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
[
8 l: q- B6 I$ S  max-grain   
8 p" o; r' y* K" D, g+ J! u9 o9 d
. a, @! I  K7 o6 V" m]
2 v8 a5 d& l1 V& O# o  @
+ h4 ~7 f" A3 C3 O( e/ gpatches-own
7 j6 }5 ~5 I1 i, R- z% \1 ?% v[
  grain-here      
: i! M' i0 G& j  max-grain-here  
+ t+ K, z. |, }$ w* K]

0 o( }7 p6 e( o1 g( Iturtles-own
0 G5 A  x' k4 U" P- v  [. E[
  J0 O! Z# l* X7 Q0 b  age              
/ ], R$ Z" g; j5 U* @9 k% [  wealth         
  life-expectancy  
2 t& i7 s# S+ L, D  metabolism      
  vision
  inherited         
]
8 t0 h5 m1 j: c+ p

to setup
  ca
. B) B% F4 e" h' C6 n& j) u  set max-grain 50
, z6 Y, J( V% Z* k2 G4 i  setup-patches
  setup-turtles
  setup-plots
  update-plots
0 I3 \! v7 K5 N% m' A& H5 A, Fend
to setup-patches
  ask patches
    [ set max-grain-here 0
" g' G. A4 i0 \$ }      if (random-float 100.0) <= percent-best-land
        [ set max-grain-here max-grain
- @" x; K# l, V          set grain-here max-grain-here ] ]
+ m% T# ]6 ^5 o& N8 k  repeat 5
3 y2 f# X9 {. O2 Y+ A    [ ask patches with [max-grain-here != 0]
        [ set grain-here max-grain-here ]
      diffuse grain-here 0.5 ]
8 S( `4 H8 L+ A: k5 B7 M. K. `8 ]  repeat 10
! `; O, D& \9 @! M- F& h- V    [ diffuse grain-here 0.5]         
6 R* L) l* X. K4 _  ask patches
    [ set grain-here floor grain-here   
      set max-grain-here grain-here      
      recolor-patch ]
9 A1 }% K0 _: |: L4 y( I: Send
to recolor-patch  
/ g8 }0 ], y( i. a7 M% E  set pcolor scale-color sky grain-here 0 max-grain
2 I. b0 x+ y3 hend
to setup-turtles
1 j% ?2 `8 V# r  set-default-shape turtles "person"
9 V! z2 W% G9 O$ C  crt num-people
    [ move-to one-of patches  
      set size 1.5  
      set-initial-turtle-vars-age
* h3 ^2 Y" j, |2 T0 t      set-initial-turtle-vars-wealth
3 _% _9 z) e$ ^: P8 _  w% l7 h      set age random life-expectancy ]
9 w  E5 D1 X: C; B. p  recolor-turtles
end

to set-initial-turtle-vars-age
let max-wealth max [wealth] of turtles
   
$ \1 ~/ k6 T! W! u" D7 y     ifelse (wealth <= max-wealth / 3)
        [ set color red
          set age 0
( ~* K4 P* p3 V: o          face one-of neighbors4
          set life-expectancy life-expectancy-min +
                        random life-expectancy-max
- V6 q5 l- {, b3 B4 c9 a8 }          set metabolism random 1 + metabolism-low
, g# d, N+ ~  W, i' D" p7 L          set wealth metabolism + random 30
* Z& D' M" F8 `          set vision 1 + random max-vision
& W" K( @6 T, Z, N! u# P             set wealth  wealth +  Wealth-inherited-low ]
, ]& H% T3 b2 j/ \3 U! r        [ ifelse (wealth <= (max-wealth * 2 / 3))
# I$ c  ~) M/ p            [ set color yellow
- b, _& @/ ^6 S              set age 0
              face one-of neighbors4
: u7 I* G' ~4 I; ^8 D# e! Z% ^              set life-expectancy life-expectancy-min +
# m8 J1 c9 k: a5 W( p2 r3 q/ j: p                        random life-expectancy-max + 1
) M+ ~7 m5 p( a; [              set metabolism  1 + random metabolism-mid
+ a/ d* ^' ~' C% s2 E- ^+ F. a              set wealth metabolism + random 30
9 h$ m/ F/ B& t1 |& y/ ]  U              set vision 3 + random max-vision
- Y4 t+ x7 M* q& M( Y                set wealth  wealth + Wealth-inherited-mid]
4 ?1 |2 Y, c4 F            [ set color green
              set age 0
              face one-of neighbors4
. s& s" }1 c6 d! }* r7 j9 N( [" s5 M              set life-expectancy life-expectancy-min +
. w% y& Q' R+ S9 s: N                        random life-expectancy-max  + 2
              set metabolism 2 + random metabolism-up
* Y: r' m1 Y- I1 E              set wealth metabolism + random 30
: s) y6 r* m: J6 w* W              set vision 3 + random max-vision
% {% S0 ?0 C+ R- K8 d              set wealth  wealth + Wealth-inherited-up ] ]

end
5 y3 ~: m0 z- D( B9 |  tto set-initial-turtle-vars-wealth
let max-wealth max [wealth] of turtles
          set age 0
          face one-of neighbors4
          set life-expectancy life-expectancy-min +
                        random life-expectancy-max
          set metabolism 1 + random metabolism-up
          set wealth metabolism + random 30
9 z3 ~( O$ s" P$ W- {) F          set vision 1 + random max-vision
4 j: [2 `) s9 i5 xend
to redistribution
let max-wealth max [wealth] of turtles
* ]$ A  G$ u/ |let min-wealth min [wealth] of turtles
if (wealth <= max-wealth / 3)
[set wealth  wealth + Low-income-protection ]
1 e& C1 R& V8 ]9 ^end
         
to recolor-turtles
; B/ D+ {" Q( `; J% G! [  let max-wealth max [wealth] of turtles
  ask turtles
   [ ifelse (wealth <= max-wealth / 3)
        [ set color red ]
        [ ifelse (wealth <= (max-wealth * 2 / 3))
: m6 K! x0 T0 s" v6 V1 s4 O            [ set color yellow ]
            [ set color green ] ] ]
ask turtles [ifelse show-wealth?
# f. W' g7 [" }' ]" J, J    [ set label wealth ]
    [ set label "" ]]
9 W& R1 b+ y: k2 K3 W1 V/ f9 ]0 Yend
* M3 {4 }+ G" |# ]) E; C( O0 f4 f6 X
to go
  ask turtles
- l1 Z5 J. v; V' X5 z+ X+ }    [ turn-towards-grain ]  
  harvest
, |' U- x) Y( x% _. ]  ask turtles
    [ move-eat-age-die ]
  recolor-turtles
# A- z- X9 b  X. z+ h! f  if ticks mod grain-growth-interval = 0
9 ?% N8 I- J8 w9 w" _% w/ {    [ ask patches [ grow-grain ] ]
" e. T) {* c! d/ W1 y   
0 g7 Q4 i8 G( w  if ticks mod 11 = 0
3 O  d4 p) x' O$ S2 A( Z* a: F  [ask turtles
' V, Q- ?7 z8 }1 [9 H6 }" R  [ redistribution ]]
6 c4 t; o& ?: g& o  if ticks mod 5 = 0
   [ask turtles
  [ visions ]]
  tick
4 R: n" E4 T! R' Q8 m. P% V4 M  update-plots
: G6 q* L5 ~- H( F/ @- G4 n. W* mend
, ~$ \9 Z+ ^. F( e8 E. `1 oto visions
- B) O6 u" J- q- d; H1 k& o5 Y5 T5 b+ P0 b set vision vision + 1
end
% [1 e5 V/ s7 g! c, Y- W$ o0 R
' R  w1 g3 I6 Z% B7 A  Z
. U" e3 w* r6 u* P6 W" d0 t0 N- a- _2 O
to turn-towards-grain  
$ O6 q- @5 g; Q3 H  set heading 0
  let best-direction 0
6 H; H" o- m( n  let best-amount grain-ahead
  set heading 90
8 D9 A6 h" X0 V5 s  @4 S2 x  if (grain-ahead > best-amount)
$ z. A+ Q" j2 U/ `  a    [ set best-direction 90
      set best-amount grain-ahead ]
: k4 G( ^& v0 C% L  set heading 180
  if (grain-ahead > best-amount)
. c, S: P2 k$ s" N# a/ G    [ set best-direction 180
      set best-amount grain-ahead ]
! C. y- e' l1 B7 x8 V  set heading 270
3 n. p; l% x2 |3 Z  if (grain-ahead > best-amount)
    [ set best-direction 270
6 ~# y1 j) T, l1 {$ `      set best-amount grain-ahead ]
  set heading best-direction
end

4 f3 m6 q6 y2 {- F
to-report grain-ahead  
1 {- [3 R- `- g. N( K% |  L  let total 0
  let how-far 1
7 Y2 ?% `" d2 U( V2 j/ g5 T  repeat vision
    [ set total total + [grain-here] of patch-ahead how-far
5 q  v/ Z2 s4 |4 `; x% r* n      set how-far how-far + 1 ]
; W$ ]# A+ o0 e+ b# [- y  report total
0 k- o. G; E$ @) P% Tend
2 y! E) o7 _- r% X5 E( ^) G2 C
to grow-grain
( J( W9 |9 K! y& v( n7 l) ~  if (grain-here < max-grain-here)
    [ set grain-here grain-here + num-grain-grown
      if (grain-here > max-grain-here)
7 U3 N$ X6 k' C        [ set grain-here max-grain-here ]
      recolor-patch ]
- @3 ~2 f4 |9 |5 L% send
to harvest
  ask turtles
; M7 ?9 E% L' g* i$ U9 M    [ set wealth floor (wealth + (grain-here / (count turtles-here))) ]
  ask turtles
    [ set grain-here 0
      recolor-patch ]
  
end

  t0 U0 h" h. k) s2 k1 Vto move-eat-age-die  
  fd 1
! ^  n: ]  t# w$ v  set wealth (wealth - metabolism)
    set age (age + 1)
  if (age >= life-expectancy)
    [ set-initial-turtle-vars-age ]
  if (wealth < 0)
    [ set-initial-turtle-vars-wealth ]
' \/ I1 {7 S- h: X& a0 I   
end
0 E* t0 c9 k; q7 J
7 E) Z0 b) [  v' X  K/ U5 I9 @1 g
3 ^& R2 N" E5 z; v& kto setup-plots
  set-current-plot "Class Plot"
3 x7 b  u7 v, u5 m* X. G3 m+ P9 \( m  set-plot-y-range 0 num-people
9 T$ G: m$ M/ S  set-current-plot "Class Histogram"
# |2 g5 G' y) o$ C  set-plot-y-range 0 num-people
& _7 G, i) o, }$ x6 V) rend
2 @: A1 g* l7 j2 \6 O
4 `" ~6 g" g6 `8 e2 s3 f" [, ~to update-plots
  update-class-plot
/ _7 |1 `! m  ^2 K8 u" m  update-class-histogram
  update-lorenz-and-gini-plots
end

5 W, v( G+ P. U  x4 x+ z; hto update-class-plot
1 ?# d! V) ^- i: a  set-current-plot "Class Plot"
  set-current-plot-pen "low"
  plot count turtles with [color = red]
  set-current-plot-pen "mid"
6 d8 v9 F: n/ ^% P) [  plot count turtles with [color = yellow]
  set-current-plot-pen "up"
- _8 f" W( D0 ?1 X7 P3 _+ y  plot count turtles with [color = green]
* i# L% O( A. h3 r0 a  d' k: n6 Send
! o# ], k! @# T' c) Z0 D( \
to update-class-histogram
  set-current-plot "Class Histogram"
  plot-pen-reset
( C% @, j  x! T4 e8 a  set-plot-pen-color red
  plot count turtles with [color = red]
  set-plot-pen-color yellow
3 Y1 F9 i* X/ B* o0 P  plot count turtles with [color = yellow]
5 v' S+ P& `# @) B, h  set-plot-pen-color green
  plot count turtles with [color = green]
end
to update-lorenz-and-gini-plots
7 M3 n1 f& C1 W6 {3 |  set-current-plot "Lorenz Curve"
. O$ N& p2 q$ x; i  clear-plot
% Z% o2 I, N' v4 z7 _4 n
" b# t3 g8 q1 O; D" h  set-current-plot-pen "equal"
$ U/ X8 G) d1 C; {8 i% O1 T8 }7 j  plot 0
% w( `- ]8 Q; r6 x8 s5 ^" B. P  plot 100
8 B0 D3 w1 l. ~6 p4 J, a( m+ ~* J* F
  set-current-plot-pen "lorenz"
  set-plot-pen-interval 100 / num-people
. {  X- J9 |, H5 ^9 S5 A* o  plot 0

  let sorted-wealths sort [wealth] of turtles
  let total-wealth sum sorted-wealths
5 p# r$ U" e3 d4 d. z9 t  let wealth-sum-so-far 0
  let index 0
4 G# l% D7 D  P0 G  let gini-index-reserve 0
. C5 M4 w" Y, s% R4 k4 `6 B
, C+ A3 q# e/ t8 O* O  repeat num-people [
% Y3 r) T9 a% _+ V1 E$ F" h    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
( [( r. c7 R" v  R0 f. I% R      gini-index-reserve +
      (index / num-people) -
. S! q0 n) K6 j& k5 m. p      (wealth-sum-so-far / total-wealth)
  ]
. c6 B) v. B  m  F' m! ~: k/ G
  set-current-plot "Gini-Index v. Time"
; ~, x# F, l- \1 e  plot (gini-index-reserve / num-people) / area-of-equality-triangle
end
7 o+ ?" J. `2 \. n, m9 E5 Z5 \to-report area-of-equality-triangle
  report (num-people * (num-people - 1) / 2) / (num-people ^ 2)
' [/ ]# t3 U7 B0 U- k4 i7 R) H- Qend

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