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
globals
. A! g& t  v4 a' V5 E2 Q[
) \. G; p+ P1 f6 q) j, |7 F  max-grain   
0 ~5 Y* k; q' N# V, f
9 N; U4 E8 C* Z$ {. Z; ?9 a) @]

patches-own
- d2 G+ n5 \+ @5 \5 Z: n6 H+ B. x. }[
  grain-here      
3 }; F& o) H7 d# M4 D( G& r( C  max-grain-here  
* g9 J. j) {3 _]

  C& z$ h" @" u) O3 yturtles-own
[
) f# p8 D0 ]" w+ e6 R  age              
  wealth         
  j2 F) D) I  |5 N5 O& b  life-expectancy  
- B+ ]9 ?0 K& O! m  metabolism      
$ ~- a* L% l" V" a  vision
! E+ ^7 }1 U6 L  inherited         
]


) s# D1 y- u9 ^: m/ u+ z( Oto setup
7 H  n# @$ b( L7 k7 Z$ W- _+ H  ca
  set max-grain 50
  setup-patches
1 `3 _  r. S, i  setup-turtles
" Z" u, R* G; f! \$ V1 [- O2 t' w  setup-plots
/ A" y: b) Z; }/ c4 R! h  update-plots
# K, k5 Q) f+ g/ ?3 eend
  K& C& t9 [# Vto setup-patches
0 v/ k( d7 X6 v. z  ask patches
2 _8 v8 V- k& J/ u- C2 u9 n    [ set max-grain-here 0
9 i- {4 s1 |& E1 W8 f" v      if (random-float 100.0) <= percent-best-land
* p5 p! @  \: \4 a        [ set max-grain-here max-grain
          set grain-here max-grain-here ] ]
  repeat 5
    [ ask patches with [max-grain-here != 0]
. K$ u( Z4 `, u; Q9 ^* b4 Z        [ set grain-here max-grain-here ]
      diffuse grain-here 0.5 ]
6 V' o) o, q  v  repeat 10
. O' {3 r& I1 X* }4 u, g# @    [ diffuse grain-here 0.5]         
  ask patches
    [ set grain-here floor grain-here   
" f2 p; U0 A9 ?! g3 R1 o( h( _5 j( g( J      set max-grain-here grain-here      
3 G0 z  p/ t7 P      recolor-patch ]
end
to recolor-patch  
  set pcolor scale-color sky grain-here 0 max-grain
0 ?6 P+ |* a7 R( [end
to setup-turtles
  set-default-shape turtles "person"
  l- o& x1 M! _  ]  d  crt num-people
    [ move-to one-of patches  
      set size 1.5  
' k$ K0 {& [! R      set-initial-turtle-vars-age
      set-initial-turtle-vars-wealth
      set age random life-expectancy ]
6 T  x9 r: T- R3 e  recolor-turtles
( S  K% r5 {- S8 d# T. \- eend

3 G% Z# S& Y/ c/ `to set-initial-turtle-vars-age
5 z& z% N1 F" p9 f let max-wealth max [wealth] of turtles
. k5 v: j, ?! \! G8 A   
8 Q9 ]" e: O; Q' {- e! ^- Z     ifelse (wealth <= max-wealth / 3)
        [ set color red
          set age 0
          face one-of neighbors4
          set life-expectancy life-expectancy-min +
+ Q8 d  x; f. m0 }: U: v                        random life-expectancy-max
          set metabolism random 1 + metabolism-low
8 k: r1 q3 w7 G: k) i) v          set wealth metabolism + random 30
& z8 T0 c- f& B% i7 O          set vision 1 + random max-vision
             set wealth  wealth +  Wealth-inherited-low ]
$ I) M" ^; v! ~# _& T        [ ifelse (wealth <= (max-wealth * 2 / 3))
1 R- C/ ^# a6 M" H% X  t8 {2 q+ ~            [ set color yellow
  g% P1 ^1 q: N              set age 0
              face one-of neighbors4
              set life-expectancy life-expectancy-min +
                        random life-expectancy-max + 1
              set metabolism  1 + random metabolism-mid
              set wealth metabolism + random 30
              set vision 3 + random max-vision
                set wealth  wealth + Wealth-inherited-mid]
            [ set color green
              set age 0
3 S5 ~( K  s# d3 v9 q9 ]              face one-of neighbors4
" i. Y3 w% J3 q. @( Y5 X              set life-expectancy life-expectancy-min +
; t( Z6 H8 o9 R0 o& R6 t3 i( o                        random life-expectancy-max  + 2
              set metabolism 2 + random metabolism-up
3 O5 P% i7 x4 T5 V- k, ]# _* H6 E" O              set wealth metabolism + random 30
              set vision 3 + random max-vision
" n1 s" m' x4 A6 f8 ^              set wealth  wealth + Wealth-inherited-up ] ]
/ T, Z/ c& P7 c2 \/ j! w
% [3 W, O( |+ X" g+ g* H9 d2 \end
- t6 r/ a, y% F$ a7 m/ s) }7 h; r5 vto set-initial-turtle-vars-wealth
let max-wealth max [wealth] of turtles
4 i+ Q& S3 B' j* C+ \  f3 }: R7 H          set age 0
          face one-of neighbors4
$ @4 X+ q3 z, \5 t          set life-expectancy life-expectancy-min +
5 V  ?( M3 L1 }' L9 G+ f: g2 t( R                        random life-expectancy-max
7 P: `" h4 M% g( b7 n  V          set metabolism 1 + random metabolism-up
          set wealth metabolism + random 30
          set vision 1 + random max-vision
end
9 W4 w+ d0 y1 E. wto redistribution
let max-wealth max [wealth] of turtles
let min-wealth min [wealth] of turtles
! H& U( h$ X& s; {4 X: Y9 E' Rif (wealth <= max-wealth / 3)
[set wealth  wealth + Low-income-protection ]
end
! B% r9 `' T- r5 U  O         
  Z7 {5 G& ?6 P& y7 ~, Z" J8 Rto recolor-turtles
  let max-wealth max [wealth] of turtles
  ask turtles
   [ ifelse (wealth <= max-wealth / 3)
        [ set color red ]
        [ ifelse (wealth <= (max-wealth * 2 / 3))
4 q$ n' x& K" w7 v3 `            [ set color yellow ]
6 w+ |4 F6 J' B5 k- a9 V( U) p! a, t            [ set color green ] ] ]
ask turtles [ifelse show-wealth?
- k0 M. d1 h2 @0 i% r' }% x    [ set label wealth ]
6 i2 p$ }0 ^! I8 o2 z# K    [ set label "" ]]
end
, c$ {7 k7 G. l6 ?$ H% J5 t$ j
to go
) Q- L: J/ u7 g  ask turtles
' N( m( s% |2 t    [ turn-towards-grain ]  
  harvest
  ask turtles
3 t7 n5 |+ Q( d$ m  F    [ move-eat-age-die ]
  recolor-turtles
* F3 m5 Q+ P: o% Y2 [9 v( j  if ticks mod grain-growth-interval = 0
9 z$ x1 N% K9 z8 d    [ ask patches [ grow-grain ] ]
% O: T# m# V) \; v+ f   
4 S$ N/ {* B6 A9 j6 m! d  if ticks mod 11 = 0
  [ask turtles
  [ redistribution ]]
  if ticks mod 5 = 0
   [ask turtles
  [ visions ]]
  tick
- N5 E6 ?( y  Q) ]  update-plots
end
3 B. T( i- h5 h  U) Rto visions
set vision vision + 1
end



6 e2 d/ K9 Y1 G# m9 fto turn-towards-grain  
! b* o+ C" Z* d# ?3 h  set heading 0
  let best-direction 0
9 F+ Q! A( i0 h" o4 Q/ u  let best-amount grain-ahead
  U- k. ^& g1 ?7 W& g  set heading 90
' G7 R: l- O1 `* ~) F& K  if (grain-ahead > best-amount)
    [ set best-direction 90
      set best-amount grain-ahead ]
, l0 d0 N0 W& j  set heading 180
& ?! O  }  m; l, Z  if (grain-ahead > best-amount)
    [ set best-direction 180
3 v# Z' k; q* @% N6 n1 w      set best-amount grain-ahead ]
- U* b+ K8 o  P" M4 K  set heading 270
  if (grain-ahead > best-amount)
+ B7 U& U, W9 Z; G1 g2 e    [ set best-direction 270
      set best-amount grain-ahead ]
, k6 ?) p: ~6 [8 c8 D1 J1 Q" |  set heading best-direction
' J5 Q2 f" t1 v% v% x/ z5 jend

; S- R9 |$ Y5 p0 g' H
% J3 h2 s! A- [8 z8 D2 Y" G% nto-report grain-ahead  
  let total 0
  let how-far 1
* I$ {% s3 K- v, u" ?1 ^9 |/ A/ o  repeat vision
9 k8 C8 K: I- G" B    [ set total total + [grain-here] of patch-ahead how-far
      set how-far how-far + 1 ]
7 n1 u' e) R+ A  P* o1 M0 P, b/ q  report total
4 B3 A2 n  Z) t) o( u& X9 m- gend

) \1 p6 n# j9 D  Uto grow-grain
! r& k% F' r$ h8 z  if (grain-here < max-grain-here)
    [ set grain-here grain-here + num-grain-grown
      if (grain-here > max-grain-here)
        [ set grain-here max-grain-here ]
3 y! n* C  F' T* T* F# x8 z# |, O      recolor-patch ]
+ @+ d& v2 K  W1 n9 Mend
to harvest
  ask turtles
$ ~* X+ @* ^! _    [ set wealth floor (wealth + (grain-here / (count turtles-here))) ]
: r8 Y$ z) ^5 Y0 x; X( q5 Q% V  ask turtles
    [ set grain-here 0
      recolor-patch ]
  
end
' S+ P7 h# e; c
to move-eat-age-die  
  fd 1
0 C: B! D: q. {9 U: P; ~, ~  set wealth (wealth - metabolism)
" F! Z$ \$ y( K$ y* Y8 V    set age (age + 1)
9 ^1 Z$ u! ~- ~6 e- u: Z+ F8 O  if (age >= life-expectancy)
! }) x; ?9 u% `9 ]- J. Z9 V4 f    [ set-initial-turtle-vars-age ]
7 ?" [" A* m& a: I  if (wealth < 0)
! i8 @: t3 Y1 P! |- K$ ~: g! m    [ set-initial-turtle-vars-wealth ]
6 F& {! d7 z% j' u0 E   
end


. B- P5 ~8 J% z1 H+ f# g. }to setup-plots
; W/ X* O! m+ S9 R, Q  set-current-plot "Class Plot"
  i% l- p( _- y  set-plot-y-range 0 num-people
  set-current-plot "Class Histogram"
) |: c* m6 |9 D3 z- d  @  set-plot-y-range 0 num-people
: ]  N9 L2 V, q/ Mend

% p, o+ m- O# j: yto update-plots
  R  p: i+ q" S- p4 Y  update-class-plot
  update-class-histogram
  update-lorenz-and-gini-plots
# C3 U) u0 e* _, h& O  Y- H) ~end
7 q2 B4 `% j- h3 R) f
+ Z6 ?5 Y! b: n" C3 D1 Y) V# u6 ^to update-class-plot
  set-current-plot "Class Plot"
; A( b3 \7 S6 H; B/ T! N$ _  set-current-plot-pen "low"
  plot count turtles with [color = red]
  set-current-plot-pen "mid"
  plot count turtles with [color = yellow]
  set-current-plot-pen "up"
  plot count turtles with [color = green]
end

to update-class-histogram
  set-current-plot "Class Histogram"
  plot-pen-reset
  set-plot-pen-color red
  plot count turtles with [color = red]
3 F3 k  _4 [/ m0 |# r$ K" }  set-plot-pen-color yellow
2 H& M( g) Q9 U, x# F) o. p5 a; Z  [2 w  plot count turtles with [color = yellow]
  set-plot-pen-color green
  plot count turtles with [color = green]
end
to update-lorenz-and-gini-plots
  set-current-plot "Lorenz Curve"
- I3 v  K% V* i* k5 s  clear-plot
0 Q( ]. a& d4 v2 D+ k
  set-current-plot-pen "equal"
  plot 0
; ^! v, @7 b7 F, Q9 i" z% a  plot 100
5 v- z: Z. S8 S+ f) b1 Y
. ?" W5 _( o4 ]& b" x$ U/ r6 q9 k  set-current-plot-pen "lorenz"
- K' b9 F& U: E- l/ B3 v  set-plot-pen-interval 100 / num-people
  plot 0

' A( G! \' R+ n7 e: n( e6 B' G  let sorted-wealths sort [wealth] of turtles
/ |6 y9 e: l7 X! E/ z" u& Y" C. s3 n  let total-wealth sum sorted-wealths
  let wealth-sum-so-far 0
  let index 0
+ B; F" C+ Q3 N5 s2 C  let gini-index-reserve 0
% W& X7 H* b5 {, q
  repeat num-people [
    set wealth-sum-so-far (wealth-sum-so-far + item index sorted-wealths)
1 U/ B! ^! _+ K. ?" j8 [8 H    plot (wealth-sum-so-far / total-wealth) * 100
- C! S' Q. a2 {* V' k) h    set index (index + 1)
    set gini-index-reserve
* O( `% r8 U' z4 o      gini-index-reserve +
* k' y) m6 ?; g+ ]" C# V0 ~6 Y+ _      (index / num-people) -
8 A/ a7 K/ I$ |6 x      (wealth-sum-so-far / total-wealth)
  ]
  Y, P( R4 B  K: J  T
  set-current-plot "Gini-Index v. Time"
  plot (gini-index-reserve / num-people) / area-of-equality-triangle
: p( ~* y# i( i! E1 G+ cend
to-report area-of-equality-triangle
  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