求教：海龟的遗产传递问题

qg_gp

请问 我现在希望设计海龟死后他的财产可以以一定的比例留给后代。这些海龟如果代表的是穷人则它死后（年龄大预期值）会生出3个孩子，其生前的财产的90%均分给其孩子。若海龟是富裕的，其死后有随机1~2个孩子，财产已70%均分。请问大家如果加到下述程序中怎么实现
  t$ R: F2 U3 y4 `globals
! |5 q2 \& P/ Q1 |9 y7 `[
5 r' c8 }! S' F  max-grain   
; P! i1 a6 G! T5 _
2 C0 P9 ?4 j3 G& I5 L$ a; j]
, _3 L9 j/ e9 o( }. F& G* A5 x/ {
7 a2 ]! d7 k- [/ v7 ~$ {patches-own
[
  grain-here      
  max-grain-here  
8 q8 q, i/ z2 {- P]

turtles-own
[
: `4 v" ^" N  U* P) @& q) X  age              
  wealth         
  life-expectancy  
& B& L7 o  ~5 w2 J+ _- p7 y  metabolism      
  vision
$ m8 L* n% g9 O  l. L' S- e  inherited         
& d( b7 H9 v% L* |7 w) C3 v" P5 D]
6 Q, Q5 B; M7 L/ k  y) r) J

7 ?: a; a! H8 @4 G* Hto setup
# m  t3 n& q' c  ca
: S$ E: X% y' Q, ?; t  set max-grain 50
  setup-patches
8 g* e9 m" \9 @: d$ M/ H6 Z( J  U  setup-turtles
  setup-plots
  update-plots
* O" n9 c7 m0 d7 C' V  tend
to setup-patches
  ask patches
    [ set max-grain-here 0
      if (random-float 100.0) <= percent-best-land
4 N3 U* k. L6 c: ?0 u        [ set max-grain-here max-grain
$ I7 f, B( t" O' b1 E; g          set grain-here max-grain-here ] ]
  repeat 5
    [ ask patches with [max-grain-here != 0]
) f1 K' K$ u4 ^( N. ~( l" x( X) ~        [ set grain-here max-grain-here ]
      diffuse grain-here 0.5 ]
  repeat 10
    [ diffuse grain-here 0.5]         
  ask patches
    [ set grain-here floor grain-here   
2 g7 n3 [% V, J, U      set max-grain-here grain-here      
      recolor-patch ]
end
to recolor-patch  
  set pcolor scale-color sky grain-here 0 max-grain
end
7 A" \& l2 E# p) g) h, Gto setup-turtles
  set-default-shape turtles "person"
3 X+ p% e  P3 y2 N  crt num-people
    [ move-to one-of patches  
      set size 1.5  
      set-initial-turtle-vars-age
      set-initial-turtle-vars-wealth
# u$ j+ d) N$ o# ]; N5 t4 k, L/ E      set age random life-expectancy ]
& Z  s$ j/ v9 [. R) V: \; k  recolor-turtles
: L! _+ a2 x  t) I6 Jend
3 d; d5 p. m9 N9 W: v
4 C7 _: j5 E/ I- C* o' bto set-initial-turtle-vars-age
let max-wealth max [wealth] of turtles
   
     ifelse (wealth <= max-wealth / 3)
        [ set color red
          set age 0
7 g, a$ l7 a8 O" |/ \          face one-of neighbors4
          set life-expectancy life-expectancy-min +
! c& u- J" q1 w% `* W4 a$ ^# N                        random life-expectancy-max
          set metabolism random 1 + metabolism-low
          set wealth metabolism + random 30
          set vision 1 + random max-vision
' ]$ `/ F) @  B# i6 G4 v; l% O             set wealth  wealth +  Wealth-inherited-low ]
. A# p) j' o9 F$ O1 ^  D" Z        [ ifelse (wealth <= (max-wealth * 2 / 3))
            [ set color yellow
              set age 0
              face one-of neighbors4
( z5 Y' R( \8 |! F              set life-expectancy life-expectancy-min +
                        random life-expectancy-max + 1
* x, @" m# i/ O, P. e- z( h              set metabolism  1 + random metabolism-mid
5 O/ n3 W4 a' U. ^              set wealth metabolism + random 30
3 O, T5 L  }3 A$ T0 P5 G              set vision 3 + random max-vision
                set wealth  wealth + Wealth-inherited-mid]
4 e5 A% i" r/ _. J# l            [ set color green
              set age 0
              face one-of neighbors4
) Q  S( I, Z) `8 W7 J              set life-expectancy life-expectancy-min +
/ [& q/ h6 G/ z# ^" [7 |( O0 l                        random life-expectancy-max  + 2
              set metabolism 2 + random metabolism-up
) c' c8 H/ e9 Z. H' R7 f8 h              set wealth metabolism + random 30
- ?7 V1 g& w/ S0 U: [              set vision 3 + random max-vision
3 G- h+ c" w! F  j! k( V1 w  ^              set wealth  wealth + Wealth-inherited-up ] ]
3 V5 k. F* f7 _/ `
end
to set-initial-turtle-vars-wealth
  G" n# t, r" B) i, _6 I& B let max-wealth max [wealth] of turtles
+ A* K* N0 }. I/ ~' Q! x/ ~% j          set age 0
+ |+ a1 Y$ O: T' u) C: ?7 b1 r' X4 E( R$ r          face one-of neighbors4
$ B4 b7 e# ^  g0 q& o# a% c" L          set life-expectancy life-expectancy-min +
                        random life-expectancy-max
          set metabolism 1 + random metabolism-up
( O, J: D2 Y4 K, R          set wealth metabolism + random 30
9 Y& I# z: e0 E* m4 t          set vision 1 + random max-vision
end
6 X- D- {/ {* u- wto redistribution
let max-wealth max [wealth] of turtles
" \" m- d6 v+ h: G/ v' V, Flet min-wealth min [wealth] of turtles
if (wealth <= max-wealth / 3)
[set wealth  wealth + Low-income-protection ]
, H; L" _! {6 o' X" {& ~end
         
0 R. ]$ q' V6 a' [to recolor-turtles
  let max-wealth max [wealth] of turtles
  ask turtles
" N$ @9 Z, s0 ]9 W' L   [ ifelse (wealth <= max-wealth / 3)
        [ set color red ]
$ A3 g5 }. I( R: H8 r' k/ m! }        [ ifelse (wealth <= (max-wealth * 2 / 3))
            [ set color yellow ]
            [ set color green ] ] ]
ask turtles [ifelse show-wealth?
    [ set label wealth ]
    [ set label "" ]]
% A9 m0 u5 C3 Pend

to go
9 ^! C; B3 ~' Z" w- s  ask turtles
+ U( H6 @: m* t& A3 Q    [ turn-towards-grain ]  
  harvest
+ }3 s* s' \$ B" I4 E$ }* e  ask turtles
    [ move-eat-age-die ]
4 z) y: b- z/ p7 |9 E" {  recolor-turtles
  if ticks mod grain-growth-interval = 0
& K5 i; D5 c5 o& y" t    [ ask patches [ grow-grain ] ]
   
, |0 d3 K, Q2 Q  if ticks mod 11 = 0
  [ask turtles
  [ redistribution ]]
  if ticks mod 5 = 0
- o5 T, P3 H$ B   [ask turtles
+ a+ j5 e! k, X  [ visions ]]
  tick
% g8 I8 q- I5 \  d! u  update-plots
end
9 U* U  t+ x  N. X$ Cto visions
set vision vision + 1
end


" x/ z3 X( o2 o* f. A' e3 f
to turn-towards-grain  
  set heading 0
" V5 t1 J5 w. a; ^& J  let best-direction 0
  let best-amount grain-ahead
. l7 C! _" m; B  set heading 90
' [- |( n, p% L6 U6 ~; _  if (grain-ahead > best-amount)
    [ set best-direction 90
' I+ k* |3 t2 v; V) E6 o      set best-amount grain-ahead ]
' w, L  K: o2 x" A  set heading 180
# f& o( ~: b7 l  if (grain-ahead > best-amount)
! q' x( N7 \% Q9 l2 u    [ set best-direction 180
0 x) M# a8 A7 j* {- _      set best-amount grain-ahead ]
  set heading 270
$ a+ \& }0 x7 E, r0 Q; P  if (grain-ahead > best-amount)
+ L0 M7 [- ^+ W$ [    [ set best-direction 270
      set best-amount grain-ahead ]
8 a7 U. e/ l7 u# o, \0 w$ c  set heading best-direction
+ H. r$ K1 U3 u4 z5 lend

8 F9 I9 y6 B3 M
* ?" e0 b- g, M# p: O0 Q3 wto-report grain-ahead  
  let total 0
: P9 N3 D( W6 ^4 U# w( n, T  let how-far 1
# v, I- Y7 N# J+ L  repeat vision
+ K. i# a6 g2 a. Q; {3 i% Z/ ~5 H    [ set total total + [grain-here] of patch-ahead how-far
6 O- p( ^7 d5 T" Z, s      set how-far how-far + 1 ]
, W0 |$ N) d6 N5 H( B1 s3 ?* ~  report total
end

$ U/ k# `/ m  S7 o4 M3 b+ }to grow-grain
  if (grain-here < max-grain-here)
6 M+ W3 _; ~1 N" x9 p    [ set grain-here grain-here + num-grain-grown
      if (grain-here > max-grain-here)
        [ set grain-here max-grain-here ]
      recolor-patch ]
  F9 q+ Z7 Y2 {; C" I1 Bend
( F* M& i8 ?6 G' y0 `& pto harvest
) }) f; a& O& E6 R  ask turtles
2 q, Z2 j1 L' k5 `    [ set wealth floor (wealth + (grain-here / (count turtles-here))) ]
7 H4 N) u# O* U2 f  ask turtles
# D, u: P/ b* n+ E8 t  L7 r1 B, _    [ set grain-here 0
! n3 O) f3 Q! ^      recolor-patch ]
  
end

7 r* Q7 t8 B, J0 uto move-eat-age-die  
  fd 1
9 G% ^1 c/ Z! O/ H( {2 O7 K5 C  set wealth (wealth - metabolism)
7 m: t6 T2 c. W. Z# g( M, j' w    set age (age + 1)
2 i7 l  |& {) n  N  if (age >= life-expectancy)
! R4 `% e! j0 j0 J; p! F% g6 {    [ set-initial-turtle-vars-age ]
  if (wealth < 0)
    [ set-initial-turtle-vars-wealth ]
, r5 P( U; n- X4 C/ i   
8 G2 n5 e" q0 k3 z' z3 zend

7 t3 ~/ o! d" z3 T! e  k+ w6 w
to setup-plots
  set-current-plot "Class Plot"
  set-plot-y-range 0 num-people
  set-current-plot "Class Histogram"
3 T5 A& M& t( @+ T  set-plot-y-range 0 num-people
2 y1 ]4 g) k6 ?2 \8 i: kend

4 D% i# P" K4 S" `, n9 gto update-plots
" ?: N7 G. `3 A0 l1 y  update-class-plot
  update-class-histogram
! I% }# z; l) Z) l* ]5 Q' M& a  update-lorenz-and-gini-plots
, d, ?) _/ |3 O( w$ ^  O. mend

to update-class-plot
  set-current-plot "Class Plot"
! u, y5 E6 ~4 X3 f  w# C( ?, r  set-current-plot-pen "low"
  plot count turtles with [color = red]
  set-current-plot-pen "mid"
4 p4 @" X' ]7 V4 d* W  plot count turtles with [color = yellow]
  set-current-plot-pen "up"
9 _+ R8 U, p2 k' b; `  plot count turtles with [color = green]
# k# n- |9 }8 s% ]end

  W) ?; `/ p& w1 O% ^to update-class-histogram
/ ^# I. k3 Q1 {2 _7 v1 G3 ^  set-current-plot "Class Histogram"
  plot-pen-reset
  set-plot-pen-color red
  plot count turtles with [color = red]
/ |4 C% c1 {/ s  set-plot-pen-color yellow
  plot count turtles with [color = yellow]
  set-plot-pen-color green
4 u8 \/ D7 G& O: E$ j- l4 ~  plot count turtles with [color = green]
8 ?7 Q+ j  e: R$ }. send
* y* B; U! H7 }9 Y! hto update-lorenz-and-gini-plots
: h4 p/ d  i1 e( n  set-current-plot "Lorenz Curve"
  clear-plot
4 A: O6 C/ G" O% e; q! {' N
( L2 x) F2 t8 f  U9 u  set-current-plot-pen "equal"
2 ]) j8 E" l# S( g7 F4 S  plot 0
  plot 100
0 E$ K8 u  |: z5 V$ v( N! @
  set-current-plot-pen "lorenz"
8 P4 L0 q( {6 d' V' a5 k) G  set-plot-pen-interval 100 / num-people
  plot 0
, ?) S* _/ {- R, x5 v; a
  let sorted-wealths sort [wealth] of turtles
  let total-wealth sum sorted-wealths
  let wealth-sum-so-far 0
  let index 0
  let gini-index-reserve 0

  ~5 H* K+ v' Q, V% Q" T3 }  repeat num-people [
    set wealth-sum-so-far (wealth-sum-so-far + item index sorted-wealths)
    plot (wealth-sum-so-far / total-wealth) * 100
    set index (index + 1)
    set gini-index-reserve
      gini-index-reserve +
      (index / num-people) -
* f  K% W# {2 N. L2 F9 r1 j      (wealth-sum-so-far / total-wealth)
# P6 v! R; Y7 Y/ Q* w9 n  ]
. ~7 ?4 s  }" F" I- h# C* h% r
7 P. ?- z# T9 _4 Z" J% c  set-current-plot "Gini-Index v. Time"
  plot (gini-index-reserve / num-people) / area-of-equality-triangle
' x" L! Y: S' C/ Gend
7 `! _/ F0 v5 J; h5 @9 h! ato-report area-of-equality-triangle
# f; `% z8 j4 g* Z  [  report (num-people * (num-people - 1) / 2) / (num-people ^ 2)
end

qg_gp

自己写了用的hatch 但加在上面的程序中运行的时候总是出现问题T_T