")
 	req.Account.Secret = reg.Account.Secret
 	assert.NoError(t, serv.Request("POST", "radar", req, resp), "Radar should pass")
 	assert.NotZero(t, resp.Range, "Radar should return valid range")
 	w := int(resp.Range*2 + 1)
 	assert.Equal(t, w*w, len(resp.Tiles), "radar should return correct number of tiles")
 	assert.Equal(t, w*w, len(resp.Objects), "radar should return correct number of objects")
 }
 func TestServer_Status(t *testing.T) {
 	acc := uuid.New().String()
 	var reg rove.RegisterResponse
 	err := serv.Request("POST", "register", &rove.RegisterRequest{Name: acc}, &reg)
 	assert.NoError(t, err, "First register attempt should pass")
 	resp := &rove.StatusResponse{}
 	req := &rove.StatusRequest{
 		Account: &rove.Account{
 			Name: reg.Account.Name,
 		},
 	}
 	assert.Error(t, serv.Request("POST", "status", req, resp), "Status should fail without secret")
 	req.Account.Secret = reg.Account.Secret
 	assert.NoError(t, serv.Request("POST", "status", req, resp), "Status should pass")
 	assert.NotZero(t, resp.Range, "Rover should return valid range")
 	assert.NotZero(t, len(resp.Name), "Rover should return valid name")
 	assert.NotZero(t, resp.Position, "Rover should return valid position")
 	assert.NotZero(t, resp.Integrity, "Rover should have positive integrity")
 }
--- a/cmd/rove-server-rest-proxy/main.go
+++ b/cmd/rove-server-rest-proxy/main.go
@ -1,51 +0,0 @@
 package main
 import (
 	"context"
 	"fmt"
 	"log"
 	"net/http"
 	"os"
 	"strconv"
 	"github.com/grpc-ecosystem/grpc-gateway/runtime"
 	"google.golang.org/grpc"
 	"github.com/mdiluz/rove/pkg/rove"
 )
 func main() {
 	ctx := context.Background()
 	ctx, cancel := context.WithCancel(ctx)
 	defer cancel()
 	var endpoint = os.Getenv("ROVE_GRPC")
 	if len(endpoint) == 0 {
 		endpoint = "localhost:9090"
 	}
 	var iport int
 	var port = os.Getenv("PORT")
 	if len(port) == 0 {
 		iport = 8080
 	} else {
 		var err error
 		iport, err = strconv.Atoi(port)
 		if err != nil {
 			log.Fatal("$PORT not valid int")
 		}
 	}
 	// Create a new mux and register it with the gRPC endpoint
 	fmt.Printf("Hosting reverse-proxy on %d for %s\n", iport, endpoint)
 	mux := runtime.NewServeMux()
 	opts := []grpc.DialOption{grpc.WithInsecure()}
 	if err := rove.RegisterRoveHandlerFromEndpoint(ctx, mux, endpoint, opts); err != nil {
 		log.Fatal(err)
 	}
 	// Start the HTTP server and proxy calls to gRPC endpoint when needed
 	if err := http.ListenAndServe(fmt.Sprintf(":%d", iport), mux); err != nil {
 		log.Fatal(err)
 	}
 }
--- a/cmd/rove-server/internal/routes.go
+++ b/cmd/rove-server/internal/routes.go
@ -5,14 +5,13 @@ import (
 	"fmt"
 	"log"
 	"github.com/mdiluz/rove/pkg/game"
 	"github.com/mdiluz/rove/pkg/rove"
 	"github.com/mdiluz/rove/pkg/version"
 	"github.com/mdiluz/rove/proto/roveapi"
 )
 // ServerStatus returns the status of the current server to a gRPC request
-func (s *Server) ServerStatus(context.Context, *rove.ServerStatusRequest) (*rove.ServerStatusResponse, error) {
+func (s *Server) ServerStatus(context.Context, *roveapi.ServerStatusRequest) (*roveapi.ServerStatusResponse, error) {
-	response := &rove.ServerStatusResponse{
+	response := &roveapi.ServerStatusResponse{
 		Ready:       true,
 		Version:     version.Version,
 		TickRate:    int32(s.minutesPerTick),
@ -28,14 +27,14 @@ func (s *Server) ServerStatus(context.Context, *rove.ServerStatusRequest) (*rove
 }
 // Register registers a new account for a gRPC request
-func (s *Server) Register(ctx context.Context, req *rove.RegisterRequest) (*rove.RegisterResponse, error) {
+func (s *Server) Register(ctx context.Context, req *roveapi.RegisterRequest) (*roveapi.RegisterResponse, error) {
 	log.Printf("Handling register request: %s\n", req.Name)
 	if len(req.Name) == 0 {
 		return nil, fmt.Errorf("empty account name")
 	}
-	if acc, err := s.accountant.RegisterAccount(req.Name); err != nil {
+	if acc, err := s.world.Accountant.RegisterAccount(req.Name); err != nil {
 		return nil, err
 	} else if _, err := s.SpawnRoverForAccount(req.Name); err != nil {
@ -45,8 +44,8 @@ func (s *Server) Register(ctx context.Context, req *rove.RegisterRequest) (*rove
 		return nil, fmt.Errorf("internal server error when saving world: %s", err)
 	} else {
-		return &rove.RegisterResponse{
+		return &roveapi.RegisterResponse{
-			Account: &rove.Account{
+			Account: &roveapi.Account{
 				Name:   acc.Name,
 				Secret: acc.Data["secret"],
 			},
@ -55,16 +54,16 @@ func (s *Server) Register(ctx context.Context, req *rove.RegisterRequest) (*rove
 }
 // Status returns rover information for a gRPC request
-func (s *Server) Status(ctx context.Context, req *rove.StatusRequest) (response *rove.StatusResponse, err error) {
+func (s *Server) Status(ctx context.Context, req *roveapi.StatusRequest) (response *roveapi.StatusResponse, err error) {
 	log.Printf("Handling status request: %s\n", req.Account.Name)
-	if valid, err := s.accountant.VerifySecret(req.Account.Name, req.Account.Secret); err != nil {
+	if valid, err := s.world.Accountant.VerifySecret(req.Account.Name, req.Account.Secret); err != nil {
 		return nil, err
 	} else if !valid {
 		return nil, fmt.Errorf("Secret incorrect for account %s", req.Account.Name)
-	} else if resp, err := s.accountant.GetValue(req.Account.Name, "rover"); err != nil {
+	} else if resp, err := s.world.Accountant.GetValue(req.Account.Name, "rover"); err != nil {
 		return nil, err
 	} else if rover, err := s.world.GetRover(resp); err != nil {
@ -76,55 +75,58 @@ func (s *Server) Status(ctx context.Context, req *rove.StatusRequest) (response
 			inv = append(inv, byte(i.Type))
 		}
-		i, q := s.world.RoverCommands(resp)
+		queued := s.world.RoverCommands(resp)
-		var incoming, queued []*rove.Command
+		var logs []*roveapi.Log
-		for _, i := range i {
+		for _, log := range rover.Logs {
-			incoming = append(incoming, &rove.Command{
+			logs = append(logs, &roveapi.Log{
-				Command: i.Command,
+				Text: log.Text,
-				Bearing: i.Bearing,
+				Time: fmt.Sprintf("%d", log.Time.Unix()), // proto uses strings under the hood for 64bit ints anyway
 			})
 		}
 		for _, q := range q {
 			queued = append(queued, &rove.Command{
 				Command: q.Command,
 				Bearing: q.Bearing,
 			})
 		}
-		response = &rove.StatusResponse{
+		response = &roveapi.StatusResponse{
-			Name: rover.Name,
+			Readings: &roveapi.RoverReadings{
-			Position: &rove.Vector{
+				Position: &roveapi.Vector{
-				X: int32(rover.Pos.X),
+					X: int32(rover.Pos.X),
-				Y: int32(rover.Pos.Y),
+					Y: int32(rover.Pos.Y),
 				},
 				Logs: logs,
 				Wind: s.world.Wind,
 			},
 			Spec: &roveapi.RoverSpecifications{
 				Name:             rover.Name,
 				Range:            int32(rover.Range),
 				Capacity:         int32(rover.Capacity),
 				MaximumIntegrity: int32(rover.MaximumIntegrity),
 				MaximumCharge:    int32(rover.MaximumCharge),
 			},
 			Status: &roveapi.RoverStatus{
 				Bearing:        rover.Bearing,
 				Inventory:      inv,
 				Integrity:      int32(rover.Integrity),
 				Charge:         int32(rover.Charge),
 				QueuedCommands: queued,
 				SailPosition:   rover.SailPosition,
 			},
 			Range:            int32(rover.Range),
 			Inventory:        inv,
 			Capacity:         int32(rover.Capacity),
 			Integrity:        int32(rover.Integrity),
 			MaximumIntegrity: int32(rover.MaximumIntegrity),
 			Charge:           int32(rover.Charge),
 			MaximumCharge:    int32(rover.MaximumCharge),
 			IncomingCommands: incoming,
 			QueuedCommands:   queued,
 		}
 	}
 	return response, nil
 }
 // Radar returns the radar information for a rover
-func (s *Server) Radar(ctx context.Context, req *rove.RadarRequest) (*rove.RadarResponse, error) {
+func (s *Server) Radar(ctx context.Context, req *roveapi.RadarRequest) (*roveapi.RadarResponse, error) {
 	log.Printf("Handling radar request: %s\n", req.Account.Name)
-	if valid, err := s.accountant.VerifySecret(req.Account.Name, req.Account.Secret); err != nil {
+	if valid, err := s.world.Accountant.VerifySecret(req.Account.Name, req.Account.Secret); err != nil {
 		return nil, err
 	} else if !valid {
 		return nil, fmt.Errorf("Secret incorrect for account %s", req.Account.Name)
 	}
-	response := &rove.RadarResponse{}
+	response := &roveapi.RadarResponse{}
-	resp, err := s.accountant.GetValue(req.Account.Name, "rover")
+	resp, err := s.world.Accountant.GetValue(req.Account.Name, "rover")
 	if err != nil {
 		return nil, err
@ -144,31 +146,24 @@ func (s *Server) Radar(ctx context.Context, req *rove.RadarRequest) (*rove.Radar
 }
 // Command issues commands to the world based on a gRPC request
-func (s *Server) Command(ctx context.Context, req *rove.CommandRequest) (*rove.CommandResponse, error) {
+func (s *Server) Command(ctx context.Context, req *roveapi.CommandRequest) (*roveapi.CommandResponse, error) {
 	log.Printf("Handling command request: %s and %+v\n", req.Account.Name, req.Commands)
-	if valid, err := s.accountant.VerifySecret(req.Account.Name, req.Account.Secret); err != nil {
+	if valid, err := s.world.Accountant.VerifySecret(req.Account.Name, req.Account.Secret); err != nil {
 		return nil, err
 	} else if !valid {
 		return nil, fmt.Errorf("Secret incorrect for account %s", req.Account.Name)
 	}
-	resp, err := s.accountant.GetValue(req.Account.Name, "rover")
+	resp, err := s.world.Accountant.GetValue(req.Account.Name, "rover")
 	if err != nil {
 		return nil, err
 	}
-	var cmds []game.Command
+	if err := s.world.Enqueue(resp, req.Commands...); err != nil {
 	for _, c := range req.Commands {
 		cmds = append(cmds, game.Command{
 			Bearing: c.Bearing,
 			Command: c.Command})
 	}
 	if err := s.world.Enqueue(resp, cmds...); err != nil {
 		return nil, err
 	}
-	return &rove.CommandResponse{}, nil
+	return &roveapi.CommandResponse{}, nil
 }
--- a/cmd/rove-server/internal/server.go
+++ b/cmd/rove-server/internal/server.go
@ -4,16 +4,21 @@ import (
 	"fmt"
 	"log"
 	"net"
 	"os"
 	"path"
 	"sync"
 	"github.com/mdiluz/rove/pkg/accounts"
 	"github.com/mdiluz/rove/pkg/game"
 	"github.com/mdiluz/rove/pkg/persistence"
 	"github.com/mdiluz/rove/pkg/rove"
 	"github.com/mdiluz/rove/proto/roveapi"
 	"github.com/robfig/cron"
 	"google.golang.org/grpc"
 	"google.golang.org/grpc/credentials"
 	"google.golang.org/grpc/reflection"
 )
 var cert = os.Getenv("CERT_NAME")
 const (
 	// PersistentData will allow the server to load and save it's state
 	PersistentData = iota
@ -26,10 +31,7 @@ const (
 type Server struct {
 	// Internal state
-	world *game.World
+	world *rove.World
 	// Accountant
 	accountant *accounts.Accountant
 	// gRPC server
 	netListener net.Listener
@ -80,8 +82,7 @@ func NewServer(opts ...ServerOption) *Server {
 		address:     "",
 		persistence: EphemeralData,
 		schedule:    cron.New(),
-		world:       game.NewWorld(32),
+		world:       rove.NewWorld(32),
 		accountant:  accounts.NewAccountant(),
 	}
 	// Apply all options
@ -108,8 +109,22 @@ func (s *Server) Initialise(fillWorld bool) (err error) {
 	if err != nil {
 		log.Fatalf("failed to listen: %v", err)
 	}
-	s.grpcServ = grpc.NewServer()
+
-	rove.RegisterRoveServer(s.grpcServ, s)
+	// Load TLS
 	var opts []grpc.ServerOption
 	if len(os.Getenv("NO_TLS")) == 0 {
 		pem := path.Join("/etc/letsencrypt/live/", cert, "fullchain.pem")
 		key := path.Join("/etc/letsencrypt/live/", cert, "privkey.pem")
 		creds, err := credentials.NewServerTLSFromFile(pem, key)
 		if err != nil {
 			log.Fatalf("failed to setup TLS: %v", err)
 		}
 		opts = append(opts, grpc.Creds(creds))
 	}
 	s.grpcServ = grpc.NewServer(opts...)
 	roveapi.RegisterRoveServer(s.grpcServ, s)
 	reflection.Register(s.grpcServ)
 	return nil
 }
@ -132,8 +147,8 @@ func (s *Server) Run() {
 			log.Println("Executing server tick")
-			// Run the command queues
+			// Tick the world
-			s.world.ExecuteCommandQueues()
+			s.world.Tick()
 			// Save out the new world state
 			if err := s.SaveWorld(); err != nil {
@ -210,22 +225,10 @@ func (s *Server) LoadWorld() error {
 // SpawnRoverForAccount spawns the rover rover for an account
 func (s *Server) SpawnRoverForAccount(account string) (string, error) {
-	inst, err := s.world.SpawnRover()
+	inst, err := s.world.SpawnRover(account)
 	if err != nil {
 		return "", err
 	}
 	err = s.accountant.AssignData(account, "rover", inst)
 	if err != nil {
 		log.Printf("Failed to assign rover to account, %s", err)
 		// Try and clear up the rover
 		if err := s.world.DestroyRover(inst); err != nil {
 			log.Printf("Failed to destroy rover after failed rover assign: %s", err)
 		}
 		return "", err
 	}
 	return inst, nil
 }
--- a/cmd/rove-server/internal/server_test.go
+++ b/cmd/rove-server/internal/server_test.go
@ -1,6 +1,7 @@
 package internal
 import (
 	"os"
 	"testing"
 )
@ -30,6 +31,7 @@ func TestNewServer_OptionPersistentData(t *testing.T) {
 }
 func TestServer_Run(t *testing.T) {
 	os.Setenv("NO_TLS", "1")
 	server := NewServer()
 	if server == nil {
 		t.Error("Failed to create server")
@ -45,6 +47,7 @@ func TestServer_Run(t *testing.T) {
 }
 func TestServer_RunPersistentData(t *testing.T) {
 	os.Setenv("NO_TLS", "1")
 	server := NewServer(OptionPersistentData())
 	if server == nil {
 		t.Error("Failed to create server")
--- a/cmd/rove-server/main.go
+++ b/cmd/rove-server/main.go
@ -52,7 +52,9 @@ func InnerMain() {
 	log.Printf("Initialising version %s...\n", version.Version)
 	// Set the persistence path
-	if err := persistence.SetPath(data); err != nil {
+	if len(data) == 0 {
 		log.Fatal("DATA_PATH not set")
 	} else if err := persistence.SetPath(data); err != nil {
 		log.Fatal(err)
 	}
--- a/cmd/rove/internal/glyph.go
+++ b/cmd/rove/internal/glyph.go
@ -0,0 +1,70 @@
 package internal
 import (
 	"log"
 	"github.com/mdiluz/rove/proto/roveapi"
 )
 // Glyph represents the text representation of something in the game
 type Glyph byte
 const (
 	// GlyphGroundRock is solid rock ground
 	GlyphGroundRock = Glyph('-')
 	// GlyphGroundGravel is loose rocks
 	GlyphGroundGravel = Glyph(':')
 	// GlyphGroundSand is sand
 	GlyphGroundSand = Glyph('~')
 	// GlyphRoverLive represents a live rover
 	GlyphRoverLive = Glyph('R')
 	// GlyphRoverDormant represents a dormant rover
 	GlyphRoverDormant = Glyph('r')
 	// GlyphRoverParts represents spare rover parts
 	GlyphRoverParts = Glyph('*')
 	// GlyphRockSmall is a small stashable rock
 	GlyphRockSmall = Glyph('o')
 	// GlyphRockLarge is a large blocking rock
 	GlyphRockLarge = Glyph('O')
 )
 // TileGlyph returns the glyph for this tile type
 func TileGlyph(t roveapi.Tile) Glyph {
 	switch t {
 	case roveapi.Tile_Rock:
 		return GlyphGroundRock
 	case roveapi.Tile_Gravel:
 		return GlyphGroundGravel
 	case roveapi.Tile_Sand:
 		return GlyphGroundSand
 	}
 	log.Fatalf("Unknown tile type: %c", t)
 	return 0
 }
 // ObjectGlyph returns the glyph for this object type
 func ObjectGlyph(o roveapi.Object) Glyph {
 	switch o {
 	case roveapi.Object_RoverLive:
 		return GlyphRoverLive
 	case roveapi.Object_RockSmall:
 		return GlyphRockSmall
 	case roveapi.Object_RoverDormant:
 		return GlyphRoverDormant
 	case roveapi.Object_RockLarge:
 		return GlyphRockLarge
 	case roveapi.Object_RoverParts:
 		return GlyphRoverParts
 	}
 	log.Fatalf("Unknown object type: %c", o)
 	return 0
 }
--- a/cmd/rove/main.go
+++ b/cmd/rove/main.go
@ -1,6 +1,7 @@
 package main
 import (
 	"crypto/tls"
 	"encoding/json"
 	"fmt"
 	"io/ioutil"
@ -8,16 +9,15 @@ import (
 	"os"
 	"path"
 	"path/filepath"
 	"strconv"
 	"time"
-	"github.com/mdiluz/rove/pkg/atlas"
+	"github.com/mdiluz/rove/cmd/rove/internal"
 	"github.com/mdiluz/rove/pkg/bearing"
 	"github.com/mdiluz/rove/pkg/game"
 	"github.com/mdiluz/rove/pkg/objects"
 	"github.com/mdiluz/rove/pkg/rove"
 	"github.com/mdiluz/rove/pkg/version"
 	"github.com/mdiluz/rove/proto/roveapi"
 	"golang.org/x/net/context"
 	"google.golang.org/grpc"
 	"google.golang.org/grpc/credentials"
 )
 var home = os.Getenv("HOME")
@ -25,37 +25,44 @@ var defaultDataPath = path.Join(home, ".local/share/")
 // Command usage
 func printUsage() {
-	fmt.Fprintf(os.Stderr, "Usage: rove COMMAND [ARGS...]\n")
+	fmt.Fprintln(os.Stderr, "Usage: rove ARG [OPT...]")
-	fmt.Fprintln(os.Stderr, "\nCommands")
+	fmt.Fprintf(os.Stderr, "\n")
-	fmt.Fprintln(os.Stderr, "\tserver-status              prints the server status")
+	fmt.Fprintln(os.Stderr, "Arguments:")
-	fmt.Fprintln(os.Stderr, "\tregister NAME              registers an account and stores it (use with -name)")
+	fmt.Fprintln(os.Stderr, "\tversion                       outputs version")
-	fmt.Fprintln(os.Stderr, "\tcommand COMMAND [VAL...]   issue commands to rover, accepts multiple, see below")
+	fmt.Fprintln(os.Stderr, "\thelp                          outputs this usage text")
-	fmt.Fprintln(os.Stderr, "\tradar                      gathers radar data for the current rover")
+	fmt.Fprintln(os.Stderr, "\tconfig [HOST]                 outputs the local config, optionally sets host")
-	fmt.Fprintln(os.Stderr, "\tstatus                     gets status info for current rover")
+	fmt.Fprintln(os.Stderr, "\tserver-status                 prints the server status")
-	fmt.Fprintln(os.Stderr, "\tconfig [HOST]              outputs the local config info, optionally sets host")
+	fmt.Fprintln(os.Stderr, "\tregister NAME                 registers an account and spawns a rover")
-	fmt.Fprintln(os.Stderr, "\thelp                       outputs this usage information")
+	fmt.Fprintln(os.Stderr, "\tradar                         prints radar data in ASCII form")
-	fmt.Fprintln(os.Stderr, "\tversion                    outputs version info")
+	fmt.Fprintln(os.Stderr, "\tstatus                        gets rover status")
-	fmt.Fprintln(os.Stderr, "\nRover commands:")
+	fmt.Fprintln(os.Stderr, "\tcommand CMD [VAL...] [REPEAT] sets the command queue, accepts multiple in sequence")
-	fmt.Fprintln(os.Stderr, "\tmove BEARING               moves the rover in the chosen direction")
+	fmt.Fprintf(os.Stderr, "\n")
-	fmt.Fprintln(os.Stderr, "\tstash                      stores the object at the rover location in the inventory")
+	fmt.Fprintln(os.Stderr, "Rover commands:")
-	fmt.Fprintln(os.Stderr, "\trepair                     uses an inventory object to repair the rover")
+	fmt.Fprintln(os.Stderr, "\ttoggle         toggles the current sail mode")
-	fmt.Fprintln(os.Stderr, "\trecharge                   wait a tick to recharge the rover")
+	fmt.Fprintln(os.Stderr, "\tstash          stores the object at the rover location in the inventory")
-	fmt.Fprintln(os.Stderr, "\nEnvironment")
+	fmt.Fprintln(os.Stderr, "\trepair         repairs the rover using inventory item")
-	fmt.Fprintln(os.Stderr, "\tROVE_USER_DATA             path to user data, defaults to "+defaultDataPath)
+	fmt.Fprintln(os.Stderr, "\tbroadcast MSG  broadcast a simple ASCII triplet to nearby rovers")
 	fmt.Fprintln(os.Stderr, "\tsalvage        salvages a dormant rover for parts")
 	fmt.Fprintln(os.Stderr, "\ttransfer       transfer's control into a dormant rover")
 	fmt.Fprintln(os.Stderr, "\tupgrade SPEC   spends rover parts to upgrade one rover spec (capacity, range, integrity, charge")
 	fmt.Fprintln(os.Stderr, "\twait           waits before performing the next command")
 	fmt.Fprintf(os.Stderr, "\n")
 	fmt.Fprintln(os.Stderr, "Environment")
 	fmt.Fprintln(os.Stderr, "\tROVE_USER_DATA        path to user data, defaults to "+defaultDataPath)
 }
 const gRPCport = 9090
 // Account stores data for an account
 type Account struct {
-	Name   string `json:"name"`
+	Name   string
-	Secret string `json:"secret"`
+	Secret string
 }
 // Config is used to store internal data
 type Config struct {
-	Host    string  `json:"host,omitempty"`
+	Host    string
-	Account Account `json:"account,omitempty"`
+	Account Account
 }
 // ConfigPath returns the configuration path
@ -66,7 +73,7 @@ func ConfigPath() string {
 	if len(override) > 0 {
 		datapath = override
 	}
-	datapath = path.Join(datapath, "rove.json")
+	datapath = path.Join(datapath, "roveapi.json")
 	return datapath
 }
@ -125,6 +132,29 @@ func checkAccount(a Account) error {
 	return nil
 }
 // BearingFromString converts a string to a bearing
 func BearingFromString(s string) roveapi.Bearing {
 	switch s {
 	case "N":
 		return roveapi.Bearing_North
 	case "NE":
 		return roveapi.Bearing_NorthEast
 	case "E":
 		return roveapi.Bearing_East
 	case "SE":
 		return roveapi.Bearing_SouthEast
 	case "S":
 		return roveapi.Bearing_South
 	case "SW":
 		return roveapi.Bearing_SouthWest
 	case "W":
 		return roveapi.Bearing_West
 	case "NW":
 		return roveapi.Bearing_NorthWest
 	}
 	return roveapi.Bearing_BearingUnknown
 }
 // InnerMain wraps the main function so we can test it
 func InnerMain(command string, args ...string) error {
@ -158,19 +188,26 @@ func InnerMain(command string, args ...string) error {
 		return fmt.Errorf("no host set in %s, set one with '%s config {HOST}'", ConfigPath(), os.Args[0])
 	}
 	var opts []grpc.DialOption
 	if len(os.Getenv("NO_TLS")) == 0 {
 		opts = append(opts, grpc.WithTransportCredentials(credentials.NewTLS(&tls.Config{})))
 	} else {
 		opts = append(opts, grpc.WithInsecure())
 	}
 	// Set up the server
-	clientConn, err := grpc.Dial(fmt.Sprintf("%s:%d", config.Host, gRPCport), grpc.WithInsecure())
+	clientConn, err := grpc.Dial(fmt.Sprintf("%s:%d", config.Host, gRPCport), opts...)
 	if err != nil {
 		return err
 	}
-	var client = rove.NewRoveClient(clientConn)
+	var client = roveapi.NewRoveClient(clientConn)
 	ctx, cancel := context.WithTimeout(context.Background(), 5*time.Second)
 	defer cancel()
 	// Handle all the commands
 	switch command {
 	case "server-status":
-		response, err := client.ServerStatus(ctx, &rove.ServerStatusRequest{})
+		response, err := client.ServerStatus(ctx, &roveapi.ServerStatusRequest{})
 		switch {
 		case err != nil:
 			return err
@ -188,7 +225,7 @@ func InnerMain(command string, args ...string) error {
 			return fmt.Errorf("must pass name to 'register'")
 		}
-		resp, err := client.Register(ctx, &rove.RegisterRequest{
+		resp, err := client.Register(ctx, &roveapi.RegisterRequest{
 			Name: args[0],
 		})
 		switch {
@ -209,34 +246,80 @@ func InnerMain(command string, args ...string) error {
 		}
 		// Iterate through each command
-		var commands []*rove.Command
+		var commands []*roveapi.Command
 		for i := 0; i < len(args); i++ {
 			var cmd *roveapi.Command
 			switch args[i] {
-			case "move":
+			case "turn":
 				i++
 				if len(args) == i {
-					return fmt.Errorf("move command must be passed bearing")
+					return fmt.Errorf("turn command must be passed a compass bearing")
-				} else if _, err := bearing.FromString(args[i]); err != nil {
+				}
-					return err
+				b := BearingFromString(args[i])
 				if b == roveapi.Bearing_BearingUnknown {
 					return fmt.Errorf("turn command must be given a valid bearing %s", args[i])
 				}
 				cmd = &roveapi.Command{
 					Command: roveapi.CommandType_turn,
 					Bearing: b,
 				}
 			case "broadcast":
 				i++
 				if len(args) == i {
 					return fmt.Errorf("broadcast command must be passed an ASCII triplet")
 				} else if len(args[i]) > 3 {
 					return fmt.Errorf("broadcast command must be given ASCII triplet of 3 or less: %s", args[i])
 				}
 				cmd = &roveapi.Command{
 					Command: roveapi.CommandType_broadcast,
 					Data:    []byte(args[i]),
 				}
 			case "upgrade":
 				i++
 				if len(args) == i {
 					return fmt.Errorf("upgrade command must be passed a spec to upgrade")
 				}
 				var u roveapi.RoverUpgrade
 				switch args[i] {
 				case "capacity":
 					u = roveapi.RoverUpgrade_Capacity
 				case "range":
 					u = roveapi.RoverUpgrade_Range
 				case "integrity":
 					u = roveapi.RoverUpgrade_MaximumIntegrity
 				case "charge":
 					u = roveapi.RoverUpgrade_MaximumCharge
 				default:
 					return fmt.Errorf("upgrade command must be passed a known upgrade spec")
 				}
 				cmd = &roveapi.Command{
 					Command: roveapi.CommandType_upgrade,
 					Upgrade: u,
 				}
 				commands = append(commands,
 					&rove.Command{
 						Command: game.CommandMove,
 						Bearing: args[i],
 					},
 				)
 			default:
 				// By default just use the command literally
-				commands = append(commands,
+				cmd = &roveapi.Command{
-					&rove.Command{
+					Command: roveapi.CommandType(roveapi.CommandType_value[args[i]]),
-						Command: args[i],
+				}
 					},
 				)
 			}
 			// Try and convert the next command to a number
 			number := 0
 			if len(args) > i+1 {
 				num, err := strconv.Atoi(args[i+1])
 				if err == nil {
 					number = num
 					i++
 				}
 			}
 			cmd.Repeat = int32(number)
 			commands = append(commands, cmd)
 		}
-		_, err := client.Command(ctx, &rove.CommandRequest{
+		_, err := client.Command(ctx, &roveapi.CommandRequest{
-			Account: &rove.Account{
+			Account: &roveapi.Account{
 				Name:   config.Account.Name,
 				Secret: config.Account.Secret,
 			},
@ -256,8 +339,8 @@ func InnerMain(command string, args ...string) error {
 			return err
 		}
-		response, err := client.Radar(ctx, &rove.RadarRequest{
+		response, err := client.Radar(ctx, &roveapi.RadarRequest{
-			Account: &rove.Account{
+			Account: &roveapi.Account{
 				Name:   config.Account.Name,
 				Secret: config.Account.Secret,
 			},
@ -275,12 +358,10 @@ func InnerMain(command string, args ...string) error {
 				for i := 0; i < num; i++ {
 					t := response.Tiles[i+num*j]
 					o := response.Objects[i+num*j]
-					if o != byte(objects.None) {
+					if o != roveapi.Object_ObjectUnknown {
-						fmt.Printf("%c", o)
+						fmt.Printf("%c", internal.ObjectGlyph(o))
 					} else if t != byte(atlas.TileNone) {
 						fmt.Printf("%c", t)
 					} else {
-						fmt.Printf(" ")
+						fmt.Printf("%c", internal.TileGlyph(t))
 					}
 				}
@ -293,8 +374,8 @@ func InnerMain(command string, args ...string) error {
 			return err
 		}
-		response, err := client.Status(ctx, &rove.StatusRequest{
+		response, err := client.Status(ctx, &roveapi.StatusRequest{
-			Account: &rove.Account{
+			Account: &roveapi.Account{
 				Name:   config.Account.Name,
 				Secret: config.Account.Secret,
 			},
@ -322,6 +403,15 @@ func InnerMain(command string, args ...string) error {
 func main() {
 	// Bail without any args
 	if len(os.Args) == 1 {
 		fmt.Fprintf(os.Stderr, "\n")
 		fmt.Fprintln(os.Stderr, "m mm   mmm   m   m   mmm")
 		fmt.Fprintln(os.Stderr, "#\"  \" #\" \"#  \"m m\"  #\"  #")
 		fmt.Fprintln(os.Stderr, "#     #   #   #m#   #\"\"\"\"")
 		fmt.Fprintln(os.Stderr, "#     \"#m#\"    #    \"#mm\"")
 		fmt.Fprintf(os.Stderr, "\n")
 		fmt.Fprintln(os.Stderr, "Rove is an asychronous nomadic game about exploring a planet as part of a loose community.")
 		fmt.Fprintln(os.Stderr, "Visit https://mdiluz.github.io/rove/ for more information.")
 		fmt.Fprintf(os.Stderr, "\n")
 		printUsage()
 		os.Exit(1)
 	}
--- a/cmd/rove/main_test.go
+++ b/cmd/rove/main_test.go
@ -13,6 +13,7 @@ import (
 )
 func Test_InnerMain(t *testing.T) {
 	os.Setenv("NO_TLS", "1")
 	// Use temporary local user data
 	tmp, err := ioutil.TempDir(os.TempDir(), "rove-")
@ -50,10 +51,17 @@ func Test_InnerMain(t *testing.T) {
 	assert.Error(t, InnerMain("command"))
 	// Give it commands
-	assert.NoError(t, InnerMain("command", "move", "N"))
+	assert.NoError(t, InnerMain("command", "toggle"))
 	assert.NoError(t, InnerMain("command", "stash"))
 	assert.NoError(t, InnerMain("command", "repair"))
 	assert.NoError(t, InnerMain("command", "upgrade", "capacity"))
 	assert.NoError(t, InnerMain("command", "broadcast", "abc"))
 	assert.NoError(t, InnerMain("command", "wait", "10"))
 	assert.NoError(t, InnerMain("command", "wait", "1", "turn", "NW", "toggle", "broadcast", "zyx"))
 	// Give it malformed commands
-	assert.Error(t, InnerMain("command", "move", "stash"))
+	assert.Error(t, InnerMain("command", "unknown"))
 	assert.Error(t, InnerMain("command", "broadcast"))
 	assert.Error(t, InnerMain("command", "upgrade"))
 	assert.Error(t, InnerMain("command", "1"))
 }
--- a/flatpak/io.github.mdiluz.Rove.json
+++ b/flatpak/io.github.mdiluz.Rove.json
--- a/docker-compose-test.yml
+++ b/docker-compose-test.yml
@ -0,0 +1,32 @@
 version: '3'
 services:
  rove-test-server:
    build:
      context: .
      dockerfile: Dockerfile
    image: rove:latest
    ports:
      - "9090:9090"
    environment:
      - PORT=9090
      - DATA_PATH=/tmp/
      - WORDS_FILE=data/words_alpha.txt
      - TICK_RATE=10
      - NO_TLS=1
    command: [ "./rove-server"]
  rove-tests:
    depends_on: [ rove-test-server ]
    build:
      context: .
      dockerfile: Dockerfile
    image: rove:latest
    environment:
      - ROVE_GRPC=rove-test-server
    command: [ "./script/wait-for-it.sh", "rove-test-server:9090", "--", "go", "test", "-v", "./...", "--tags=integration", "-cover", "-coverprofile=/mnt/coverage-data/c.out", "-count", "1" ]
    volumes:
      - /tmp/coverage-data:/mnt/coverage-data:rw
--- a/docker-compose.yml
+++ b/docker-compose.yml
@ -4,16 +4,6 @@ volumes:
  persistent-data:
 services:
  rove-docs:
    build:
      context: .
      dockerfile: Dockerfile.docs
    image: rove-docs:latest
    ports:
      - "80:80"
    environment: 
      - PORT=80
  rove-server:
    build:
      context: .
@ -25,36 +15,11 @@ services:
      - PORT=9090
      - DATA_PATH=/mnt/rove-server
      - WORDS_FILE=data/words_alpha.txt
-      - TICK_RATE=5
+      - TICK_RATE=3
      - CERT_NAME=${CERT_NAME}
    volumes:
      - persistent-data:/mnt/rove-server:rw
      - /etc/letsencrypt/:/etc/letsencrypt/
    command: [ "./rove-server"]
  rove:
    depends_on: [ rove-server, rove-docs ]
    build:
      context: .
      dockerfile: Dockerfile
    image: rove:latest
    ports:
      - "8080:8080"
    environment:
      - PORT=8080
      - ROVE_GRPC=rove-server:9090
    command: [ "./script/wait-for-it.sh", "rove-server:9090", "--", "./rove-server-rest-proxy" ]
  rove-tests:
    depends_on: [ rove ]
    build:
      context: .
      dockerfile: Dockerfile
    image: rove:latest
    environment:
      - ROVE_HTTP=rove
      - ROVE_GRPC=rove-server
    command: [ "./script/wait-for-it.sh", "rove:8080", "--", "go", "test", "-v", "./...", "--tags=integration", "-cover", "-coverprofile=/mnt/coverage-data/c.out", "-count", "1" ]
    volumes:
      - /tmp/coverage-data:/mnt/coverage-data:rw
--- a/docs/README.md
+++ b/docs/README.md
@ -1,67 +1,61 @@
 Rove
 =====
-An asynchronous nomadic game about exploring a planet as part of a loose community.
+Rove is an asynchronous nomadic game about exploring a planet as part of a loose community.
 -------------------------------------------
-## The Basics
+## Core gameplay
-### Core
+Remotely explore the surface of a planet with an upgradable and customisable rover. Send commands to be executed asynchronously, view the rover's radar, and communicate and coordinate with other nearby rovers.
-Control a rover on the surface of the planet using a remote control interface.
+### Key Components
-Commands are sent and happen asynchronously, and the rover feeds back information about position and surroundings, as well as photos.
+* Navigate an expansive world
-
+* Collect resources to repair and upgrade
-### General
+* Keep the rover batteries charged as you explore
-
+* Help other players on their journey
-Movement is slow and sometimes dangerous.
+* Explore north to discover more
 Resources can be collected, and rovers recharge power during the day.
 Hazards damage the rover. Resources can be spent to repair.
 Spend resources to create and spawn a new improved rover a significant distance away, leaving the current one dormant.
 "Dying" leaves the current rover dormant and assigns the users a new rover.
 Players can repair dormant rovers to gain control of them, taking on their improvements and inventory.
 ### Multiplayer
 Players can see each other and use very rudimentary signals.
 Dormant rovers store full history of travel and owners, as well as their improvements and resources.
 -------------------------------------------
-### Implementation
+## Installing
-* A server that receives the commands, sends out data, and handles interactions between players.
+On Ubuntu:
 ```
 $ snap install rove
 ```
-* An app, or apps, that interface with the server to let you control and view rover information
+Elsewhere (with [go](https://golang.org/doc/install) installed)
 ```
 go get github.com/mdiluz/rove
 cd $GOPATH/src/github.com/mdiluz/rove/
 make install
 ```
 -------------------------------------------
-### To Solve
+### Implementation Details
 `rove-server` hosts the game world and a gRPC server to allow users to interact from any client.
 `rove` is a basic example command-line client that allows for simple play, to explore it's usage, see the output of `rove help`
 -------------------------------------------
 ### "Find the fun" issues to solve
 * What kinds of progression/upgrades exist?
 * How does the game encourage cooperation?
 * How would the gameplay prevent griefing?
 * What drives the exploration?
 -------------------------------------------
 ### Key ideas left to integrate
-Feeling “known for” something -  the person who did X thing. Limit number of  X things that can be done, possibly over time.
+* Feeling “known for” something -  the person who did X thing. Limit number of  X things that can be done, possibly over time.
-
+* A significant aspect of failure - failing must be a focus of the game. Winning the game might actually be failing in some specific way.
-A significant aspect of failure - failing must be a focus of the game. Winning the game might actually be failing in some specific way.
+* A clear and well  defined investment vs. payoff curve.
-
+* Not an infinite game, let the game have a point where you’re done and can move on.
 A clear and well  defined investment vs. payoff curve.
 Not an infinite game, let the game have a point where you’re done and can move on.
--- a/go.mod
+++ b/go.mod
@ -8,12 +8,12 @@ require (
 	github.com/google/uuid v1.1.1
 	github.com/grpc-ecosystem/grpc-gateway v1.14.6
 	github.com/kr/pretty v0.1.0 // indirect
 	github.com/ojrac/opensimplex-go v1.0.1
 	github.com/robfig/cron v1.2.0
 	github.com/stretchr/testify v1.6.0
 	golang.org/x/net v0.0.0-20200602114024-627f9648deb9
 	golang.org/x/sys v0.0.0-20200602225109-6fdc65e7d980 // indirect
 	golang.org/x/text v0.3.3 // indirect
 	google.golang.org/genproto v0.0.0-20200526211855-cb27e3aa2013
 	google.golang.org/grpc v1.30.0
 	google.golang.org/protobuf v1.25.0
 	gopkg.in/check.v1 v1.0.0-20190902080502-41f04d3bba15 // indirect
--- a/go.sum
+++ b/go.sum
@ -50,6 +50,8 @@ github.com/kr/pretty v0.1.0/go.mod h1:dAy3ld7l9f0ibDNOQOHHMYYIIbhfbHSm3C4ZsoJORN
 github.com/kr/pty v1.1.1/go.mod h1:pFQYn66WHrOpPYNljwOMqo10TkYh1fy3cYio2l3bCsQ=
 github.com/kr/text v0.1.0 h1:45sCR5RtlFHMR4UwH9sdQ5TC8v0qDQCHnXt+kaKSTVE=
 github.com/kr/text v0.1.0/go.mod h1:4Jbv+DJW3UT/LiOwJeYQe1efqtUx/iVham/4vfdArNI=
 github.com/ojrac/opensimplex-go v1.0.1 h1:XslvpLP6XqQSATUtsOnGBYtFPw7FQ6h6y0ihjVeOLHo=
 github.com/ojrac/opensimplex-go v1.0.1/go.mod h1:MoSgj04tZpH8U0RefZabnHV2AbLgv/2mo3hLJtWqSEs=
 github.com/pmezard/go-difflib v1.0.0 h1:4DBwDE0NGyQoBHbLQYPwSUPoCMWR5BEzIk/f1lZbAQM=
 github.com/pmezard/go-difflib v1.0.0/go.mod h1:iKH77koFhYxTK1pcRnkKkqfTogsbg7gZNVY4sRDYZ/4=
 github.com/prometheus/client_model v0.0.0-20190812154241-14fe0d1b01d4/go.mod h1:xMI15A0UPsDsEKsMN9yxemIoYk6Tm2C1GtYGdfGttqA=
--- a/pkg/accounts/accounts.go
+++ b/pkg/accounts/accounts.go
@ -1,89 +1,28 @@
 package accounts
-import (
+// Accountant decribes something that stores accounts and account values
-	"fmt"
+type Accountant interface {
-	"time"
+	// RegisterAccount will register a new account and return it's info
 	RegisterAccount(name string) (acc Account, err error)
-	"github.com/google/uuid"
+	// AssignData stores a custom account key value pair
-)
+	AssignData(account string, key string, value string) error
 	// GetValue returns custom account data for a specific key
 	GetValue(account string, key string) (string, error)
 	// VerifySecret will verify whether the account secret matches with the
 	VerifySecret(account string, secret string) (bool, error)
 	// GetSecret gets the secret associated with an account
 	GetSecret(account string) (string, error)
 }
 // Account represents a registered user
 type Account struct {
 	// Name simply describes the account and must be unique
-	Name string `json:"name"`
+	Name string
 	// Data represents internal account data
-	Data map[string]string `json:"data"`
+	Data map[string]string
 }
 // Accountant manages a set of accounts
 type Accountant struct {
 	Accounts map[string]Account `json:"accounts"`
 }
 // NewAccountant creates a new accountant
 func NewAccountant() *Accountant {
 	return &Accountant{
 		Accounts: make(map[string]Account),
 	}
 }
 // RegisterAccount adds an account to the set of internal accounts
 func (a *Accountant) RegisterAccount(name string) (acc Account, err error) {
 	// Set up the account info
 	acc.Name = name
 	acc.Data = make(map[string]string)
 	// Verify this acount isn't already registered
 	for _, a := range a.Accounts {
 		if a.Name == acc.Name {
 			return Account{}, fmt.Errorf("account name already registered: %s", a.Name)
 		}
 	}
 	// Set the creation time
 	acc.Data["created"] = time.Now().String()
 	// Create a secret
 	acc.Data["secret"] = uuid.New().String()
 	// Simply add the account to the map
 	a.Accounts[acc.Name] = acc
 	return
 }
 // VerifySecret verifies if an account secret is correct
 func (a *Accountant) VerifySecret(account string, secret string) (bool, error) {
 	// Find the account matching the ID
 	if this, ok := a.Accounts[account]; ok {
 		return this.Data["secret"] == secret, nil
 	}
 	return false, fmt.Errorf("no account found for id: %s", account)
 }
 // AssignData assigns data to an account
 func (a *Accountant) AssignData(account string, key string, value string) error {
 	// Find the account matching the ID
 	if this, ok := a.Accounts[account]; ok {
 		this.Data[key] = value
 		a.Accounts[account] = this
 	} else {
 		return fmt.Errorf("no account found for id: %s", account)
 	}
 	return nil
 }
 // GetValue gets the rover rover for the account
 func (a *Accountant) GetValue(account string, key string) (string, error) {
 	// Find the account matching the ID
 	this, ok := a.Accounts[account]
 	if !ok {
 		return "", fmt.Errorf("no account found for id: %s", account)
 	}
 	return this.Data[key], nil
 }
--- a/pkg/accounts/accounts_test.go
+++ b/pkg/accounts/accounts_test.go
@ -8,7 +8,7 @@ import (
 func TestNewAccountant(t *testing.T) {
 	// Very basic verify here for now
-	accountant := NewAccountant()
+	accountant := NewSimpleAccountant()
 	if accountant == nil {
 		t.Error("Failed to create accountant")
 	}
@ -16,7 +16,7 @@ func TestNewAccountant(t *testing.T) {
 func TestAccountant_RegisterAccount(t *testing.T) {
-	accountant := NewAccountant()
+	accountant := NewSimpleAccountant()
 	// Start by making two accounts
@ -44,10 +44,7 @@ func TestAccountant_RegisterAccount(t *testing.T) {
 }
 func TestAccountant_AssignGetData(t *testing.T) {
-	accountant := NewAccountant()
+	accountant := NewSimpleAccountant()
 	if len(accountant.Accounts) != 0 {
 		t.Error("New accountant created with non-zero account number")
 	}
 	name := uuid.New().String()
 	a, err := accountant.RegisterAccount(name)
--- a/pkg/accounts/simpleAccountant.go
+++ b/pkg/accounts/simpleAccountant.go
@ -0,0 +1,90 @@
 package accounts
 import (
 	"fmt"
 	"time"
 	"github.com/google/uuid"
 )
 // SimpleAccountant manages a set of accounts
 type SimpleAccountant struct {
 	Accounts map[string]Account
 }
 // NewSimpleAccountant creates a new accountant
 func NewSimpleAccountant() Accountant {
 	return &SimpleAccountant{
 		Accounts: make(map[string]Account),
 	}
 }
 // RegisterAccount adds an account to the set of internal accounts
 func (a *SimpleAccountant) RegisterAccount(name string) (acc Account, err error) {
 	// Set up the account info
 	acc.Name = name
 	acc.Data = make(map[string]string)
 	// Verify this acount isn't already registered
 	for _, a := range a.Accounts {
 		if a.Name == acc.Name {
 			return Account{}, fmt.Errorf("account name already registered: %s", a.Name)
 		}
 	}
 	// Set the creation time
 	acc.Data["created"] = time.Now().String()
 	// Create a secret
 	acc.Data["secret"] = uuid.New().String()
 	// Simply add the account to the map
 	a.Accounts[acc.Name] = acc
 	return
 }
 // VerifySecret verifies if an account secret is correct
 func (a *SimpleAccountant) VerifySecret(account string, secret string) (bool, error) {
 	// Find the account matching the ID
 	if this, ok := a.Accounts[account]; ok {
 		return this.Data["secret"] == secret, nil
 	}
 	return false, fmt.Errorf("no account found for id: %s", account)
 }
 // GetSecret gets the internal secret
 func (a *SimpleAccountant) GetSecret(account string) (string, error) {
 	// Find the account matching the ID
 	if this, ok := a.Accounts[account]; ok {
 		return this.Data["secret"], nil
 	}
 	return "", fmt.Errorf("no account found for id: %s", account)
 }
 // AssignData assigns data to an account
 func (a *SimpleAccountant) AssignData(account string, key string, value string) error {
 	// Find the account matching the ID
 	if this, ok := a.Accounts[account]; ok {
 		this.Data[key] = value
 		a.Accounts[account] = this
 	} else {
 		return fmt.Errorf("no account found for id: %s", account)
 	}
 	return nil
 }
 // GetValue gets the rover rover for the account
 func (a *SimpleAccountant) GetValue(account string, key string) (string, error) {
 	// Find the account matching the ID
 	this, ok := a.Accounts[account]
 	if !ok {
 		return "", fmt.Errorf("no account found for id: %s", account)
 	}
 	return this.Data[key], nil
 }
--- a/pkg/atlas/atlas_test.go
+++ b/pkg/atlas/atlas_test.go
@ -1,250 +0,0 @@
 package atlas
 import (
 	"testing"
 	"github.com/mdiluz/rove/pkg/objects"
 	"github.com/mdiluz/rove/pkg/vector"
 	"github.com/stretchr/testify/assert"
 )
 func TestAtlas_NewAtlas(t *testing.T) {
 	a := NewAtlas(1)
 	assert.NotNil(t, a)
 	assert.Equal(t, 1, a.ChunkSize)
 	assert.Equal(t, 1, len(a.Chunks)) // Should start empty
 }
 func TestAtlas_toChunk(t *testing.T) {
 	a := NewAtlas(1)
 	assert.NotNil(t, a)
 	// Get a tile to spawn the chunks
 	a.QueryPosition(vector.Vector{X: -1, Y: -1})
 	a.QueryPosition(vector.Vector{X: 0, Y: 0})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	// Chunks should look like:
 	//  2 | 3
 	//  -----
 	//  0 | 1
 	chunkID := a.worldSpaceToChunkIndex(vector.Vector{X: 0, Y: 0})
 	assert.Equal(t, 3, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(vector.Vector{X: 0, Y: -1})
 	assert.Equal(t, 1, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(vector.Vector{X: -1, Y: -1})
 	assert.Equal(t, 0, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(vector.Vector{X: -1, Y: 0})
 	assert.Equal(t, 2, chunkID)
 	a = NewAtlas(2)
 	assert.NotNil(t, a)
 	// Get a tile to spawn the chunks
 	a.QueryPosition(vector.Vector{X: -2, Y: -2})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	a.QueryPosition(vector.Vector{X: 1, Y: 1})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	// Chunks should look like:
 	// 2 | 3
 	// -----
 	// 0 | 1
 	chunkID = a.worldSpaceToChunkIndex(vector.Vector{X: 1, Y: 1})
 	assert.Equal(t, 3, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(vector.Vector{X: 1, Y: -2})
 	assert.Equal(t, 1, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(vector.Vector{X: -2, Y: -2})
 	assert.Equal(t, 0, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(vector.Vector{X: -2, Y: 1})
 	assert.Equal(t, 2, chunkID)
 	a = NewAtlas(2)
 	assert.NotNil(t, a)
 	// Get a tile to spawn a 4x4 grid of chunks
 	a.QueryPosition(vector.Vector{X: 3, Y: 3})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	a.QueryPosition(vector.Vector{X: -3, Y: -3})
 	assert.Equal(t, 4*4, len(a.Chunks))
 	// Chunks should look like:
 	//  12| 13|| 14| 15
 	// ----------------
 	//  8 | 9 || 10| 11
 	// ================
 	//  4 | 5 || 6 | 7
 	// ----------------
 	//  0 | 1 || 2 | 3
 	chunkID = a.worldSpaceToChunkIndex(vector.Vector{X: 1, Y: 3})
 	assert.Equal(t, 14, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(vector.Vector{X: 1, Y: -3})
 	assert.Equal(t, 2, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(vector.Vector{X: -1, Y: -1})
 	assert.Equal(t, 5, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(vector.Vector{X: -2, Y: 2})
 	assert.Equal(t, 13, chunkID)
 	a = NewAtlas(3)
 	assert.NotNil(t, a)
 	// Get a tile to spawn a 4x4 grid of chunks
 	a.QueryPosition(vector.Vector{X: 3, Y: 3})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	// Chunks should look like:
 	// || 2| 3
 	// -------
 	// || 0| 1
 	// =======
 	chunkID = a.worldSpaceToChunkIndex(vector.Vector{X: 1, Y: 1})
 	assert.Equal(t, 0, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(vector.Vector{X: 3, Y: 1})
 	assert.Equal(t, 1, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(vector.Vector{X: 1, Y: 4})
 	assert.Equal(t, 2, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(vector.Vector{X: 5, Y: 5})
 	assert.Equal(t, 3, chunkID)
 }
 func TestAtlas_toWorld(t *testing.T) {
 	a := NewAtlas(1)
 	assert.NotNil(t, a)
 	// Get a tile to spawn some chunks
 	a.QueryPosition(vector.Vector{X: -1, Y: -1})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	// Chunks should look like:
 	//  2 | 3
 	//  -----
 	//  0 | 1
 	assert.Equal(t, vector.Vector{X: -1, Y: -1}, a.chunkOriginInWorldSpace(0))
 	assert.Equal(t, vector.Vector{X: 0, Y: -1}, a.chunkOriginInWorldSpace(1))
 	a = NewAtlas(2)
 	assert.NotNil(t, a)
 	// Get a tile to spawn the chunks
 	a.QueryPosition(vector.Vector{X: -2, Y: -2})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	a.QueryPosition(vector.Vector{X: 1, Y: 1})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	// Chunks should look like:
 	// 2 | 3
 	// -----
 	// 0 | 1
 	assert.Equal(t, vector.Vector{X: -2, Y: -2}, a.chunkOriginInWorldSpace(0))
 	assert.Equal(t, vector.Vector{X: -2, Y: 0}, a.chunkOriginInWorldSpace(2))
 	a = NewAtlas(2)
 	assert.NotNil(t, a)
 	// Get a tile to spawn a 4x4 grid of chunks
 	a.QueryPosition(vector.Vector{X: 3, Y: 3})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	a.QueryPosition(vector.Vector{X: -3, Y: -3})
 	assert.Equal(t, 4*4, len(a.Chunks))
 	// Chunks should look like:
 	//  12| 13|| 14| 15
 	// ----------------
 	//  8 | 9 || 10| 11
 	// ================
 	//  4 | 5 || 6 | 7
 	// ----------------
 	//  0 | 1 || 2 | 3
 	assert.Equal(t, vector.Vector{X: -4, Y: -4}, a.chunkOriginInWorldSpace(0))
 	assert.Equal(t, vector.Vector{X: 2, Y: -2}, a.chunkOriginInWorldSpace(7))
 	a = NewAtlas(3)
 	assert.NotNil(t, a)
 	// Get a tile to spawn a 4x4 grid of chunks
 	a.QueryPosition(vector.Vector{X: 3, Y: 3})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	// Chunks should look like:
 	// || 2| 3
 	// -------
 	// || 0| 1
 	// =======
 	assert.Equal(t, vector.Vector{X: 0, Y: 0}, a.chunkOriginInWorldSpace(0))
 }
 func TestAtlas_GetSetTile(t *testing.T) {
 	a := NewAtlas(10)
 	assert.NotNil(t, a)
 	// Set the origin tile to 1 and test it
 	a.SetTile(vector.Vector{X: 0, Y: 0}, 1)
 	tile, _ := a.QueryPosition(vector.Vector{X: 0, Y: 0})
 	assert.Equal(t, byte(1), tile)
 	// Set another tile to 1 and test it
 	a.SetTile(vector.Vector{X: 5, Y: -2}, 2)
 	tile, _ = a.QueryPosition(vector.Vector{X: 5, Y: -2})
 	assert.Equal(t, byte(2), tile)
 }
 func TestAtlas_GetSetObject(t *testing.T) {
 	a := NewAtlas(10)
 	assert.NotNil(t, a)
 	// Set the origin tile to 1 and test it
 	a.SetObject(vector.Vector{X: 0, Y: 0}, objects.Object{Type: objects.LargeRock})
 	_, obj := a.QueryPosition(vector.Vector{X: 0, Y: 0})
 	assert.Equal(t, objects.Object{Type: objects.LargeRock}, obj)
 	// Set another tile to 1 and test it
 	a.SetObject(vector.Vector{X: 5, Y: -2}, objects.Object{Type: objects.SmallRock})
 	_, obj = a.QueryPosition(vector.Vector{X: 5, Y: -2})
 	assert.Equal(t, objects.Object{Type: objects.SmallRock}, obj)
 }
 func TestAtlas_Grown(t *testing.T) {
 	// Start with a small example
 	a := NewAtlas(2)
 	assert.NotNil(t, a)
 	assert.Equal(t, 1, len(a.Chunks))
 	// Set a few tiles to values
 	a.SetTile(vector.Vector{X: 0, Y: 0}, 1)
 	a.SetTile(vector.Vector{X: -1, Y: -1}, 2)
 	a.SetTile(vector.Vector{X: 1, Y: -2}, 3)
 	// Check tile values
 	tile, _ := a.QueryPosition(vector.Vector{X: 0, Y: 0})
 	assert.Equal(t, byte(1), tile)
 	tile, _ = a.QueryPosition(vector.Vector{X: -1, Y: -1})
 	assert.Equal(t, byte(2), tile)
 	tile, _ = a.QueryPosition(vector.Vector{X: 1, Y: -2})
 	assert.Equal(t, byte(3), tile)
 	tile, _ = a.QueryPosition(vector.Vector{X: 0, Y: 0})
 	assert.Equal(t, byte(1), tile)
 	tile, _ = a.QueryPosition(vector.Vector{X: -1, Y: -1})
 	assert.Equal(t, byte(2), tile)
 	tile, _ = a.QueryPosition(vector.Vector{X: 1, Y: -2})
 	assert.Equal(t, byte(3), tile)
 }
 func TestAtlas_GetSetCorrect(t *testing.T) {
 	// Big stress test to ensure we do actually properly expand for all reasonable values
 	for i := 1; i <= 4; i++ {
 		for x := -i * 2; x < i*2; x++ {
 			for y := -i * 2; y < i*2; y++ {
 				a := NewAtlas(i)
 				assert.NotNil(t, a)
 				assert.Equal(t, 1, len(a.Chunks))
 				pos := vector.Vector{X: x, Y: y}
 				a.SetTile(pos, TileRock)
 				a.SetObject(pos, objects.Object{Type: objects.LargeRock})
 				tile, obj := a.QueryPosition(pos)
 				assert.Equal(t, TileRock, Tile(tile))
 				assert.Equal(t, objects.Object{Type: objects.LargeRock}, obj)
 			}
 		}
 	}
 }
--- a/pkg/bearing/bearing.go
+++ b/pkg/bearing/bearing.go
@ -1,84 +0,0 @@
 package bearing
 import (
 	"fmt"
 	"strings"
 	"github.com/mdiluz/rove/pkg/vector"
 )
 // Bearing describes a compass direction
 type Bearing int
 const (
 	// North describes a 0,1 vector
 	North Bearing = iota
 	// NorthEast describes a 1,1 vector
 	NorthEast
 	// East describes a 1,0 vector
 	East
 	// SouthEast describes a 1,-1 vector
 	SouthEast
 	// South describes a 0,-1 vector
 	South
 	// SouthWest describes a -1,-1 vector
 	SouthWest
 	// West describes a -1,0 vector
 	West
 	// NorthWest describes a -1,1 vector
 	NorthWest
 )
 // bearingString simply describes the strings associated with a direction
 type bearingString struct {
 	Long  string
 	Short string
 }
 // bearingStrings is the set of strings for each direction
 var bearingStrings = []bearingString{
 	{"North", "N"},
 	{"NorthEast", "NE"},
 	{"East", "E"},
 	{"SouthEast", "SE"},
 	{"South", "S"},
 	{"SouthWest", "SW"},
 	{"West", "W"},
 	{"NorthWest", "NW"},
 }
 // String converts a Direction to a String
 func (d Bearing) String() string {
 	return bearingStrings[d].Long
 }
 // ShortString converts a Direction to a short string version
 func (d Bearing) ShortString() string {
 	return bearingStrings[d].Short
 }
 // FromString gets the Direction from a string
 func FromString(s string) (Bearing, error) {
 	for i, d := range bearingStrings {
 		if strings.EqualFold(d.Long, s) || strings.EqualFold(d.Short, s) {
 			return Bearing(i), nil
 		}
 	}
 	return -1, fmt.Errorf("unknown bearing: %s", s)
 }
 var bearingVectors = []vector.Vector{
 	{X: 0, Y: 1},  // N
 	{X: 1, Y: 1},  // NE
 	{X: 1, Y: 0},  // E
 	{X: 1, Y: -1}, // SE
 	{X: 0, Y: -1}, // S
 	{X: -1, Y: 1}, // SW
 	{X: -1, Y: 0}, // W
 	{X: -1, Y: 1}, // NW
 }
 // Vector converts a Direction to a Vector
 func (d Bearing) Vector() vector.Vector {
 	return bearingVectors[d]
 }
--- a/pkg/bearing/bearing_test.go
+++ b/pkg/bearing/bearing_test.go
@ -1,32 +0,0 @@
 package bearing
 import (
 	"testing"
 	"github.com/mdiluz/rove/pkg/vector"
 	"github.com/stretchr/testify/assert"
 )
 func TestDirection(t *testing.T) {
 	dir := North
 	assert.Equal(t, "North", dir.String())
 	assert.Equal(t, "N", dir.ShortString())
 	assert.Equal(t, vector.Vector{X: 0, Y: 1}, dir.Vector())
 	dir, err := FromString("N")
 	assert.NoError(t, err)
 	assert.Equal(t, North, dir)
 	dir, err = FromString("n")
 	assert.NoError(t, err)
 	assert.Equal(t, North, dir)
 	dir, err = FromString("north")
 	assert.NoError(t, err)
 	assert.Equal(t, North, dir)
 	dir, err = FromString("NorthWest")
 	assert.NoError(t, err)
 	assert.Equal(t, NorthWest, dir)
 }
--- a/pkg/game/command.go
+++ b/pkg/game/command.go
@ -1,26 +0,0 @@
 package game
 const (
 	// CommandMove Moves the rover in the chosen bearing
 	CommandMove = "move"
 	// CommandStash Will attempt to stash the object at the current location
 	CommandStash = "stash"
 	// CommandRepair Will attempt to repair the rover with an inventory object
 	CommandRepair = "repair"
 	// CommandRecharge Will use one tick to charge the rover
 	CommandRecharge = "recharge"
 )
 // Command represends a single command to execute
 type Command struct {
 	Command string `json:"command"`
 	// Used in the move command
 	Bearing string `json:"bearing,omitempty"`
 }
 // CommandStream is a list of commands to execute in order
 type CommandStream []Command
--- a/pkg/game/command_test.go
+++ b/pkg/game/command_test.go
@ -1,69 +0,0 @@
 package game
 import (
 	"testing"
 	"github.com/mdiluz/rove/pkg/vector"
 	"github.com/stretchr/testify/assert"
 )
 func TestCommand_Move(t *testing.T) {
 	world := NewWorld(8)
 	a, err := world.SpawnRover()
 	assert.NoError(t, err)
 	pos := vector.Vector{
 		X: 1.0,
 		Y: 2.0,
 	}
 	err = world.WarpRover(a, pos)
 	assert.NoError(t, err, "Failed to set position for rover")
 	// Try the move command
 	moveCommand := Command{Command: CommandMove, Bearing: "N"}
 	assert.NoError(t, world.Enqueue(a, moveCommand), "Failed to execute move command")
 	// Tick the world
 	world.EnqueueAllIncoming()
 	world.ExecuteCommandQueues()
 	newPos, err := world.RoverPosition(a)
 	assert.NoError(t, err, "Failed to set position for rover")
 	pos.Add(vector.Vector{X: 0.0, Y: 1})
 	assert.Equal(t, pos, newPos, "Failed to correctly set position for rover")
 }
 func TestCommand_Recharge(t *testing.T) {
 	world := NewWorld(8)
 	a, err := world.SpawnRover()
 	assert.NoError(t, err)
 	pos := vector.Vector{
 		X: 1.0,
 		Y: 2.0,
 	}
 	err = world.WarpRover(a, pos)
 	assert.NoError(t, err, "Failed to set position for rover")
 	// Move to use up some charge
 	moveCommand := Command{Command: CommandMove, Bearing: "N"}
 	assert.NoError(t, world.Enqueue(a, moveCommand), "Failed to queue move command")
 	// Tick the world
 	world.EnqueueAllIncoming()
 	world.ExecuteCommandQueues()
 	rover, _ := world.GetRover(a)
 	assert.Equal(t, rover.MaximumCharge-1, rover.Charge)
 	chargeCommand := Command{Command: CommandRecharge}
 	assert.NoError(t, world.Enqueue(a, chargeCommand), "Failed to queue recharge command")
 	// Tick the world
 	world.EnqueueAllIncoming()
 	world.ExecuteCommandQueues()
 	rover, _ = world.GetRover(a)
 	assert.Equal(t, rover.MaximumCharge, rover.Charge)
 }
--- a/pkg/game/rover.go
+++ b/pkg/game/rover.go
@ -1,36 +0,0 @@
 package game
 import (
 	"github.com/mdiluz/rove/pkg/objects"
 	"github.com/mdiluz/rove/pkg/vector"
 )
 // Rover describes a single rover in the world
 type Rover struct {
 	// Unique name of this rover
 	Name string `json:"name"`
 	// Pos represents where this rover is in the world
 	Pos vector.Vector `json:"pos"`
 	// Range represents the distance the unit's radar can see
 	Range int `json:"range"`
 	// Inventory represents any items the rover is carrying
 	Inventory []objects.Object `json:"inventory"`
 	// Capacity is the maximum number of inventory items
 	Capacity int `json:"capacity"`
 	// Integrity represents current rover health
 	Integrity int `json:"integrity"`
 	// MaximumIntegrity is the full integrity of the rover
 	MaximumIntegrity int `json:"maximum-integrity"`
 	// Charge is the amount of energy the rover has
 	Charge int `json:"charge"`
 	// ChargeCharge is the maximum charge able to be stored
 	MaximumCharge int `json:"maximum-Charge"`
 }
--- a/pkg/game/world.go
+++ b/pkg/game/world.go
@ -1,526 +0,0 @@
 package game
 import (
 	"bufio"
 	"fmt"
 	"log"
 	"math/rand"
 	"os"
 	"sync"
 	"github.com/google/uuid"
 	"github.com/mdiluz/rove/pkg/atlas"
 	"github.com/mdiluz/rove/pkg/bearing"
 	"github.com/mdiluz/rove/pkg/objects"
 	"github.com/mdiluz/rove/pkg/vector"
 )
 // World describes a self contained universe and everything in it
 type World struct {
 	// Rovers is a id->data map of all the rovers in the game
 	Rovers map[string]Rover `json:"rovers"`
 	// Atlas represends the world map of chunks and tiles
 	Atlas atlas.Atlas `json:"atlas"`
 	// Mutex to lock around all world operations
 	worldMutex sync.RWMutex
 	// Commands is the set of currently executing command streams per rover
 	CommandQueue map[string]CommandStream `json:"commands"`
 	// Incoming represents the set of commands to add to the queue at the end of the current tick
 	CommandIncoming map[string]CommandStream `json:"incoming"`
 	// Mutex to lock around command operations
 	cmdMutex sync.RWMutex
 	// Set of possible words to use for names
 	words []string
 	// TicksPerDay is the amount of ticks in a single day
 	TicksPerDay int `json:"ticks-per-day"`
 	// Current number of ticks from the start
 	CurrentTicks int `json:"current-ticks"`
 }
 var wordsFile = os.Getenv("WORDS_FILE")
 // NewWorld creates a new world object
 func NewWorld(chunkSize int) *World {
 	// Try and load the words file
 	var lines []string
 	if file, err := os.Open(wordsFile); err != nil {
 		log.Printf("Couldn't read words file [%s], running without words: %s\n", wordsFile, err)
 	} else {
 		defer file.Close()
 		scanner := bufio.NewScanner(file)
 		for scanner.Scan() {
 			lines = append(lines, scanner.Text())
 		}
 		if scanner.Err() != nil {
 			log.Printf("Failure during word file scan: %s\n", scanner.Err())
 		}
 	}
 	return &World{
 		Rovers:          make(map[string]Rover),
 		CommandQueue:    make(map[string]CommandStream),
 		CommandIncoming: make(map[string]CommandStream),
 		Atlas:           atlas.NewAtlas(chunkSize),
 		words:           lines,
 		TicksPerDay:     24,
 		CurrentTicks:    0,
 	}
 }
 // SpawnRover adds an rover to the game
 func (w *World) SpawnRover() (string, error) {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	// Initialise the rover
 	rover := Rover{
 		Range:            4,
 		Integrity:        10,
 		MaximumIntegrity: 10,
 		Capacity:         10,
 		Charge:           10,
 		MaximumCharge:    10,
 		Name:             uuid.New().String(),
 	}
 	// Assign a random name if we have words
 	if len(w.words) > 0 {
 		for {
 			// Loop until we find a unique name
 			name := fmt.Sprintf("%s-%s", w.words[rand.Intn(len(w.words))], w.words[rand.Intn(len(w.words))])
 			if _, ok := w.Rovers[name]; !ok {
 				rover.Name = name
 				break
 			}
 		}
 	}
 	// Spawn in a random place near the origin
 	rover.Pos = vector.Vector{
 		X: w.Atlas.ChunkSize/2 - rand.Intn(w.Atlas.ChunkSize),
 		Y: w.Atlas.ChunkSize/2 - rand.Intn(w.Atlas.ChunkSize),
 	}
 	// Seach until we error (run out of world)
 	for {
 		_, obj := w.Atlas.QueryPosition(rover.Pos)
 		if !obj.IsBlocking() {
 			break
 		} else {
 			// Try and spawn to the east of the blockage
 			rover.Pos.Add(vector.Vector{X: 1, Y: 0})
 		}
 	}
 	log.Printf("Spawned rover at %+v\n", rover.Pos)
 	// Append the rover to the list
 	w.Rovers[rover.Name] = rover
 	return rover.Name, nil
 }
 // GetRover gets a specific rover by name
 func (w *World) GetRover(rover string) (Rover, error) {
 	w.worldMutex.RLock()
 	defer w.worldMutex.RUnlock()
 	i, ok := w.Rovers[rover]
 	if !ok {
 		return Rover{}, fmt.Errorf("Failed to find rover with name: %s", rover)
 	}
 	return i, nil
 }
 // RoverRecharge charges up a rover
 func (w *World) RoverRecharge(rover string) (int, error) {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	i, ok := w.Rovers[rover]
 	if !ok {
 		return 0, fmt.Errorf("Failed to find rover with name: %s", rover)
 	}
 	// We can only recharge during the day
 	if !w.Daytime() {
 		return i.Charge, nil
 	}
 	// Add one charge
 	if i.Charge < i.MaximumCharge {
 		i.Charge++
 	}
 	w.Rovers[rover] = i
 	return i.Charge, nil
 }
 // DestroyRover Removes an rover from the game
 func (w *World) DestroyRover(rover string) error {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	_, ok := w.Rovers[rover]
 	if !ok {
 		return fmt.Errorf("no rover matching id")
 	}
 	delete(w.Rovers, rover)
 	return nil
 }
 // RoverPosition returns the position of the rover
 func (w *World) RoverPosition(rover string) (vector.Vector, error) {
 	w.worldMutex.RLock()
 	defer w.worldMutex.RUnlock()
 	i, ok := w.Rovers[rover]
 	if !ok {
 		return vector.Vector{}, fmt.Errorf("no rover matching id")
 	}
 	return i.Pos, nil
 }
 // SetRoverPosition sets the position of the rover
 func (w *World) SetRoverPosition(rover string, pos vector.Vector) error {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	i, ok := w.Rovers[rover]
 	if !ok {
 		return fmt.Errorf("no rover matching id")
 	}
 	i.Pos = pos
 	w.Rovers[rover] = i
 	return nil
 }
 // RoverInventory returns the inventory of a requested rover
 func (w *World) RoverInventory(rover string) ([]objects.Object, error) {
 	w.worldMutex.RLock()
 	defer w.worldMutex.RUnlock()
 	i, ok := w.Rovers[rover]
 	if !ok {
 		return nil, fmt.Errorf("no rover matching id")
 	}
 	return i.Inventory, nil
 }
 // WarpRover sets an rovers position
 func (w *World) WarpRover(rover string, pos vector.Vector) error {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	i, ok := w.Rovers[rover]
 	if !ok {
 		return fmt.Errorf("no rover matching id")
 	}
 	// Nothing to do if these positions match
 	if i.Pos == pos {
 		return nil
 	}
 	// Check the tile is not blocked
 	_, obj := w.Atlas.QueryPosition(pos)
 	if obj.IsBlocking() {
 		return fmt.Errorf("can't warp rover to occupied tile, check before warping")
 	}
 	i.Pos = pos
 	w.Rovers[rover] = i
 	return nil
 }
 // MoveRover attempts to move a rover in a specific direction
 func (w *World) MoveRover(rover string, b bearing.Bearing) (vector.Vector, error) {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	i, ok := w.Rovers[rover]
 	if !ok {
 		return vector.Vector{}, fmt.Errorf("no rover matching id")
 	}
 	// Ensure the rover has energy
 	if i.Charge <= 0 {
 		return i.Pos, nil
 	}
 	i.Charge--
 	// Try the new move position
 	newPos := i.Pos.Added(b.Vector())
 	// Get the tile and verify it's empty
 	_, obj := w.Atlas.QueryPosition(newPos)
 	if !obj.IsBlocking() {
 		// Perform the move
 		i.Pos = newPos
 		w.Rovers[rover] = i
 	} else {
 		// If it is a blocking tile, reduce the rover integrity
 		i.Integrity = i.Integrity - 1
 		if i.Integrity == 0 {
 			// TODO: The rover needs to be left dormant with the player
 		} else {
 			w.Rovers[rover] = i
 		}
 	}
 	return i.Pos, nil
 }
 // RoverStash will stash an item at the current rovers position
 func (w *World) RoverStash(rover string) (objects.Type, error) {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	r, ok := w.Rovers[rover]
 	if !ok {
 		return objects.None, fmt.Errorf("no rover matching id")
 	}
 	// Can't pick up when full
 	if len(r.Inventory) >= r.Capacity {
 		return objects.None, nil
 	}
 	// Ensure the rover has energy
 	if r.Charge <= 0 {
 		return objects.None, nil
 	}
 	r.Charge--
 	_, obj := w.Atlas.QueryPosition(r.Pos)
 	if !obj.IsStashable() {
 		return objects.None, nil
 	}
 	r.Inventory = append(r.Inventory, obj)
 	w.Rovers[rover] = r
 	w.Atlas.SetObject(r.Pos, objects.Object{Type: objects.None})
 	return obj.Type, nil
 }
 // RadarFromRover can be used to query what a rover can currently see
 func (w *World) RadarFromRover(rover string) (radar []byte, objs []byte, err error) {
 	w.worldMutex.RLock()
 	defer w.worldMutex.RUnlock()
 	r, ok := w.Rovers[rover]
 	if !ok {
 		err = fmt.Errorf("no rover matching id")
 		return
 	}
 	// The radar should span in range direction on each axis, plus the row/column the rover is currently on
 	radarSpan := (r.Range * 2) + 1
 	roverPos := r.Pos
 	// Get the radar min and max values
 	radarMin := vector.Vector{
 		X: roverPos.X - r.Range,
 		Y: roverPos.Y - r.Range,
 	}
 	radarMax := vector.Vector{
 		X: roverPos.X + r.Range,
 		Y: roverPos.Y + r.Range,
 	}
 	// Gather up all tiles within the range
 	radar = make([]byte, radarSpan*radarSpan)
 	objs = make([]byte, radarSpan*radarSpan)
 	for j := radarMin.Y; j <= radarMax.Y; j++ {
 		for i := radarMin.X; i <= radarMax.X; i++ {
 			q := vector.Vector{X: i, Y: j}
 			tile, obj := w.Atlas.QueryPosition(q)
 			// Get the position relative to the bottom left of the radar
 			relative := q.Added(radarMin.Negated())
 			index := relative.X + relative.Y*radarSpan
 			radar[index] = tile
 			objs[index] = byte(obj.Type)
 		}
 	}
 	// Add all rovers to the radar
 	for _, r := range w.Rovers {
 		// If the rover is in range
 		dist := r.Pos.Added(roverPos.Negated())
 		dist = dist.Abs()
 		if dist.X <= r.Range && dist.Y <= r.Range {
 			relative := r.Pos.Added(radarMin.Negated())
 			index := relative.X + relative.Y*radarSpan
 			objs[index] = byte(objects.Rover)
 		}
 	}
 	return radar, objs, nil
 }
 // RoverCommands returns current commands for the given rover
 func (w *World) RoverCommands(rover string) (incoming []Command, queued []Command) {
 	if c, ok := w.CommandIncoming[rover]; ok {
 		incoming = c
 	}
 	if c, ok := w.CommandQueue[rover]; ok {
 		queued = c
 	}
 	return
 }
 // Enqueue will queue the commands given
 func (w *World) Enqueue(rover string, commands ...Command) error {
 	// First validate the commands
 	for _, c := range commands {
 		switch c.Command {
 		case CommandMove:
 			if _, err := bearing.FromString(c.Bearing); err != nil {
 				return fmt.Errorf("unknown bearing: %s", c.Bearing)
 			}
 		case CommandStash:
 		case CommandRepair:
 		case CommandRecharge:
 			// Nothing to verify
 		default:
 			return fmt.Errorf("unknown command: %s", c.Command)
 		}
 	}
 	// Lock our commands edit
 	w.cmdMutex.Lock()
 	defer w.cmdMutex.Unlock()
 	// Override the incoming command set
 	w.CommandIncoming[rover] = commands
 	return nil
 }
 // EnqueueAllIncoming will enqueue the incoming commands
 func (w *World) EnqueueAllIncoming() {
 	// Add any incoming commands from this tick and clear that queue
 	for id, incoming := range w.CommandIncoming {
 		commands := w.CommandQueue[id]
 		commands = append(commands, incoming...)
 		w.CommandQueue[id] = commands
 	}
 	w.CommandIncoming = make(map[string]CommandStream)
 }
 // ExecuteCommandQueues will execute any commands in the current command queue
 func (w *World) ExecuteCommandQueues() {
 	w.cmdMutex.Lock()
 	defer w.cmdMutex.Unlock()
 	// Iterate through all the current commands
 	for rover, cmds := range w.CommandQueue {
 		if len(cmds) != 0 {
 			// Extract the first command in the queue
 			c := cmds[0]
 			w.CommandQueue[rover] = cmds[1:]
 			// Execute the command
 			if err := w.ExecuteCommand(&c, rover); err != nil {
 				log.Println(err)
 				// TODO: Report this error somehow
 			}
 		} else {
 			// Clean out the empty entry
 			delete(w.CommandQueue, rover)
 		}
 	}
 	// Add any incoming commands from this tick and clear that queue
 	w.EnqueueAllIncoming()
 	// Increment the current tick count
 	w.CurrentTicks++
 }
 // ExecuteCommand will execute a single command
 func (w *World) ExecuteCommand(c *Command, rover string) (err error) {
 	log.Printf("Executing command: %+v for %s\n", *c, rover)
 	switch c.Command {
 	case CommandMove:
 		if dir, err := bearing.FromString(c.Bearing); err != nil {
 			return err
 		} else if _, err := w.MoveRover(rover, dir); err != nil {
 			return err
 		}
 	case CommandStash:
 		if _, err := w.RoverStash(rover); err != nil {
 			return err
 		}
 	case CommandRepair:
 		r, err := w.GetRover(rover)
 		if err != nil {
 			return err
 		}
 		// Consume an inventory item to repair if possible
 		if len(r.Inventory) > 0 && r.Integrity < r.MaximumIntegrity {
 			r.Inventory = r.Inventory[:len(r.Inventory)-1]
 			r.Integrity = r.Integrity + 1
 			w.Rovers[rover] = r
 		}
 	case CommandRecharge:
 		_, err := w.RoverRecharge(rover)
 		if err != nil {
 			return err
 		}
 	default:
 		return fmt.Errorf("unknown command: %s", c.Command)
 	}
 	return
 }
 // Daytime returns if it's currently daytime
 // for simplicity this uses the 1st half of the day as daytime, the 2nd half as nighttime
 func (w *World) Daytime() bool {
 	tickInDay := w.CurrentTicks % w.TicksPerDay
 	return tickInDay < w.TicksPerDay/2
 }
 // RLock read locks the world
 func (w *World) RLock() {
 	w.worldMutex.RLock()
 	w.cmdMutex.RLock()
 }
 // RUnlock read unlocks the world
 func (w *World) RUnlock() {
 	w.worldMutex.RUnlock()
 	w.cmdMutex.RUnlock()
 }
 // Lock locks the world
 func (w *World) Lock() {
 	w.worldMutex.Lock()
 	w.cmdMutex.Lock()
 }
 // Unlock unlocks the world
 func (w *World) Unlock() {
 	w.worldMutex.Unlock()
 	w.cmdMutex.Unlock()
 }
--- a/pkg/game/world_test.go
+++ b/pkg/game/world_test.go
@ -1,362 +0,0 @@
 package game
 import (
 	"testing"
 	"github.com/mdiluz/rove/pkg/atlas"
 	"github.com/mdiluz/rove/pkg/bearing"
 	"github.com/mdiluz/rove/pkg/objects"
 	"github.com/mdiluz/rove/pkg/vector"
 	"github.com/stretchr/testify/assert"
 )
 func TestNewWorld(t *testing.T) {
 	// Very basic for now, nothing to verify
 	world := NewWorld(4)
 	if world == nil {
 		t.Error("Failed to create world")
 	}
 }
 func TestWorld_CreateRover(t *testing.T) {
 	world := NewWorld(8)
 	a, err := world.SpawnRover()
 	assert.NoError(t, err)
 	b, err := world.SpawnRover()
 	assert.NoError(t, err)
 	// Basic duplicate check
 	if a == b {
 		t.Errorf("Created identical rovers")
 	} else if len(world.Rovers) != 2 {
 		t.Errorf("Incorrect number of rovers created")
 	}
 }
 func TestWorld_GetRover(t *testing.T) {
 	world := NewWorld(4)
 	a, err := world.SpawnRover()
 	assert.NoError(t, err)
 	rover, err := world.GetRover(a)
 	assert.NoError(t, err, "Failed to get rover attribs")
 	assert.NotZero(t, rover.Range, "Rover should not be spawned blind")
 }
 func TestWorld_DestroyRover(t *testing.T) {
 	world := NewWorld(1)
 	a, err := world.SpawnRover()
 	assert.NoError(t, err)
 	b, err := world.SpawnRover()
 	assert.NoError(t, err)
 	err = world.DestroyRover(a)
 	assert.NoError(t, err, "Error returned from rover destroy")
 	// Basic duplicate check
 	if len(world.Rovers) != 1 {
 		t.Error("Too many rovers left in world")
 	} else if _, ok := world.Rovers[b]; !ok {
 		t.Error("Remaining rover is incorrect")
 	}
 }
 func TestWorld_GetSetMovePosition(t *testing.T) {
 	world := NewWorld(4)
 	a, err := world.SpawnRover()
 	assert.NoError(t, err)
 	pos := vector.Vector{
 		X: 0.0,
 		Y: 0.0,
 	}
 	err = world.WarpRover(a, pos)
 	assert.NoError(t, err, "Failed to set position for rover")
 	newPos, err := world.RoverPosition(a)
 	assert.NoError(t, err, "Failed to set position for rover")
 	assert.Equal(t, pos, newPos, "Failed to correctly set position for rover")
 	b := bearing.North
 	newPos, err = world.MoveRover(a, b)
 	assert.NoError(t, err, "Failed to set position for rover")
 	pos.Add(vector.Vector{X: 0, Y: 1})
 	assert.Equal(t, pos, newPos, "Failed to correctly move position for rover")
 	rover, err := world.GetRover(a)
 	assert.NoError(t, err, "Failed to get rover information")
 	assert.Equal(t, rover.MaximumCharge-1, rover.Charge, "Rover should have lost charge for moving")
 	// Place a tile in front of the rover
 	world.Atlas.SetObject(vector.Vector{X: 0, Y: 2}, objects.Object{Type: objects.LargeRock})
 	newPos, err = world.MoveRover(a, b)
 	assert.NoError(t, err, "Failed to move rover")
 	assert.Equal(t, pos, newPos, "Failed to correctly not move position for rover into wall")
 	rover, err = world.GetRover(a)
 	assert.NoError(t, err, "Failed to get rover information")
 	assert.Equal(t, rover.MaximumCharge-2, rover.Charge, "Rover should have lost charge for move attempt")
 }
 func TestWorld_RadarFromRover(t *testing.T) {
 	// Create world that should have visible walls on the radar
 	world := NewWorld(2)
 	a, err := world.SpawnRover()
 	assert.NoError(t, err)
 	b, err := world.SpawnRover()
 	assert.NoError(t, err)
 	// Warp the rovers into position
 	bpos := vector.Vector{X: -3, Y: -3}
 	assert.NoError(t, world.WarpRover(b, bpos), "Failed to warp rover")
 	assert.NoError(t, world.WarpRover(a, vector.Vector{X: 0, Y: 0}), "Failed to warp rover")
 	radar, objs, err := world.RadarFromRover(a)
 	assert.NoError(t, err, "Failed to get radar from rover")
 	fullRange := 4 + 4 + 1
 	assert.Equal(t, fullRange*fullRange, len(radar), "Radar returned wrong length")
 	assert.Equal(t, fullRange*fullRange, len(objs), "Radar returned wrong length")
 	// Test the expected values
 	assert.Equal(t, byte(objects.Rover), objs[1+fullRange])
 	assert.Equal(t, byte(objects.Rover), objs[4+4*fullRange])
 	// Check the radar results are stable
 	radar1, objs1, err := world.RadarFromRover(a)
 	assert.NoError(t, err)
 	radar2, objs2, err := world.RadarFromRover(a)
 	assert.NoError(t, err)
 	assert.Equal(t, radar1, radar2)
 	assert.Equal(t, objs1, objs2)
 }
 func TestWorld_RoverStash(t *testing.T) {
 	world := NewWorld(2)
 	a, err := world.SpawnRover()
 	assert.NoError(t, err)
 	pos := vector.Vector{
 		X: 0.0,
 		Y: 0.0,
 	}
 	err = world.WarpRover(a, pos)
 	assert.NoError(t, err, "Failed to set position for rover")
 	// Set to a traversible tile
 	world.Atlas.SetTile(pos, atlas.TileRock)
 	rover, err := world.GetRover(a)
 	assert.NoError(t, err, "Failed to get rover")
 	for i := 0; i < rover.Capacity; i++ {
 		// Place an object
 		world.Atlas.SetObject(pos, objects.Object{Type: objects.SmallRock})
 		// Pick it up
 		o, err := world.RoverStash(a)
 		assert.NoError(t, err, "Failed to stash")
 		assert.Equal(t, objects.SmallRock, o, "Failed to get correct object")
 		// Check it's gone
 		_, obj := world.Atlas.QueryPosition(pos)
 		assert.Equal(t, objects.None, obj.Type, "Stash failed to remove object from atlas")
 		// Check we have it
 		inv, err := world.RoverInventory(a)
 		assert.NoError(t, err, "Failed to get inventory")
 		assert.Equal(t, i+1, len(inv))
 		assert.Equal(t, objects.Object{Type: objects.SmallRock}, inv[i])
 		// Check that this didn't reduce the charge
 		info, err := world.GetRover(a)
 		assert.NoError(t, err, "Failed to get rover")
 		assert.Equal(t, info.MaximumCharge-(i+1), info.Charge, "Rover lost charge for stash")
 	}
 	// Recharge the rover
 	for i := 0; i < rover.MaximumCharge; i++ {
 		_, err = world.RoverRecharge(a)
 		assert.NoError(t, err)
 	}
 	// Place an object
 	world.Atlas.SetObject(pos, objects.Object{Type: objects.SmallRock})
 	// Try to pick it up
 	o, err := world.RoverStash(a)
 	assert.NoError(t, err, "Failed to stash")
 	assert.Equal(t, objects.None, o, "Failed to get correct object")
 	// Check it's still there
 	_, obj := world.Atlas.QueryPosition(pos)
 	assert.Equal(t, objects.SmallRock, obj.Type, "Stash failed to remove object from atlas")
 	// Check we don't have it
 	inv, err := world.RoverInventory(a)
 	assert.NoError(t, err, "Failed to get inventory")
 	assert.Equal(t, rover.Capacity, len(inv))
 	// Check that this didn't reduce the charge
 	info, err := world.GetRover(a)
 	assert.NoError(t, err, "Failed to get rover")
 	assert.Equal(t, info.MaximumCharge, info.Charge, "Rover lost charge for non-stash")
 }
 func TestWorld_RoverDamage(t *testing.T) {
 	world := NewWorld(2)
 	a, err := world.SpawnRover()
 	assert.NoError(t, err)
 	pos := vector.Vector{
 		X: 0.0,
 		Y: 0.0,
 	}
 	err = world.WarpRover(a, pos)
 	assert.NoError(t, err, "Failed to set position for rover")
 	info, err := world.GetRover(a)
 	assert.NoError(t, err, "couldn't get rover info")
 	world.Atlas.SetObject(vector.Vector{X: 0.0, Y: 1.0}, objects.Object{Type: objects.LargeRock})
 	vec, err := world.MoveRover(a, bearing.North)
 	assert.NoError(t, err, "Failed to move rover")
 	assert.Equal(t, pos, vec, "Rover managed to move into large rock")
 	newinfo, err := world.GetRover(a)
 	assert.NoError(t, err, "couldn't get rover info")
 	assert.Equal(t, info.Integrity-1, newinfo.Integrity, "rover should have lost integrity")
 }
 func TestWorld_RoverRepair(t *testing.T) {
 	world := NewWorld(2)
 	a, err := world.SpawnRover()
 	assert.NoError(t, err)
 	pos := vector.Vector{
 		X: 0.0,
 		Y: 0.0,
 	}
 	world.Atlas.SetTile(pos, atlas.TileNone)
 	world.Atlas.SetObject(pos, objects.Object{Type: objects.None})
 	err = world.WarpRover(a, pos)
 	assert.NoError(t, err, "Failed to set position for rover")
 	originalInfo, err := world.GetRover(a)
 	assert.NoError(t, err, "couldn't get rover info")
 	// Pick up something to repair with
 	world.Atlas.SetObject(pos, objects.Object{Type: objects.SmallRock})
 	o, err := world.RoverStash(a)
 	assert.NoError(t, err, "Failed to stash")
 	assert.Equal(t, objects.SmallRock, o, "Failed to get correct object")
 	world.Atlas.SetObject(vector.Vector{X: 0.0, Y: 1.0}, objects.Object{Type: objects.LargeRock})
 	// Try and bump into the rock
 	vec, err := world.MoveRover(a, bearing.North)
 	assert.NoError(t, err, "Failed to move rover")
 	assert.Equal(t, pos, vec, "Rover managed to move into large rock")
 	newinfo, err := world.GetRover(a)
 	assert.NoError(t, err, "couldn't get rover info")
 	assert.Equal(t, originalInfo.Integrity-1, newinfo.Integrity, "rover should have lost integrity")
 	err = world.ExecuteCommand(&Command{Command: CommandRepair}, a)
 	assert.NoError(t, err, "Failed to repair rover")
 	newinfo, err = world.GetRover(a)
 	assert.NoError(t, err, "couldn't get rover info")
 	assert.Equal(t, originalInfo.Integrity, newinfo.Integrity, "rover should have gained integrity")
 	// Check again that it can't repair past the max
 	world.Atlas.SetObject(pos, objects.Object{Type: objects.SmallRock})
 	o, err = world.RoverStash(a)
 	assert.NoError(t, err, "Failed to stash")
 	assert.Equal(t, objects.SmallRock, o, "Failed to get correct object")
 	err = world.ExecuteCommand(&Command{Command: CommandRepair}, a)
 	assert.NoError(t, err, "Failed to repair rover")
 	newinfo, err = world.GetRover(a)
 	assert.NoError(t, err, "couldn't get rover info")
 	assert.Equal(t, originalInfo.Integrity, newinfo.Integrity, "rover should have kept the same integrity")
 }
 func TestWorld_Charge(t *testing.T) {
 	world := NewWorld(4)
 	a, err := world.SpawnRover()
 	assert.NoError(t, err)
 	// Get the rover information
 	rover, err := world.GetRover(a)
 	assert.NoError(t, err, "Failed to get rover information")
 	assert.Equal(t, rover.MaximumCharge, rover.Charge, "Rover should start with maximum charge")
 	// Use up all the charge
 	for i := 0; i < rover.MaximumCharge; i++ {
 		// Get the initial position
 		initialPos, err := world.RoverPosition(a)
 		assert.NoError(t, err, "Failed to get position for rover")
 		// Ensure the path ahead is empty
 		world.Atlas.SetTile(initialPos.Added(bearing.North.Vector()), atlas.TileRock)
 		world.Atlas.SetObject(initialPos.Added(bearing.North.Vector()), objects.Object{Type: objects.None})
 		// Try and move north (along unblocked path)
 		newPos, err := world.MoveRover(a, bearing.North)
 		assert.NoError(t, err, "Failed to set position for rover")
 		assert.Equal(t, initialPos.Added(bearing.North.Vector()), newPos, "Failed to correctly move position for rover")
 		// Ensure rover lost charge
 		rover, err := world.GetRover(a)
 		assert.NoError(t, err, "Failed to get rover information")
 		assert.Equal(t, rover.MaximumCharge-(i+1), rover.Charge, "Rover should have lost charge")
 	}
 }
 func TestWorld_Daytime(t *testing.T) {
 	world := NewWorld(1)
 	a, err := world.SpawnRover()
 	assert.NoError(t, err)
 	// Remove rover charge
 	rover := world.Rovers[a]
 	rover.Charge = 0
 	world.Rovers[a] = rover
 	// Try and recharge, should work
 	_, err = world.RoverRecharge(a)
 	assert.NoError(t, err)
 	assert.Equal(t, 1, world.Rovers[a].Charge)
 	// Loop for half the day
 	for i := 0; i < world.TicksPerDay/2; i++ {
 		assert.True(t, world.Daytime())
 		world.ExecuteCommandQueues()
 	}
 	// Remove rover charge again
 	rover = world.Rovers[a]
 	rover.Charge = 0
 	world.Rovers[a] = rover
 	// Try and recharge, should fail
 	_, err = world.RoverRecharge(a)
 	assert.NoError(t, err)
 	assert.Equal(t, 0, world.Rovers[a].Charge)
 	// Loop for half the day
 	for i := 0; i < world.TicksPerDay/2; i++ {
 		assert.False(t, world.Daytime())
 		world.ExecuteCommandQueues()
 	}
 }
--- a/pkg/vector/vector.go
+++ b/pkg/vector/vector.go
@ -1,15 +1,15 @@
-package vector
+package maths
 import (
 	"math"
-	"github.com/mdiluz/rove/pkg/maths"
+	"github.com/mdiluz/rove/proto/roveapi"
 )
 // Vector desribes a 3D vector
 type Vector struct {
-	X int `json:"x"`
+	X int
-	Y int `json:"y"`
+	Y int
 }
 // Add adds one vector to another
@ -71,15 +71,49 @@ func (v Vector) DividedFloor(val int) Vector {
 // Abs returns an absolute version of the vector
 func (v Vector) Abs() Vector {
-	return Vector{maths.Abs(v.X), maths.Abs(v.Y)}
+	return Vector{Abs(v.X), Abs(v.Y)}
 }
-// Min returns the minimum values in both vectors
+// Min2 returns the minimum values in both vectors
-func Min(v1 Vector, v2 Vector) Vector {
+func Min2(v1 Vector, v2 Vector) Vector {
-	return Vector{maths.Min(v1.X, v2.X), maths.Min(v1.Y, v2.Y)}
+	return Vector{Min(v1.X, v2.X), Min(v1.Y, v2.Y)}
 }
-// Max returns the max values in both vectors
+// Max2 returns the max values in both vectors
-func Max(v1 Vector, v2 Vector) Vector {
+func Max2(v1 Vector, v2 Vector) Vector {
-	return Vector{maths.Max(v1.X, v2.X), maths.Max(v1.Y, v2.Y)}
+	return Vector{Max(v1.X, v2.X), Max(v1.Y, v2.Y)}
 }
 // BearingToVector converts a bearing to a vector
 func BearingToVector(b roveapi.Bearing) Vector {
 	switch b {
 	case roveapi.Bearing_North:
 		return Vector{Y: 1}
 	case roveapi.Bearing_NorthEast:
 		return Vector{X: 1, Y: 1}
 	case roveapi.Bearing_East:
 		return Vector{X: 1}
 	case roveapi.Bearing_SouthEast:
 		return Vector{X: 1, Y: -1}
 	case roveapi.Bearing_South:
 		return Vector{Y: -1}
 	case roveapi.Bearing_SouthWest:
 		return Vector{X: -1, Y: -1}
 	case roveapi.Bearing_West:
 		return Vector{X: -1}
 	case roveapi.Bearing_NorthWest:
 		return Vector{X: -1, Y: 1}
 	}
 	return Vector{}
 }
 // Dot returns the dot product of two vectors
 func Dot(a Vector, b Vector) int {
 	return a.X*b.X + a.Y*b.Y
 }
 // AngleCos returns the cosine of the angle between two vectors
 func AngleCos(a Vector, b Vector) float64 {
 	return float64(Dot(a, b)) / a.Length() * b.Length()
 }
--- a/pkg/vector/vector_test.go
+++ b/pkg/vector/vector_test.go
@ -1,4 +1,4 @@
-package vector
+package maths
 import (
 	"math"
--- a/pkg/objects/objects.go
+++ b/pkg/objects/objects.go
@ -1,53 +0,0 @@
 package objects
 // Type represents an object type
 type Type byte
 // Types of objects
 const (
 	// None represents no object at all
 	None = Type(0)
 	// Rover represents a live rover
 	Rover = Type('R')
 	// SmallRock is a small stashable rock
 	SmallRock = Type('o')
 	// LargeRock is a large blocking rock
 	LargeRock = Type('O')
 )
 // Object represents an object in the world
 type Object struct {
 	Type Type `json:"type"`
 }
 // IsBlocking checks if an object is a blocking object
 func (o *Object) IsBlocking() bool {
 	var blocking = [...]Type{
 		Rover,
 		LargeRock,
 	}
 	for _, t := range blocking {
 		if o.Type == t {
 			return true
 		}
 	}
 	return false
 }
 // IsStashable checks if an object is stashable
 func (o *Object) IsStashable() bool {
 	var stashable = [...]Type{
 		SmallRock,
 	}
 	for _, t := range stashable {
 		if o.Type == t {
 			return true
 		}
 	}
 	return false
 }
--- a/pkg/rove/atlas.go
+++ b/pkg/rove/atlas.go
@ -0,0 +1,18 @@
 package rove
 import (
 	"github.com/mdiluz/rove/pkg/maths"
 	"github.com/mdiluz/rove/proto/roveapi"
 )
 // Atlas represents a 2D world atlas of tiles and objects
 type Atlas interface {
 	// SetTile sets a location on the Atlas to a type of tile
 	SetTile(v maths.Vector, tile roveapi.Tile)
 	// SetObject will set a location on the Atlas to contain an object
 	SetObject(v maths.Vector, obj Object)
 	// QueryPosition queries a position on the atlas
 	QueryPosition(v maths.Vector) (roveapi.Tile, Object)
 }
--- a/pkg/rove/atlas_test.go
+++ b/pkg/rove/atlas_test.go
@ -0,0 +1,257 @@
 package rove
 import (
 	"testing"
 	"github.com/mdiluz/rove/pkg/maths"
 	"github.com/mdiluz/rove/proto/roveapi"
 	"github.com/stretchr/testify/assert"
 )
 func TestAtlas_NewAtlas(t *testing.T) {
 	a := NewChunkAtlas(1).(*chunkBasedAtlas)
 	assert.NotNil(t, a)
 	assert.Equal(t, 1, a.ChunkSize)
 	assert.Equal(t, 1, len(a.Chunks)) // Should start empty
 }
 func TestAtlas_toChunk(t *testing.T) {
 	a := NewChunkAtlas(1).(*chunkBasedAtlas)
 	assert.NotNil(t, a)
 	// Get a tile to spawn the chunks
 	a.QueryPosition(maths.Vector{X: -1, Y: -1})
 	a.QueryPosition(maths.Vector{X: 0, Y: 0})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	// Chunks should look like:
 	//  2 | 3
 	//  -----
 	//  0 | 1
 	chunkID := a.worldSpaceToChunkIndex(maths.Vector{X: 0, Y: 0})
 	assert.Equal(t, 3, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 0, Y: -1})
 	assert.Equal(t, 1, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: -1, Y: -1})
 	assert.Equal(t, 0, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: -1, Y: 0})
 	assert.Equal(t, 2, chunkID)
 	a = NewChunkAtlas(2).(*chunkBasedAtlas)
 	assert.NotNil(t, a)
 	// Get a tile to spawn the chunks
 	a.QueryPosition(maths.Vector{X: -2, Y: -2})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	a.QueryPosition(maths.Vector{X: 1, Y: 1})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	// Chunks should look like:
 	// 2 | 3
 	// -----
 	// 0 | 1
 	chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 1, Y: 1})
 	assert.Equal(t, 3, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 1, Y: -2})
 	assert.Equal(t, 1, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: -2, Y: -2})
 	assert.Equal(t, 0, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: -2, Y: 1})
 	assert.Equal(t, 2, chunkID)
 	a = NewChunkAtlas(2).(*chunkBasedAtlas)
 	assert.NotNil(t, a)
 	// Get a tile to spawn a 4x4 grid of chunks
 	a.QueryPosition(maths.Vector{X: 3, Y: 3})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	a.QueryPosition(maths.Vector{X: -3, Y: -3})
 	assert.Equal(t, 4*4, len(a.Chunks))
 	// Chunks should look like:
 	//  12| 13|| 14| 15
 	// ----------------
 	//  8 | 9 || 10| 11
 	// ================
 	//  4 | 5 || 6 | 7
 	// ----------------
 	//  0 | 1 || 2 | 3
 	chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 1, Y: 3})
 	assert.Equal(t, 14, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 1, Y: -3})
 	assert.Equal(t, 2, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: -1, Y: -1})
 	assert.Equal(t, 5, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: -2, Y: 2})
 	assert.Equal(t, 13, chunkID)
 	a = NewChunkAtlas(3).(*chunkBasedAtlas)
 	assert.NotNil(t, a)
 	// Get a tile to spawn a 4x4 grid of chunks
 	a.QueryPosition(maths.Vector{X: 3, Y: 3})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	// Chunks should look like:
 	// || 2| 3
 	// -------
 	// || 0| 1
 	// =======
 	chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 1, Y: 1})
 	assert.Equal(t, 0, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 3, Y: 1})
 	assert.Equal(t, 1, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 1, Y: 4})
 	assert.Equal(t, 2, chunkID)
 	chunkID = a.worldSpaceToChunkIndex(maths.Vector{X: 5, Y: 5})
 	assert.Equal(t, 3, chunkID)
 }
 func TestAtlas_toWorld(t *testing.T) {
 	a := NewChunkAtlas(1).(*chunkBasedAtlas)
 	assert.NotNil(t, a)
 	// Get a tile to spawn some chunks
 	a.QueryPosition(maths.Vector{X: -1, Y: -1})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	// Chunks should look like:
 	//  2 | 3
 	//  -----
 	//  0 | 1
 	assert.Equal(t, maths.Vector{X: -1, Y: -1}, a.chunkOriginInWorldSpace(0))
 	assert.Equal(t, maths.Vector{X: 0, Y: -1}, a.chunkOriginInWorldSpace(1))
 	a = NewChunkAtlas(2).(*chunkBasedAtlas)
 	assert.NotNil(t, a)
 	// Get a tile to spawn the chunks
 	a.QueryPosition(maths.Vector{X: -2, Y: -2})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	a.QueryPosition(maths.Vector{X: 1, Y: 1})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	// Chunks should look like:
 	// 2 | 3
 	// -----
 	// 0 | 1
 	assert.Equal(t, maths.Vector{X: -2, Y: -2}, a.chunkOriginInWorldSpace(0))
 	assert.Equal(t, maths.Vector{X: -2, Y: 0}, a.chunkOriginInWorldSpace(2))
 	a = NewChunkAtlas(2).(*chunkBasedAtlas)
 	assert.NotNil(t, a)
 	// Get a tile to spawn a 4x4 grid of chunks
 	a.QueryPosition(maths.Vector{X: 3, Y: 3})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	a.QueryPosition(maths.Vector{X: -3, Y: -3})
 	assert.Equal(t, 4*4, len(a.Chunks))
 	// Chunks should look like:
 	//  12| 13|| 14| 15
 	// ----------------
 	//  8 | 9 || 10| 11
 	// ================
 	//  4 | 5 || 6 | 7
 	// ----------------
 	//  0 | 1 || 2 | 3
 	assert.Equal(t, maths.Vector{X: -4, Y: -4}, a.chunkOriginInWorldSpace(0))
 	assert.Equal(t, maths.Vector{X: 2, Y: -2}, a.chunkOriginInWorldSpace(7))
 	a = NewChunkAtlas(3).(*chunkBasedAtlas)
 	assert.NotNil(t, a)
 	// Get a tile to spawn a 4x4 grid of chunks
 	a.QueryPosition(maths.Vector{X: 3, Y: 3})
 	assert.Equal(t, 2*2, len(a.Chunks))
 	// Chunks should look like:
 	// || 2| 3
 	// -------
 	// || 0| 1
 	// =======
 	assert.Equal(t, maths.Vector{X: 0, Y: 0}, a.chunkOriginInWorldSpace(0))
 }
 func TestAtlas_GetSetTile(t *testing.T) {
 	a := NewChunkAtlas(10)
 	assert.NotNil(t, a)
 	// Set the origin tile and test it
 	a.SetTile(maths.Vector{X: 0, Y: 0}, roveapi.Tile_Gravel)
 	tile, _ := a.QueryPosition(maths.Vector{X: 0, Y: 0})
 	assert.Equal(t, roveapi.Tile_Gravel, tile)
 	// Set another tile and test it
 	a.SetTile(maths.Vector{X: 5, Y: -2}, roveapi.Tile_Rock)
 	tile, _ = a.QueryPosition(maths.Vector{X: 5, Y: -2})
 	assert.Equal(t, roveapi.Tile_Rock, tile)
 }
 func TestAtlas_GetSetObject(t *testing.T) {
 	a := NewChunkAtlas(10)
 	assert.NotNil(t, a)
 	// Set the origin tile to 1 and test it
 	a.SetObject(maths.Vector{X: 0, Y: 0}, Object{Type: roveapi.Object_RockLarge})
 	_, obj := a.QueryPosition(maths.Vector{X: 0, Y: 0})
 	assert.Equal(t, Object{Type: roveapi.Object_RockLarge}, obj)
 	// Set another tile to 1 and test it
 	a.SetObject(maths.Vector{X: 5, Y: -2}, Object{Type: roveapi.Object_RockSmall})
 	_, obj = a.QueryPosition(maths.Vector{X: 5, Y: -2})
 	assert.Equal(t, Object{Type: roveapi.Object_RockSmall}, obj)
 }
 func TestAtlas_Grown(t *testing.T) {
 	// Start with a small example
 	a := NewChunkAtlas(2).(*chunkBasedAtlas)
 	assert.NotNil(t, a)
 	assert.Equal(t, 1, len(a.Chunks))
 	// Set a few tiles to values
 	a.SetTile(maths.Vector{X: 0, Y: 0}, roveapi.Tile_Gravel)
 	a.SetTile(maths.Vector{X: -1, Y: -1}, roveapi.Tile_Rock)
 	a.SetTile(maths.Vector{X: 1, Y: -2}, roveapi.Tile_Sand)
 	// Check tile values
 	tile, _ := a.QueryPosition(maths.Vector{X: 0, Y: 0})
 	assert.Equal(t, roveapi.Tile_Gravel, tile)
 	tile, _ = a.QueryPosition(maths.Vector{X: -1, Y: -1})
 	assert.Equal(t, roveapi.Tile_Rock, tile)
 	tile, _ = a.QueryPosition(maths.Vector{X: 1, Y: -2})
 	assert.Equal(t, roveapi.Tile_Sand, tile)
 	tile, _ = a.QueryPosition(maths.Vector{X: 0, Y: 0})
 	assert.Equal(t, roveapi.Tile_Gravel, tile)
 	tile, _ = a.QueryPosition(maths.Vector{X: -1, Y: -1})
 	assert.Equal(t, roveapi.Tile_Rock, tile)
 	tile, _ = a.QueryPosition(maths.Vector{X: 1, Y: -2})
 	assert.Equal(t, roveapi.Tile_Sand, tile)
 }
 func TestAtlas_GetSetCorrect(t *testing.T) {
 	// Big stress test to ensure we do actually properly expand for all reasonable values
 	for i := 1; i <= 4; i++ {
 		for x := -i * 2; x < i*2; x++ {
 			for y := -i * 2; y < i*2; y++ {
 				a := NewChunkAtlas(i).(*chunkBasedAtlas)
 				assert.NotNil(t, a)
 				assert.Equal(t, 1, len(a.Chunks))
 				pos := maths.Vector{X: x, Y: y}
 				a.SetTile(pos, roveapi.Tile_Rock)
 				a.SetObject(pos, Object{Type: roveapi.Object_RockLarge})
 				tile, obj := a.QueryPosition(pos)
 				assert.Equal(t, roveapi.Tile_Rock, roveapi.Tile(tile))
 				assert.Equal(t, Object{Type: roveapi.Object_RockLarge}, obj)
 			}
 		}
 	}
 }
 func TestAtlas_WorldGen(t *testing.T) {
 	a := NewChunkAtlas(8)
 	// Spawn a large world
 	_, _ = a.QueryPosition(maths.Vector{X: 20, Y: 20})
 }
--- a/pkg/rove/chunkAtlas.go
+++ b/pkg/rove/chunkAtlas.go
@ -1,144 +1,133 @@
-package atlas
+package rove
 import (
 	"log"
 	"math/rand"
 	"github.com/mdiluz/rove/pkg/maths"
-	"github.com/mdiluz/rove/pkg/objects"
+	"github.com/mdiluz/rove/proto/roveapi"
 	"github.com/mdiluz/rove/pkg/vector"
 )
-// Tile describes the type of terrain
+// chunk represents a fixed square grid of tiles
-type Tile byte
+type chunk struct {
 const (
 	// TileNone is a keyword for nothing
 	TileNone = Tile(0)
 	// TileRock is solid rock ground
 	TileRock = Tile('.')
 	// TileSand is sand
 	TileSand = Tile(',')
 )
 // Chunk represents a fixed square grid of tiles
 type Chunk struct {
 	// Tiles represents the tiles within the chunk
-	Tiles []byte `json:"tiles"`
+	Tiles []byte
 	// Objects represents the objects within the chunk
 	// only one possible object per tile for now
-	Objects map[int]objects.Object `json:"objects"`
+	Objects map[int]Object
 }
-// Atlas represents a grid of Chunks
+// chunkBasedAtlas represents a grid of Chunks
-type Atlas struct {
+type chunkBasedAtlas struct {
 	// Chunks represents all chunks in the world
 	// This is intentionally not a 2D array so it can be expanded in all directions
-	Chunks []Chunk `json:"chunks"`
+	Chunks []chunk
 	// LowerBound is the origin of the bottom left corner of the current chunks in world space (current chunks cover >= this value)
-	LowerBound vector.Vector `json:"lowerBound"`
+	LowerBound maths.Vector
 	// UpperBound is the top left corner of the current chunks (curent chunks cover < this value)
-	UpperBound vector.Vector `json:"upperBound"`
+	UpperBound maths.Vector
 	// ChunkSize is the x/y dimensions of each square chunk
-	ChunkSize int `json:"chunksize"`
+	ChunkSize int
 	// worldGen is the internal world generator
 	worldGen WorldGen
 }
-// NewAtlas creates a new empty atlas
+const (
-func NewAtlas(chunkSize int) Atlas {
+	noiseSeed = 1024
 )
 // NewChunkAtlas creates a new empty atlas
 func NewChunkAtlas(chunkSize int) Atlas {
 	// Start up with one chunk
-	a := Atlas{
+	a := chunkBasedAtlas{
 		ChunkSize:  chunkSize,
-		Chunks:     make([]Chunk, 1),
+		Chunks:     make([]chunk, 1),
-		LowerBound: vector.Vector{X: 0, Y: 0},
+		LowerBound: maths.Vector{X: 0, Y: 0},
-		UpperBound: vector.Vector{X: chunkSize, Y: chunkSize},
+		UpperBound: maths.Vector{X: chunkSize, Y: chunkSize},
 		worldGen:   NewNoiseWorldGen(noiseSeed),
 	}
 	// Initialise the first chunk
-	a.Chunks[0].populate(chunkSize)
+	a.populate(0)
-	return a
+	return &a
 }
 // SetTile sets an individual tile's kind
-func (a *Atlas) SetTile(v vector.Vector, tile Tile) {
+func (a *chunkBasedAtlas) SetTile(v maths.Vector, tile roveapi.Tile) {
 	c := a.worldSpaceToChunkWithGrow(v)
 	local := a.worldSpaceToChunkLocal(v)
 	a.setTile(c, local, byte(tile))
 }
 // SetObject sets the object on a tile
-func (a *Atlas) SetObject(v vector.Vector, obj objects.Object) {
+func (a *chunkBasedAtlas) SetObject(v maths.Vector, obj Object) {
 	c := a.worldSpaceToChunkWithGrow(v)
 	local := a.worldSpaceToChunkLocal(v)
 	a.setObject(c, local, obj)
 }
 // QueryPosition will return information for a specific position
-func (a *Atlas) QueryPosition(v vector.Vector) (byte, objects.Object) {
+func (a *chunkBasedAtlas) QueryPosition(v maths.Vector) (roveapi.Tile, Object) {
 	c := a.worldSpaceToChunkWithGrow(v)
 	local := a.worldSpaceToChunkLocal(v)
 	a.populate(c)
 	chunk := a.Chunks[c]
 	if chunk.Tiles == nil {
 		chunk.populate(a.ChunkSize)
 		a.Chunks[c] = chunk
 	}
 	i := a.chunkTileIndex(local)
-	return chunk.Tiles[i], chunk.Objects[i]
+	return roveapi.Tile(chunk.Tiles[i]), chunk.Objects[i]
 }
 // chunkTileID returns the tile index within a chunk
-func (a *Atlas) chunkTileIndex(local vector.Vector) int {
+func (a *chunkBasedAtlas) chunkTileIndex(local maths.Vector) int {
 	return local.X + local.Y*a.ChunkSize
 }
 // populate will fill a chunk with data
-func (c *Chunk) populate(size int) {
+func (a *chunkBasedAtlas) populate(chunk int) {
-	c.Tiles = make([]byte, size*size)
+	c := a.Chunks[chunk]
-	c.Objects = make(map[int]objects.Object)
+	if c.Tiles != nil {
 		return
 	}
-	// Set up the tiles
+	c.Tiles = make([]byte, a.ChunkSize*a.ChunkSize)
-	for i := 0; i < len(c.Tiles); i++ {
+	c.Objects = make(map[int]Object)
-		if rand.Intn(3) == 0 {
+
-			c.Tiles[i] = byte(TileRock)
+	origin := a.chunkOriginInWorldSpace(chunk)
-		} else {
+	for i := 0; i < a.ChunkSize; i++ {
-			c.Tiles[i] = byte(TileSand)
+		for j := 0; j < a.ChunkSize; j++ {
 			loc := maths.Vector{X: origin.X + i, Y: origin.Y + j}
 			// Set the tile
 			c.Tiles[j*a.ChunkSize+i] = byte(a.worldGen.GetTile(loc))
 			// Set the object
 			obj := a.worldGen.GetObject(loc)
 			if obj.Type != roveapi.Object_ObjectUnknown {
 				c.Objects[j*a.ChunkSize+i] = obj
 			}
 		}
 	}
-	// Set up any objects
+	a.Chunks[chunk] = c
 	for i := 0; i < len(c.Tiles); i++ {
 		if rand.Intn(16) == 0 {
 			c.Objects[i] = objects.Object{Type: objects.LargeRock}
 		} else if rand.Intn(32) == 0 {
 			c.Objects[i] = objects.Object{Type: objects.SmallRock}
 		}
 	}
 }
 // setTile sets a tile in a specific chunk
-func (a *Atlas) setTile(chunk int, local vector.Vector, tile byte) {
+func (a *chunkBasedAtlas) setTile(chunk int, local maths.Vector, tile byte) {
 	a.populate(chunk)
 	c := a.Chunks[chunk]
 	if c.Tiles == nil {
 		c.populate(a.ChunkSize)
 	}
 	c.Tiles[a.chunkTileIndex(local)] = tile
 	a.Chunks[chunk] = c
 }
 // setObject sets an object in a specific chunk
-func (a *Atlas) setObject(chunk int, local vector.Vector, object objects.Object) {
+func (a *chunkBasedAtlas) setObject(chunk int, local maths.Vector, object Object) {
-	c := a.Chunks[chunk]
+	a.populate(chunk)
 	if c.Tiles == nil {
 		c.populate(a.ChunkSize)
 	}
 	c := a.Chunks[chunk]
 	i := a.chunkTileIndex(local)
-	if object.Type != objects.None {
+	if object.Type != roveapi.Object_ObjectUnknown {
 		c.Objects[i] = object
 	} else {
 		delete(c.Objects, i)
@ -147,12 +136,12 @@ func (a *Atlas) setObject(chunk int, local vector.Vector, object objects.Object)
 }
 // worldSpaceToChunkLocal gets a chunk local coordinate for a tile
-func (a *Atlas) worldSpaceToChunkLocal(v vector.Vector) vector.Vector {
+func (a *chunkBasedAtlas) worldSpaceToChunkLocal(v maths.Vector) maths.Vector {
-	return vector.Vector{X: maths.Pmod(v.X, a.ChunkSize), Y: maths.Pmod(v.Y, a.ChunkSize)}
+	return maths.Vector{X: maths.Pmod(v.X, a.ChunkSize), Y: maths.Pmod(v.Y, a.ChunkSize)}
 }
 // worldSpaceToChunkID gets the current chunk ID for a position in the world
-func (a *Atlas) worldSpaceToChunkIndex(v vector.Vector) int {
+func (a *chunkBasedAtlas) worldSpaceToChunkIndex(v maths.Vector) int {
 	// Shift the vector by our current min
 	v = v.Added(a.LowerBound.Negated())
@ -168,13 +157,13 @@ func (a *Atlas) worldSpaceToChunkIndex(v vector.Vector) int {
 }
 // chunkOriginInWorldSpace returns the origin of the chunk in world space
-func (a *Atlas) chunkOriginInWorldSpace(chunk int) vector.Vector {
+func (a *chunkBasedAtlas) chunkOriginInWorldSpace(chunk int) maths.Vector {
 	// Calculate the width
 	width := a.UpperBound.X - a.LowerBound.X
 	widthInChunks := width / a.ChunkSize
 	// Reverse the along the corridor and up the stairs
-	v := vector.Vector{
+	v := maths.Vector{
 		X: chunk % widthInChunks,
 		Y: chunk / widthInChunks,
 	}
@ -185,15 +174,15 @@ func (a *Atlas) chunkOriginInWorldSpace(chunk int) vector.Vector {
 }
 // getNewBounds gets new lower and upper bounds for the world space given a vector
-func (a *Atlas) getNewBounds(v vector.Vector) (lower vector.Vector, upper vector.Vector) {
+func (a *chunkBasedAtlas) getNewBounds(v maths.Vector) (lower maths.Vector, upper maths.Vector) {
-	lower = vector.Min(v, a.LowerBound)
+	lower = maths.Min2(v, a.LowerBound)
-	upper = vector.Max(v.Added(vector.Vector{X: 1, Y: 1}), a.UpperBound)
+	upper = maths.Max2(v.Added(maths.Vector{X: 1, Y: 1}), a.UpperBound)
-	lower = vector.Vector{
+	lower = maths.Vector{
 		X: maths.RoundDown(lower.X, a.ChunkSize),
 		Y: maths.RoundDown(lower.Y, a.ChunkSize),
 	}
-	upper = vector.Vector{
+	upper = maths.Vector{
 		X: maths.RoundUp(upper.X, a.ChunkSize),
 		Y: maths.RoundUp(upper.Y, a.ChunkSize),
 	}
@ -201,7 +190,7 @@ func (a *Atlas) getNewBounds(v vector.Vector) (lower vector.Vector, upper vector
 }
 // worldSpaceToTrunkWithGrow will expand the current atlas for a given world space position if needed
-func (a *Atlas) worldSpaceToChunkWithGrow(v vector.Vector) int {
+func (a *chunkBasedAtlas) worldSpaceToChunkWithGrow(v maths.Vector) int {
 	// If we're within bounds, just return the current chunk
 	if v.X >= a.LowerBound.X && v.Y >= a.LowerBound.Y && v.X < a.UpperBound.X && v.Y < a.UpperBound.Y {
 		return a.worldSpaceToChunkIndex(v)
@ -213,11 +202,12 @@ func (a *Atlas) worldSpaceToChunkWithGrow(v vector.Vector) int {
 	size = size.Divided(a.ChunkSize)
 	// Create the new empty atlas
-	newAtlas := Atlas{
+	newAtlas := chunkBasedAtlas{
 		ChunkSize:  a.ChunkSize,
 		LowerBound: lower,
 		UpperBound: upper,
-		Chunks:     make([]Chunk, size.X*size.Y),
+		Chunks:     make([]chunk, size.X*size.Y),
 		worldGen:   a.worldGen,
 	}
 	// Log that we're resizing
--- a/pkg/rove/command_test.go
+++ b/pkg/rove/command_test.go
@ -0,0 +1,305 @@
 package rove
 import (
 	"encoding/json"
 	"testing"
 	"github.com/mdiluz/rove/pkg/maths"
 	"github.com/mdiluz/rove/proto/roveapi"
 	"github.com/stretchr/testify/assert"
 )
 func TestCommand_Invalid(t *testing.T) {
 	w := NewWorld(8)
 	name, err := w.SpawnRover("")
 	assert.NoError(t, err)
 	err = w.Enqueue(name, &roveapi.Command{Command: roveapi.CommandType_none})
 	assert.Error(t, err)
 }
 func TestCommand_Toggle(t *testing.T) {
 	w := NewWorld(8)
 	a, err := w.SpawnRover("")
 	assert.NoError(t, err)
 	r, err := w.GetRover(a)
 	assert.NoError(t, err)
 	assert.Equal(t, roveapi.SailPosition_SolarCharging, r.SailPosition)
 	err = w.Enqueue(a, &roveapi.Command{Command: roveapi.CommandType_toggle})
 	assert.NoError(t, err)
 	w.Tick()
 	r, err = w.GetRover(a)
 	assert.NoError(t, err)
 	assert.Equal(t, roveapi.SailPosition_CatchingWind, r.SailPosition)
 	err = w.Enqueue(a, &roveapi.Command{Command: roveapi.CommandType_toggle})
 	assert.NoError(t, err)
 	w.Tick()
 	r, err = w.GetRover(a)
 	assert.NoError(t, err)
 	assert.Equal(t, roveapi.SailPosition_SolarCharging, r.SailPosition)
 }
 func TestCommand_Turn(t *testing.T) {
 	w := NewWorld(8)
 	a, err := w.SpawnRover("")
 	assert.NoError(t, err)
 	err = w.Enqueue(a, &roveapi.Command{Command: roveapi.CommandType_turn, Bearing: roveapi.Bearing_NorthWest})
 	assert.NoError(t, err)
 	w.Tick()
 	r, err := w.GetRover(a)
 	assert.NoError(t, err)
 	assert.Equal(t, roveapi.Bearing_NorthWest, r.Bearing)
 }
 func TestCommand_Stash(t *testing.T) {
 	w := NewWorld(8)
 	name, err := w.SpawnRover("")
 	assert.NoError(t, err)
 	info, err := w.GetRover(name)
 	assert.NoError(t, err)
 	assert.Empty(t, info.Inventory)
 	// Drop a pickup below us
 	w.Atlas.SetObject(info.Pos, Object{Type: roveapi.Object_RockSmall})
 	// Try and stash it
 	err = w.Enqueue(name, &roveapi.Command{Command: roveapi.CommandType_stash})
 	assert.NoError(t, err)
 	w.Tick()
 	// Check we now have it in the inventory
 	info, err = w.GetRover(name)
 	assert.NoError(t, err)
 	assert.Equal(t, 1, len(info.Inventory))
 	assert.Equal(t, Object{Type: roveapi.Object_RockSmall}, info.Inventory[0])
 	// Check it's no longer on the atlas
 	_, obj := w.Atlas.QueryPosition(info.Pos)
 	assert.Equal(t, Object{Type: roveapi.Object_ObjectUnknown}, obj)
 }
 func TestCommand_Repair(t *testing.T) {
 	w := NewWorld(8)
 	name, err := w.SpawnRover("")
 	assert.NoError(t, err)
 	info, err := w.GetRover(name)
 	assert.NoError(t, err)
 	assert.Equal(t, info.MaximumIntegrity, info.Integrity)
 	// Put a blocking rock to the north
 	w.Atlas.SetObject(info.Pos.Added(maths.Vector{X: 0, Y: 1}), Object{Type: roveapi.Object_RockLarge})
 	// Try and move and make sure we're blocked
 	newpos, err := w.TryMoveRover(name, roveapi.Bearing_North)
 	assert.NoError(t, err)
 	assert.Equal(t, info.Pos, newpos)
 	// Check we're damaged
 	info, err = w.GetRover(name)
 	assert.NoError(t, err)
 	assert.Equal(t, info.MaximumIntegrity-1, info.Integrity)
 	// Stash a repair object
 	w.Atlas.SetObject(info.Pos, Object{Type: roveapi.Object_RoverParts})
 	obj, err := w.RoverStash(name)
 	assert.NoError(t, err)
 	assert.Equal(t, roveapi.Object_RoverParts, obj)
 	// Enqueue the repair and tick
 	err = w.Enqueue(name, &roveapi.Command{Command: roveapi.CommandType_repair})
 	assert.NoError(t, err)
 	w.Tick()
 	// Check we're repaired
 	info, err = w.GetRover(name)
 	assert.NoError(t, err)
 	assert.Equal(t, info.MaximumIntegrity, info.Integrity)
 	assert.Equal(t, 0, len(info.Inventory))
 }
 func TestCommand_Broadcast(t *testing.T) {
 	w := NewWorld(8)
 	name, err := w.SpawnRover("")
 	assert.NoError(t, err)
 	// Enqueue the broadcast and tick
 	err = w.Enqueue(name, &roveapi.Command{Command: roveapi.CommandType_broadcast, Data: []byte("ABC")})
 	assert.NoError(t, err)
 	w.Tick()
 	info, err := w.GetRover(name)
 	assert.NoError(t, err)
 	assert.Contains(t, info.Logs[len(info.Logs)-1].Text, "ABC")
 }
 func TestCommand_Salvage(t *testing.T) {
 	w := NewWorld(8)
 	name, err := w.SpawnRover("")
 	assert.NoError(t, err)
 	info, err := w.GetRover(name)
 	assert.NoError(t, err)
 	w.Atlas.SetObject(info.Pos, Object{Type: roveapi.Object_RoverDormant})
 	// Enqueue the broadcast and tick
 	err = w.Enqueue(name, &roveapi.Command{Command: roveapi.CommandType_salvage})
 	assert.NoError(t, err)
 	w.Tick()
 	// Check we now have some rover parts
 	info, err = w.GetRover(name)
 	assert.NoError(t, err)
 	assert.NotEmpty(t, info.Inventory)
 	for _, i := range info.Inventory {
 		assert.Equal(t, roveapi.Object_RoverParts, i.Type)
 	}
 	// Check the dormant rover is gone
 	_, obj := w.Atlas.QueryPosition(info.Pos)
 	assert.Equal(t, roveapi.Object_ObjectUnknown, obj.Type)
 }
 func TestCommand_Transfer(t *testing.T) {
 	w := NewWorld(8)
 	acc, err := w.Accountant.RegisterAccount("tmp")
 	assert.NoError(t, err)
 	nameA, err := w.SpawnRover(acc.Name)
 	assert.NoError(t, err)
 	infoA, err := w.GetRover(nameA)
 	assert.NoError(t, err)
 	// Drop a dormant rover on the current position
 	infoB := DefaultRover()
 	infoB.Name = "abc"
 	infoB.Pos = infoA.Pos
 	data, err := json.Marshal(infoB)
 	assert.NoError(t, err)
 	w.Atlas.SetObject(infoA.Pos, Object{Type: roveapi.Object_RoverDormant, Data: data})
 	// Enqueue a transfer as well as a dud command
 	err = w.Enqueue(nameA,
 		&roveapi.Command{Command: roveapi.CommandType_transfer},
 		&roveapi.Command{Command: roveapi.CommandType_broadcast, Data: []byte("xyz")})
 	assert.NoError(t, err)
 	w.Tick()
 	// Ensure both command queues are empty
 	assert.Empty(t, w.CommandQueue[nameA])
 	assert.Empty(t, w.CommandQueue[infoB.Name])
 	// Verify the account now controls the new rover
 	accountRover, err := w.Accountant.GetValue(acc.Name, "rover")
 	assert.NoError(t, err)
 	assert.Equal(t, infoB.Name, accountRover)
 	// Verify the position now has a dormant rover
 	_, obj := w.Atlas.QueryPosition(infoA.Pos)
 	assert.Equal(t, roveapi.Object_RoverDormant, obj.Type)
 	// Verify the stored data matches
 	var stored Rover
 	err = json.Unmarshal(obj.Data, &stored)
 	assert.NoError(t, err)
 	assert.Equal(t, infoA.Name, stored.Name)
 	// Verify the new rover data matches what we put in
 	infoB2, err := w.GetRover(infoB.Name)
 	assert.NoError(t, err)
 	assert.Equal(t, infoB.Name, infoB2.Name)
 }
 func TestCommand_Wait(t *testing.T) {
 	w := NewWorld(8)
 	a, err := w.SpawnRover("")
 	assert.NoError(t, err)
 	r, err := w.GetRover(a)
 	assert.NoError(t, err)
 	assert.Equal(t, roveapi.SailPosition_SolarCharging, r.SailPosition)
 	err = w.Enqueue(a, &roveapi.Command{Command: roveapi.CommandType_wait, Repeat: 4}, &roveapi.Command{Command: roveapi.CommandType_toggle})
 	assert.NoError(t, err)
 	// Tick 5 times during the wait (1 normal execute + 4)
 	for i := 0; i < 5; i++ {
 		w.Tick()
 		r, err = w.GetRover(a)
 		assert.NoError(t, err)
 		assert.Equal(t, roveapi.SailPosition_SolarCharging, r.SailPosition)
 	}
 	// One last tick to do the toggle
 	w.Tick()
 	r, err = w.GetRover(a)
 	assert.NoError(t, err)
 	assert.Equal(t, roveapi.SailPosition_CatchingWind, r.SailPosition)
 }
 func TestCommand_Upgrade(t *testing.T) {
 	w := NewWorld(8)
 	name, err := w.SpawnRover("")
 	assert.NoError(t, err)
 	rover, ok := w.Rovers[name]
 	assert.True(t, ok)
 	// Try an invalid upgrade
 	err = w.Enqueue(name, &roveapi.Command{Command: roveapi.CommandType_upgrade})
 	assert.Error(t, err)
 	// Try a valid command but without the parts
 	err = w.Enqueue(name, &roveapi.Command{Command: roveapi.CommandType_upgrade, Upgrade: roveapi.RoverUpgrade_Capacity})
 	assert.NoError(t, err)
 	// Ensure nothing changed and we logged the attempt
 	pre := rover.Capacity
 	w.Tick()
 	assert.Equal(t, pre, rover.Capacity)
 	assert.Contains(t, rover.Logs[len(rover.Logs)-1].Text, "tried")
 	// One non-part item
 	rover.Inventory = []Object{
 		{
 			Type: roveapi.Object_RoverParts,
 		},
 		{
 			Type: roveapi.Object_RoverParts,
 		},
 		{
 			Type: roveapi.Object_RockSmall,
 		},
 		{
 			Type: roveapi.Object_RoverParts,
 		},
 		{
 			Type: roveapi.Object_RoverParts,
 		},
 		{
 			Type: roveapi.Object_RoverParts,
 		},
 	}
 	// Try a valid command again
 	err = w.Enqueue(name, &roveapi.Command{Command: roveapi.CommandType_upgrade, Upgrade: roveapi.RoverUpgrade_Capacity})
 	assert.NoError(t, err)
 	// Check that the capacity increases on the tick and all the parts are used
 	pre = rover.Capacity
 	w.Tick()
 	assert.Equal(t, pre+1, rover.Capacity)
 	assert.Equal(t, 1, len(rover.Inventory))
 	assert.Equal(t, roveapi.Object_RockSmall, rover.Inventory[0].Type)
 }
--- a/pkg/rove/objects.go
+++ b/pkg/rove/objects.go
@ -0,0 +1,44 @@
 package rove
 import (
 	"github.com/mdiluz/rove/proto/roveapi"
 )
 // Object represents an object in the world
 type Object struct {
 	// The type of the object
 	Type roveapi.Object
 	// Data is an internal type used for certain types of object
 	Data []byte
 }
 // IsBlocking checks if an object is a blocking object
 func (o *Object) IsBlocking() bool {
 	var blocking = [...]roveapi.Object{
 		roveapi.Object_RoverLive,
 		roveapi.Object_RockLarge,
 	}
 	for _, t := range blocking {
 		if o.Type == t {
 			return true
 		}
 	}
 	return false
 }
 // IsStashable checks if an object is stashable
 func (o *Object) IsStashable() bool {
 	var stashable = [...]roveapi.Object{
 		roveapi.Object_RockSmall,
 		roveapi.Object_RoverParts,
 	}
 	for _, t := range stashable {
 		if o.Type == t {
 			return true
 		}
 	}
 	return false
 }
--- a/pkg/rove/rove.pb.go
+++ b/pkg/rove/rove.pb.go
--- a/pkg/rove/rove.pb.gw.go
+++ b/pkg/rove/rove.pb.gw.go
@ -1,459 +0,0 @@
 // Code generated by protoc-gen-grpc-gateway. DO NOT EDIT.
 // source: rove/rove.proto
 /*
 Package rove is a reverse proxy.
 It translates gRPC into RESTful JSON APIs.
 */
 package rove
 import (
 	"context"
 	"io"
 	"net/http"
 	"github.com/golang/protobuf/descriptor"
 	"github.com/golang/protobuf/proto"
 	"github.com/grpc-ecosystem/grpc-gateway/runtime"
 	"github.com/grpc-ecosystem/grpc-gateway/utilities"
 	"google.golang.org/grpc"
 	"google.golang.org/grpc/codes"
 	"google.golang.org/grpc/grpclog"
 	"google.golang.org/grpc/status"
 )
 // Suppress "imported and not used" errors
 var _ codes.Code
 var _ io.Reader
 var _ status.Status
 var _ = runtime.String
 var _ = utilities.NewDoubleArray
 var _ = descriptor.ForMessage
 func request_Rove_ServerStatus_0(ctx context.Context, marshaler runtime.Marshaler, client RoveClient, req *http.Request, pathParams map[string]string) (proto.Message, runtime.ServerMetadata, error) {
 	var protoReq ServerStatusRequest
 	var metadata runtime.ServerMetadata
 	msg, err := client.ServerStatus(ctx, &protoReq, grpc.Header(&metadata.HeaderMD), grpc.Trailer(&metadata.TrailerMD))
 	return msg, metadata, err
 }
 func local_request_Rove_ServerStatus_0(ctx context.Context, marshaler runtime.Marshaler, server RoveServer, req *http.Request, pathParams map[string]string) (proto.Message, runtime.ServerMetadata, error) {
 	var protoReq ServerStatusRequest
 	var metadata runtime.ServerMetadata
 	msg, err := server.ServerStatus(ctx, &protoReq)
 	return msg, metadata, err
 }
 func request_Rove_Register_0(ctx context.Context, marshaler runtime.Marshaler, client RoveClient, req *http.Request, pathParams map[string]string) (proto.Message, runtime.ServerMetadata, error) {
 	var protoReq RegisterRequest
 	var metadata runtime.ServerMetadata
 	newReader, berr := utilities.IOReaderFactory(req.Body)
 	if berr != nil {
 		return nil, metadata, status.Errorf(codes.InvalidArgument, "%v", berr)
 	}
 	if err := marshaler.NewDecoder(newReader()).Decode(&protoReq); err != nil && err != io.EOF {
 		return nil, metadata, status.Errorf(codes.InvalidArgument, "%v", err)
 	}
 	msg, err := client.Register(ctx, &protoReq, grpc.Header(&metadata.HeaderMD), grpc.Trailer(&metadata.TrailerMD))
 	return msg, metadata, err
 }
 func local_request_Rove_Register_0(ctx context.Context, marshaler runtime.Marshaler, server RoveServer, req *http.Request, pathParams map[string]string) (proto.Message, runtime.ServerMetadata, error) {
 	var protoReq RegisterRequest
 	var metadata runtime.ServerMetadata
 	newReader, berr := utilities.IOReaderFactory(req.Body)
 	if berr != nil {
 		return nil, metadata, status.Errorf(codes.InvalidArgument, "%v", berr)
 	}
 	if err := marshaler.NewDecoder(newReader()).Decode(&protoReq); err != nil && err != io.EOF {
 		return nil, metadata, status.Errorf(codes.InvalidArgument, "%v", err)
 	}
 	msg, err := server.Register(ctx, &protoReq)
 	return msg, metadata, err
 }
 func request_Rove_Command_0(ctx context.Context, marshaler runtime.Marshaler, client RoveClient, req *http.Request, pathParams map[string]string) (proto.Message, runtime.ServerMetadata, error) {
 	var protoReq CommandRequest
 	var metadata runtime.ServerMetadata
 	newReader, berr := utilities.IOReaderFactory(req.Body)
 	if berr != nil {
 		return nil, metadata, status.Errorf(codes.InvalidArgument, "%v", berr)
 	}
 	if err := marshaler.NewDecoder(newReader()).Decode(&protoReq); err != nil && err != io.EOF {
 		return nil, metadata, status.Errorf(codes.InvalidArgument, "%v", err)
 	}
 	msg, err := client.Command(ctx, &protoReq, grpc.Header(&metadata.HeaderMD), grpc.Trailer(&metadata.TrailerMD))
 	return msg, metadata, err
 }
 func local_request_Rove_Command_0(ctx context.Context, marshaler runtime.Marshaler, server RoveServer, req *http.Request, pathParams map[string]string) (proto.Message, runtime.ServerMetadata, error) {
 	var protoReq CommandRequest
 	var metadata runtime.ServerMetadata
 	newReader, berr := utilities.IOReaderFactory(req.Body)
 	if berr != nil {
 		return nil, metadata, status.Errorf(codes.InvalidArgument, "%v", berr)
 	}
 	if err := marshaler.NewDecoder(newReader()).Decode(&protoReq); err != nil && err != io.EOF {
 		return nil, metadata, status.Errorf(codes.InvalidArgument, "%v", err)
 	}
 	msg, err := server.Command(ctx, &protoReq)
 	return msg, metadata, err
 }
 func request_Rove_Radar_0(ctx context.Context, marshaler runtime.Marshaler, client RoveClient, req *http.Request, pathParams map[string]string) (proto.Message, runtime.ServerMetadata, error) {
 	var protoReq RadarRequest
 	var metadata runtime.ServerMetadata
 	newReader, berr := utilities.IOReaderFactory(req.Body)
 	if berr != nil {
 		return nil, metadata, status.Errorf(codes.InvalidArgument, "%v", berr)
 	}
 	if err := marshaler.NewDecoder(newReader()).Decode(&protoReq); err != nil && err != io.EOF {
 		return nil, metadata, status.Errorf(codes.InvalidArgument, "%v", err)
 	}
 	msg, err := client.Radar(ctx, &protoReq, grpc.Header(&metadata.HeaderMD), grpc.Trailer(&metadata.TrailerMD))
 	return msg, metadata, err
 }
 func local_request_Rove_Radar_0(ctx context.Context, marshaler runtime.Marshaler, server RoveServer, req *http.Request, pathParams map[string]string) (proto.Message, runtime.ServerMetadata, error) {
 	var protoReq RadarRequest
 	var metadata runtime.ServerMetadata
 	newReader, berr := utilities.IOReaderFactory(req.Body)
 	if berr != nil {
 		return nil, metadata, status.Errorf(codes.InvalidArgument, "%v", berr)
 	}
 	if err := marshaler.NewDecoder(newReader()).Decode(&protoReq); err != nil && err != io.EOF {
 		return nil, metadata, status.Errorf(codes.InvalidArgument, "%v", err)
 	}
 	msg, err := server.Radar(ctx, &protoReq)
 	return msg, metadata, err
 }
 func request_Rove_Status_0(ctx context.Context, marshaler runtime.Marshaler, client RoveClient, req *http.Request, pathParams map[string]string) (proto.Message, runtime.ServerMetadata, error) {
 	var protoReq StatusRequest
 	var metadata runtime.ServerMetadata
 	newReader, berr := utilities.IOReaderFactory(req.Body)
 	if berr != nil {
 		return nil, metadata, status.Errorf(codes.InvalidArgument, "%v", berr)
 	}
 	if err := marshaler.NewDecoder(newReader()).Decode(&protoReq); err != nil && err != io.EOF {
 		return nil, metadata, status.Errorf(codes.InvalidArgument, "%v", err)
 	}
 	msg, err := client.Status(ctx, &protoReq, grpc.Header(&metadata.HeaderMD), grpc.Trailer(&metadata.TrailerMD))
 	return msg, metadata, err
 }
 func local_request_Rove_Status_0(ctx context.Context, marshaler runtime.Marshaler, server RoveServer, req *http.Request, pathParams map[string]string) (proto.Message, runtime.ServerMetadata, error) {
 	var protoReq StatusRequest
 	var metadata runtime.ServerMetadata
 	newReader, berr := utilities.IOReaderFactory(req.Body)
 	if berr != nil {
 		return nil, metadata, status.Errorf(codes.InvalidArgument, "%v", berr)
 	}
 	if err := marshaler.NewDecoder(newReader()).Decode(&protoReq); err != nil && err != io.EOF {
 		return nil, metadata, status.Errorf(codes.InvalidArgument, "%v", err)
 	}
 	msg, err := server.Status(ctx, &protoReq)
 	return msg, metadata, err
 }
 // RegisterRoveHandlerServer registers the http handlers for service Rove to "mux".
 // UnaryRPC     :call RoveServer directly.
 // StreamingRPC :currently unsupported pending https://github.com/grpc/grpc-go/issues/906.
 func RegisterRoveHandlerServer(ctx context.Context, mux *runtime.ServeMux, server RoveServer) error {
 	mux.Handle("GET", pattern_Rove_ServerStatus_0, func(w http.ResponseWriter, req *http.Request, pathParams map[string]string) {
 		ctx, cancel := context.WithCancel(req.Context())
 		defer cancel()
 		inboundMarshaler, outboundMarshaler := runtime.MarshalerForRequest(mux, req)
 		rctx, err := runtime.AnnotateIncomingContext(ctx, mux, req)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		resp, md, err := local_request_Rove_ServerStatus_0(rctx, inboundMarshaler, server, req, pathParams)
 		ctx = runtime.NewServerMetadataContext(ctx, md)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		forward_Rove_ServerStatus_0(ctx, mux, outboundMarshaler, w, req, resp, mux.GetForwardResponseOptions()...)
 	})
 	mux.Handle("POST", pattern_Rove_Register_0, func(w http.ResponseWriter, req *http.Request, pathParams map[string]string) {
 		ctx, cancel := context.WithCancel(req.Context())
 		defer cancel()
 		inboundMarshaler, outboundMarshaler := runtime.MarshalerForRequest(mux, req)
 		rctx, err := runtime.AnnotateIncomingContext(ctx, mux, req)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		resp, md, err := local_request_Rove_Register_0(rctx, inboundMarshaler, server, req, pathParams)
 		ctx = runtime.NewServerMetadataContext(ctx, md)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		forward_Rove_Register_0(ctx, mux, outboundMarshaler, w, req, resp, mux.GetForwardResponseOptions()...)
 	})
 	mux.Handle("POST", pattern_Rove_Command_0, func(w http.ResponseWriter, req *http.Request, pathParams map[string]string) {
 		ctx, cancel := context.WithCancel(req.Context())
 		defer cancel()
 		inboundMarshaler, outboundMarshaler := runtime.MarshalerForRequest(mux, req)
 		rctx, err := runtime.AnnotateIncomingContext(ctx, mux, req)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		resp, md, err := local_request_Rove_Command_0(rctx, inboundMarshaler, server, req, pathParams)
 		ctx = runtime.NewServerMetadataContext(ctx, md)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		forward_Rove_Command_0(ctx, mux, outboundMarshaler, w, req, resp, mux.GetForwardResponseOptions()...)
 	})
 	mux.Handle("POST", pattern_Rove_Radar_0, func(w http.ResponseWriter, req *http.Request, pathParams map[string]string) {
 		ctx, cancel := context.WithCancel(req.Context())
 		defer cancel()
 		inboundMarshaler, outboundMarshaler := runtime.MarshalerForRequest(mux, req)
 		rctx, err := runtime.AnnotateIncomingContext(ctx, mux, req)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		resp, md, err := local_request_Rove_Radar_0(rctx, inboundMarshaler, server, req, pathParams)
 		ctx = runtime.NewServerMetadataContext(ctx, md)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		forward_Rove_Radar_0(ctx, mux, outboundMarshaler, w, req, resp, mux.GetForwardResponseOptions()...)
 	})
 	mux.Handle("POST", pattern_Rove_Status_0, func(w http.ResponseWriter, req *http.Request, pathParams map[string]string) {
 		ctx, cancel := context.WithCancel(req.Context())
 		defer cancel()
 		inboundMarshaler, outboundMarshaler := runtime.MarshalerForRequest(mux, req)
 		rctx, err := runtime.AnnotateIncomingContext(ctx, mux, req)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		resp, md, err := local_request_Rove_Status_0(rctx, inboundMarshaler, server, req, pathParams)
 		ctx = runtime.NewServerMetadataContext(ctx, md)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		forward_Rove_Status_0(ctx, mux, outboundMarshaler, w, req, resp, mux.GetForwardResponseOptions()...)
 	})
 	return nil
 }
 // RegisterRoveHandlerFromEndpoint is same as RegisterRoveHandler but
 // automatically dials to "endpoint" and closes the connection when "ctx" gets done.
 func RegisterRoveHandlerFromEndpoint(ctx context.Context, mux *runtime.ServeMux, endpoint string, opts []grpc.DialOption) (err error) {
 	conn, err := grpc.Dial(endpoint, opts...)
 	if err != nil {
 		return err
 	}
 	defer func() {
 		if err != nil {
 			if cerr := conn.Close(); cerr != nil {
 				grpclog.Infof("Failed to close conn to %s: %v", endpoint, cerr)
 			}
 			return
 		}
 		go func() {
 			<-ctx.Done()
 			if cerr := conn.Close(); cerr != nil {
 				grpclog.Infof("Failed to close conn to %s: %v", endpoint, cerr)
 			}
 		}()
 	}()
 	return RegisterRoveHandler(ctx, mux, conn)
 }
 // RegisterRoveHandler registers the http handlers for service Rove to "mux".
 // The handlers forward requests to the grpc endpoint over "conn".
 func RegisterRoveHandler(ctx context.Context, mux *runtime.ServeMux, conn *grpc.ClientConn) error {
 	return RegisterRoveHandlerClient(ctx, mux, NewRoveClient(conn))
 }
 // RegisterRoveHandlerClient registers the http handlers for service Rove
 // to "mux". The handlers forward requests to the grpc endpoint over the given implementation of "RoveClient".
 // Note: the gRPC framework executes interceptors within the gRPC handler. If the passed in "RoveClient"
 // doesn't go through the normal gRPC flow (creating a gRPC client etc.) then it will be up to the passed in
 // "RoveClient" to call the correct interceptors.
 func RegisterRoveHandlerClient(ctx context.Context, mux *runtime.ServeMux, client RoveClient) error {
 	mux.Handle("GET", pattern_Rove_ServerStatus_0, func(w http.ResponseWriter, req *http.Request, pathParams map[string]string) {
 		ctx, cancel := context.WithCancel(req.Context())
 		defer cancel()
 		inboundMarshaler, outboundMarshaler := runtime.MarshalerForRequest(mux, req)
 		rctx, err := runtime.AnnotateContext(ctx, mux, req)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		resp, md, err := request_Rove_ServerStatus_0(rctx, inboundMarshaler, client, req, pathParams)
 		ctx = runtime.NewServerMetadataContext(ctx, md)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		forward_Rove_ServerStatus_0(ctx, mux, outboundMarshaler, w, req, resp, mux.GetForwardResponseOptions()...)
 	})
 	mux.Handle("POST", pattern_Rove_Register_0, func(w http.ResponseWriter, req *http.Request, pathParams map[string]string) {
 		ctx, cancel := context.WithCancel(req.Context())
 		defer cancel()
 		inboundMarshaler, outboundMarshaler := runtime.MarshalerForRequest(mux, req)
 		rctx, err := runtime.AnnotateContext(ctx, mux, req)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		resp, md, err := request_Rove_Register_0(rctx, inboundMarshaler, client, req, pathParams)
 		ctx = runtime.NewServerMetadataContext(ctx, md)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		forward_Rove_Register_0(ctx, mux, outboundMarshaler, w, req, resp, mux.GetForwardResponseOptions()...)
 	})
 	mux.Handle("POST", pattern_Rove_Command_0, func(w http.ResponseWriter, req *http.Request, pathParams map[string]string) {
 		ctx, cancel := context.WithCancel(req.Context())
 		defer cancel()
 		inboundMarshaler, outboundMarshaler := runtime.MarshalerForRequest(mux, req)
 		rctx, err := runtime.AnnotateContext(ctx, mux, req)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		resp, md, err := request_Rove_Command_0(rctx, inboundMarshaler, client, req, pathParams)
 		ctx = runtime.NewServerMetadataContext(ctx, md)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		forward_Rove_Command_0(ctx, mux, outboundMarshaler, w, req, resp, mux.GetForwardResponseOptions()...)
 	})
 	mux.Handle("POST", pattern_Rove_Radar_0, func(w http.ResponseWriter, req *http.Request, pathParams map[string]string) {
 		ctx, cancel := context.WithCancel(req.Context())
 		defer cancel()
 		inboundMarshaler, outboundMarshaler := runtime.MarshalerForRequest(mux, req)
 		rctx, err := runtime.AnnotateContext(ctx, mux, req)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		resp, md, err := request_Rove_Radar_0(rctx, inboundMarshaler, client, req, pathParams)
 		ctx = runtime.NewServerMetadataContext(ctx, md)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		forward_Rove_Radar_0(ctx, mux, outboundMarshaler, w, req, resp, mux.GetForwardResponseOptions()...)
 	})
 	mux.Handle("POST", pattern_Rove_Status_0, func(w http.ResponseWriter, req *http.Request, pathParams map[string]string) {
 		ctx, cancel := context.WithCancel(req.Context())
 		defer cancel()
 		inboundMarshaler, outboundMarshaler := runtime.MarshalerForRequest(mux, req)
 		rctx, err := runtime.AnnotateContext(ctx, mux, req)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		resp, md, err := request_Rove_Status_0(rctx, inboundMarshaler, client, req, pathParams)
 		ctx = runtime.NewServerMetadataContext(ctx, md)
 		if err != nil {
 			runtime.HTTPError(ctx, mux, outboundMarshaler, w, req, err)
 			return
 		}
 		forward_Rove_Status_0(ctx, mux, outboundMarshaler, w, req, resp, mux.GetForwardResponseOptions()...)
 	})
 	return nil
 }
 var (
 	pattern_Rove_ServerStatus_0 = runtime.MustPattern(runtime.NewPattern(1, []int{2, 0}, []string{"server-status"}, "", runtime.AssumeColonVerbOpt(true)))
 	pattern_Rove_Register_0 = runtime.MustPattern(runtime.NewPattern(1, []int{2, 0}, []string{"register"}, "", runtime.AssumeColonVerbOpt(true)))
 	pattern_Rove_Command_0 = runtime.MustPattern(runtime.NewPattern(1, []int{2, 0}, []string{"command"}, "", runtime.AssumeColonVerbOpt(true)))
 	pattern_Rove_Radar_0 = runtime.MustPattern(runtime.NewPattern(1, []int{2, 0}, []string{"radar"}, "", runtime.AssumeColonVerbOpt(true)))
 	pattern_Rove_Status_0 = runtime.MustPattern(runtime.NewPattern(1, []int{2, 0}, []string{"status"}, "", runtime.AssumeColonVerbOpt(true)))
 )
 var (
 	forward_Rove_ServerStatus_0 = runtime.ForwardResponseMessage
 	forward_Rove_Register_0 = runtime.ForwardResponseMessage
 	forward_Rove_Command_0 = runtime.ForwardResponseMessage
 	forward_Rove_Radar_0 = runtime.ForwardResponseMessage
 	forward_Rove_Status_0 = runtime.ForwardResponseMessage
 )
--- a/pkg/rove/rove.swagger.json
+++ b/pkg/rove/rove.swagger.json
@ -1,415 +0,0 @@
 {
  "swagger": "2.0",
  "info": {
    "title": "Rove",
    "description": "Rove is an asychronous nomadic game about exploring a planet as part of a loose community",
    "version": "version not set"
  },
  "consumes": [
    "application/json"
  ],
  "produces": [
    "application/json"
  ],
  "paths": {
    "/command": {
      "post": {
        "summary": "Send commands to rover",
        "description": "Sending commands to this endpoint will queue them to be executed during the following ticks, in the order sent",
        "operationId": "Rove_Command",
        "responses": {
          "200": {
            "description": "A successful response.",
            "schema": {
              "$ref": "#/definitions/roveCommandResponse"
            }
          },
          "default": {
            "description": "An unexpected error response",
            "schema": {
              "$ref": "#/definitions/gatewayruntimeError"
            }
          }
        },
        "parameters": [
          {
            "name": "body",
            "in": "body",
            "required": true,
            "schema": {
              "$ref": "#/definitions/roveCommandRequest"
            }
          }
        ],
        "tags": [
          "Rove"
        ]
      }
    },
    "/radar": {
      "post": {
        "summary": "Get radar information",
        "description": "Gets the radar output for the given rover",
        "operationId": "Rove_Radar",
        "responses": {
          "200": {
            "description": "A successful response.",
            "schema": {
              "$ref": "#/definitions/roveRadarResponse"
            }
          },
          "default": {
            "description": "An unexpected error response",
            "schema": {
              "$ref": "#/definitions/gatewayruntimeError"
            }
          }
        },
        "parameters": [
          {
            "name": "body",
            "in": "body",
            "required": true,
            "schema": {
              "$ref": "#/definitions/roveRadarRequest"
            }
          }
        ],
        "tags": [
          "Rove"
        ]
      }
    },
    "/register": {
      "post": {
        "summary": "Register an account",
        "description": "Tries to register an account with the given name",
        "operationId": "Rove_Register",
        "responses": {
          "200": {
            "description": "A successful response.",
            "schema": {
              "$ref": "#/definitions/roveRegisterResponse"
            }
          },
          "default": {
            "description": "An unexpected error response",
            "schema": {
              "$ref": "#/definitions/gatewayruntimeError"
            }
          }
        },
        "parameters": [
          {
            "name": "body",
            "in": "body",
            "required": true,
            "schema": {
              "$ref": "#/definitions/roveRegisterRequest"
            }
          }
        ],
        "tags": [
          "Rove"
        ]
      }
    },
    "/server-status": {
      "get": {
        "summary": "Server status",
        "description": "Responds with various details about the current server status",
        "operationId": "Rove_ServerStatus",
        "responses": {
          "200": {
            "description": "A successful response.",
            "schema": {
              "$ref": "#/definitions/roveServerStatusResponse"
            }
          },
          "default": {
            "description": "An unexpected error response",
            "schema": {
              "$ref": "#/definitions/gatewayruntimeError"
            }
          }
        },
        "tags": [
          "Rove"
        ]
      }
    },
    "/status": {
      "post": {
        "summary": "Get rover information",
        "description": "Gets information for the account's rover",
        "operationId": "Rove_Status",
        "responses": {
          "200": {
            "description": "A successful response.",
            "schema": {
              "$ref": "#/definitions/roveStatusResponse"
            }
          },
          "default": {
            "description": "An unexpected error response",
            "schema": {
              "$ref": "#/definitions/gatewayruntimeError"
            }
          }
        },
        "parameters": [
          {
            "name": "body",
            "in": "body",
            "required": true,
            "schema": {
              "$ref": "#/definitions/roveStatusRequest"
            }
          }
        ],
        "tags": [
          "Rove"
        ]
      }
    }
  },
  "definitions": {
    "gatewayruntimeError": {
      "type": "object",
      "properties": {
        "error": {
          "type": "string"
        },
        "code": {
          "type": "integer",
          "format": "int32"
        },
        "message": {
          "type": "string"
        },
        "details": {
          "type": "array",
          "items": {
            "$ref": "#/definitions/protobufAny"
          }
        }
      }
    },
    "protobufAny": {
      "type": "object",
      "properties": {
        "type_url": {
          "type": "string"
        },
        "value": {
          "type": "string",
          "format": "byte"
        }
      }
    },
    "roveAccount": {
      "type": "object",
      "properties": {
        "name": {
          "type": "string"
        },
        "secret": {
          "type": "string"
        }
      }
    },
    "roveCommand": {
      "type": "object",
      "properties": {
        "command": {
          "type": "string",
          "title": "The command to execute\n\"move\" - Move the rover in a direction, requires bearing\n\"stash\" - Stashes item at current location in rover inventory\n\"repair\" - Repairs the rover using an inventory object\n\"recharge\" - Waits a tick to add more charge to the rover"
        },
        "bearing": {
          "type": "string",
          "title": "The bearing, example: NE"
        }
      }
    },
    "roveCommandRequest": {
      "type": "object",
      "properties": {
        "account": {
          "$ref": "#/definitions/roveAccount",
          "title": "The account to execute these commands"
        },
        "commands": {
          "type": "array",
          "items": {
            "$ref": "#/definitions/roveCommand"
          },
          "title": "The set of desired commands"
        }
      }
    },
    "roveCommandResponse": {
      "type": "object",
      "title": "Empty placeholder"
    },
    "roveRadarRequest": {
      "type": "object",
      "properties": {
        "account": {
          "$ref": "#/definitions/roveAccount",
          "title": "The account for this request"
        }
      }
    },
    "roveRadarResponse": {
      "type": "object",
      "properties": {
        "range": {
          "type": "integer",
          "format": "int32",
          "title": "The range in tiles from the rover of the radar data"
        },
        "tiles": {
          "type": "string",
          "format": "byte",
          "title": "A 1D array representing range*2 + 1 squared set of tiles, origin bottom left and in row-\u003ecolumn order"
        },
        "objects": {
          "type": "string",
          "format": "byte",
          "title": "A similar array to the tile array, but containing objects"
        }
      }
    },
    "roveRegisterRequest": {
      "type": "object",
      "properties": {
        "name": {
          "type": "string",
          "title": "The desired account name"
        }
      }
    },
    "roveRegisterResponse": {
      "type": "object",
      "properties": {
        "account": {
          "$ref": "#/definitions/roveAccount",
          "title": "The registered account information"
        }
      },
      "title": "Empty placeholder"
    },
    "roveServerStatusResponse": {
      "type": "object",
      "properties": {
        "version": {
          "type": "string",
          "title": "The version of the server in v{major}.{minor}-{delta}-{sha} form"
        },
        "ready": {
          "type": "boolean",
          "format": "boolean",
          "title": "Whether the server is ready to accept requests"
        },
        "tickRate": {
          "type": "integer",
          "format": "int32",
          "title": "The tick rate of the server in minutes (how many minutes per tick)"
        },
        "currentTick": {
          "type": "integer",
          "format": "int32",
          "title": "The current tick of the server"
        },
        "next_tick": {
          "type": "string",
          "title": "The time the next tick will occur"
        }
      }
    },
    "roveStatusRequest": {
      "type": "object",
      "properties": {
        "account": {
          "$ref": "#/definitions/roveAccount",
          "title": "The account for this request"
        }
      }
    },
    "roveStatusResponse": {
      "type": "object",
      "properties": {
        "name": {
          "type": "string",
          "title": "The name of the rover"
        },
        "position": {
          "$ref": "#/definitions/roveVector",
          "title": "Position of the rover in world coordinates"
        },
        "range": {
          "type": "integer",
          "format": "int32",
          "title": "The range of this rover's radar"
        },
        "inventory": {
          "type": "string",
          "format": "byte",
          "title": "The items in the rover inventory"
        },
        "capacity": {
          "type": "integer",
          "format": "int32",
          "title": "The capacity of the inventory"
        },
        "integrity": {
          "type": "integer",
          "format": "int32",
          "title": "The current health of the rover"
        },
        "maximumIntegrity": {
          "type": "integer",
          "format": "int32",
          "title": "The maximum health of the rover"
        },
        "charge": {
          "type": "integer",
          "format": "int32",
          "title": "The energy stored in the rover"
        },
        "maximumCharge": {
          "type": "integer",
          "format": "int32",
          "title": "The max energy the rover can store"
        },
        "incomingCommands": {
          "type": "array",
          "items": {
            "$ref": "#/definitions/roveCommand"
          },
          "title": "The set of currently incoming commands for this tick"
        },
        "queuedCommands": {
          "type": "array",
          "items": {
            "$ref": "#/definitions/roveCommand"
          },
          "title": "The set of currently queued commands"
        }
      }
    },
    "roveVector": {
      "type": "object",
      "properties": {
        "x": {
          "type": "integer",
          "format": "int32"
        },
        "y": {
          "type": "integer",
          "format": "int32"
        }
      }
    }
  }
 }
--- a/pkg/rove/rover.go
+++ b/pkg/rove/rover.go
@ -0,0 +1,137 @@
 package rove
 import (
 	"bufio"
 	"fmt"
 	"log"
 	"math/rand"
 	"os"
 	"time"
 	"github.com/google/uuid"
 	"github.com/mdiluz/rove/pkg/maths"
 	"github.com/mdiluz/rove/proto/roveapi"
 )
 const (
 	maxLogEntries = 16
 )
 // RoverLogEntry describes a single log entry for the rover
 type RoverLogEntry struct {
 	// Time is the timestamp of the entry
 	Time time.Time
 	// Text contains the information in this log entry
 	Text string
 }
 // Rover describes a single rover in the world
 type Rover struct {
 	// Unique name of this rover
 	Name string
 	// Pos represents where this rover is in the world
 	Pos maths.Vector
 	// Bearing is the current direction the rover is facing
 	Bearing roveapi.Bearing
 	// Range represents the distance the unit's radar can see
 	Range int
 	// Inventory represents any items the rover is carrying
 	Inventory []Object
 	// Capacity is the maximum number of inventory items
 	Capacity int
 	// Integrity represents current rover health
 	Integrity int
 	// MaximumIntegrity is the full integrity of the rover
 	MaximumIntegrity int
 	// Charge is the amount of energy the rover has
 	Charge int
 	// MaximumCharge is the maximum charge able to be stored
 	MaximumCharge int
 	// SailPosition is the current position of the sails
 	SailPosition roveapi.SailPosition
 	// Current number of ticks in this move, used for sailing speeds
 	MoveTicks int
 	// Logs Stores log of information
 	Logs []RoverLogEntry
 	// The account that owns this rover
 	Owner string
 }
 // DefaultRover returns a default rover object with default settings
 func DefaultRover() *Rover {
 	return &Rover{
 		Range:            10,
 		Integrity:        10,
 		MaximumIntegrity: 10,
 		Capacity:         10,
 		Charge:           10,
 		MaximumCharge:    10,
 		Bearing:          roveapi.Bearing_North,
 		SailPosition:     roveapi.SailPosition_SolarCharging,
 		Name:             GenerateRoverName(),
 	}
 }
 // AddLogEntryf adds an entry to the rovers log
 func (r *Rover) AddLogEntryf(format string, args ...interface{}) {
 	text := fmt.Sprintf(format, args...)
 	log.Printf("%s log entry: %s", r.Name, text)
 	r.Logs = append(r.Logs,
 		RoverLogEntry{
 			Time: time.Now(),
 			Text: text,
 		},
 	)
 	// Limit the number of logs
 	if len(r.Logs) > maxLogEntries {
 		r.Logs = r.Logs[len(r.Logs)-maxLogEntries:]
 	}
 }
 var wordsFile = os.Getenv("WORDS_FILE")
 var roverWords []string
 // GenerateRoverName generates a new rover name
 func GenerateRoverName() string {
 	// Try and load the rover words file
 	if len(roverWords) == 0 {
 		// Try and load the words file
 		if file, err := os.Open(wordsFile); err != nil {
 			log.Printf("Couldn't read words file [%s], running without words: %s\n", wordsFile, err)
 		} else {
 			defer file.Close()
 			scanner := bufio.NewScanner(file)
 			for scanner.Scan() {
 				roverWords = append(roverWords, scanner.Text())
 			}
 			if scanner.Err() != nil {
 				log.Printf("Failure during word file scan: %s\n", scanner.Err())
 			}
 		}
 	}
 	// Assign a random name if we have words
 	if len(roverWords) > 0 {
 		// Loop until we find a unique name
 		return fmt.Sprintf("%s-%s", roverWords[rand.Intn(len(roverWords))], roverWords[rand.Intn(len(roverWords))])
 	}
 	// Default to a unique string
 	return uuid.New().String()
 }
--- a/pkg/rove/world.go
+++ b/pkg/rove/world.go
@ -0,0 +1,840 @@
 package rove
 import (
 	"encoding/json"
 	"fmt"
 	"log"
 	"math/rand"
 	"sync"
 	"github.com/mdiluz/rove/pkg/accounts"
 	"github.com/mdiluz/rove/pkg/maths"
 	"github.com/mdiluz/rove/proto/roveapi"
 )
 const (
 	// ticksPerNormalMove defines the number of ticks it should take for a "normal" speed move
 	ticksPerNormalMove = 4
 	// upgradeCost is the cost in rover parts needed to upgrade a rover specification
 	upgradeCost = 5
 )
 // CommandStream is a list of commands to execute in order
 type CommandStream []*roveapi.Command
 // World describes a self contained universe and everything in it
 type World struct {
 	// TicksPerDay is the amount of ticks in a single day
 	TicksPerDay int
 	// Current number of ticks from the start
 	CurrentTicks int
 	// Rovers is a id->data map of all the rovers in the game
 	Rovers map[string]*Rover
 	// Atlas represends the world map of chunks and tiles
 	Atlas Atlas
 	// Wind is the current wind direction
 	Wind roveapi.Bearing
 	// Commands is the set of currently executing command streams per rover
 	CommandQueue map[string]CommandStream
 	// Accountant
 	Accountant accounts.Accountant
 	// Mutex to lock around all world operations
 	worldMutex sync.RWMutex
 	// Mutex to lock around command operations
 	cmdMutex sync.RWMutex
 }
 // NewWorld creates a new world object
 func NewWorld(chunkSize int) *World {
 	return &World{
 		Rovers:       make(map[string]*Rover),
 		CommandQueue: make(map[string]CommandStream),
 		Atlas:        NewChunkAtlas(chunkSize),
 		TicksPerDay:  24,
 		CurrentTicks: 0,
 		Accountant:   accounts.NewSimpleAccountant(),
 		Wind:         roveapi.Bearing_North,
 	}
 }
 // SpawnRover adds an rover to the game (without lock)
 func (w *World) SpawnRover(account string) (string, error) {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	// Initialise the rover
 	rover := DefaultRover()
 	// Assign the owner
 	rover.Owner = account
 	// Spawn in a random place near the origin
 	rover.Pos = maths.Vector{
 		X: 10 - rand.Intn(20),
 		Y: 10 - rand.Intn(20),
 	}
 	// Seach until we error (run out of world)
 	for {
 		_, obj := w.Atlas.QueryPosition(rover.Pos)
 		if !obj.IsBlocking() {
 			break
 		} else {
 			// Try and spawn to the east of the blockage
 			rover.Pos.Add(maths.Vector{X: 1, Y: 0})
 		}
 	}
 	// Add a log entry for robot creation
 	rover.AddLogEntryf("created at %+v", rover.Pos)
 	// Append the rover to the list
 	w.Rovers[rover.Name] = rover
 	var err error
 	// Only assign if we've been given an account
 	if len(account) > 0 {
 		err = w.Accountant.AssignData(account, "rover", rover.Name)
 	}
 	return rover.Name, err
 }
 // GetRover gets a specific rover by name
 func (w *World) GetRover(rover string) (Rover, error) {
 	w.worldMutex.RLock()
 	defer w.worldMutex.RUnlock()
 	i, ok := w.Rovers[rover]
 	if !ok {
 		return Rover{}, fmt.Errorf("Failed to find rover with name: %s", rover)
 	}
 	return *i, nil
 }
 // RoverRecharge charges up a rover
 func (w *World) RoverRecharge(rover string) (int, error) {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	i, ok := w.Rovers[rover]
 	if !ok {
 		return 0, fmt.Errorf("Failed to find rover with name: %s", rover)
 	}
 	// We can only recharge during the day
 	if !w.Daytime() {
 		return i.Charge, nil
 	}
 	// Add one charge
 	if i.Charge < i.MaximumCharge {
 		i.Charge++
 		i.AddLogEntryf("recharged to %d", i.Charge)
 	}
 	return i.Charge, nil
 }
 // RoverBroadcast broadcasts a message to nearby rovers
 func (w *World) RoverBroadcast(rover string, message []byte) (err error) {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	i, ok := w.Rovers[rover]
 	if !ok {
 		return fmt.Errorf("Failed to find rover with name: %s", rover)
 	}
 	// Use up a charge as needed, if available
 	if i.Charge == 0 {
 		return
 	}
 	i.Charge--
 	// Check all rovers
 	for r, rover := range w.Rovers {
 		if rover.Name == i.Name {
 			continue
 		}
 		// Check if this rover is within range
 		if i.Pos.Distance(rover.Pos) < float64(i.Range) {
 			rover.AddLogEntryf("recieved %s from %s", string(message), i.Name)
 			w.Rovers[r] = rover
 		}
 	}
 	i.AddLogEntryf("broadcasted %s", string(message))
 	return
 }
 // DestroyRover Removes an rover from the game
 func (w *World) DestroyRover(rover string) error {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	r, ok := w.Rovers[rover]
 	if !ok {
 		return fmt.Errorf("no rover matching id")
 	}
 	// Remove this rover from tracked rovers
 	delete(w.Rovers, rover)
 	r.Owner = ""
 	r.AddLogEntryf("rover destroyed")
 	// Marshal the rover data
 	data, err := json.Marshal(r)
 	if err != nil {
 		return err
 	}
 	// Place the dormant rover down
 	w.Atlas.SetObject(r.Pos, Object{Type: roveapi.Object_RoverDormant, Data: data})
 	return nil
 }
 // RoverPosition returns the position of the rover
 func (w *World) RoverPosition(rover string) (maths.Vector, error) {
 	w.worldMutex.RLock()
 	defer w.worldMutex.RUnlock()
 	i, ok := w.Rovers[rover]
 	if !ok {
 		return maths.Vector{}, fmt.Errorf("no rover matching id")
 	}
 	return i.Pos, nil
 }
 // SetRoverPosition sets the position of the rover
 func (w *World) SetRoverPosition(rover string, pos maths.Vector) error {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	i, ok := w.Rovers[rover]
 	if !ok {
 		return fmt.Errorf("no rover matching id")
 	}
 	i.Pos = pos
 	return nil
 }
 // RoverInventory returns the inventory of a requested rover
 func (w *World) RoverInventory(rover string) ([]Object, error) {
 	w.worldMutex.RLock()
 	defer w.worldMutex.RUnlock()
 	i, ok := w.Rovers[rover]
 	if !ok {
 		return nil, fmt.Errorf("no rover matching id")
 	}
 	return i.Inventory, nil
 }
 // WarpRover sets an rovers position
 func (w *World) WarpRover(rover string, pos maths.Vector) error {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	i, ok := w.Rovers[rover]
 	if !ok {
 		return fmt.Errorf("no rover matching id")
 	}
 	// Nothing to do if these positions match
 	if i.Pos == pos {
 		return nil
 	}
 	// Check the tile is not blocked
 	_, obj := w.Atlas.QueryPosition(pos)
 	if obj.IsBlocking() {
 		return fmt.Errorf("can't warp rover to occupied tile, check before warping")
 	}
 	i.Pos = pos
 	return nil
 }
 // TryMoveRover attempts to move a rover in a specific direction
 func (w *World) TryMoveRover(rover string, b roveapi.Bearing) (maths.Vector, error) {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	i, ok := w.Rovers[rover]
 	if !ok {
 		return maths.Vector{}, fmt.Errorf("no rover matching id")
 	}
 	// Try the new move position
 	newPos := i.Pos.Added(maths.BearingToVector(b))
 	// Get the tile and verify it's empty
 	_, obj := w.Atlas.QueryPosition(newPos)
 	if !obj.IsBlocking() {
 		i.AddLogEntryf("moved %s to %+v", b.String(), newPos)
 		// Perform the move
 		i.Pos = newPos
 	} else {
 		// If it is a blocking tile, reduce the rover integrity
 		i.AddLogEntryf("tried to move %s to %+v", b.String(), newPos)
 		i.Integrity = i.Integrity - 1
 		i.AddLogEntryf("had a collision, new integrity %d", i.Integrity)
 	}
 	return i.Pos, nil
 }
 // RoverStash will stash an item at the current rovers position
 func (w *World) RoverStash(rover string) (roveapi.Object, error) {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	r, ok := w.Rovers[rover]
 	if !ok {
 		return roveapi.Object_ObjectUnknown, fmt.Errorf("no rover matching id")
 	}
 	// Can't pick up when full
 	if len(r.Inventory) >= r.Capacity {
 		r.AddLogEntryf("tried to stash object but inventory was full")
 		return roveapi.Object_ObjectUnknown, nil
 	}
 	// Ensure the rover has energy
 	if r.Charge <= 0 {
 		r.AddLogEntryf("tried to stash object but had no charge")
 		return roveapi.Object_ObjectUnknown, nil
 	}
 	r.Charge--
 	_, obj := w.Atlas.QueryPosition(r.Pos)
 	if !obj.IsStashable() {
 		return roveapi.Object_ObjectUnknown, nil
 	}
 	r.AddLogEntryf("stashed %c", obj.Type)
 	r.Inventory = append(r.Inventory, obj)
 	w.Atlas.SetObject(r.Pos, Object{Type: roveapi.Object_ObjectUnknown})
 	return obj.Type, nil
 }
 // RoverSalvage will salvage a rover for parts
 func (w *World) RoverSalvage(rover string) (roveapi.Object, error) {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	r, ok := w.Rovers[rover]
 	if !ok {
 		return roveapi.Object_ObjectUnknown, fmt.Errorf("no rover matching id")
 	}
 	// Can't pick up when full
 	if len(r.Inventory) >= r.Capacity {
 		r.AddLogEntryf("tried to salvage dormant rover but inventory was full")
 		return roveapi.Object_ObjectUnknown, nil
 	}
 	// Ensure the rover has energy
 	if r.Charge <= 0 {
 		r.AddLogEntryf("tried to salvage dormant rover but had no charge")
 		return roveapi.Object_ObjectUnknown, nil
 	}
 	r.Charge--
 	_, obj := w.Atlas.QueryPosition(r.Pos)
 	if obj.Type != roveapi.Object_RoverDormant {
 		r.AddLogEntryf("tried to salvage dormant rover but found no rover to salvage")
 		return roveapi.Object_ObjectUnknown, nil
 	}
 	r.AddLogEntryf("salvaged dormant rover")
 	for i := 0; i < 5; i++ {
 		if len(r.Inventory) == r.Capacity {
 			break
 		}
 		r.Inventory = append(r.Inventory, Object{Type: roveapi.Object_RoverParts})
 	}
 	w.Atlas.SetObject(r.Pos, Object{Type: roveapi.Object_ObjectUnknown})
 	return obj.Type, nil
 }
 // RoverTransfer will transfer rover control to dormant rover
 func (w *World) RoverTransfer(rover string) (string, error) {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	oldRover, ok := w.Rovers[rover]
 	if !ok {
 		return "", fmt.Errorf("no rover matching id")
 	}
 	_, obj := w.Atlas.QueryPosition(oldRover.Pos)
 	if obj.Type != roveapi.Object_RoverDormant {
 		oldRover.AddLogEntryf("tried to transfer to dormant rover but found no rover")
 		return "", nil
 	}
 	// Unmarshal the dormant rover
 	var newRover Rover
 	err := json.Unmarshal(obj.Data, &newRover)
 	if err != nil {
 		return "", err
 	}
 	// Add logs
 	oldRover.AddLogEntryf("transferring to dormant rover %s", newRover.Name)
 	newRover.AddLogEntryf("transferred from rover %s", oldRover.Name)
 	// Transfer the ownership
 	err = w.Accountant.AssignData(oldRover.Owner, "rover", newRover.Name)
 	if err != nil {
 		return "", err
 	}
 	newRover.Owner = oldRover.Owner
 	oldRover.Owner = ""
 	// Place the old rover in the world
 	oldRoverData, err := json.Marshal(oldRover)
 	if err != nil {
 		return "", err
 	}
 	w.Atlas.SetObject(oldRover.Pos, Object{Type: roveapi.Object_RoverDormant, Data: oldRoverData})
 	// Swap the rovers in the tracking
 	w.Rovers[newRover.Name] = &newRover
 	delete(w.Rovers, oldRover.Name)
 	// Clear the command queues for both rovers
 	delete(w.CommandQueue, oldRover.Name)
 	delete(w.CommandQueue, newRover.Name)
 	return newRover.Name, nil
 }
 // RoverToggle will toggle the sail position
 func (w *World) RoverToggle(rover string) (roveapi.SailPosition, error) {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	r, ok := w.Rovers[rover]
 	if !ok {
 		return roveapi.SailPosition_UnknownSailPosition, fmt.Errorf("no rover matching id")
 	}
 	// Swap the sail position
 	switch r.SailPosition {
 	case roveapi.SailPosition_CatchingWind:
 		r.SailPosition = roveapi.SailPosition_SolarCharging
 	case roveapi.SailPosition_SolarCharging:
 		r.SailPosition = roveapi.SailPosition_CatchingWind
 	}
 	// Reset the movement ticks
 	r.MoveTicks = 0
 	return r.SailPosition, nil
 }
 // RoverUpgrade will try to upgrade the rover
 func (w *World) RoverUpgrade(rover string, upgrade roveapi.RoverUpgrade) (int, error) {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	r, ok := w.Rovers[rover]
 	if !ok {
 		return 0, fmt.Errorf("no rover matching id")
 	}
 	cost := upgradeCost
 	num := 0
 	for i := range r.Inventory {
 		if r.Inventory[i].Type == roveapi.Object_RoverParts {
 			num++
 		}
 	}
 	if num < cost {
 		r.AddLogEntryf("tried to upgrade but lacked rover parts")
 		return 0, nil
 	}
 	// Apply the upgrade
 	var ret int
 	switch upgrade {
 	case roveapi.RoverUpgrade_Capacity:
 		r.Capacity++
 		ret = r.Capacity
 	case roveapi.RoverUpgrade_Range:
 		r.Range++
 		ret = r.Range
 	case roveapi.RoverUpgrade_MaximumCharge:
 		r.MaximumCharge++
 		ret = r.MaximumCharge
 	case roveapi.RoverUpgrade_MaximumIntegrity:
 		r.MaximumIntegrity++
 		ret = r.MaximumIntegrity
 	default:
 		return 0, fmt.Errorf("unknown upgrade: %s", upgrade)
 	}
 	// Remove the cost in rover parts
 	var n []Object
 	for _, o := range r.Inventory {
 		if o.Type == roveapi.Object_RoverParts && cost > 0 {
 			cost--
 		} else {
 			n = append(n, o)
 		}
 	}
 	// Assign back the inventory
 	r.Inventory = n
 	r.AddLogEntryf("upgraded %s to %d", upgrade, ret)
 	return ret, nil
 }
 // RoverTurn will turn the rover
 func (w *World) RoverTurn(rover string, bearing roveapi.Bearing) (roveapi.Bearing, error) {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	r, ok := w.Rovers[rover]
 	if !ok {
 		return roveapi.Bearing_BearingUnknown, fmt.Errorf("no rover matching id")
 	}
 	// Set the new bearing
 	r.Bearing = bearing
 	// Reset the movement ticks
 	r.MoveTicks = 0
 	return r.Bearing, nil
 }
 // RoverRepair will turn the rover
 func (w *World) RoverRepair(rover string) (int, error) {
 	w.worldMutex.Lock()
 	defer w.worldMutex.Unlock()
 	r, ok := w.Rovers[rover]
 	if !ok {
 		return 0, fmt.Errorf("no rover matching id")
 	}
 	// Can't repair past max
 	if r.Integrity >= r.MaximumIntegrity {
 		return r.Integrity, nil
 	}
 	// Find rover parts in inventory
 	for i, o := range r.Inventory {
 		if o.Type == roveapi.Object_RoverParts {
 			// Copy-erase from slice
 			r.Inventory[i] = r.Inventory[len(r.Inventory)-1]
 			r.Inventory = r.Inventory[:len(r.Inventory)-1]
 			// Repair
 			r.Integrity = r.Integrity + 1
 			r.AddLogEntryf("repaired self to %d", r.Integrity)
 			break
 		}
 	}
 	return r.Integrity, nil
 }
 // RadarFromRover can be used to query what a rover can currently see
 func (w *World) RadarFromRover(rover string) (radar []roveapi.Tile, objs []roveapi.Object, err error) {
 	w.worldMutex.RLock()
 	defer w.worldMutex.RUnlock()
 	r, ok := w.Rovers[rover]
 	if !ok {
 		err = fmt.Errorf("no rover matching id")
 		return
 	}
 	// The radar should span in range direction on each axis, plus the row/column the rover is currently on
 	radarSpan := (r.Range * 2) + 1
 	roverPos := r.Pos
 	// Get the radar min and max values
 	radarMin := maths.Vector{
 		X: roverPos.X - r.Range,
 		Y: roverPos.Y - r.Range,
 	}
 	radarMax := maths.Vector{
 		X: roverPos.X + r.Range,
 		Y: roverPos.Y + r.Range,
 	}
 	// Gather up all tiles within the range
 	radar = make([]roveapi.Tile, radarSpan*radarSpan)
 	objs = make([]roveapi.Object, radarSpan*radarSpan)
 	for j := radarMin.Y; j <= radarMax.Y; j++ {
 		for i := radarMin.X; i <= radarMax.X; i++ {
 			q := maths.Vector{X: i, Y: j}
 			tile, obj := w.Atlas.QueryPosition(q)
 			// Get the position relative to the bottom left of the radar
 			relative := q.Added(radarMin.Negated())
 			index := relative.X + relative.Y*radarSpan
 			radar[index] = tile
 			objs[index] = obj.Type
 		}
 	}
 	// Add all rovers to the radar
 	for _, r := range w.Rovers {
 		// If the rover is in range
 		dist := r.Pos.Added(roverPos.Negated())
 		dist = dist.Abs()
 		if dist.X <= r.Range && dist.Y <= r.Range {
 			relative := r.Pos.Added(radarMin.Negated())
 			index := relative.X + relative.Y*radarSpan
 			objs[index] = roveapi.Object_RoverLive
 		}
 	}
 	return radar, objs, nil
 }
 // RoverCommands returns current commands for the given rover
 func (w *World) RoverCommands(rover string) (queued CommandStream) {
 	if c, ok := w.CommandQueue[rover]; ok {
 		queued = c
 	}
 	return
 }
 // Enqueue will queue the commands given
 func (w *World) Enqueue(rover string, commands ...*roveapi.Command) error {
 	// First validate the commands
 	for _, c := range commands {
 		switch c.Command {
 		case roveapi.CommandType_broadcast:
 			if len(c.GetData()) > 3 {
 				return fmt.Errorf("too many characters in message (limit 3): %d", len(c.GetData()))
 			}
 			for _, b := range c.GetData() {
 				if b < 37 || b > 126 {
 					return fmt.Errorf("invalid message character: %c", b)
 				}
 			}
 		case roveapi.CommandType_turn:
 			if c.GetBearing() == roveapi.Bearing_BearingUnknown {
 				return fmt.Errorf("turn command given unknown bearing")
 			}
 		case roveapi.CommandType_upgrade:
 			if c.GetUpgrade() == roveapi.RoverUpgrade_RoverUpgradeUnknown {
 				return fmt.Errorf("upgrade command given unknown upgrade")
 			}
 		case roveapi.CommandType_wait:
 		case roveapi.CommandType_toggle:
 		case roveapi.CommandType_stash:
 		case roveapi.CommandType_repair:
 		case roveapi.CommandType_salvage:
 		case roveapi.CommandType_transfer:
 			// Nothing to verify
 		default:
 			return fmt.Errorf("unknown command: %s", c.Command)
 		}
 	}
 	// Lock our commands edit
 	w.cmdMutex.Lock()
 	defer w.cmdMutex.Unlock()
 	w.CommandQueue[rover] = commands
 	return nil
 }
 // Tick will execute any commands in the current command queue and tick the world
 func (w *World) Tick() {
 	w.cmdMutex.Lock()
 	defer w.cmdMutex.Unlock()
 	// Iterate through all the current commands
 	for rover, cmds := range w.CommandQueue {
 		if len(cmds) != 0 {
 			// Execute the command
 			if done, err := w.ExecuteCommand(cmds[0], rover); err != nil {
 				log.Println(err)
 				// TODO: Report this error somehow
 			} else if done {
 				// Extract the first command in the queue
 				// Only if the command queue still has entries (the command may have modified this queue)
 				if _, ok := w.CommandQueue[rover]; ok {
 					w.CommandQueue[rover] = cmds[1:]
 				}
 			}
 		} else {
 			// Clean out the empty entry
 			delete(w.CommandQueue, rover)
 		}
 	}
 	// Move all the rovers based on current wind and sails
 	for n, r := range w.Rovers {
 		// Skip if we're not catching the wind
 		if r.SailPosition != roveapi.SailPosition_CatchingWind {
 			continue
 		}
 		// Increment the current move ticks
 		r.MoveTicks++
 		// Get the difference between the two bearings
 		// Normalise, we don't care about clockwise/anticlockwise
 		diff := maths.Abs(int(w.Wind - r.Bearing))
 		if diff > 4 {
 			diff = 8 - diff
 		}
 		// Calculate the travel "ticks"
 		var ticksToMove int
 		switch diff {
 		case 0:
 			// Going with the wind, travel at base speed of once every 4 ticks
 			ticksToMove = ticksPerNormalMove
 		case 1:
 			// At a slight angle, we can go a little faster
 			ticksToMove = ticksPerNormalMove / 2
 		case 2:
 			// Perpendicular to wind, max speed
 			ticksToMove = 1
 		case 3:
 			// Heading at 45 degrees into the wind, back to min speed
 			ticksToMove = ticksPerNormalMove
 		case 4:
 			// Heading durectly into the wind, no movement at all
 		default:
 			log.Fatalf("bearing difference of %d should be impossible", diff)
 		}
 		// If we've incremented over the current move ticks on the rover, we can try and make the move
 		if ticksToMove != 0 && r.MoveTicks >= ticksToMove {
 			_, err := w.TryMoveRover(n, r.Bearing)
 			if err != nil {
 				log.Println(err)
 				// TODO: Report this error somehow
 			}
 			// Reset the move ticks
 			r.MoveTicks = 0
 		}
 	}
 	// Check all rover integrities
 	for _, r := range w.Rovers {
 		if r.Integrity <= 0 {
 			// The rover has died destroy it
 			err := w.DestroyRover(r.Name)
 			if err != nil {
 				log.Println(err)
 				// TODO: Report this error somehow
 			}
 			// Spawn a new one for this account
 			_, err = w.SpawnRover(r.Owner)
 			if err != nil {
 				log.Println(err)
 				// TODO: Report this error somehow
 			}
 		}
 	}
 	// Increment the current tick count
 	w.CurrentTicks++
 	// Change the wind every day
 	if (w.CurrentTicks % w.TicksPerDay) == 0 {
 		w.Wind = roveapi.Bearing((rand.Int() % 8) + 1) // Random cardinal bearing
 	}
 }
 // ExecuteCommand will execute a single command
 func (w *World) ExecuteCommand(c *roveapi.Command, rover string) (done bool, err error) {
 	log.Printf("Executing command: %+v for %s\n", c.Command, rover)
 	switch c.Command {
 	case roveapi.CommandType_toggle:
 		_, err = w.RoverToggle(rover)
 	case roveapi.CommandType_stash:
 		_, err = w.RoverStash(rover)
 	case roveapi.CommandType_repair:
 		_, err = w.RoverRepair(rover)
 	case roveapi.CommandType_broadcast:
 		err = w.RoverBroadcast(rover, c.GetData())
 	case roveapi.CommandType_turn:
 		_, err = w.RoverTurn(rover, c.GetBearing())
 	case roveapi.CommandType_salvage:
 		_, err = w.RoverSalvage(rover)
 	case roveapi.CommandType_transfer:
 		_, err = w.RoverTransfer(rover)
 	case roveapi.CommandType_upgrade:
 		_, err = w.RoverUpgrade(rover, c.GetUpgrade())
 	case roveapi.CommandType_wait:
 		// Nothing to do
 	default:
 		return true, fmt.Errorf("unknown command: %s", c.Command)
 	}
 	// Decrement the repeat number
 	c.Repeat--
 	return c.Repeat < 0, err
 }
 // Daytime returns if it's currently daytime
 // for simplicity this uses the 1st half of the day as daytime, the 2nd half as nighttime
 func (w *World) Daytime() bool {
 	tickInDay := w.CurrentTicks % w.TicksPerDay
 	return tickInDay < w.TicksPerDay/2
 }
 // RLock read locks the world
 func (w *World) RLock() {
 	w.worldMutex.RLock()
 	w.cmdMutex.RLock()
 }
 // RUnlock read unlocks the world
 func (w *World) RUnlock() {
 	w.worldMutex.RUnlock()
 	w.cmdMutex.RUnlock()
 }
 // Lock locks the world
 func (w *World) Lock() {
 	w.worldMutex.Lock()
 	w.cmdMutex.Lock()
 }
 // Unlock unlocks the world
 func (w *World) Unlock() {
 	w.worldMutex.Unlock()
 	w.cmdMutex.Unlock()
 }
--- a/pkg/rove/world_test.go
+++ b/pkg/rove/world_test.go
@ -0,0 +1,359 @@
 package rove
 import (
 	"testing"
 	"github.com/mdiluz/rove/pkg/maths"
 	"github.com/mdiluz/rove/proto/roveapi"
 	"github.com/stretchr/testify/assert"
 )
 func TestNewWorld(t *testing.T) {
 	// Very basic for now, nothing to verify
 	world := NewWorld(4)
 	if world == nil {
 		t.Error("Failed to create world")
 	}
 }
 func TestWorld_CreateRover(t *testing.T) {
 	world := NewWorld(8)
 	a, err := world.SpawnRover("")
 	assert.NoError(t, err)
 	b, err := world.SpawnRover("")
 	assert.NoError(t, err)
 	// Basic duplicate check
 	if a == b {
 		t.Errorf("Created identical rovers")
 	} else if len(world.Rovers) != 2 {
 		t.Errorf("Incorrect number of rovers created")
 	}
 }
 func TestWorld_GetRover(t *testing.T) {
 	world := NewWorld(4)
 	a, err := world.SpawnRover("")
 	assert.NoError(t, err)
 	rover, err := world.GetRover(a)
 	assert.NoError(t, err, "Failed to get rover attribs")
 	assert.NotZero(t, rover.Range, "Rover should not be spawned blind")
 	assert.Contains(t, rover.Logs[len(rover.Logs)-1].Text, "created", "Rover logs should contain the creation")
 }
 func TestWorld_DestroyRover(t *testing.T) {
 	world := NewWorld(1)
 	a, err := world.SpawnRover("")
 	assert.NoError(t, err)
 	b, err := world.SpawnRover("")
 	assert.NoError(t, err)
 	err = world.DestroyRover(a)
 	assert.NoError(t, err, "Error returned from rover destroy")
 	// Basic duplicate check
 	if len(world.Rovers) != 1 {
 		t.Error("Too many rovers left in world")
 	} else if _, ok := world.Rovers[b]; !ok {
 		t.Error("Remaining rover is incorrect")
 	}
 }
 func TestWorld_GetSetMovePosition(t *testing.T) {
 	world := NewWorld(4)
 	a, err := world.SpawnRover("")
 	assert.NoError(t, err)
 	pos := maths.Vector{
 		X: 0.0,
 		Y: 0.0,
 	}
 	err = world.WarpRover(a, pos)
 	assert.NoError(t, err, "Failed to set position for rover")
 	newPos, err := world.RoverPosition(a)
 	assert.NoError(t, err, "Failed to set position for rover")
 	assert.Equal(t, pos, newPos, "Failed to correctly set position for rover")
 	b := roveapi.Bearing_North
 	newPos, err = world.TryMoveRover(a, b)
 	assert.NoError(t, err, "Failed to set position for rover")
 	pos.Add(maths.Vector{X: 0, Y: 1})
 	assert.Equal(t, pos, newPos, "Failed to correctly move position for rover")
 	rover, err := world.GetRover(a)
 	assert.NoError(t, err, "Failed to get rover information")
 	assert.Contains(t, rover.Logs[len(rover.Logs)-1].Text, "moved", "Rover logs should contain the move")
 	// Place a tile in front of the rover
 	world.Atlas.SetObject(maths.Vector{X: 0, Y: 2}, Object{Type: roveapi.Object_RockLarge})
 	newPos, err = world.TryMoveRover(a, b)
 	assert.NoError(t, err, "Failed to move rover")
 	assert.Equal(t, pos, newPos, "Failed to correctly not move position for rover into wall")
 }
 func TestWorld_RadarFromRover(t *testing.T) {
 	// Create world that should have visible walls on the radar
 	world := NewWorld(2)
 	a, err := world.SpawnRover("")
 	assert.NoError(t, err)
 	b, err := world.SpawnRover("")
 	assert.NoError(t, err)
 	// Warp the rovers into position
 	bpos := maths.Vector{X: -3, Y: -3}
 	world.Atlas.SetObject(bpos, Object{Type: roveapi.Object_ObjectUnknown})
 	assert.NoError(t, world.WarpRover(b, bpos), "Failed to warp rover")
 	world.Atlas.SetObject(maths.Vector{X: 0, Y: 0}, Object{Type: roveapi.Object_ObjectUnknown})
 	assert.NoError(t, world.WarpRover(a, maths.Vector{X: 0, Y: 0}), "Failed to warp rover")
 	r, err := world.GetRover(a)
 	assert.NoError(t, err)
 	radar, objs, err := world.RadarFromRover(a)
 	assert.NoError(t, err, "Failed to get radar from rover")
 	fullRange := r.Range + r.Range + 1
 	assert.Equal(t, fullRange*fullRange, len(radar), "Radar returned wrong length")
 	assert.Equal(t, fullRange*fullRange, len(objs), "Radar returned wrong length")
 	// TODO: Verify the other rover is on the radar
 	// Check the radar results are stable
 	radar1, objs1, err := world.RadarFromRover(a)
 	assert.NoError(t, err)
 	radar2, objs2, err := world.RadarFromRover(a)
 	assert.NoError(t, err)
 	assert.Equal(t, radar1, radar2)
 	assert.Equal(t, objs1, objs2)
 }
 func TestWorld_RoverDamage(t *testing.T) {
 	world := NewWorld(2)
 	acc, err := world.Accountant.RegisterAccount("tmp")
 	assert.NoError(t, err)
 	a, err := world.SpawnRover(acc.Name)
 	assert.NoError(t, err)
 	pos := maths.Vector{
 		X: 0.0,
 		Y: 0.0,
 	}
 	world.Atlas.SetObject(pos, Object{Type: roveapi.Object_ObjectUnknown})
 	err = world.WarpRover(a, pos)
 	assert.NoError(t, err, "Failed to set position for rover")
 	info, err := world.GetRover(a)
 	assert.NoError(t, err, "couldn't get rover info")
 	world.Atlas.SetObject(maths.Vector{X: 0.0, Y: 1.0}, Object{Type: roveapi.Object_RockLarge})
 	vec, err := world.TryMoveRover(a, roveapi.Bearing_North)
 	assert.NoError(t, err, "Failed to move rover")
 	assert.Equal(t, pos, vec, "Rover managed to move into large rock")
 	newinfo, err := world.GetRover(a)
 	assert.NoError(t, err, "couldn't get rover info")
 	assert.Equal(t, info.Integrity-1, newinfo.Integrity, "rover should have lost integrity")
 	assert.Contains(t, newinfo.Logs[len(newinfo.Logs)-1].Text, "collision", "Rover logs should contain the collision")
 	// Keep moving to damage the rover
 	for i := 0; i < info.Integrity-1; i++ {
 		vec, err := world.TryMoveRover(a, roveapi.Bearing_North)
 		assert.NoError(t, err, "Failed to move rover")
 		assert.Equal(t, pos, vec, "Rover managed to move into large rock")
 	}
 	// Tick the world to check for rover deaths
 	world.Tick()
 	// Rover should have been destroyed now
 	_, err = world.GetRover(a)
 	assert.Error(t, err)
 	_, obj := world.Atlas.QueryPosition(info.Pos)
 	assert.Equal(t, roveapi.Object_RoverDormant, obj.Type)
 }
 func TestWorld_Daytime(t *testing.T) {
 	world := NewWorld(1)
 	a, err := world.SpawnRover("")
 	assert.NoError(t, err)
 	// Remove rover charge
 	rover := world.Rovers[a]
 	rover.Charge = 0
 	world.Rovers[a] = rover
 	// Try and recharge, should work
 	_, err = world.RoverRecharge(a)
 	assert.NoError(t, err)
 	assert.Equal(t, 1, world.Rovers[a].Charge)
 	// Loop for half the day
 	for i := 0; i < world.TicksPerDay/2; i++ {
 		assert.True(t, world.Daytime())
 		world.Tick()
 	}
 	// Remove rover charge again
 	rover = world.Rovers[a]
 	rover.Charge = 0
 	world.Rovers[a] = rover
 	// Try and recharge, should fail
 	_, err = world.RoverRecharge(a)
 	assert.NoError(t, err)
 	assert.Equal(t, 0, world.Rovers[a].Charge)
 	// Loop for half the day
 	for i := 0; i < world.TicksPerDay/2; i++ {
 		assert.False(t, world.Daytime())
 		world.Tick()
 	}
 }
 func TestWorld_Broadcast(t *testing.T) {
 	world := NewWorld(8)
 	a, err := world.SpawnRover("")
 	assert.NoError(t, err)
 	b, err := world.SpawnRover("")
 	assert.NoError(t, err)
 	// Warp rovers near to eachother
 	world.Atlas.SetObject(maths.Vector{X: 0, Y: 0}, Object{Type: roveapi.Object_ObjectUnknown})
 	world.Atlas.SetObject(maths.Vector{X: 1, Y: 0}, Object{Type: roveapi.Object_ObjectUnknown})
 	assert.NoError(t, world.WarpRover(a, maths.Vector{X: 0, Y: 0}))
 	assert.NoError(t, world.WarpRover(b, maths.Vector{X: 1, Y: 0}))
 	// Broadcast from a
 	assert.NoError(t, world.RoverBroadcast(a, []byte{'A', 'B', 'C'}))
 	// Check if b heard it
 	ra, err := world.GetRover(a)
 	assert.NoError(t, err)
 	assert.Equal(t, ra.MaximumCharge-1, ra.Charge, "A should have used a charge to broadcast")
 	assert.Contains(t, ra.Logs[len(ra.Logs)-1].Text, "ABC", "Rover B should have heard the broadcast")
 	// Check if a logged it
 	rb, err := world.GetRover(b)
 	assert.NoError(t, err)
 	assert.Contains(t, rb.Logs[len(rb.Logs)-1].Text, "ABC", "Rover A should have logged it's broadcast")
 	// Warp B outside of the range of A
 	world.Atlas.SetObject(maths.Vector{X: ra.Range, Y: 0}, Object{Type: roveapi.Object_ObjectUnknown})
 	assert.NoError(t, world.WarpRover(b, maths.Vector{X: ra.Range, Y: 0}))
 	// Broadcast from a again
 	assert.NoError(t, world.RoverBroadcast(a, []byte{'X', 'Y', 'Z'}))
 	// Check if b heard it
 	ra, err = world.GetRover(b)
 	assert.NoError(t, err)
 	assert.NotContains(t, ra.Logs[len(ra.Logs)-1].Text, "XYZ", "Rover B should not have heard the broadcast")
 	// Check if a logged it
 	rb, err = world.GetRover(a)
 	assert.NoError(t, err)
 	assert.Contains(t, rb.Logs[len(rb.Logs)-1].Text, "XYZ", "Rover A should have logged it's broadcast")
 	// Warp B outside of the range of A
 	world.Atlas.SetObject(maths.Vector{X: ra.Range + 1, Y: 0}, Object{Type: roveapi.Object_ObjectUnknown})
 	assert.NoError(t, world.WarpRover(b, maths.Vector{X: ra.Range + 1, Y: 0}))
 	// Broadcast from a again
 	assert.NoError(t, world.RoverBroadcast(a, []byte{'H', 'J', 'K'}))
 	// Check if b heard it
 	ra, err = world.GetRover(b)
 	assert.NoError(t, err)
 	assert.NotContains(t, ra.Logs[len(ra.Logs)-1].Text, "HJK", "Rover B should have heard the broadcast")
 	// Check if a logged it
 	rb, err = world.GetRover(a)
 	assert.NoError(t, err)
 	assert.Contains(t, rb.Logs[len(rb.Logs)-1].Text, "HJK", "Rover A should have logged it's broadcast")
 }
 func TestWorld_Sailing(t *testing.T) {
 	world := NewWorld(8)
 	world.Tick()                       // One initial tick to set the wind direction the first time
 	world.Wind = roveapi.Bearing_North // Set the wind direction to north
 	name, err := world.SpawnRover("")
 	assert.NoError(t, err)
 	// Warp the rover to 0,0 after clearing it
 	world.Atlas.SetObject(maths.Vector{X: 0, Y: 0}, Object{Type: roveapi.Object_ObjectUnknown})
 	assert.NoError(t, world.WarpRover(name, maths.Vector{X: 0, Y: 0}))
 	s, err := world.RoverToggle(name)
 	assert.NoError(t, err)
 	assert.Equal(t, roveapi.SailPosition_CatchingWind, s)
 	b, err := world.RoverTurn(name, roveapi.Bearing_North)
 	assert.NoError(t, err)
 	assert.Equal(t, roveapi.Bearing_North, b)
 	// Clear the space to the north
 	world.Atlas.SetObject(maths.Vector{X: 0, Y: 1}, Object{Type: roveapi.Object_ObjectUnknown})
 	// Tick the world and check we've moved not moved
 	world.Tick()
 	info, err := world.GetRover(name)
 	assert.NoError(t, err)
 	assert.Equal(t, maths.Vector{Y: 0}, info.Pos)
 	// Loop a few more times
 	for i := 0; i < ticksPerNormalMove-2; i++ {
 		world.Tick()
 		info, err := world.GetRover(name)
 		assert.NoError(t, err)
 		assert.Equal(t, maths.Vector{Y: 0}, info.Pos)
 	}
 	// Now check we've moved (after the TicksPerNormalMove number of ticks)
 	world.Tick()
 	info, err = world.GetRover(name)
 	assert.NoError(t, err)
 	assert.Equal(t, maths.Vector{Y: 1}, info.Pos)
 	// Reset the world ticks back to stop any wind changes etc.
 	world.CurrentTicks = 1
 	// Face the rover south, into the wind
 	b, err = world.RoverTurn(name, roveapi.Bearing_South)
 	assert.NoError(t, err)
 	assert.Equal(t, roveapi.Bearing_South, b)
 	// Tick a bunch, we should never move
 	for i := 0; i < ticksPerNormalMove*2; i++ {
 		world.Tick()
 		info, err := world.GetRover(name)
 		assert.NoError(t, err)
 		assert.Equal(t, maths.Vector{Y: 1}, info.Pos)
 	}
 	// Reset the world ticks back to stop any wind changes etc.
 	world.CurrentTicks = 1
 	world.Wind = roveapi.Bearing_SouthEast // Set up a south easternly wind
 	// Turn the rover perpendicular
 	b, err = world.RoverTurn(name, roveapi.Bearing_NorthEast)
 	assert.NoError(t, err)
 	assert.Equal(t, roveapi.Bearing_NorthEast, b)
 	// Clear a space
 	world.Atlas.SetObject(maths.Vector{X: 1, Y: 2}, Object{Type: roveapi.Object_ObjectUnknown})
 	// Now check we've moved immediately
 	world.Tick()
 	info, err = world.GetRover(name)
 	assert.NoError(t, err)
 	assert.Equal(t, maths.Vector{X: 1, Y: 2}, info.Pos)
 }
--- a/pkg/rove/worldgen.go
+++ b/pkg/rove/worldgen.go
@ -0,0 +1,70 @@
 package rove
 import (
 	"github.com/mdiluz/rove/pkg/maths"
 	"github.com/mdiluz/rove/proto/roveapi"
 	"github.com/ojrac/opensimplex-go"
 )
 // WorldGen describes a world gen algorythm
 type WorldGen interface {
 	// GetTile generates a tile for a location
 	GetTile(v maths.Vector) roveapi.Tile
 	// GetObject generates an object for a location
 	GetObject(v maths.Vector) Object
 }
 // NoiseWorldGen returns a noise based world generator
 type NoiseWorldGen struct {
 	// noise describes the noise function
 	noise opensimplex.Noise
 }
 // NewNoiseWorldGen creates a new noise based world generator
 func NewNoiseWorldGen(seed int64) WorldGen {
 	return &NoiseWorldGen{
 		noise: opensimplex.New(seed),
 	}
 }
 const (
 	terrainNoiseScale = 15
 	rockNoiseScale    = 3
 	partsNoiseScale   = 2
 )
 // GetTile returns the chosen tile at a location
 func (g *NoiseWorldGen) GetTile(v maths.Vector) roveapi.Tile {
 	t := g.noise.Eval2(float64(v.X)/terrainNoiseScale, float64(v.Y)/terrainNoiseScale)
 	switch {
 	case t > 0.5:
 		return roveapi.Tile_Gravel
 	case t > 0.05:
 		return roveapi.Tile_Sand
 	default:
 		return roveapi.Tile_Rock
 	}
 }
 // GetObject returns the chosen object at a location
 func (g *NoiseWorldGen) GetObject(v maths.Vector) (obj Object) {
 	r := g.noise.Eval2(float64(v.X)/rockNoiseScale, float64(v.Y)/rockNoiseScale)
 	switch {
 	// Prioritise rocks
 	case r > 0.6:
 		obj.Type = roveapi.Object_RockLarge
 	case r > 0.5:
 		obj.Type = roveapi.Object_RockSmall
 	default:
 		// Otherwise, try some rover parts
 		p := g.noise.Eval2(float64(v.X)/partsNoiseScale, float64(v.Y)/partsNoiseScale)
 		switch {
 		case p > 0.7:
 			obj.Type = roveapi.Object_RoverParts
 		}
 	}
 	return obj
 }
--- a/proto/google/README.grpc-gateway
+++ b/proto/google/README.grpc-gateway
@ -1,23 +0,0 @@
 Google APIs
 ============
 Project: Google APIs
 URL: https://github.com/google/googleapis
 Revision: 3544ab16c3342d790b00764251e348705991ea4b
 License: Apache License 2.0
 Imported Files
 ---------------
 - google/api/annotations.proto
 - google/api/http.proto
 - google/api/httpbody.proto
 Generated Files
 ----------------
 They are generated from the .proto files by protoc-gen-go.
 - google/api/annotations.pb.go
 - google/api/http.pb.go
--- a/proto/google/api/annotations.proto
+++ b/proto/google/api/annotations.proto
@ -1,31 +0,0 @@
 // Copyright (c) 2015, Google Inc.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 syntax = "proto3";
 package google.api;
 import "google/api/http.proto";
 import "google/protobuf/descriptor.proto";
 option go_package = "google.golang.org/genproto/googleapis/api/annotations;annotations";
 option java_multiple_files = true;
 option java_outer_classname = "AnnotationsProto";
 option java_package = "com.google.api";
 option objc_class_prefix = "GAPI";
 extend google.protobuf.MethodOptions {
  // See `HttpRule`.
  HttpRule http = 72295728;
 }
--- a/proto/google/api/http.proto
+++ b/proto/google/api/http.proto
@ -1,318 +0,0 @@
 // Copyright 2018 Google LLC
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 syntax = "proto3";
 package google.api;
 option cc_enable_arenas = true;
 option go_package = "google.golang.org/genproto/googleapis/api/annotations;annotations";
 option java_multiple_files = true;
 option java_outer_classname = "HttpProto";
 option java_package = "com.google.api";
 option objc_class_prefix = "GAPI";
 // Defines the HTTP configuration for an API service. It contains a list of
 // [HttpRule][google.api.HttpRule], each specifying the mapping of an RPC method
 // to one or more HTTP REST API methods.
 message Http {
  // A list of HTTP configuration rules that apply to individual API methods.
  //
  // **NOTE:** All service configuration rules follow "last one wins" order.
  repeated HttpRule rules = 1;
  // When set to true, URL path parmeters will be fully URI-decoded except in
  // cases of single segment matches in reserved expansion, where "%2F" will be
  // left encoded.
  //
  // The default behavior is to not decode RFC 6570 reserved characters in multi
  // segment matches.
  bool fully_decode_reserved_expansion = 2;
 }
 // `HttpRule` defines the mapping of an RPC method to one or more HTTP
 // REST API methods. The mapping specifies how different portions of the RPC
 // request message are mapped to URL path, URL query parameters, and
 // HTTP request body. The mapping is typically specified as an
 // `google.api.http` annotation on the RPC method,
 // see "google/api/annotations.proto" for details.
 //
 // The mapping consists of a field specifying the path template and
 // method kind.  The path template can refer to fields in the request
 // message, as in the example below which describes a REST GET
 // operation on a resource collection of messages:
 //
 //
 //     service Messaging {
 //       rpc GetMessage(GetMessageRequest) returns (Message) {
 //         option (google.api.http).get = "/v1/messages/{message_id}/{sub.subfield}";
 //       }
 //     }
 //     message GetMessageRequest {
 //       message SubMessage {
 //         string subfield = 1;
 //       }
 //       string message_id = 1; // mapped to the URL
 //       SubMessage sub = 2;    // `sub.subfield` is url-mapped
 //     }
 //     message Message {
 //       string text = 1; // content of the resource
 //     }
 //
 // The same http annotation can alternatively be expressed inside the
 // `GRPC API Configuration` YAML file.
 //
 //     http:
 //       rules:
 //         - selector: <proto_package_name>.Messaging.GetMessage
 //           get: /v1/messages/{message_id}/{sub.subfield}
 //
 // This definition enables an automatic, bidrectional mapping of HTTP
 // JSON to RPC. Example:
 //
 // HTTP | RPC
 // -----|-----
 // `GET /v1/messages/123456/foo`  | `GetMessage(message_id: "123456" sub: SubMessage(subfield: "foo"))`
 //
 // In general, not only fields but also field paths can be referenced
 // from a path pattern. Fields mapped to the path pattern cannot be
 // repeated and must have a primitive (non-message) type.
 //
 // Any fields in the request message which are not bound by the path
 // pattern automatically become (optional) HTTP query
 // parameters. Assume the following definition of the request message:
 //
 //
 //     service Messaging {
 //       rpc GetMessage(GetMessageRequest) returns (Message) {
 //         option (google.api.http).get = "/v1/messages/{message_id}";
 //       }
 //     }
 //     message GetMessageRequest {
 //       message SubMessage {
 //         string subfield = 1;
 //       }
 //       string message_id = 1; // mapped to the URL
 //       int64 revision = 2;    // becomes a parameter
 //       SubMessage sub = 3;    // `sub.subfield` becomes a parameter
 //     }
 //
 //
 // This enables a HTTP JSON to RPC mapping as below:
 //
 // HTTP | RPC
 // -----|-----
 // `GET /v1/messages/123456?revision=2&sub.subfield=foo` | `GetMessage(message_id: "123456" revision: 2 sub: SubMessage(subfield: "foo"))`
 //
 // Note that fields which are mapped to HTTP parameters must have a
 // primitive type or a repeated primitive type. Message types are not
 // allowed. In the case of a repeated type, the parameter can be
 // repeated in the URL, as in `...?param=A&param=B`.
 //
 // For HTTP method kinds which allow a request body, the `body` field
 // specifies the mapping. Consider a REST update method on the
 // message resource collection:
 //
 //
 //     service Messaging {
 //       rpc UpdateMessage(UpdateMessageRequest) returns (Message) {
 //         option (google.api.http) = {
 //           put: "/v1/messages/{message_id}"
 //           body: "message"
 //         };
 //       }
 //     }
 //     message UpdateMessageRequest {
 //       string message_id = 1; // mapped to the URL
 //       Message message = 2;   // mapped to the body
 //     }
 //
 //
 // The following HTTP JSON to RPC mapping is enabled, where the
 // representation of the JSON in the request body is determined by
 // protos JSON encoding:
 //
 // HTTP | RPC
 // -----|-----
 // `PUT /v1/messages/123456 { "text": "Hi!" }` | `UpdateMessage(message_id: "123456" message { text: "Hi!" })`
 //
 // The special name `*` can be used in the body mapping to define that
 // every field not bound by the path template should be mapped to the
 // request body.  This enables the following alternative definition of
 // the update method:
 //
 //     service Messaging {
 //       rpc UpdateMessage(Message) returns (Message) {
 //         option (google.api.http) = {
 //           put: "/v1/messages/{message_id}"
 //           body: "*"
 //         };
 //       }
 //     }
 //     message Message {
 //       string message_id = 1;
 //       string text = 2;
 //     }
 //
 //
 // The following HTTP JSON to RPC mapping is enabled:
 //
 // HTTP | RPC
 // -----|-----
 // `PUT /v1/messages/123456 { "text": "Hi!" }` | `UpdateMessage(message_id: "123456" text: "Hi!")`
 //
 // Note that when using `*` in the body mapping, it is not possible to
 // have HTTP parameters, as all fields not bound by the path end in
 // the body. This makes this option more rarely used in practice of
 // defining REST APIs. The common usage of `*` is in custom methods
 // which don't use the URL at all for transferring data.
 //
 // It is possible to define multiple HTTP methods for one RPC by using
 // the `additional_bindings` option. Example:
 //
 //     service Messaging {
 //       rpc GetMessage(GetMessageRequest) returns (Message) {
 //         option (google.api.http) = {
 //           get: "/v1/messages/{message_id}"
 //           additional_bindings {
 //             get: "/v1/users/{user_id}/messages/{message_id}"
 //           }
 //         };
 //       }
 //     }
 //     message GetMessageRequest {
 //       string message_id = 1;
 //       string user_id = 2;
 //     }
 //
 //
 // This enables the following two alternative HTTP JSON to RPC
 // mappings:
 //
 // HTTP | RPC
 // -----|-----
 // `GET /v1/messages/123456` | `GetMessage(message_id: "123456")`
 // `GET /v1/users/me/messages/123456` | `GetMessage(user_id: "me" message_id: "123456")`
 //
 // # Rules for HTTP mapping
 //
 // The rules for mapping HTTP path, query parameters, and body fields
 // to the request message are as follows:
 //
 // 1. The `body` field specifies either `*` or a field path, or is
 //    omitted. If omitted, it indicates there is no HTTP request body.
 // 2. Leaf fields (recursive expansion of nested messages in the
 //    request) can be classified into three types:
 //     (a) Matched in the URL template.
 //     (b) Covered by body (if body is `*`, everything except (a) fields;
 //         else everything under the body field)
 //     (c) All other fields.
 // 3. URL query parameters found in the HTTP request are mapped to (c) fields.
 // 4. Any body sent with an HTTP request can contain only (b) fields.
 //
 // The syntax of the path template is as follows:
 //
 //     Template = "/" Segments [ Verb ] ;
 //     Segments = Segment { "/" Segment } ;
 //     Segment  = "*" | "**" | LITERAL | Variable ;
 //     Variable = "{" FieldPath [ "=" Segments ] "}" ;
 //     FieldPath = IDENT { "." IDENT } ;
 //     Verb     = ":" LITERAL ;
 //
 // The syntax `*` matches a single path segment. The syntax `**` matches zero
 // or more path segments, which must be the last part of the path except the
 // `Verb`. The syntax `LITERAL` matches literal text in the path.
 //
 // The syntax `Variable` matches part of the URL path as specified by its
 // template. A variable template must not contain other variables. If a variable
 // matches a single path segment, its template may be omitted, e.g. `{var}`
 // is equivalent to `{var=*}`.
 //
 // If a variable contains exactly one path segment, such as `"{var}"` or
 // `"{var=*}"`, when such a variable is expanded into a URL path, all characters
 // except `[-_.~0-9a-zA-Z]` are percent-encoded. Such variables show up in the
 // Discovery Document as `{var}`.
 //
 // If a variable contains one or more path segments, such as `"{var=foo/*}"`
 // or `"{var=**}"`, when such a variable is expanded into a URL path, all
 // characters except `[-_.~/0-9a-zA-Z]` are percent-encoded. Such variables
 // show up in the Discovery Document as `{+var}`.
 //
 // NOTE: While the single segment variable matches the semantics of
 // [RFC 6570](https://tools.ietf.org/html/rfc6570) Section 3.2.2
 // Simple String Expansion, the multi segment variable **does not** match
 // RFC 6570 Reserved Expansion. The reason is that the Reserved Expansion
 // does not expand special characters like `?` and `#`, which would lead
 // to invalid URLs.
 //
 // NOTE: the field paths in variables and in the `body` must not refer to
 // repeated fields or map fields.
 message HttpRule {
  // Selects methods to which this rule applies.
  //
  // Refer to [selector][google.api.DocumentationRule.selector] for syntax details.
  string selector = 1;
  // Determines the URL pattern is matched by this rules. This pattern can be
  // used with any of the {get|put|post|delete|patch} methods. A custom method
  // can be defined using the 'custom' field.
  oneof pattern {
    // Used for listing and getting information about resources.
    string get = 2;
    // Used for updating a resource.
    string put = 3;
    // Used for creating a resource.
    string post = 4;
    // Used for deleting a resource.
    string delete = 5;
    // Used for updating a resource.
    string patch = 6;
    // The custom pattern is used for specifying an HTTP method that is not
    // included in the `pattern` field, such as HEAD, or "*" to leave the
    // HTTP method unspecified for this rule. The wild-card rule is useful
    // for services that provide content to Web (HTML) clients.
    CustomHttpPattern custom = 8;
  }
  // The name of the request field whose value is mapped to the HTTP body, or
  // `*` for mapping all fields not captured by the path pattern to the HTTP
  // body. NOTE: the referred field must not be a repeated field and must be
  // present at the top-level of request message type.
  string body = 7;
  // Optional. The name of the response field whose value is mapped to the HTTP
  // body of response. Other response fields are ignored. When
  // not set, the response message will be used as HTTP body of response.
  string response_body = 12;
  // Additional HTTP bindings for the selector. Nested bindings must
  // not contain an `additional_bindings` field themselves (that is,
  // the nesting may only be one level deep).
  repeated HttpRule additional_bindings = 11;
 }
 // A custom pattern is used for defining custom HTTP verb.
 message CustomHttpPattern {
  // The name of this custom HTTP verb.
  string kind = 1;
  // The path matched by this custom verb.
  string path = 2;
 }
--- a/proto/google/api/httpbody.proto
+++ b/proto/google/api/httpbody.proto
@ -1,78 +0,0 @@
 // Copyright 2018 Google LLC.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 //
 syntax = "proto3";
 package google.api;
 import "google/protobuf/any.proto";
 option cc_enable_arenas = true;
 option go_package = "google.golang.org/genproto/googleapis/api/httpbody;httpbody";
 option java_multiple_files = true;
 option java_outer_classname = "HttpBodyProto";
 option java_package = "com.google.api";
 option objc_class_prefix = "GAPI";
 // Message that represents an arbitrary HTTP body. It should only be used for
 // payload formats that can't be represented as JSON, such as raw binary or
 // an HTML page.
 //
 //
 // This message can be used both in streaming and non-streaming API methods in
 // the request as well as the response.
 //
 // It can be used as a top-level request field, which is convenient if one
 // wants to extract parameters from either the URL or HTTP template into the
 // request fields and also want access to the raw HTTP body.
 //
 // Example:
 //
 //     message GetResourceRequest {
 //       // A unique request id.
 //       string request_id = 1;
 //
 //       // The raw HTTP body is bound to this field.
 //       google.api.HttpBody http_body = 2;
 //     }
 //
 //     service ResourceService {
 //       rpc GetResource(GetResourceRequest) returns (google.api.HttpBody);
 //       rpc UpdateResource(google.api.HttpBody) returns
 //       (google.protobuf.Empty);
 //     }
 //
 // Example with streaming methods:
 //
 //     service CaldavService {
 //       rpc GetCalendar(stream google.api.HttpBody)
 //         returns (stream google.api.HttpBody);
 //       rpc UpdateCalendar(stream google.api.HttpBody)
 //         returns (stream google.api.HttpBody);
 //     }
 //
 // Use of this type only changes how the request and response bodies are
 // handled, all other features will continue to work unchanged.
 message HttpBody {
  // The HTTP Content-Type header value specifying the content type of the body.
  string content_type = 1;
  // The HTTP request/response body as raw binary.
  bytes data = 2;
  // Application specific response metadata. Must be set in the first response
  // for streaming APIs.
  repeated google.protobuf.Any extensions = 3;
 }
--- a/proto/google/rpc/code.proto
+++ b/proto/google/rpc/code.proto
@ -1,186 +0,0 @@
 // Copyright 2017 Google Inc.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 syntax = "proto3";
 package google.rpc;
 option go_package = "google.golang.org/genproto/googleapis/rpc/code;code";
 option java_multiple_files = true;
 option java_outer_classname = "CodeProto";
 option java_package = "com.google.rpc";
 option objc_class_prefix = "RPC";
 // The canonical error codes for Google APIs.
 //
 //
 // Sometimes multiple error codes may apply.  Services should return
 // the most specific error code that applies.  For example, prefer
 // `OUT_OF_RANGE` over `FAILED_PRECONDITION` if both codes apply.
 // Similarly prefer `NOT_FOUND` or `ALREADY_EXISTS` over `FAILED_PRECONDITION`.
 enum Code {
  // Not an error; returned on success
  //
  // HTTP Mapping: 200 OK
  OK = 0;
  // The operation was cancelled, typically by the caller.
  //
  // HTTP Mapping: 499 Client Closed Request
  CANCELLED = 1;
  // Unknown error.  For example, this error may be returned when
  // a `Status` value received from another address space belongs to
  // an error space that is not known in this address space.  Also
  // errors raised by APIs that do not return enough error information
  // may be converted to this error.
  //
  // HTTP Mapping: 500 Internal Server Error
  UNKNOWN = 2;
  // The client specified an invalid argument.  Note that this differs
  // from `FAILED_PRECONDITION`.  `INVALID_ARGUMENT` indicates arguments
  // that are problematic regardless of the state of the system
  // (e.g., a malformed file name).
  //
  // HTTP Mapping: 400 Bad Request
  INVALID_ARGUMENT = 3;
  // The deadline expired before the operation could complete. For operations
  // that change the state of the system, this error may be returned
  // even if the operation has completed successfully.  For example, a
  // successful response from a server could have been delayed long
  // enough for the deadline to expire.
  //
  // HTTP Mapping: 504 Gateway Timeout
  DEADLINE_EXCEEDED = 4;
  // Some requested entity (e.g., file or directory) was not found.
  //
  // Note to server developers: if a request is denied for an entire class
  // of users, such as gradual feature rollout or undocumented whitelist,
  // `NOT_FOUND` may be used. If a request is denied for some users within
  // a class of users, such as user-based access control, `PERMISSION_DENIED`
  // must be used.
  //
  // HTTP Mapping: 404 Not Found
  NOT_FOUND = 5;
  // The entity that a client attempted to create (e.g., file or directory)
  // already exists.
  //
  // HTTP Mapping: 409 Conflict
  ALREADY_EXISTS = 6;
  // The caller does not have permission to execute the specified
  // operation. `PERMISSION_DENIED` must not be used for rejections
  // caused by exhausting some resource (use `RESOURCE_EXHAUSTED`
  // instead for those errors). `PERMISSION_DENIED` must not be
  // used if the caller can not be identified (use `UNAUTHENTICATED`
  // instead for those errors). This error code does not imply the
  // request is valid or the requested entity exists or satisfies
  // other pre-conditions.
  //
  // HTTP Mapping: 403 Forbidden
  PERMISSION_DENIED = 7;
  // The request does not have valid authentication credentials for the
  // operation.
  //
  // HTTP Mapping: 401 Unauthorized
  UNAUTHENTICATED = 16;
  // Some resource has been exhausted, perhaps a per-user quota, or
  // perhaps the entire file system is out of space.
  //
  // HTTP Mapping: 429 Too Many Requests
  RESOURCE_EXHAUSTED = 8;
  // The operation was rejected because the system is not in a state
  // required for the operation's execution.  For example, the directory
  // to be deleted is non-empty, an rmdir operation is applied to
  // a non-directory, etc.
  //
  // Service implementors can use the following guidelines to decide
  // between `FAILED_PRECONDITION`, `ABORTED`, and `UNAVAILABLE`:
  //  (a) Use `UNAVAILABLE` if the client can retry just the failing call.
  //  (b) Use `ABORTED` if the client should retry at a higher level
  //      (e.g., when a client-specified test-and-set fails, indicating the
  //      client should restart a read-modify-write sequence).
  //  (c) Use `FAILED_PRECONDITION` if the client should not retry until
  //      the system state has been explicitly fixed.  E.g., if an "rmdir"
  //      fails because the directory is non-empty, `FAILED_PRECONDITION`
  //      should be returned since the client should not retry unless
  //      the files are deleted from the directory.
  //
  // HTTP Mapping: 400 Bad Request
  FAILED_PRECONDITION = 9;
  // The operation was aborted, typically due to a concurrency issue such as
  // a sequencer check failure or transaction abort.
  //
  // See the guidelines above for deciding between `FAILED_PRECONDITION`,
  // `ABORTED`, and `UNAVAILABLE`.
  //
  // HTTP Mapping: 409 Conflict
  ABORTED = 10;
  // The operation was attempted past the valid range.  E.g., seeking or
  // reading past end-of-file.
  //
  // Unlike `INVALID_ARGUMENT`, this error indicates a problem that may
  // be fixed if the system state changes. For example, a 32-bit file
  // system will generate `INVALID_ARGUMENT` if asked to read at an
  // offset that is not in the range [0,2^32-1], but it will generate
  // `OUT_OF_RANGE` if asked to read from an offset past the current
  // file size.
  //
  // There is a fair bit of overlap between `FAILED_PRECONDITION` and
  // `OUT_OF_RANGE`.  We recommend using `OUT_OF_RANGE` (the more specific
  // error) when it applies so that callers who are iterating through
  // a space can easily look for an `OUT_OF_RANGE` error to detect when
  // they are done.
  //
  // HTTP Mapping: 400 Bad Request
  OUT_OF_RANGE = 11;
  // The operation is not implemented or is not supported/enabled in this
  // service.
  //
  // HTTP Mapping: 501 Not Implemented
  UNIMPLEMENTED = 12;
  // Internal errors.  This means that some invariants expected by the
  // underlying system have been broken.  This error code is reserved
  // for serious errors.
  //
  // HTTP Mapping: 500 Internal Server Error
  INTERNAL = 13;
  // The service is currently unavailable.  This is most likely a
  // transient condition, which can be corrected by retrying with
  // a backoff.
  //
  // See the guidelines above for deciding between `FAILED_PRECONDITION`,
  // `ABORTED`, and `UNAVAILABLE`.
  //
  // HTTP Mapping: 503 Service Unavailable
  UNAVAILABLE = 14;
  // Unrecoverable data loss or corruption.
  //
  // HTTP Mapping: 500 Internal Server Error
  DATA_LOSS = 15;
 }
--- a/proto/google/rpc/error_details.proto
+++ b/proto/google/rpc/error_details.proto
@ -1,200 +0,0 @@
 // Copyright 2017 Google Inc.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 syntax = "proto3";
 package google.rpc;
 import "google/protobuf/duration.proto";
 option go_package = "google.golang.org/genproto/googleapis/rpc/errdetails;errdetails";
 option java_multiple_files = true;
 option java_outer_classname = "ErrorDetailsProto";
 option java_package = "com.google.rpc";
 option objc_class_prefix = "RPC";
 // Describes when the clients can retry a failed request. Clients could ignore
 // the recommendation here or retry when this information is missing from error
 // responses.
 //
 // It's always recommended that clients should use exponential backoff when
 // retrying.
 //
 // Clients should wait until `retry_delay` amount of time has passed since
 // receiving the error response before retrying.  If retrying requests also
 // fail, clients should use an exponential backoff scheme to gradually increase
 // the delay between retries based on `retry_delay`, until either a maximum
 // number of retires have been reached or a maximum retry delay cap has been
 // reached.
 message RetryInfo {
  // Clients should wait at least this long between retrying the same request.
  google.protobuf.Duration retry_delay = 1;
 }
 // Describes additional debugging info.
 message DebugInfo {
  // The stack trace entries indicating where the error occurred.
  repeated string stack_entries = 1;
  // Additional debugging information provided by the server.
  string detail = 2;
 }
 // Describes how a quota check failed.
 //
 // For example if a daily limit was exceeded for the calling project,
 // a service could respond with a QuotaFailure detail containing the project
 // id and the description of the quota limit that was exceeded.  If the
 // calling project hasn't enabled the service in the developer console, then
 // a service could respond with the project id and set `service_disabled`
 // to true.
 //
 // Also see RetryDetail and Help types for other details about handling a
 // quota failure.
 message QuotaFailure {
  // A message type used to describe a single quota violation.  For example, a
  // daily quota or a custom quota that was exceeded.
  message Violation {
    // The subject on which the quota check failed.
    // For example, "clientip:<ip address of client>" or "project:<Google
    // developer project id>".
    string subject = 1;
    // A description of how the quota check failed. Clients can use this
    // description to find more about the quota configuration in the service's
    // public documentation, or find the relevant quota limit to adjust through
    // developer console.
    //
    // For example: "Service disabled" or "Daily Limit for read operations
    // exceeded".
    string description = 2;
  }
  // Describes all quota violations.
  repeated Violation violations = 1;
 }
 // Describes what preconditions have failed.
 //
 // For example, if an RPC failed because it required the Terms of Service to be
 // acknowledged, it could list the terms of service violation in the
 // PreconditionFailure message.
 message PreconditionFailure {
  // A message type used to describe a single precondition failure.
  message Violation {
    // The type of PreconditionFailure. We recommend using a service-specific
    // enum type to define the supported precondition violation types. For
    // example, "TOS" for "Terms of Service violation".
    string type = 1;
    // The subject, relative to the type, that failed.
    // For example, "google.com/cloud" relative to the "TOS" type would
    // indicate which terms of service is being referenced.
    string subject = 2;
    // A description of how the precondition failed. Developers can use this
    // description to understand how to fix the failure.
    //
    // For example: "Terms of service not accepted".
    string description = 3;
  }
  // Describes all precondition violations.
  repeated Violation violations = 1;
 }
 // Describes violations in a client request. This error type focuses on the
 // syntactic aspects of the request.
 message BadRequest {
  // A message type used to describe a single bad request field.
  message FieldViolation {
    // A path leading to a field in the request body. The value will be a
    // sequence of dot-separated identifiers that identify a protocol buffer
    // field. E.g., "field_violations.field" would identify this field.
    string field = 1;
    // A description of why the request element is bad.
    string description = 2;
  }
  // Describes all violations in a client request.
  repeated FieldViolation field_violations = 1;
 }
 // Contains metadata about the request that clients can attach when filing a bug
 // or providing other forms of feedback.
 message RequestInfo {
  // An opaque string that should only be interpreted by the service generating
  // it. For example, it can be used to identify requests in the service's logs.
  string request_id = 1;
  // Any data that was used to serve this request. For example, an encrypted
  // stack trace that can be sent back to the service provider for debugging.
  string serving_data = 2;
 }
 // Describes the resource that is being accessed.
 message ResourceInfo {
  // A name for the type of resource being accessed, e.g. "sql table",
  // "cloud storage bucket", "file", "Google calendar"; or the type URL
  // of the resource: e.g. "type.googleapis.com/google.pubsub.v1.Topic".
  string resource_type = 1;
  // The name of the resource being accessed.  For example, a shared calendar
  // name: "example.com_4fghdhgsrgh@group.calendar.google.com", if the current
  // error is [google.rpc.Code.PERMISSION_DENIED][google.rpc.Code.PERMISSION_DENIED].
  string resource_name = 2;
  // The owner of the resource (optional).
  // For example, "user:<owner email>" or "project:<Google developer project
  // id>".
  string owner = 3;
  // Describes what error is encountered when accessing this resource.
  // For example, updating a cloud project may require the `writer` permission
  // on the developer console project.
  string description = 4;
 }
 // Provides links to documentation or for performing an out of band action.
 //
 // For example, if a quota check failed with an error indicating the calling
 // project hasn't enabled the accessed service, this can contain a URL pointing
 // directly to the right place in the developer console to flip the bit.
 message Help {
  // Describes a URL link.
  message Link {
    // Describes what the link offers.
    string description = 1;
    // The URL of the link.
    string url = 2;
  }
  // URL(s) pointing to additional information on handling the current error.
  repeated Link links = 1;
 }
 // Provides a localized error message that is safe to return to the user
 // which can be attached to an RPC error.
 message LocalizedMessage {
  // The locale used following the specification defined at
  // http://www.rfc-editor.org/rfc/bcp/bcp47.txt.
  // Examples are: "en-US", "fr-CH", "es-MX"
  string locale = 1;
  // The localized error message in the above locale.
  string message = 2;
 }
--- a/proto/google/rpc/status.proto
+++ b/proto/google/rpc/status.proto
@ -1,92 +0,0 @@
 // Copyright 2017 Google Inc.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //     http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 syntax = "proto3";
 package google.rpc;
 import "google/protobuf/any.proto";
 option go_package = "google.golang.org/genproto/googleapis/rpc/status;status";
 option java_multiple_files = true;
 option java_outer_classname = "StatusProto";
 option java_package = "com.google.rpc";
 option objc_class_prefix = "RPC";
 // The `Status` type defines a logical error model that is suitable for different
 // programming environments, including REST APIs and RPC APIs. It is used by
 // [gRPC](https://github.com/grpc). The error model is designed to be:
 //
 // - Simple to use and understand for most users
 // - Flexible enough to meet unexpected needs
 //
 // # Overview
 //
 // The `Status` message contains three pieces of data: error code, error message,
 // and error details. The error code should be an enum value of
 // [google.rpc.Code][google.rpc.Code], but it may accept additional error codes if needed.  The
 // error message should be a developer-facing English message that helps
 // developers *understand* and *resolve* the error. If a localized user-facing
 // error message is needed, put the localized message in the error details or
 // localize it in the client. The optional error details may contain arbitrary
 // information about the error. There is a predefined set of error detail types
 // in the package `google.rpc` that can be used for common error conditions.
 //
 // # Language mapping
 //
 // The `Status` message is the logical representation of the error model, but it
 // is not necessarily the actual wire format. When the `Status` message is
 // exposed in different client libraries and different wire protocols, it can be
 // mapped differently. For example, it will likely be mapped to some exceptions
 // in Java, but more likely mapped to some error codes in C.
 //
 // # Other uses
 //
 // The error model and the `Status` message can be used in a variety of
 // environments, either with or without APIs, to provide a
 // consistent developer experience across different environments.
 //
 // Example uses of this error model include:
 //
 // - Partial errors. If a service needs to return partial errors to the client,
 //     it may embed the `Status` in the normal response to indicate the partial
 //     errors.
 //
 // - Workflow errors. A typical workflow has multiple steps. Each step may
 //     have a `Status` message for error reporting.
 //
 // - Batch operations. If a client uses batch request and batch response, the
 //     `Status` message should be used directly inside batch response, one for
 //     each error sub-response.
 //
 // - Asynchronous operations. If an API call embeds asynchronous operation
 //     results in its response, the status of those operations should be
 //     represented directly using the `Status` message.
 //
 // - Logging. If some API errors are stored in logs, the message `Status` could
 //     be used directly after any stripping needed for security/privacy reasons.
 message Status {
  // The status code, which should be an enum value of [google.rpc.Code][google.rpc.Code].
  int32 code = 1;
  // A developer-facing error message, which should be in English. Any
  // user-facing error message should be localized and sent in the
  // [google.rpc.Status.details][google.rpc.Status.details] field, or localized by the client.
  string message = 2;
  // A list of messages that carry the error details.  There is a common set of
  // message types for APIs to use.
  repeated google.protobuf.Any details = 3;
 }
--- a/proto/rove/rove.proto
+++ b/proto/rove/rove.proto
@ -1,186 +0,0 @@
 syntax = "proto3";
 // Rove
 //
 // Rove is an asychronous nomadic game about exploring a planet as part of a loose community
 package rove;
 option go_package = "github.com/mdiluz/rove/pkg/rove";
 import "google/api/annotations.proto";
 service Rove {
    // Server status
    // 
    // Responds with various details about the current server status
    rpc ServerStatus(ServerStatusRequest) returns (ServerStatusResponse) {
        option (google.api.http) = {
            get: "/server-status"
          };
    }
    // Register an account
    // 
    // Tries to register an account with the given name
    rpc Register(RegisterRequest) returns (RegisterResponse) {
        option (google.api.http) = {
            post: "/register"
            body: "*"
          };
    }
    // Send commands to rover
    // 
    // Sending commands to this endpoint will queue them to be executed during the following ticks, in the order sent
    rpc Command(CommandRequest) returns (CommandResponse) {
        option (google.api.http) = {
            post: "/command"
            body: "*"
          };
    }
    // Get radar information
    // 
    // Gets the radar output for the given rover
    rpc Radar(RadarRequest) returns (RadarResponse) {
        option (google.api.http) = {
            post: "/radar"
            body: "*"
          };
    }
    // Get rover information
    // 
    // Gets information for the account's rover
    rpc Status(StatusRequest) returns (StatusResponse) {
        option (google.api.http) = {
            post: "/status"
            body: "*"
          };
    }
 }
 message Command {
    // The command to execute
    // "move" - Move the rover in a direction, requires bearing
    // "stash" - Stashes item at current location in rover inventory
    // "repair" - Repairs the rover using an inventory object
    // "recharge" - Waits a tick to add more charge to the rover
    string command = 1;
    // The bearing, example: NE
    string bearing = 2;
 }
 message CommandRequest {
    // The account to execute these commands
    Account account = 1;
    // The set of desired commands
    repeated Command commands = 2;
 }
 // Empty placeholder
 message CommandResponse {}
 message Error {
    // An explanation for the HTTP error returned
    string error = 1;
 }
 message RadarRequest {
    // The account for this request
    Account account = 1;
 }
 message RadarResponse {
    // The range in tiles from the rover of the radar data
    int32 range = 1;
    // A 1D array representing range*2 + 1 squared set of tiles, origin bottom left and in row->column order
    bytes tiles = 2;
    // A similar array to the tile array, but containing objects
    bytes objects = 3;
 }
 message RegisterRequest {
    // The desired account name
    string name = 1;
 }
 // Empty placeholder
 message RegisterResponse{
    // The registered account information
    Account account = 1;
 }
 message StatusRequest {
    // The account for this request
    Account account = 1;
 }
 message StatusResponse {
    // The name of the rover
    string name = 1;
    // Position of the rover in world coordinates
    Vector position = 2;
    // The range of this rover's radar
    int32 range = 3;
    // The items in the rover inventory
    bytes inventory = 4;
    // The capacity of the inventory
    int32 capacity = 5;
    // The current health of the rover
    int32 integrity = 6;
    // The maximum health of the rover
    int32 maximumIntegrity = 7;
    // The energy stored in the rover
    int32 charge = 8;
    // The max energy the rover can store
    int32 maximumCharge = 9;
    // The set of currently incoming commands for this tick
    repeated Command incomingCommands = 10;
    // The set of currently queued commands
    repeated Command queuedCommands = 11;
 }
 // Empty placeholder
 message ServerStatusRequest {}
 message ServerStatusResponse {
    // The version of the server in v{major}.{minor}-{delta}-{sha} form
    string version = 1;
    // Whether the server is ready to accept requests
    bool ready = 2;
    // The tick rate of the server in minutes (how many minutes per tick)
    int32 tickRate = 3;
    // The current tick of the server
    int32 currentTick = 4;
    // The time the next tick will occur
    string next_tick = 5;
 }
 message Vector {
    int32 x = 1;
    int32 y = 2;
 }
 message Account {
    string name = 1;
    string secret = 2;
 }
--- a/proto/roveapi/roveapi.pb.go
+++ b/proto/roveapi/roveapi.pb.go
--- a/proto/roveapi/roveapi.proto
+++ b/proto/roveapi/roveapi.proto
@ -0,0 +1,322 @@
 syntax = "proto3";
 // Rove
 //
 // Rove is an asychronous nomadic game about exploring a planet as part of a
 // loose community
 package roveapi;
 option go_package = "github.com/mdiluz/rove/proto/roveapi";
 // The Rove server hosts a single game session and world with multiple players
 service Rove {
  // Server status
  // Responds with various details about the current server status
  rpc ServerStatus(ServerStatusRequest) returns (ServerStatusResponse) {}
  // Register an account
  // Tries to register an account with the given name
  rpc Register(RegisterRequest) returns (RegisterResponse) {}
  // Send commands to rover
  // Sending commands to this endpoint will queue them to be executed during the
  // following ticks, in the order sent. Commands sent within the same tick will
  // overwrite until the tick has finished and the commands are queued
  rpc Command(CommandRequest) returns (CommandResponse) {}
  // Get radar information
  // Gets the radar output for the given rover
  rpc Radar(RadarRequest) returns (RadarResponse) {}
  // Get rover information
  // Gets information for the account's rover
  rpc Status(StatusRequest) returns (StatusResponse) {}
 }
 //
 // ServerStatus
 //
 // ServerStatusRequest is an empty placeholder
 message ServerStatusRequest {}
 // ServerStatusResponse is a response with useful server information
 message ServerStatusResponse {
  // The version of the server in v{major}.{minor}-{delta}-{sha} form
  string version = 1;
  // Whether the server is ready to accept requests
  bool ready = 2;
  // The tick rate of the server in minutes (how many minutes per tick)
  int32 tickRate = 3;
  // The current tick of the server
  int32 currentTick = 4;
  // The time the next tick will occur
  string next_tick = 5;
 }
 //
 // Register
 //
 // RegisterRequest contains data to register an account
 message RegisterRequest {
  // The desired account name
  string name = 1;
 }
 // Account describes a registered account
 message Account {
  // The account name
  string name = 1;
  // The account secret value, given when creating the account
  string secret = 2;
 }
 // RegisterResponse is the response given to registering an account
 message RegisterResponse {
  // The registered account information
  Account account = 1;
 }
 //
 // Command
 //
 // CommandType defines the type of a command to give to the rover
 enum CommandType {
  none = 0;
  // Waits before performing the next command
  wait = 1;
  // Toggles the sails, either catching the wind, or charging from the sun
  toggle = 2;
  // Turns the rover in the specified bearing (requires bearing)
  turn = 3;
  // Stashes item at current location in rover inventory
  stash = 4;
  // Repairs the rover using an inventory object
  repair = 5;
  // Broadcasts a message to nearby rovers (requires data)
  broadcast = 6;
  // Salvages a neighboring dormant rover for parts
  salvage = 7;
  // Transfers remote control into dormant rover
  transfer = 8;
  // Upgrades a chosen rover specification using 5 rover parts
  upgrade = 9;
 }
 // Bearing represents a compass direction
 enum Bearing {
  // BearingUnknown an unknown invalid bearing
  BearingUnknown = 0;
  North = 1;
  NorthEast = 2;
  East = 3;
  SouthEast = 4;
  South = 5;
  SouthWest = 6;
  West = 7;
  NorthWest = 8;
 }
 // Describes the type of upgrade
 enum RoverUpgrade {
  RoverUpgradeUnknown = 0;
  Range = 1;
  Capacity = 2;
  MaximumIntegrity = 3;
  MaximumCharge = 4;
 }
 // Command is a single command for a rover
 message Command {
  // The command type
  CommandType command = 1;
  // The number of times to repeat the command after the first
  int32 repeat = 2;
  // broadcast - a simple message, must be composed of up to 3 printable ASCII
  // glyphs (32-126)
  bytes data = 3;
  // move - the bearing for the rover to turn to
  Bearing bearing = 4;
  // upgrade - the upgrade to apply to the rover
  RoverUpgrade upgrade = 5;
 }
 // CommandRequest describes a set of commands to be requested for the rover
 message CommandRequest {
  // The account to execute these commands
  Account account = 1;
  // The set of desired commands
  repeated Command commands = 2;
 }
 // CommandResponse is an empty placeholder
 message CommandResponse {}
 //
 // Radar
 //
 // Types of objects
 enum Object {
  // ObjectUnknown represents no object at all
  ObjectUnknown = 0;
  // RoverLive represents a live rover
  RoverLive = 1;
  // RoverDormant describes a dormant rover
  RoverDormant = 2;
  // RockSmall is a small stashable rock
  RockSmall = 3;
  // RockLarge is a large blocking rock
  RockLarge = 4;
  // RoverParts is one unit of rover parts, used for repairing and fixing the
  // rover
  RoverParts = 5;
 }
 enum Tile {
  // TileUnknown is a keyword for nothing
  TileUnknown = 0;
  // Rock is solid rock ground
  Rock = 1;
  // Gravel is loose rocks
  Gravel = 2;
  // Sand is sand
  Sand = 3;
 }
 // RadarRequest is the data needed to request the radar for a rover
 message RadarRequest {
  // The account for this request
  Account account = 1;
 }
 // RadarResponse describes radar information
 message RadarResponse {
  // The range in tiles from the rover of the radar data
  int32 range = 1;
  // A 1D array representing range*2 + 1 squared set of tiles, origin bottom
  // left and in row->column order
  repeated Tile tiles = 2;
  // A similar array to the tile array, but containing objects
  repeated Object objects = 3;
 }
 //
 // Status
 //
 // StatusRequest is information needed to request rover status
 message StatusRequest {
  // The account for this request
  Account account = 1;
 }
 // Log is a single log item
 message Log {
  // The unix timestamp of the log
  string time = 1;
  // The text of the log
  string text = 2;
 }
 // Vector describes a point or vector in 2D space
 message Vector {
  int32 x = 1;
  int32 y = 2;
 }
 // SailPosition represents the position of the sola sail
 enum SailPosition {
  UnknownSailPosition = 0;
  // CatchingWind means the sail is catching the wind and moving the rover
  CatchingWind = 1;
  // SolarCharging means the sail is facing the sun and charging
  SolarCharging = 2;
 }
 message RoverSpecifications {
  // The name of the rover
  string name = 1;
  // The range of this rover's radar and broadcasting
  int32 range = 2;
  // The capacity of the inventory
  int32 capacity = 3;
  // The maximum health of the rover
  int32 maximumIntegrity = 4;
  // The max energy the rover can store
  int32 maximumCharge = 5;
 }
 message RoverStatus {
  // The current direction of the rover
  Bearing bearing = 1;
  // The current position of the sails
  SailPosition sailPosition = 2;
  // The items in the rover inventory
  bytes inventory = 3;
  // The current health of the rover
  int32 integrity = 4;
  // The energy stored in the rover
  int32 charge = 5;
  // The set of currently queued commands
  repeated Command queuedCommands = 6;
 }
 message RoverReadings {
  // Position of the rover in world coordinates
  Vector position = 1;
  // The current wind direction
  Bearing wind = 2;
  // The most recent logs
  repeated Log logs = 3;
 }
 // StatusResponse is the response given to a status request
 message StatusResponse {
  // The static rover information
  RoverSpecifications spec = 1;
  // Current rover status
  RoverStatus status = 2;
  // Current rover readings
  RoverReadings readings = 3;
 }
--- a/snap/snapcraft.yaml
+++ b/snap/snapcraft.yaml
@ -27,15 +27,7 @@ apps:
    environment:
      WORDS_FILE : "$SNAP/data/words_alpha.txt"
      DATA_PATH : $SNAP_USER_DATA
-
+      
  rove-rest-server:
    command: bin/rove-server-rest-proxy
    plugs:
      - network
      - network-bind
    environment:
      DATA_PATH : $SNAP_USER_DATA
 parts:
  go-rove:
    plugin: go
Author	SHA1	Message	Date
mdiluz	f29b189a42	Update README.md Some checks failed Docker / build (push) Has been cancelled Details Tests / Build and Test (push) Has been cancelled Details	2024-09-27 10:43:28 +01:00
Marc Di Luzio	fe8029a4b3	Merge pull request #43 from mdiluz/gameplay-improvements Assorted gameplay improvements from play testing	2020-08-02 12:52:29 +01:00
Marc Di Luzio	35b25dde98	Add the upgrade command to the cmdline client	2020-08-02 12:49:15 +01:00
Marc Di Luzio	804f82dd20	Fix up commandline interface for repeat commands to go after the command	2020-08-02 12:43:44 +01:00
Marc Di Luzio	4e4af1a1be	Add a test for the upgrade command	2020-08-02 12:15:49 +01:00
Marc Di Luzio	b114b68ff7	Add upgrade command code	2020-08-02 12:03:12 +01:00
Marc Di Luzio	1200b0a2a2	Add "upgrade" command to use the rover parts	2020-08-02 11:39:28 +01:00
Marc Di Luzio	6a44633d40	Add rover parts to the cmdline pretty printer	2020-08-02 11:28:14 +01:00
Marc Di Luzio	636f0ed773	Spawn rover parts a little more frequently	2020-08-01 11:26:10 +01:00
Marc Di Luzio	018c122861	Stop spawning dormant rovers in the world	2020-08-01 11:24:53 +01:00
Marc Di Luzio	e66b899e2a	Increase the base rover range to 10	2020-08-01 11:15:34 +01:00
Marc Di Luzio	70f041ae5d	Spawn rover parts in the world	2020-08-01 11:09:15 +01:00
Marc Di Luzio	d7bda3f607	Merge pull request #42 from mdiluz/tls Add TLS to server-client communications	2020-07-26 23:57:35 +01:00
Marc Di Luzio	94767f06d3	Fix to disable TLS in tests	2020-07-26 23:53:29 +01:00
Marc Di Luzio	500e0f9557	Skip the tls verify on the client side for now	2020-07-26 23:46:42 +01:00
Marc Di Luzio	4f2a7edeb1	Skip local tests, removing duplicate test runs	2020-07-26 23:42:23 +01:00
Marc Di Luzio	cf1dff2814	Make sure the client verifies the TLS	2020-07-26 23:41:52 +01:00
Marc Di Luzio	71a0ef9920	Use the fullchain.pem not the cert.pem as explained by letsencrypt	2020-07-26 23:36:34 +01:00
Marc Di Luzio	9b03ffb7f1	Add skip verify on the client for now	2020-07-26 23:30:09 +01:00
Marc Di Luzio	4821a90143	Pass the cert name into the docker deployment	2020-07-26 23:29:58 +01:00
Marc Di Luzio	ac3844fe7a	Mount letsencrypt in the docker to read the certs	2020-07-26 23:26:36 +01:00
Marc Di Luzio	70d92c2d5e	Add TLS to gRPC	2020-07-26 23:10:39 +01:00
Marc Di Luzio	bb50fae00b	Merge pull request #41 from mdiluz/add-reflection Add gRPC reflection to the server	2020-07-26 22:53:59 +01:00
Marc Di Luzio	a321e5d72f	Add gRPC reflection to the server	2020-07-26 22:48:48 +01:00
Marc Di Luzio	49ffa18f23	Merge pull request #40 from mdiluz/add-wait-command Add wait command	2020-07-26 18:19:30 +01:00
Marc Di Luzio	e542999b91	Move test deployment out to it's own file	2020-07-26 18:11:01 +01:00
Marc Di Luzio	74e1cd4564	Convert number to repeat to avoid confusion	2020-07-26 18:02:06 +01:00
Marc Di Luzio	c0d4a809c9	Update command line client to allow specifying command number	2020-07-26 17:31:09 +01:00
Marc Di Luzio	1514603517	Allow number to be used in all commands	2020-07-26 17:19:04 +01:00
Marc Di Luzio	9dcbbee1a2	Merge pull request #39 from mdiluz/fix-help-text Big update to help text and add a simple description	2020-07-26 17:12:22 +01:00
Marc Di Luzio	bcf71f0bf9	Add a "wait" command with a number	2020-07-26 17:09:47 +01:00
Marc Di Luzio	cec61a9db7	Big update to help text and add a simple description	2020-07-26 16:57:43 +01:00
Marc Di Luzio	47e2e13c49	Merge pull request #38 from mdiluz/world-gen-improve World gen improve	2020-07-25 23:48:59 +01:00
Marc Di Luzio	6891ec8439	Adjust the terrain scale to be much larger	2020-07-25 23:39:32 +01:00
Marc Di Luzio	113090fbcb	Fix bug where we were still placing psuedo-random objects down	2020-07-25 23:39:13 +01:00
Marc Di Luzio	a235f6a5f5	Merge pull request #37 from mdiluz/destroy-rovers Destroy rovers	2020-07-25 23:24:46 +01:00
Marc Di Luzio	cd97220a11	Perform rover destruction during the main server tick	2020-07-25 23:18:21 +01:00
Marc Di Luzio	f9b3ce3edb	Destroy the rover when it has 0 integrity	2020-07-25 23:13:05 +01:00
Marc Di Luzio	abf67f7f37	Merge pull request #35 from mdiluz/fix-starting-wind Add the starting wind as north and ensure it's only updated the next day	2020-07-24 23:27:07 +01:00
Marc Di Luzio	5d4fd801c1	Add the starting wind as north and ensure it's only updated the next day	2020-07-24 23:22:46 +01:00
Marc Di Luzio	fa05e7f253	Merge pull request #34 from mdiluz/implement-salvage Add rover salvage mechanics	2020-07-24 23:08:27 +01:00
Marc Di Luzio	1f5aa765f4	Merge remote-tracking branch 'origin/master' into implement-salvage	2020-07-24 23:05:02 +01:00
Marc Di Luzio	7be0f83c5e	Fix golanglint missing error check	2020-07-24 22:58:59 +01:00
Marc Di Luzio	a0e04b7e3a	Placed dormant world rovers randomly have better base stats	2020-07-24 22:56:35 +01:00
Marc Di Luzio	a93ce97b0b	Only assign rovers to accounts if given an account	2020-07-24 22:54:06 +01:00
Marc Di Luzio	57621d169a	Implement a test for transfer and fix bugs	2020-07-24 22:50:47 +01:00
Marc Di Luzio	fdfcc88540	Move the account registration into the world	2020-07-24 22:50:35 +01:00
Marc Di Luzio	6f2d67bd7c	Tag rovers by the controlling account	2020-07-24 22:22:32 +01:00
Marc Di Luzio	e840b3e47b	Move accountant into world	2020-07-24 20:06:06 +01:00
Marc Di Luzio	1e4d642038	Add rover transfer command and implementation Need to swap the accounts	2020-07-24 20:01:35 +01:00
Marc Di Luzio	5b2ea533f4	Remove incorrect proto comment	2020-07-24 19:46:32 +01:00
Marc Di Luzio	edd3e5a6cb	Fix test by removing object before warping rover	2020-07-24 19:42:34 +01:00
Marc Di Luzio	b0ff3eb6ea	Remove redundant tests (covered in command_tests)	2020-07-24 19:39:33 +01:00
Marc Di Luzio	be36f0631b	Add logs for failed stashes	2020-07-24 19:39:25 +01:00
Marc Di Luzio	c321f88d96	Add code for salvage command	2020-07-24 19:39:14 +01:00
Marc Di Luzio	7cccb4394f	Fix the help text comment	2020-07-24 19:28:44 +01:00
Marc Di Luzio	524487ce14	Stop the dormant rover from being a blocking object	2020-07-24 19:27:54 +01:00
Marc Di Luzio	2f1ccdfdb9	Make repair require rover parts	2020-07-24 19:08:39 +01:00
Marc Di Luzio	ce6e10afbb	Add salvage command to main.go man page	2020-07-24 19:08:03 +01:00
Marc Di Luzio	2c1bb80779	Add salvage command Slight refactor to re-use command variables Also fixes the cmdline client turn command	2020-07-23 20:57:36 +01:00
Marc Di Luzio	a5ac809387	Merge pull request #33 from mdiluz/dev General dev	2020-07-23 18:50:31 +01:00
Marc Di Luzio	41cd93e986	Add command test for no command as error	2020-07-23 18:41:12 +01:00
Marc Di Luzio	8cc3b9155e	Implement broadcast command test	2020-07-23 18:40:32 +01:00
Marc Di Luzio	8a8a27ab47	Add a test for the repair command	2020-07-23 18:37:54 +01:00
Marc Di Luzio	3bfc91b8f6	Add command test for stashing	2020-07-23 16:58:17 +01:00
Marc Di Luzio	8279a08a37	Limit the log entries to a max number	2020-07-23 16:47:39 +01:00
Marc Di Luzio	46d904acc6	Rename and comment ticksPerNormalMove	2020-07-23 16:44:15 +01:00
Marc Di Luzio	be74183878	Merge pull request #32 from mdiluz/simplifystatus Organise the status response into sub-sections	2020-07-23 16:33:10 +01:00
Marc Di Luzio	13e4d6a5e6	Remove an old log left in	2020-07-23 00:34:57 +01:00
Marc Di Luzio	f7192b3997	Organise the status response into sub-sections	2020-07-23 00:32:19 +01:00
Marc Di Luzio	4cbf4a9ab5	Merge pull request #31 from mdiluz/remove-doublequeue Remove the incoming command streams, de-scopes and simplifies	2020-07-23 00:18:51 +01:00
Marc Di Luzio	2bc2477128	Remove the incoming command streams, de-scopes and simplifies	2020-07-23 00:13:28 +01:00
Marc Di Luzio	d49d034f0e	Merge pull request #30 from mdiluz/sailing Swap out movement mechanics for sailing mechanics	2020-07-23 00:03:26 +01:00
Marc Di Luzio	6adc652cea	Fix lint errors	2020-07-22 23:59:28 +01:00
Marc Di Luzio	1e18610c5c	Set tick rate to 3	2020-07-22 23:57:22 +01:00
Marc Di Luzio	5d80cb2596	Implement sailing tests and fix into-the-wind bug	2020-07-22 23:50:42 +01:00
Marc Di Luzio	c89c5f6e74	Implement current wind direction and rover wind movement	2020-07-22 23:36:13 +01:00
Marc Di Luzio	c94ac68f44	Remove all json tags, simply not needed	2020-07-22 19:55:38 +01:00
Marc Di Luzio	075a502103	Pull the repair function out	2020-07-22 19:25:47 +01:00
Marc Di Luzio	9e42764398	Update the rover list to a list of pointers	2020-07-22 19:25:32 +01:00
Marc Di Luzio	447dbe3582	Fix a test comment	2020-07-22 19:24:55 +01:00
Marc Di Luzio	6b5d5abea1	Rename the world tick function and set the tick rate back to default	2020-07-22 19:24:36 +01:00
Marc Di Luzio	8667f55143	Simplify by making command streams pointer lists like in proto	2020-07-21 23:52:14 +01:00
Marc Di Luzio	f78efd1223	Add SailPosition to the rover and implement toggle command This also converts the commands to use the proto type for simplicity	2020-07-21 23:44:06 +01:00
Marc Di Luzio	6f30b665c7	Make the bearings 8 directional	2020-07-21 22:58:59 +01:00
Marc Di Luzio	6c75f07aff	Remove move and recharge commands in favor of toggle command for the sails	2020-07-21 22:57:43 +01:00
Marc Di Luzio	89123394cd	Merge pull request #28 from mdiluz/dormant-rovers Dormant rovers	2020-07-19 19:20:03 +01:00
Marc Di Luzio	77212c7258	Fix logic for rover marshal test	2020-07-19 18:57:22 +01:00
Marc Di Luzio	bffad84181	Don't use noise for rover spawns for now	2020-07-19 18:57:12 +01:00
Marc Di Luzio	04d7a5a4ca	Fill in the dormant rover log	2020-07-19 18:47:54 +01:00
Marc Di Luzio	211771121f	Extract rover naming to rover.go	2020-07-19 18:47:44 +01:00
Marc Di Luzio	d3c480cb04	Add dormant rover data marshalled into obj data	2020-07-19 18:39:16 +01:00
Marc Di Luzio	1281713211	Clear locations before warp in tests	2020-07-19 18:35:12 +01:00
Marc Di Luzio	9130cf2517	Move atlas package into rove	2020-07-19 18:30:07 +01:00
Marc Di Luzio	c48274eb23	Small refactor in GetObject	2020-07-19 18:27:58 +01:00
Marc Di Luzio	ddbbdce1f8	Move default rover params to function	2020-07-19 18:23:11 +01:00
Marc Di Luzio	faa1271c5a	Try and very rarely spawn a dormant rover	2020-07-19 13:57:45 +01:00
Marc Di Luzio	37d828c457	Rename the rock noise	2020-07-19 13:53:38 +01:00
Marc Di Luzio	959cbfa15a	Combine the two noise functions, we only need one	2020-07-19 13:51:49 +01:00
Marc Di Luzio	c637ed37b9	Make the dormat rover blocking	2020-07-19 13:49:43 +01:00
Marc Di Luzio	87a9abcd12	Add a glyph for the dormant rover	2020-07-19 13:49:34 +01:00
Marc Di Luzio	1eba9a8652	Pull world gen out into interface	2020-07-19 13:41:47 +01:00
Marc Di Luzio	4f1a9c2c2b	Re-order object types	2020-07-19 13:27:59 +01:00
Marc Di Luzio	713699687f	Add a dormat rover data type	2020-07-19 13:27:38 +01:00
Marc Di Luzio	fd0992353d	Add data to objects	2020-07-19 13:27:29 +01:00
Marc Di Luzio	e27398dbc0	Merge pull request #27 from mdiluz/bearings Refactor bearing out to proto file	2020-07-19 13:16:59 +01:00
Marc Di Luzio	4b7510ffa1	Merge remote-tracking branch 'origin/master' into bearings	2020-07-19 13:13:36 +01:00
Marc Di Luzio	57f668ae54	Reinstate BearingFromString function	2020-07-19 13:13:09 +01:00
Marc Di Luzio	c13151b60f	Merge pull request #26 from mdiluz/glyphs Refactor to move object/tile types into the proto file	2020-07-19 13:02:47 +01:00
Marc Di Luzio	db8ed0302d	Merge glyphs branch	2020-07-19 13:01:25 +01:00
Marc Di Luzio	cd6a275bb9	Move code to internal cmd/main	2020-07-19 12:59:36 +01:00
Marc Di Luzio	4e0e55af88	Move bearing into proto file	2020-07-19 12:54:41 +01:00
Marc Di Luzio	3796ee09a3	Merge remote-tracking branch 'origin/master' into glyphs	2020-07-19 12:38:46 +01:00
Marc Di Luzio	0a8b8d5979	Merge pull request #25 from mdiluz/remove-diagonal-moves Remove diagonal moves	2020-07-19 12:37:59 +01:00
Marc Di Luzio	e9188dbbf6	Auto-format proto file	2020-07-19 12:37:36 +01:00
Marc Di Luzio	da91d31649	MOve glyph code into client	2020-07-19 12:36:48 +01:00
Marc Di Luzio	4a89cb9d6e	Move glyph functions out to the glyph file	2020-07-19 12:34:54 +01:00
Marc Di Luzio	7bdfa44fb6	Fix up the concept of "None" tiles and objects Replace with "Unknown" which is effectively an invalid value	2020-07-19 12:33:11 +01:00
Marc Di Luzio	305f64ec38	Large refactor, move object and tile types out into the proto	2020-07-19 12:26:57 +01:00
Marc Di Luzio	24d4fe9273	Convert tiles and object types to typed consts	2020-07-19 11:59:14 +01:00
Marc Di Luzio	7e41ac0028	Rename the glyphs	2020-07-19 11:57:41 +01:00
Marc Di Luzio	f665436007	Convert objects and tiles to base ints	2020-07-19 11:54:11 +01:00
Marc Di Luzio	acdd019093	Add Glyph methods to convert to a glyph	2020-07-19 11:50:19 +01:00
Marc Di Luzio	53d6ad08d9	Rename Type to ObjectType	2020-07-19 11:47:19 +01:00
Marc Di Luzio	a0b811a659	Move glyph definitions into a central type	2020-07-19 11:46:37 +01:00
Marc Di Luzio	5814ac95b8	Make sure we fallthrough for the NES cases	2020-07-19 11:29:28 +01:00
Marc Di Luzio	c2e3c9f090	Reject move commands in non-cardinal directions	2020-07-19 11:26:08 +01:00
Marc Di Luzio	0e731df1a3	Merge pull request #24 from mdiluz/fix-southwest Fix SW direction to go south rather than north	2020-07-11 17:31:40 +01:00
Marc Di Luzio	105d69bd7c	Fix SW direction to go south rather than north	2020-07-11 17:25:38 +01:00
Marc Di Luzio	79598c3373	Merge pull request #23 from mdiluz/update-page Small clean up	2020-07-10 21:43:25 +01:00
Marc Di Luzio	9593602dc5	Move flatpak file to data	2020-07-10 21:38:16 +01:00
Marc Di Luzio	327c246c8e	Remove vscode viles	2020-07-10 21:37:19 +01:00
Marc Di Luzio	346bc940e2	Merge pull request #22 from mdiluz/update-page Update the github page markdown	2020-07-10 21:36:00 +01:00
Marc Di Luzio	427db95b5b	Fix grammar	2020-07-10 21:32:02 +01:00
Marc Di Luzio	a0946f9e58	Merge pull request #21 from mdiluz/mdiluz-patch-1 Update README.md	2020-07-10 21:30:46 +01:00
Marc Di Luzio	5c4d7469bb	Update the github page markdown	2020-07-10 21:30:15 +01:00
Marc Di Luzio	3bad9f0122	Update README.md Fix proto link and amend text	2020-07-10 20:59:26 +01:00
Marc Di Luzio	3f2ae97048	Merge pull request #20 from mdiluz/more-improvements Various refactors and improvements	2020-07-10 20:39:40 +01:00
Marc Di Luzio	737534f739	Move roveapi into the proto dir	2020-07-10 19:01:41 +01:00
Marc Di Luzio	46f81abbd7	Move accounts into rove-server.internal	2020-07-10 18:57:57 +01:00
Marc Di Luzio	9ccb7ac019	Remove google proto files, no longer needed	2020-07-10 18:48:03 +01:00
Marc Di Luzio	f0ab2abf6e	Move object into atlas	2020-07-10 18:39:33 +01:00
Marc Di Luzio	f40f7123d4	Move bearing into maths	2020-07-10 18:24:54 +01:00
Marc Di Luzio	5b1fe61097	Move vector into maths package	2020-07-10 18:22:59 +01:00
Marc Di Luzio	97d3be000b	Re-order some World members	2020-07-10 18:14:32 +01:00
Marc Di Luzio	065f79cbb3	Fix warping to non-empty space	2020-07-10 18:11:38 +01:00
Marc Di Luzio	b534ac0516	Rename generated rove package to roveapi and the game package to rove	2020-07-10 18:09:51 +01:00
Marc Di Luzio	b451ea519d	Make sure the accounts are saved as well	2020-07-10 17:21:59 +01:00
Marc Di Luzio	dc2800fa54	Move Accountant behind an interface	2020-07-10 17:09:47 +01:00
Marc Di Luzio	c1267829ac	Clear out genproto mod require	2020-07-10 17:00:30 +01:00
Marc Di Luzio	d6349d081e	Clear the tile before warping to it	2020-07-10 16:59:55 +01:00
Marc Di Luzio	9a7c48ae78	Make chunkBasedAtlas private	2020-07-10 16:56:17 +01:00
Marc Di Luzio	a0be8a463c	Pull out chunk based atlas into new file	2020-07-10 16:54:43 +01:00
Marc Di Luzio	655e00b41f	Don't expose Chunk externally	2020-07-10 16:52:31 +01:00
Marc Di Luzio	fb2ffc5252	Convert Atlas to an interface	2020-07-10 16:52:00 +01:00
Marc Di Luzio	5ac44d85cb	Add a warning to missing DATA_PATH env	2020-07-10 16:38:49 +01:00
Marc Di Luzio	3665a62c6e	Merge pull request #19 from mdiluz/clean-proto De-scope and proto clean	2020-07-10 09:38:33 +01:00
Marc Di Luzio	6c1ee311cd	Delete unused files	2020-07-10 00:29:06 +01:00
Marc Di Luzio	fe6dae4c52	Update the generated file for rove.pb.go	2020-07-10 00:27:14 +01:00
Marc Di Luzio	0be6aa7c12	Clean, format and comment the rove.proto file	2020-07-10 00:26:49 +01:00
Marc Di Luzio	96a137ad2f	Simplify - remove duplicate command types in favor of a better defined Command type in proto	2020-07-10 00:12:54 +01:00
Marc Di Luzio	7d780d05bd	De-scope - remove swagger docs and http proxy HTTP proxy was becoming annoying to maintain, and gRPC is easier to use anyway swagger docs are just part of the fallout	2020-07-10 00:12:35 +01:00
Marc Di Luzio	59a1bdc14b	Update launch.json Remove old comments	2020-07-09 23:15:33 +01:00
Marc Di Luzio	bffe539d77	Merge pull request #18 from mdiluz/fix-missing-message-in-reply Fix missing broadcast message in status reply	2020-07-09 22:57:42 +01:00
Marc Di Luzio	b032fdbfe2	Fix missing broadcast message in status reply	2020-07-09 22:52:58 +01:00
Marc Di Luzio	23764a3fc3	Merge pull request #17 from mdiluz/add-broadcast-to-cmdline Add broadcast command to the cmdline client	2020-07-09 22:44:51 +01:00
Marc Di Luzio	091469dd91	Add broadcast command to the cmdline client	2020-07-09 22:37:55 +01:00
Marc Di Luzio	db19e4a657	Merge pull request #16 from mdiluz/rover-logs-and-communication Add "broadcast" command	2020-07-09 22:19:42 +01:00
Marc Di Luzio	e21023ec25	Update generated files	2020-07-09 22:12:13 +01:00
Marc Di Luzio	d4d82c38e0	Add "broadcast" command This will send a readable ascii triplet to all rovers in range	2020-07-09 22:05:12 +01:00
Marc Di Luzio	2671398593	Merge pull request #15 from mdiluz/rover-logs-and-communication Add rover logs	2020-07-09 19:42:48 +01:00
Marc Di Luzio	30ca488890	Use string for the timestamp, proto uses this under the hood anyway https://github.com/grpc-ecosystem/grpc-gateway/issues/438	2020-07-09 19:38:23 +01:00
Marc Di Luzio	b748846c55	Use a unix timestamp rather than a timestamppb	2020-07-09 19:29:04 +01:00
Marc Di Luzio	55c85d2a22	Add logs to the rover status output	2020-07-09 19:01:09 +01:00
Marc Di Luzio	b2f169d99f	Remove Warped log, unneeded	2020-07-09 18:31:51 +01:00
Marc Di Luzio	8866f28bf5	Add test coverage checks for logging additions	2020-07-09 18:26:24 +01:00
Marc Di Luzio	0dc3cab9c0	Store log entries for actions in the rover	2020-07-09 18:19:49 +01:00
Marc Di Luzio	84be8bff05	Merge pull request #14 from mdiluz/improved-world-gen Noise based world gen	2020-07-09 00:11:46 +01:00
Marc Di Luzio	9682cfa7ea	Spawn objects using OpenSimplex noise as well	2020-07-09 00:04:46 +01:00
Marc Di Luzio	4b715bdff3	Move to OpenSimplex noise Apart from other benefits, this produces much nicer direction agnostic noise	2020-07-08 23:58:11 +01:00
Marc Di Luzio	7b4541716a	Add gravel tiles	2020-07-08 23:45:52 +01:00
Marc Di Luzio	ed9ecef80a	Add perlin based generation for the terrain tiles	2020-07-08 23:38:08 +01:00
Marc Di Luzio	10959ef726	Refactor populate to be an Atlas function This simplifies usage greatly	2020-07-08 19:40:15 +01:00