;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Variable declarations ;;
;;;;;;;;;;;;;;;;;;;;;;;;;;;

globals
[
  grid-x-inc  ;; the amount of patches in between two roads in the x direction
  grid-y-inc  ;; the amount of patches in between two roads in the y direction
  acceleration  ;; the constant that controls how much a car speeds up or slows down by if it is to accelerate or decelerate
  phase  ;; keeps track of the phase
  clock  ;; keeps track of the total times thru the go procedure
  num-cars-stopped  ;; the number of cars that are stopped during a single pass thru the go procedure
  old-display-which-metric  ;; holds the value of display-which-metric for the last time through the go procedure

  ;; patch agentsets
  intersections  ;; agentset containing the patches that are intersections
  roads  ;; agentset containing the patches that are roads

  ;; string and list variables that hold data passed accumulated in the model run
  wait-data  ;; list that holds the average wait time of the cars for each pass through the go procedure
  stopped-data  ;; list that holds the number of stopped of the cars for each pass through the go procedure
  speed-data  ;; list that holds the average speed of the cars for each pass through the go procedure
  time-data  ;; list that holds the value of clock for each pass through the go procedure
  
  ;; variables for plotting client-defined metrics in the client plot
  current-client-metric  ;; the current metric that is being plotted in the client plot
  current-intersection-for-client-metric  ;; the intersection whose metric we are currently plotting in the client plot
  old-intersection-for-client-metric  ;; the last intersection for current-intersection-for-metric

  ;;quick start instructions variables
  quick-start  ;; the current quickstart instruction displayed in the quickstart monitor
  qs-item  ;; the index of the current quickstart instruction
  qs-items  ;; the list of quickstart instructions
]

turtles-own
[
  speed  ;; the speed of the turtle
  up-car?  ;; this will be true if the turtle moves downwards and false if it moves to the right
  wait-time  ;; the amount of time since the last time a turtle has moved
]

patches-own
[
  intersection?  ;; this is true if the patch is at the intersection of two roads
  accident?  ;; this is true if a crash has occurred at this intersection.  this will never be true for a non-intersection patch
  green-light-up?  ;; this is true if the green light is above the intersection.  otherwise, it is false.  this is only true for patches that are intersections.
  my-row  ;; this holds the row of the intersection counting from the upper left corner of the graphics window.  it is -1 for patches that are not intersections.
  my-column  ;; this holds the column of the intersection counting from the upper left corner of the graphics window.  it is -1 for patches that are not intersections.
  user-id  ;; this holds the user-id that corresponds to the intersection.  it is -1 for patches that are not intersections.
  my-phase  ;; this holds the phase for the intersection.  it is -1 for patches that are not intersections.
  
  ;; client plot variables
  ;; this is a list of the values generated by the my-plot-metric that 
  ;; will be plotted when this intersection's metric is plotted in the client plot
  my-plot-data
  ;; this is NetLogo code generates values for this intersection's values for my-plot-data.
  ;; the code should be a meaningful metric of how to measure traffic efficiency.
  my-plot-metric
]


;;;;;;;;;;;;;;;;;;;;;
;; Setup Functions ;;
;;;;;;;;;;;;;;;;;;;;;

to startup
  setup true
  setup-quick-start
  hubnet-set-client-interface "COMPUTER" [ "clients/Gridlock Alternate client.nlogo" ]
  hubnet-reset
end

;; Initialize the display by giving the global and patch variables initial values.
;; Create num-cars of turtles if there are enough road patches for one turtle to be created per road patch.
;; Setup the plots
;; All code in setup is done if full-setup? is true.  If it is false, then it doesn't clear the information
;; about the users; users still retain the same light that they had before.
;; "setup false" is done by the re-run button.
to setup [full-setup?]
  cc
  if full-setup?  ;; We only want to clear the patches if the we are doing a full-setup
  [ clear-patches ]
  clear-turtles
  clear-all-plots

  setup-globals full-setup?

  ;; First we ask the patches to draw themselves and set up a few variables
  setup-patches full-setup?

  set-default-shape turtles "car"

  if (number > count roads)
  [
    user-message "There are too many cars for the amount of road.  " +
    "Either increase the amount of roads by increasing the GRID-SIZE-X " +
    "or GRID-SIZE-Y sliders, or decrease the number of cars by lowering " +
    "the NUMBER slider.\nThe setup has stopped."
    stop
  ]

  ;; Now create the turtles and have each created turtle call the functions setup-cars and set-car-color
  cct number
  [
    setup-cars
    set-car-color
    record-data
  ]

  ;; give the turtles an initial speed
  ask turtles
  [ set-car-speed ]

  update-list-info

  setup-plots
end

;; Initialize the global variables to appropriate values
to setup-globals [full-setup?]
  set phase 0
  set clock 0
  set num-cars-stopped 0
  if full-setup?
  [
    set grid-x-inc screen-size-x / grid-size-x
    set grid-y-inc screen-size-y / grid-size-y
  ]

  ;; initialize the lists and string for HubNet
  set wait-data []
  set stopped-data []
  set speed-data []
  set time-data []

  set current-client-metric ""
  set current-intersection-for-client-metric nobody
  set old-intersection-for-client-metric nobody

  ;; don't make acceleration 0.1 since we could get a rounding error and end up on a patch boundary
  set acceleration 0.099
end

;; Make the patches have appropriate colors, setup the roads and intersections agentsets,
;; and initialize the traffic lights to one setting
to setup-patches [full-setup?]
  if full-setup?
  [
    ;; initialize the patch-own variables and color the patches to a base-color
    ask patches
    [
      set intersection? false
      set accident? false
      set green-light-up? true
      set my-row -1
      set my-column -1
      set user-id -1
      set my-phase -1
      set my-plot-data []
      set my-plot-metric ""

      set pcolor brown + 3
    ]

    ;; initialize the global variables that hold patch agentsets
    set roads patches with [ (floor ((pxcor + screen-edge-x - floor(grid-x-inc - 1)) mod grid-x-inc) = 0) or
                             (floor ((pycor + screen-edge-y) mod grid-y-inc) = 0) ]
    set intersections roads with [ (floor ((pxcor + screen-edge-x - floor(grid-x-inc - 1)) mod grid-x-inc) = 0) and
                                   (floor ((pycor + screen-edge-y) mod grid-y-inc) = 0) ]

    ask roads
    [ set pcolor white ]
  ]
  setup-intersections full-setup?
end

;; Give the intersections appropriate values for the intersection?, my-row, and my-column 
;; patch variables.  Make all the traffic lights start off so that the lights are red 
;; horizontally and green vertically.  
to setup-intersections [full-setup?]
  ask intersections
  [
    set intersection? true
    set green-light-up? true
    set my-phase 0
    if full-setup?
    [
      set my-row floor ((pycor + screen-edge-y) / grid-y-inc )
      set my-column floor ((pxcor + screen-edge-x) / grid-x-inc )
    ]
    set-signal-colors
  ]
end

;; Initialize the turtle variables to appropriate values and place the turtle on an empty road patch.
to setup-cars  ;; turtle procedure
  set speed 0
  set wait-time 0

  put-on-empty-road

  ifelse intersection?
  [
    ifelse random 2 = 1
    [ set up-car? true ]
    [ set up-car? false ]
  ]
  [
    ifelse (floor ((pxcor + screen-edge-x - floor(grid-x-inc - 1)) mod grid-x-inc) = 0)
    [ set up-car? true ]
    [ set up-car? false ]
  ]

  ifelse up-car?
  [ set heading 180 ]
  [ set heading 90 ]
end

;; Find a road patch without any turtles on it and place the turtle there.
to put-on-empty-road  ;; turtle procedure
  locals [road]

  set road random-one-of roads
  setxy (pxcor-of road) (pycor-of road)
  if any? other-turtles-here
  [ put-on-empty-road ]
end

;; Initialize the plots
to setup-plots
set-current-plot "Stopped Cars"
  set-plot-y-range 0 number
  plot num-cars-stopped
  
  set-current-plot "Average Wait Time of Cars"
  plot mean values-from turtles [wait-time]
  
  set-current-plot "Average Speed of Cars"
  set-plot-y-range 0 speed-limit
  plot mean values-from turtles [speed]
end

;; give the user some information about what the setup button does so they can 
;; know whether they want to proceed before actually doing the setup
to setup-prompt
  if user-yes-or-no? ("The SETUP button should only be used when starting "
              + "over with a new group (such as a new set of students) since "
              + "all data is lost.  Use the RE-RUN button for continuing with "
              + "an existing group."
              + "\n\nDo you really want to setup the model?")
  [ setup true ]
end


;;;;;;;;;;;;;;;;;;;;;;;
;; Runtime Functions ;;
;;;;;;;;;;;;;;;;;;;;;;;

;; receives information from the clients and runs the simulation
to go
  every delay
  [
    ;; get commands and data from the clients
    listen-clients
    
    ;; clear any accidents from the last time thru the go procedure
    clear-accidents
    
    ;; if there are any intersections that are to switch automatically, have them change their color
    set-signals
    set num-cars-stopped 0

    ;; set the turtles speed for this time thru the procedure, move them forward their speed,
    ;; record data for plotting, and set the color of the turtles
    ;; to an appropriate color based on their speed
    ask turtles
    [
      set-car-speed
      fd speed
      record-data
      set-car-color
    ]
    ;; crash the cars if crash? is true
    if crash?
    [ crash-cars ]

    ;; update the information in the lists of plot data
    update-list-info

    ;; update the plots with the new information from this pass thru the procedure
    do-plotting
    ;; update the clock and the phase
    clock-tick
  ]
end

;; reports the amount of seconds by which to slow the model down
to-report delay
  ifelse simulation-speed <= 0
  [ report ln (10 / 0.001) ]
  [ report ln (10 / simulation-speed) ]
end

;; have the traffic lights change color if phase equals each intersections' my-phase
to set-signals
  locals [ intersections-to-change ]
  ifelse auto?
  [
    set intersections-to-change intersections with
      [phase = floor ((my-phase * ticks-per-cycle) / 100)]
  ]
  [
    set intersections-to-change intersections with
      [user-id = -1 and phase = floor ((my-phase * ticks-per-cycle) / 100)]
  ]
  ask intersections-to-change
  [
    set green-light-up? (not green-light-up?)
    set-signal-colors
  ]
end

;; This procedure checks the variable green-light-up? at each intersection and sets the
;; traffic lights to have the green light up or the green light to the left.
to set-signal-colors  ;; intersection (patch) procedure
  ifelse power?
  [
    ifelse green-light-up?
    [
      set (pcolor-of patch-at -1 0) red
      set (pcolor-of patch-at 0 1) green
    ]
    [
      set (pcolor-of patch-at -1 0) green
      set (pcolor-of patch-at 0 1) red
    ]
  ]
  [
    set (pcolor-of patch-at -1 0) white
    set (pcolor-of patch-at 0 1) white
  ]
end

;; set any intersection's color that had an accident back to white and make accident? false
to clear-accidents
  if crash?
  [
    ask patches with [accident?]
    [
      set pcolor white
      set accident? false
    ]
  ]
end

;; set the turtles' speed based on whether they are at a red traffic light or the speed of the
;; turtle (if any) on the patch in front of them
to set-car-speed  ;; turtle procedure
  ifelse pcolor = red
  [ set speed 0 ]
  [
    ifelse up-car?
    [ set-speed 0 -1 ]
    [ set-speed 1 0 ]
  ]
end

;; set the speed variable of the turtle to an appropriate value (not exceeding the
;; speed limit) based on whether there are turtles on the patch in front of the turtle
to set-speed [delta-x delta-y]  ;; turtle procedure
  locals
  [
    up-cars?-ahead
    turtles-ahead
  ]

  ;; get the turtles on the patch in front of the turtle
  ask patch-at delta-x delta-y
  [ set turtles-ahead turtles-here ]

  ;; if there are turtles in front of the turtle, slow down
  ;; otherwise, speed up
  ifelse any? turtles-ahead
  [
    set up-cars?-ahead values-from turtles-ahead [up-car?]
    ifelse member? up-car? up-cars?-ahead and member? (not up-car?) up-cars?-ahead
    [
      if not crash?
      [ set speed 0 ]
    ]
    [
      set speed speed-of one-of turtles-ahead
      slow-down
    ]
  ]
  [ speed-up ]
end

;; decrease the speed of the turtle
to slow-down  ;; turtle procedure
  ifelse speed <= 0  ;;if speed < 0
  [ set speed 0 ]
  [ set speed speed - acceleration ]
end

;; increase the speed of the turtle
to speed-up  ;; turtle procedure
  ifelse speed > speed-limit
  [ set speed speed-limit ]
  [ set speed speed + acceleration ]
end

;; set the color of the turtle to a different color based on how fast the turtle is moving
to set-car-color  ;; turtle procedure
  ifelse speed < (speed-limit / 2)
  [ set color blue ]
  [ set color cyan - 2 ]
end

;; keep track of the number of stopped turtles and the amount of time a turtle has been stopped 
;; if its speed is 0
to record-data  ;; turtle procedure
  ifelse speed = 0
  [
    set num-cars-stopped num-cars-stopped + 1
    set wait-time wait-time + 1
  ]
  [ set wait-time 0 ]
end

;; crash any turtles at the same intersection going in different directions
to crash-cars
  ask intersections with [any? turtles-here with [up-car?] and any? turtles-here with [not up-car?]]
  [
    set accident? true
    set pcolor orange
  ]
end

;; add the new information from this pass thru the go procedure to the HubNet lists
to update-list-info
  set wait-data lput (mean values-from turtles [wait-time]) wait-data
  set stopped-data lput num-cars-stopped stopped-data
  set speed-data lput (mean values-from turtles [speed]) speed-data
  set time-data lput clock time-data
  ask intersections with [ my-plot-metric != "" ]
  [ add-new-client-metric-value ]
end

;; verify that my-plot-metric is a valid metric that will result in a number 
;; and add that number to the my-plot-data list for the intersection
to add-new-client-metric-value  ;; intersection procedure
  locals [ new-value error-message ]
  set error-message __check-syntax ("plotxy clock " + my-plot-metric)
  ifelse error-message = ""
  [
    set new-value run-result my-plot-metric
    ifelse is-number? new-value
    [ set my-plot-data lput list clock new-value my-plot-data ]
    [
      hubnet-send user-id "metric-error-message" (my-plot-metric 
        + " does not produce a numeric value.")
      clear-client-plot-data
    ]
  ]
  [
    hubnet-send user-id "metric-error-message" (my-plot-metric 
      + " does not produce a numeric value.")
    clear-client-plot-data
  ]
end

;; clears the intersection's plot data and the client plot if 
;; current-intersection-for-metric is the intersection
to clear-client-plot-data  ;; intersection procedure
  set my-plot-metric ""
  set my-plot-data []
  if current-intersection-for-client-metric = self
  [
    set-current-plot "Client Plot"
    clear-plot
    set current-intersection-for-client-metric nobody
    set old-intersection-for-client-metric nobody
    set current-client-metric ""
  ]
end

;; plot the data from this pass thru the go procedure
to do-plotting
  if current-intersection-for-client-metric != nobody
  [ update-client-plot ]
  ifelse display-which-metric = old-display-which-metric
  [
    ;; don't plot if no plots should be plotted
    if display-which-metric != 0
    [
      ;; we only need to plot 1 value since the current plot is the same as the plot we are supposed to plot to now
      ifelse display-which-metric = 1
      [ plot-new-value "Stopped Cars" num-cars-stopped ]
      [
        ifelse display-which-metric = 2
        [ plot-new-value "Average Speed of Cars" mean values-from turtles [speed] ]
        [
          ifelse display-which-metric = 3
          [ plot-new-value "Average Wait Time of Cars" mean values-from turtles [wait-time] ]
          [
            ;; therefore display-which-metric = 4
            plot-new-value "Stopped Cars" num-cars-stopped
            plot-new-value "Average Wait Time of Cars" mean values-from turtles [wait-time]
            plot-new-value "Average Speed of Cars" mean values-from turtles [speed]
          ]
        ]
      ]
    ]
  ]
  [
    ;; otherwise, we need to plot at least 1 list since the plot we are supposed to plot to is different from the plot we last plotted in
    ifelse display-which-metric = 0
    [ clear-all-non-client-plot ]
    [
      ifelse display-which-metric = 1
      [ clear-plots-and-plot-in-new-plot "Stopped Cars" stopped-data ]
      [
        ifelse display-which-metric = 2
        [ clear-plots-and-plot-in-new-plot "Average Speed of Cars" speed-data ]
        [
          ifelse display-which-metric = 3
          [ clear-plots-and-plot-in-new-plot "Average Wait Time of Cars" wait-data ]
          [
            ;; therefore display-which-metric = 4
            ifelse old-display-which-metric = 1
            [ plot-value-and-lists "Stopped Cars" num-cars-stopped "Average Speed of Cars" speed-data "Average Wait Time of Cars" wait-data ]
            [
              ifelse old-display-which-metric = 2
              [ plot-value-and-lists "Average Speed of Cars" (mean values-from turtles [speed]) "Stopped Cars" stopped-data "Average Wait Time of Cars" wait-data ]
              [
                ifelse old-display-which-metric = 3
                [ plot-value-and-lists "Average Wait Time of Cars" (mean values-from turtles [wait-time]) "Stopped Cars" stopped-data "Average Speed of Cars" speed-data ]
                [
                  ;; therefore old-display-which-metric = 0
                  plot-new-list "Stopped Cars" stopped-data
                  plot-new-list "Average Speed of Cars" speed-data
                  plot-new-list "Average Wait Time of Cars" wait-data
                ]
              ]
            ]
          ]
        ]
      ]
    ]
    set old-display-which-metric display-which-metric
  ]
end

;; update the client plot with the appropriate information
to update-client-plot
  locals [ index current-item ]
  set-current-plot "Client Plot"
  ifelse current-intersection-for-client-metric != old-intersection-for-client-metric
  [
    clear-plot
    ;; update client plot with the new intersection's data
    ask current-intersection-for-client-metric
    [
      set current-client-metric my-plot-metric
      set index 0
      repeat length my-plot-data
      [
        set current-item item index my-plot-data
        plotxy first current-item last current-item
        set index index + 1
      ]
    ]
    set old-intersection-for-client-metric current-intersection-for-client-metric
  ]
  [
    ask current-intersection-for-client-metric
    [
      if length my-plot-data != 0
      [ plotxy first last my-plot-data last last my-plot-data ]
    ]
  ]
end

;; clear all the plots that are not the client plot
to clear-all-non-client-plot
  set-current-plot "Stopped Cars"
  clear-plot
  set-current-plot "Average Speed of Cars"
  clear-plot
  set-current-plot "Average Wait Time of Cars"
  clear-plot
end

to plot-new-value [name-of-plot value]
  set-current-plot name-of-plot
  plot value
end

to clear-plots-and-plot-in-new-plot [name-of-plot list-to-plot]
  clear-all-non-client-plot
  plot-new-list name-of-plot list-to-plot
end

to plot-new-list [name-of-plot list-to-plot]
  locals [index]
  set index 0

  set-current-plot name-of-plot
  clear-plot
  repeat length list-to-plot
  [
    plot item index list-to-plot
    set index index + 1
  ]
end

to plot-value-and-lists [value-plot value list-plot1 list-to-plot1 list-plot2 list-to-plot2]
  plot-new-value value-plot value
  plot-new-list list-plot1 list-to-plot1
  plot-new-list list-plot2 list-to-plot2
end

;; increases the clock by 1 and cycles phase to the next appropriate value
to clock-tick
  set clock clock + 1
  ;; The phase cycles from 0 to ticks-per-cycle, then starts over.
  set phase phase + 1
  if phase mod ticks-per-cycle = 0
  [ set phase 0 ]
end

;; update the plots to show the current value of display-which-metric
;; done only by the Refresh Plots button
to show-current-metric-in-plots
  if display-which-metric != old-display-which-metric
  [
    ;; we need to plot at least 1 list since the plot we are supposed to plot to is different from the plot we last plotted in
    ifelse display-which-metric = 0
    [ clear-all-non-client-plot ]
    [
      ifelse display-which-metric = 1
      [ clear-plots-and-plot-in-new-plot "Stopped Cars" stopped-data ]
      [
        ifelse display-which-metric = 2
        [ clear-plots-and-plot-in-new-plot "Average Speed of Cars" speed-data ]
        [
          ifelse display-which-metric = 3
          [ clear-plots-and-plot-in-new-plot "Average Wait Time of Cars" wait-data ]
          [
            ;; therefore display-which-metric = 4
            ifelse old-display-which-metric = 1
            [
              plot-new-list "Average Speed of Cars" speed-data
              plot-new-list "Average Wait Time of Cars" wait-data
            ]
            [
              ifelse old-display-which-metric = 2
              [
                plot-new-list "Stopped Cars" stopped-data
                plot-new-list "Average Wait Time of Cars" wait-data
              ]
              [
                ifelse old-display-which-metric = 3
                [
                  plot-new-list "Stopped Cars" stopped-data
                  plot-new-list "Average Speed of Cars" speed-data
                ]
                [
                  ;; therefore old-display-which-metric = 0
                  plot-new-list "Stopped Cars" stopped-data
                  plot-new-list "Average Speed of Cars" speed-data
                  plot-new-list "Average Wait Time of Cars" wait-data
                ]
              ]
            ]
          ]
        ]
      ]
    ]
    set old-display-which-metric display-which-metric
  ]
end

;; set the current client plot's variable information
to set-current-client-metric-intersection [ intersection-to-plot ]
  set current-intersection-for-client-metric intersection-to-plot
  set current-client-metric my-plot-metric-of intersection-to-plot
end

;; select an intersection to plot its my-plot-metric in the client plot
to select-intersection-for-client-plot
  locals
  [ current-patch ]
  
  if mouse-down?
  [
    set current-patch patch-at round mouse-xcor round mouse-ycor
    if (intersection?-of current-patch) and (-1 != user-id-of current-patch)
    [
      set-current-client-metric-intersection patch-at round mouse-xcor round mouse-ycor
      stop
    ]
  ]
end


;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Quick Start functions ;;
;;;;;;;;;;;;;;;;;;;;;;;;;;;

;; instructions to quickly setup the model, and clients to run this activity
to setup-quick-start
  set qs-item 0
  set qs-items
  [
    "Teacher: Follow these directions to setup the HubNet activity."
    "Optional: Zoom In (see Tools in the Menu Bar)"
    "Change the traffic grid (using the sliders GRID-SIZE-X and..."
      "GRID-SIZE-Y) to make enough lights for everyone."
    "Change any other of the settings that you would like to change."
    "For example, if you plan on running Gridlock in..."
      "the MANUAL mode, be sure to have AUTO? set to OFF."
    "Press the NetLogo SETUP button."
    "Press the INITIAL LOGIN button."
    "Everyone: Open the HubNet Client on your machine and..."
      "input the IP Address of this computer, type your user name in..."
        "the user name box and press ENTER"
    "Teacher: Once everyone is logged in and has a light..."
      "stop the INITIAL LOGIN button by pressing it again."
    "Everyone: Whichever mode AUTO? is set for in NetLogo,..."
      "you will control your intersection in a different way."
    "If you have chosen MANUAL,..."
      "you can change the state of your light by pressing..."
        "the CHANGE LIGHT button."
    "If you have chosen AUTO,..."
      "you can change the phase of your light by moving..."
        "the PHASE slider to a different position."
    "If you wish to keep track of your own metric,..."
      "input it in the metric-code input box."
    "Teacher: Once everyone is ready,..."
      "start the simulation by pressing the GO button."
    "Teacher: You may want to view some of the plots."
      "Do this by changing the DISPLAY-WHICH-METRIC slider,..."
        "which changes the plot displayed for everyone."
    "Choose 0 to turn off all the plots..."
      "Choose 1 to see the STOPPED CARS plot..."
        "Choose 2 for the AVERAGE SPEED plot..."
          "Choose 3 for the AVERAGE WAIT plot..."
            "or Choose 4 for all the plots..."

    "Teacher: To rerun the activity with the same group,..."
      "stop the model by pressing the NetLogo GO button, if it is on."
        "Change any of the settings that you would like."
          "Press the NetLogo RE-RUN button."
    "Teacher: Once everyone is ready,..."
      "restart the simulation by pressing the GO button."
    
    "Teacher: To start the simulation over with a new group,..."
      "stop the model by pressing the NetLogo GO button, if it is on..."
        "and follow these instructions again from the beginning."
  ]
  set quick-start (item qs-item qs-items)
end

;; view the next item in the quickstart monitor
to view-next
  set qs-item qs-item + 1
  if qs-item >= length qs-items
  [ set qs-item length qs-items - 1 ]
  set quick-start (item qs-item qs-items)
end

;; view the previous item in the quickstart monitor
to view-prev
  set qs-item qs-item - 1
  if qs-item < 0
  [ set qs-item 0 ]
  set quick-start (item qs-item qs-items)
end


;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
;; Code for interacting with the clients ;;
;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;

;; when a command is sent, find out which client sent it and then execute the command
to listen-clients
  ;; use without-interruption to eliminate the possibility that if both the GO and 
  ;; INITIAL-LOGIN buttons are pressed that they both try processing the same message
  without-interruption
  [
    while [hubnet-message-waiting?]
    [
      hubnet-fetch-message
      ifelse hubnet-enter-message?
      [
        give-intersection-coords
        wait 1  ;; we want to give some time for other clients to log in on this round
      ]
      [
        ifelse hubnet-exit-message?
        [ abandon-intersection ]
        [
          ifelse hubnet-message-tag = "Change Light"
          [ manual hubnet-message-source ]
          [
            ifelse hubnet-message-tag = "Phase"
            [ auto hubnet-message-source ]
            [
              if hubnet-message-tag = "metric-code"
              [ new-client-metric hubnet-message-source hubnet-message ]
            ]
          ]
        ]
      ]
    ]
  ]
end

;; when a new client logs in, if there are free intersections, 
;; assign one of them to that client
;; if this current-id already has an intersection, give the client that intersection.
to give-intersection-coords
  locals [current-id]
  set current-id hubnet-message-source
  ifelse not any? intersections with [user-id = current-id]
  [
      ;; the case where they tried logging in previously but there was no room for them
      ;; or they haven't logged in before
      get-free-intersection current-id
  ]
  [
    ;; otherwise, we already have an intersection for the current-id.
    ;; all we need to do is send where the light is located at
    ask intersections with [user-id = current-id]
    [ hubnet-send current-id "Located At:" ("(" + my-column + "," + my-row + ")") ]
  ]
end

;; when a client disconnects, free up its intersection
to abandon-intersection
  ask intersections with [user-id = hubnet-message-source]
  [
    set user-id -1
    set my-phase 0
    set plabel-of patch-at -1 1 no-label
  ]
end

;; if there are any free intersections, pick one of them at random and give it to the current-id.
;; if there are not any free intersections, toss an error and put error values into the list
to get-free-intersection [current-id]
  ifelse any? intersections with [user-id = -1]
  [
    ;; pick a random intersection that hasn't been taken yet
    ask random-one-of intersections with [user-id = -1]
    [
      set user-id current-id
      ask patch-at -1 1
      [
        set plabel-color black
        set plabel current-id
      ]
      hubnet-send current-id "Located At:" ("(" + my-column + "," + my-row + ")")
    ]
  ]
  [
    hubnet-send current-id "Located At:" "Not enough lights"
    user-message "Not enough lights for student with id: " + current-id
  ]
end

;; switch the traffic lights at the intersection for the client with user-id
to manual [current-id]
  if not auto?
  [
    ask intersections with [user-id = current-id]
    [
      set green-light-up? (not green-light-up?)
      set-signal-colors
    ]
  ]
end

;; change the value of the phase for the intersection at (xc,yc) to 
;; the value passed by the client
to auto [current-id]
  ask intersections with [user-id = current-id]
  [
    set my-phase hubnet-message
  ]
end

;; change the metric to plot on the client plot for the client
;; if it is valid code to generate values to plot
to new-client-metric [ current-id new-metric ]
  locals
  [ error-message ]
  without-interruption
  [
    ask intersections with [ user-id = current-id ]
    [
      set error-message __check-syntax ("plotxy clock " + new-metric)
      ;; don't send an error message if the client sent the empty string
      if new-metric != ""
      [ hubnet-send user-id "metric-error-message" error-message ]
      ifelse error-message = ""
      [
        set my-plot-metric new-metric
        set my-plot-data []
        if current-intersection-for-client-metric = self
        [
          set-current-plot "Client Plot"
          clear-plot
          set current-client-metric my-plot-metric
        ]
      ]
      [ clear-client-plot-data ]
    ]
  ]
end

;; report the user-id of current-intersection-for-metric or the empty string if it is nobody
to-report user-id-of-intersection-for-current-metric
  ifelse current-intersection-for-client-metric = nobody or not is-patch? current-intersection-for-client-metric
  [ report "" ]
  [ report user-id-of current-intersection-for-client-metric ]
end


; *** NetLogo Model Copyright Notice ***
;
; This activity and associated models and materials was created as part of the projects:
; PARTICIPATORY SIMULATIONS: NETWORK-BASED DESIGN FOR SYSTEMS LEARNING IN CLASSROOMS and 
; INTEGRATED SIMULATION AND MODELING ENVIRONMENT.
; These projects gratefully acknowledge the support of the 
; National Science Foundation (REPP & ROLE programs) -- grant numbers 
; REC #9814682 and REC-0126227.
;
; Copyright 2003 by Uri Wilensky & Walter Stroup. Updated 2003. All rights reserved.
;
; Permission to use, modify or redistribute this model is hereby granted,
; provided that both of the following requirements are followed:
; a) this copyright notice is included.
; b) this model will not be redistributed for profit without permission
;    from the copyright holders.
; Contact the copyright holders for appropriate licenses for redistribution 
; for profit.
;
; To refer to this model in academic publications, please use:
; Wilensky, U. & Stroup, W. (2003).  NetLogo HubNet Gridlock Alternate model.
; http://ccl.northwestern.edu/netlogo/models/HubNetGridlockAlternate.
; Center for Connected Learning and Computer-Based Modeling,
; Northwestern University, Evanston, IL.
;
; In other publications, please use:
; Copyright 2003 by Uri Wilensky and Walter Stroup.  All rights reserved.  See
; http://ccl.northwestern.edu/netlogo/models/HubNetGridlockAlternate
; for terms of use.
;
; *** End of NetLogo Model Copyright Notice ***
@#$#@#$#@
GRAPHICS-WINDOW
566
96
946
497
18
18
10.0
1
10
0
0
0

CC-WINDOW
286
10
560
245
Command Center

TEXTBOX
4
400
279
463
This slider determines which plot is drawn.\n0=no plots, 1=stopped cars\n2=average speed, 3=average wait\n4=all three plots

SLIDER
1
464
166
497
display-which-metric
display-which-metric
0
4
0
1
1
NIL

BUTTON
103
212
198
245
Initial Login
listen-clients
T
1
T
OBSERVER
T

PLOT
565
500
844
689
Average Wait Time of Cars
Time
Average Wait
0.0
100.0
0.0
5.0
true
false
PENS
"default" 1.0 0 -65536 true

PLOT
283
500
562
689
Average Speed of Cars
Time
Average Speed
0.0
100.0
0.0
1.0
true
false
PENS
"default" 1.0 0 -65536 true

BUTTON
571
60
689
93
Reset Instructions
setup-quick-start
NIL
1
T
OBSERVER
T

BUTTON
857
60
941
93
NEXT >>>
view-next
NIL
1
T
OBSERVER
T

BUTTON
780
60
858
93
<<< PREV
view-prev
NIL
1
T
OBSERVER
T

MONITOR
571
10
941
59
Quick Start Instructions- More in Info Window
quick-start
0
1

SLIDER
98
10
195
43
grid-size-y
grid-size-y
1
9
5
1
1
NIL

SLIDER
2
10
96
43
grid-size-x
grid-size-x
1
9
5
1
1
NIL

SWITCH
99
82
189
115
auto?
auto?
1
1
-1000

SWITCH
191
82
281
115
crash?
crash?
1
1
-1000

SWITCH
2
82
97
115
power?
power?
0
1
-1000

SLIDER
2
46
281
79
number
number
0
400
200
1
1
cars

PLOT
1
500
280
689
Stopped Cars
Time
Stopped Cars
0.0
100.0
0.0
100.0
true
false
PENS
"default" 1.0 0 -65536 true

BUTTON
217
212
281
245
Go
go
T
1
T
OBSERVER
T

SLIDER
2
118
154
151
simulation-speed
simulation-speed
0
10.0
7.5
0.1
1
NIL

BUTTON
197
10
281
43
Setup
setup-prompt
NIL
1
T
OBSERVER
T

SLIDER
156
118
281
151
speed-limit
speed-limit
0.0
1.0
1.0
0.1
1
NIL

BUTTON
2
212
83
245
Re-Run
setup false
NIL
1
T
OBSERVER
T

MONITOR
176
154
281
203
Current Phase
phase
3
1

SLIDER
2
170
174
203
ticks-per-cycle
ticks-per-cycle
1
100
20
1
1
NIL

BUTTON
168
464
280
497
Refresh Plots
show-current-metric-in-plots
NIL
1
T
OBSERVER
T

PLOT
284
299
562
498
Client Plot
time
NIL
0.0
100.0
0.0
1.0
true
false
PENS
"client metric" 1.0 0 -16777216 true

MONITOR
2
302
242
351
Client Plot's Current Intersection's User Id
user-id-of-intersection-for-current-metric
3
1

MONITOR
2
249
562
298
Current Client Metric
current-client-metric
3
1

BUTTON
2
353
282
386
Select Intersection To Plot Metric in Client Plot
select-intersection-for-client-plot
T
1
T
OBSERVER
NIL

@#$#@#$#@
WHAT IS IT?
-----------
Students control traffic lights in a real-time traffic simulation.  The teacher controls overall variables, such as the speed limit and the number of cars.  This allows students to explore traffic dynamics, which can lead into many areas of study, from calculus to social studies.

Challenge the students to develop strategies to improve traffic and discuss the different ways to measure the quality of traffic.

The coordinates for the traffic lights are based on the first quadrant of the Cartesian plane.  Therefore, the traffic light with the coordinates (0,0) is in the lowest row and the left-most column.  The traffic light above it has coordinates (0,1) and the traffic light to the right of it has (1,0).

This activity uses Gridlock Alternate client.nlogo for the HubNet Client interface.

For further documentation, see the Participatory Simulations Guide found at http://ccl.northwestern.edu/ps/

Notice: Gridlock Alternate uses features in NetLogo that are considered experimental.  The model may stop running if a student enters a metric in the client that is incorrect, such as dividing by 0, and causes a NetLogo error.  Further, we have not yet tested this alternate version of the model in real classrooms. If you use it in a classroom, we'd like to hear how it goes; contact us at feedback@ccl.northwestern.edu.


HOW TO USE IT
-------------
QUICKSTART INSTRUCTIONS:
------------------------
Contains instructions as to how to quickly setup the model, and clients to run this activity.  The instructions can be found below and can be seen progressively in the Quick Start instructions monitor in the Interface:

Teacher: Follow these directions to setup the HubNet activity.
Optional: Zoom In (see Tools in the Menu Bar)
Change the traffic grid (using the sliders GRID-SIZE-X and GRID-SIZE-Y) to make enough lights for everyone.
Change any other of the settings that you would like to change.  For example, if you plan on running Gridlock in the MANUAL mode, be sure to have AUTO? set to OFF.

Press the NetLogo SETUP button.
Press the INITIAL LOGIN button.

Everyone: Open up a HubNet Client on your machine and input the IP Address of this computer, type your user name in the user name box and press ENTER.
Teacher: Once everyone is logged in and has a light stop the INITIAL LOGIN button by pressing it again.

Everyone: Whichever mode AUTO? is set for in NetLogo, you will control your intersection in a different way:
If you have chosen MANUAL, you can change the state of your light by pressing the CHANGE LIGHT button.
If you have chosen AUTO, you can change the phase of your light by moving the PHASE slider to a different position.
If you wish to keep track of your own metric, input it in the metric-code input box.

Teacher: Once everyone is ready, start the simulation by pressing the GO button.

Teacher: You may want to view some of the plots.  Do this by changing the DISPLAY-WHICH-METRIC slider, which changes the plot displayed for everyone.
- Choose 0 to turn off all the plots.
- Choose 1 to see the STOPPED CARS plot.
- Choose 2 for the AVERAGE SPEED OF CARS plot.
- Choose 3 for the AVERAGE WAIT TIME OF CARS plot.
- Choose 4 for all the plots.

Teacher: To rerun the activity with the same group, stop the model by pressing the NetLogo GO button, if it is on.  Change the values of the sliders and switches to the values you want for the new run.  Press the NetLogo RE-RUN button.  Once everyone is ready, restart the simulation by pressing the GO button.

Teacher: To start the simulation over with a new group, stop the model by pressing the NetLogo GO button, if it is on and follow these instructions again from the beginning.

BUTTONS:
--------
SETUP - generates a new traffic grid based on the current GRID-SIZE-X and GRID-SIZE-Y and NUM-CARS number of cars.  This also clears all the plots.  This should only be pressed when starting out with a new group of users since all users associated with a traffic light will be disassociated from that traffic light.
RE-RUN - allows you to keep the current traffic light/calculator associations, but clears the plots and after deleting all the currently existing cars, creates NUM-CARS number of cars.  This does not change the grid size.  This should be used to setup the model again for collecting more data or running the model again with the same users connected.
GO - runs the simulation indefinitely
INITIAL LOGIN - allows users to log into the activity without running the model or collecting data
REFRESH PLOTS - redraws the plots based on the current value of DISPLAY-WHICH-METRIC.  Useful for looking at different plots when GO is off.
SELECT INTERSECTION TO PLOT METRIC IN CLIENT PLOT - allows you to use the mouse to click on an intersection associated with a HubNet client to plot that client's submitted metric in the CLIENT PLOT.
NEXT>>> - shows the next quick start instruction
<<<PREV - shows the previous quick start instruction
RESET INSTRUCTIONS - shows the first quick start instruction

SLIDERS:
--------
SPEED-LIMIT - sets the maximum speed for the cars
NUMBER - the number of cars in the simulation (you must press the SETUP or RE-RUN buttons to see the change)
SIMULATION-SPEED - the speed at which the simulation runs
TICKS-PER-CYCLE - sets the maximum value that the phase can be.  This has no effect when the model is run with AUTO? false.  Also, the phase that each user chooses is scaled to be less than or equal to this value.
GRID-SIZE-X - sets the number of vertical roads there are (you must press the SETUP button to see the change)
GRID-SIZE-Y - sets the number of horizontal roads there are (you must press the SETUP button to see the change)
DISPLAY-WHICH-METRIC - determines which plot is drawn in NetLogo:
- 0=No Plots.
- 1=STOPPED CARS
- 2=AVERAGE SPEED OF CARS
- 3=AVERAGE WAIT TIME OF CARS
- 4=All three plots.

SWITCHES:
---------
CRASH? - toggles car crashing
POWER? - toggles the presence of traffic lights
AUTO? - toggles between automatic mode, where the students' lights change on a cycle, and manual in which students directly control the lights with their clients. Lights which aren't associated with clients always change on a cycle.

PLOTS:
------
STOPPED CARS - displays the number of stopped cars over time
AVERAGE SPEED OF CARS - displays the average speed of cars over time
AVERAGE WAIT TIME OF CARS - displays the average time cars are stopped over time
CLIENT PLOT - displays the currently selected client's submitted metric over time.  You select a client's intersection by using the SELECT INTERSECTION TO PLOT METRIC IN CLIENT PLOT button.


CLIENT INFORMATION
------------------
After logging in, the client interface will appear for the students.  The controls for manual and automatic mode are both included, but which one works is based on the setting of the AUTO? switch in NetLogo.  In MANUAL mode, click the CHANGE LIGHT button to switch the state of the light you control.  In AUTO mode, move the PHASE slider to change the phase for your light.  The phase determines what percent of the way through the cycle to switch on.

If the users wish to send a metric of their own making that measures the efficiency of the traffic to the model, they can do so with the text input interface element called METRIC-CODE.  The user should input a valid NetLogo expression that evaluates to a number.  Then if this client is selected during a run, the values of the metric will be plotted in the CLIENT PLOT.  If you don't type a valid NetLogo expression that evaluates to a number, an error message will appear in the METRIC-ERROR-MESSAGE monitor.

The clients also contain the same four plots as NetLogo and will show exactly the same data as NetLogo if plot mirroring is enabled.


THINGS TO NOTICE
----------------
When cars have stopped at a traffic light, and then they start moving again, the traffic jam will move backwards even though the cars are moving forwards.  Why is this?  Discuss in your class possible reasons for this phenomena.


THINGS TO TRY
-------------
Try changing the speed limit for the cars.  How does this affect the overall efficiency of the traffic flow?  Are fewer cars stopping for a shorter amount of time?  Is the average speed of the cars higher or lower than before?

Try changing the number of cars on the roads.  Does this affect the efficiency of the traffic flow?

How about changing the speed of the simulation?  Does this affect the efficiency of the traffic flow?

Using HubNet, try running this simulation with AUTO? being true and AUTO? being false.  Is it harder to make the traffic move well using one scheme or the other?  Why?

Using HubNet, try running this simulation with AUTO? being true.  Try to find a way of setting the phases of the traffic lights so that the average speed of the cars is the highest.  Now try to minimize the number of stopped cars.  Now try to decrease the average wait time of the cars.  Is there any correlation between these different metrics?

Try coming up with new and good ways of measuring the efficiency of the traffic flow.


EXTENDING THE MODEL
-------------------
Currently, the maximum speed limit (found in the SPEED-LIMIT slider) for the cars is 1.0.  This is due to the fact that the cars must look ahead the speed that they are traveling to see if there are cars ahead of them.  If there aren't, they speed up.  If there are, they slow down.  Looking ahead for a value greater than 1 is a little bit tricky.  Try implementing the correct behavior for speeds greater than 1.


NETLOGO FEATURES
----------------------------------
This model uses a text input interface element in the clients to allow clients to send text to the model.  It also uses the experimental __check-syntax primitive to try to ensure a string is safe to pass to the run-result primitive.  Together, these features allow the client to send NetLogo code to the model to be run and produce values which can then be plotted in the CLIENT PLOT.  If the code that is executed is valid NetLogo syntax and doesn't produce any bad side-effects, such as clearing the Graphics Window or having turtles die, everything should work fine.  However, there is no easy way of ensuring this currently.  As a result, code which may be unsafe to the model could be executed and may cause the model to stop unexpectedly or give a runtime error when trying to plot to the CLIENT PLOT.  We will be improving these features in future versions of NetLogo.


CREDITS AND REFERENCES
----------------------
This activity and associated models and materials was created as part of the projects:
PARTICIPATORY SIMULATIONS: NETWORK-BASED DESIGN FOR SYSTEMS LEARNING IN CLASSROOMS and INTEGRATED SIMULATION AND MODELING ENVIRONMENT. These projects gratefully acknowledge the support of the National Science Foundation (REPP & ROLE programs) -- grant numbers REC #9814682 and REC-0126227.

Copyright 2003 by Uri Wilensky & Walter Stroup. All rights reserved. 

Permission to use, modify or redistribute this model is hereby granted, provided that both of the following requirements are followed: 
a) this copyright notice is included. 
b) this model will not be redistributed for profit without permission from the copyright holders. 
Contact the copyright holders for appropriate licenses for redistribution for profit. 

To refer to this model in academic publications, please use: Wilensky, U. & Stroup, W. (2003). NetLogo HubNet Gridlock Alternate model. http://ccl.northwestern.edu/netlogo/models/HubNetGridlockAlternate.  Center for Connected Learning and Computer-Based Modeling, Northwestern University, Evanston, IL. 

In other publications, please use: Copyright 2003 by Uri Wilensky and Walter Stroup.  All rights reserved.  See http://ccl.northwestern.edu/netlogo/models/HubNetGridlockAlternate for terms of use.
@#$#@#$#@
default
true
0
Polygon -7566196 true true 150 5 40 250 150 205 260 250

car
true
15
Circle -1 false true 185 55 60
Circle -1 false true 183 186 61
Polygon -1 true true 214 52 214 22 182 26 162 38 144 74 138 102 100 120 99 161 102 201 118 246 152 267 190 275 210 251 187 240 178 200 204 182 215 181 214 118 193 112 182 98 181 72 198 52

@#$#@#$#@
NetLogo 2.0.0
@#$#@#$#@
@#$#@#$#@
@#$#@#$#@