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
$ j% o% \8 K+ F+ k2 b! i[
  max-grain   
7 C. [  a4 m* X; T# g
]

patches-own
[
  grain-here      
! G9 k' X1 B; W0 \0 N5 J4 z+ B  max-grain-here  
]
$ A# C- o+ o* \  }( s; d( o9 `
turtles-own
( u6 ]4 m$ h* `2 e[
  age              
  wealth         
  life-expectancy  
! q4 X3 V3 T% R2 d  metabolism      
7 X# i$ ]  y  t: [& y0 x) J1 @  S: D+ r  vision
' j' S+ u5 t% u1 ]" G  inherited         
; S' J4 t, l& Q/ P1 Z  ~& Z]
+ ?; a6 m" E7 c3 f' L, D3 U- ~$ i8 R6 M

to setup
  ca
  set max-grain 50
$ p5 W( l  t, s4 r  x  setup-patches
1 P6 m# y8 T+ O  setup-turtles
* ]) s/ f1 W1 X4 |  setup-plots
  update-plots
end
! g5 S1 J. |% ~to setup-patches
  ask patches
    [ set max-grain-here 0
. @3 z/ P( B1 N$ I& ?' N, \, X      if (random-float 100.0) <= percent-best-land
        [ set max-grain-here max-grain
          set grain-here max-grain-here ] ]
  repeat 5
    [ ask patches with [max-grain-here != 0]
        [ set grain-here max-grain-here ]
: U/ N+ V1 b6 T) D      diffuse grain-here 0.5 ]
; E4 M& K; i# F: t/ N* Z  i7 P  g1 P  repeat 10
4 K5 ]7 A# m0 P# F( ~# J) `& X    [ diffuse grain-here 0.5]         
5 q2 K; i, a. D# e  ask patches
5 z, D6 _$ ]9 y; {: @& I+ f    [ set grain-here floor grain-here   
      set max-grain-here grain-here      
7 o! k; `! |# A0 |      recolor-patch ]
6 @5 |' q2 t( J4 E* q! {) Dend
' e6 M2 M: l+ e1 @. Z  Nto recolor-patch  
( A$ z4 d+ s7 K: u( z  Y" p5 ~  set pcolor scale-color sky grain-here 0 max-grain
end
) Q7 m5 [( u  ~  u4 s+ ?) a# Z/ Ito setup-turtles
% c; n' i9 m; @0 \7 q9 O  set-default-shape turtles "person"
  crt num-people
    [ move-to one-of patches  
      set size 1.5  
0 O$ b' u5 P& Q. n$ I2 B      set-initial-turtle-vars-age
0 S* N1 `8 v) |2 }2 ^' v/ h9 H      set-initial-turtle-vars-wealth
$ ^0 k9 f( w: ~2 s8 L      set age random life-expectancy ]
% `- a6 @* ?3 l: I2 d6 k$ w  recolor-turtles
6 \0 Z8 t$ d9 X) @end
4 m& ^5 V# T3 }  b( k: o* h
to set-initial-turtle-vars-age
5 [/ T1 X/ \0 p; O let max-wealth max [wealth] of turtles
' m6 h" ^+ z/ W( _1 J* s- r5 H   
     ifelse (wealth <= max-wealth / 3)
        [ set color red
2 i# R! O, \- X  ?2 K          set age 0
          face one-of neighbors4
/ {+ G' j: F' ~# d) m- K7 v9 l1 s          set life-expectancy life-expectancy-min +
                        random life-expectancy-max
          set metabolism random 1 + metabolism-low
& G; t; [! ^2 R8 {. K+ V1 s( e          set wealth metabolism + random 30
          set vision 1 + random max-vision
7 x9 a; C9 V7 E' S2 B& u             set wealth  wealth +  Wealth-inherited-low ]
        [ ifelse (wealth <= (max-wealth * 2 / 3))
            [ set color yellow
              set age 0
              face one-of neighbors4
              set life-expectancy life-expectancy-min +
                        random life-expectancy-max + 1
) w; _- E. Q9 F+ e" N* K              set metabolism  1 + random metabolism-mid
5 ^/ ], e. p  W0 K4 u) z              set wealth metabolism + random 30
4 X" {% d9 j2 M8 J2 W' I% `7 I( T# m* ~              set vision 3 + random max-vision
                set wealth  wealth + Wealth-inherited-mid]
            [ set color green
0 Z5 ~; f7 a, C: k% _0 H              set age 0
              face one-of neighbors4
% f" W- b% M, a& I! k: `              set life-expectancy life-expectancy-min +
                        random life-expectancy-max  + 2
6 }+ Q, ^- P2 a' w" E              set metabolism 2 + random metabolism-up
) T; z" i3 b# q2 R3 B) s! B- O              set wealth metabolism + random 30
: ]% v' V/ @0 n% ~4 r, `! r              set vision 3 + random max-vision
4 J4 Z' k9 G. `( R& D3 q* ?# @$ y              set wealth  wealth + Wealth-inherited-up ] ]
# N" W# A4 e% F- x7 m$ }
1 m8 \$ `7 F- c3 C5 t5 r( H% aend
: ]- [. W/ U) X1 Z3 a. C3 v3 Eto set-initial-turtle-vars-wealth
2 _4 M3 _/ q9 U* V let max-wealth max [wealth] of turtles
          set age 0
          face one-of neighbors4
" h( Y; E2 P  }  Z# G! ?          set life-expectancy life-expectancy-min +
                        random life-expectancy-max
          set metabolism 1 + random metabolism-up
          set wealth metabolism + random 30
          set vision 1 + random max-vision
2 Q$ d5 j7 t# Z* Aend
to redistribution
let max-wealth max [wealth] of turtles
2 A. T; R4 @! D! s' v- wlet min-wealth min [wealth] of turtles
if (wealth <= max-wealth / 3)
[set wealth  wealth + Low-income-protection ]
/ c6 w0 t. A' J) z$ t! Xend
         
to recolor-turtles
( L. U- b6 [3 @! r7 M& X2 Q  let max-wealth max [wealth] of turtles
  ask turtles
- s1 x! _. Z8 m1 b0 i# r: \; H* F   [ ifelse (wealth <= max-wealth / 3)
* U& m2 o- E% a' a* }+ Z; g        [ set color red ]
        [ ifelse (wealth <= (max-wealth * 2 / 3))
            [ set color yellow ]
5 B5 `! a/ e- \! z1 k4 ~            [ set color green ] ] ]
ask turtles [ifelse show-wealth?
    [ set label wealth ]
5 v$ n0 E, B8 e9 g    [ set label "" ]]
end
  ^7 U4 @9 u! b/ j
to go
  ask turtles
1 j, C) x, ?+ i1 H! h1 [4 O+ U) R' a" y    [ turn-towards-grain ]  
  harvest
  ask turtles
. Y! S6 n7 ~" i: m    [ move-eat-age-die ]
  recolor-turtles
$ E& C% j8 g' \% E/ w  if ticks mod grain-growth-interval = 0
+ I; D; B$ O6 E0 ]6 M7 j. A! k    [ ask patches [ grow-grain ] ]
' ]0 z! |8 r7 t" _   
3 Y0 {" }; f1 {  if ticks mod 11 = 0
% I- }  m9 i, q9 b5 X  [ask turtles
* m% Z. V; Z' y4 F0 @7 H& c( R# Q  [ redistribution ]]
  if ticks mod 5 = 0
/ h5 p/ @, r0 h: a   [ask turtles
  [ visions ]]
+ }0 I) y( x8 d' t* ]8 _: O  tick
  update-plots
end
to visions
+ h) a8 _$ E5 s  ~$ y7 { set vision vision + 1
end
) [2 `; O# C* \8 P9 u

4 b) P) [. K* C* p6 Q+ S; k
to turn-towards-grain  
. J* i, r8 x! T& s5 K, U  set heading 0
: x4 U1 V- @" m' \. m  let best-direction 0
  let best-amount grain-ahead
& `; ]3 J# w4 S$ s3 s  x6 A  set heading 90
  if (grain-ahead > best-amount)
. j! ?4 L0 a1 o    [ set best-direction 90
1 \% \* ]' u9 M      set best-amount grain-ahead ]
! l1 _$ e5 d) \  v; Z  set heading 180
6 f( O' x9 D" I4 `- h! E- B  if (grain-ahead > best-amount)
1 T7 S" m$ R. O- @$ U    [ set best-direction 180
) i. J0 X5 i# C      set best-amount grain-ahead ]
5 d* O- U. T' `& R# ~  set heading 270
  if (grain-ahead > best-amount)
3 G# E( H8 ]& H% M9 J! Y    [ set best-direction 270
; I: ?, y; ?5 S+ @      set best-amount grain-ahead ]
  set heading best-direction
end
0 g0 A8 o& m0 \1 T" m

to-report grain-ahead  
  let total 0
5 B) ^4 Y/ f! }; |4 D- W' V  let how-far 1
& L) s6 X7 C: o( w5 {/ X- X  repeat vision
7 ~( v% f7 t! e9 S- `    [ set total total + [grain-here] of patch-ahead how-far
& b7 R) U/ H; d: R# x5 T      set how-far how-far + 1 ]
  report total
3 T& B( m$ Q: dend
! F& C5 z, O5 y0 X5 v% \  u, B9 v
; n8 L) i7 D7 L. P% xto grow-grain
( R& t7 H; Y) Y  if (grain-here < max-grain-here)
    [ set grain-here grain-here + num-grain-grown
1 S# |' P) Q* E' ?- H      if (grain-here > max-grain-here)
        [ set grain-here max-grain-here ]
) Q( F) i" b7 g; q5 h      recolor-patch ]
" o0 R2 ^( K! zend
: C$ w7 a3 f2 z0 q0 \: X) F$ hto harvest
  ask turtles
    [ set wealth floor (wealth + (grain-here / (count turtles-here))) ]
- a' ]1 ^& j- b& W2 ~  ask turtles
$ `  `3 B3 e' c* `' d    [ set grain-here 0
      recolor-patch ]
  
end
5 m& {+ |& Q0 M
, m) [* U2 e7 d; w1 gto move-eat-age-die  
2 D' t6 f! ^3 s8 {, J  fd 1
9 i$ M# r# ^+ ~* R: f  set wealth (wealth - metabolism)
    set age (age + 1)
% d3 R$ e5 K- e7 o; j- X! e1 s  if (age >= life-expectancy)
, d# K) O) t2 e- w& n    [ set-initial-turtle-vars-age ]
  if (wealth < 0)
    [ set-initial-turtle-vars-wealth ]
   
end


3 c) ~  e2 u7 Q, f, k3 ]& cto setup-plots
  set-current-plot "Class Plot"
0 D2 P# i: T) A" J7 V2 e  set-plot-y-range 0 num-people
5 `+ R2 X5 R# ?  B/ H& h  set-current-plot "Class Histogram"
  set-plot-y-range 0 num-people
' }( C% j9 _3 u6 |) Z3 S6 ?end

to update-plots
  update-class-plot
9 g+ w; M9 \: X9 r5 K& E1 a% i6 j  update-class-histogram
1 |* j( v7 l$ F+ i; q  update-lorenz-and-gini-plots
( m, C3 W$ K+ Z0 q! Gend

to update-class-plot
  set-current-plot "Class Plot"
0 x4 V8 T3 u6 G4 s& e% m  set-current-plot-pen "low"
  plot count turtles with [color = red]
1 x4 `/ Q1 ]& T5 _- T) k3 }  set-current-plot-pen "mid"
9 T+ u1 U- J) |  plot count turtles with [color = yellow]
# _% `3 f0 A, [- t" m( ~  set-current-plot-pen "up"
6 Z$ }& [% N( b7 b  plot count turtles with [color = green]
! H- S6 `. v& }: b& w! j9 `end

to update-class-histogram
+ n- f4 T1 V" o; K, S  set-current-plot "Class Histogram"
  plot-pen-reset
  set-plot-pen-color red
  plot count turtles with [color = red]
  set-plot-pen-color yellow
) `; b% l! K. p  plot count turtles with [color = yellow]
. d; K/ G/ y9 L  set-plot-pen-color green
  plot count turtles with [color = green]
$ _# B( Z0 ~+ Hend
to update-lorenz-and-gini-plots
  set-current-plot "Lorenz Curve"
  clear-plot
0 m' D& ^" k# Q; N3 h  X
  set-current-plot-pen "equal"
  plot 0
  plot 100

6 G2 `; V  |" e, U  h- Y; X  set-current-plot-pen "lorenz"
  set-plot-pen-interval 100 / num-people
  plot 0
/ H" W. C8 Z' X
3 C/ ~6 C8 g( u0 x1 `- N  let sorted-wealths sort [wealth] of turtles
) i5 Y7 X: s. A" E  let total-wealth sum sorted-wealths
  let wealth-sum-so-far 0
0 i/ j( c' l% [" J, |  let index 0
8 T8 U9 c4 ~- A9 S& i/ x  let gini-index-reserve 0

  repeat num-people [
    set wealth-sum-so-far (wealth-sum-so-far + item index sorted-wealths)
+ p) c' k5 v3 {1 C" F9 [    plot (wealth-sum-so-far / total-wealth) * 100
    set index (index + 1)
    set gini-index-reserve
! B8 |1 T1 \0 g7 m- z/ y+ A. X      gini-index-reserve +
      (index / num-people) -
- M7 R0 n# U, g+ _0 J: K' M7 @      (wealth-sum-so-far / total-wealth)
  ]

% N) j+ A, c# ~3 L5 N$ n  set-current-plot "Gini-Index v. Time"
( d( q# J. U! S( [  plot (gini-index-reserve / num-people) / area-of-equality-triangle
end
to-report area-of-equality-triangle
! W' r! k$ D2 a  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