Difference between revisions of "Esercizi di "lettura" programmi in Python 2019/20"
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(Created page with "Gli esercizi proposti sono programmi funzionanti. Come svolgimento dell'esercizio si deve: * determinare lo scopo del programma * modificare, migliorare discutere le soluzion...") |
(→5) |
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Line 78: | Line 78: | ||
<source lang=python> | <source lang=python> | ||
import turtle | import turtle | ||
+ | import random | ||
+ | |||
def cy(r): | def cy(r): | ||
turtle.setup(400,400) | turtle.setup(400,400) | ||
Line 84: | Line 86: | ||
turtle.speed(0) | turtle.speed(0) | ||
for i in range(1000): | for i in range(1000): | ||
− | x,y=random.randint(-200,200),random.randint(-200,200) | + | x,y = random.randint(-200,200),random.randint(-200,200) |
− | if (x*x+y*y)**0.5 < r: | + | if (x*x + y*y)**0.5 < r: |
− | color="red" | + | color = "red" |
else: | else: | ||
− | color="blue" | + | color = "blue" |
turtle.goto(x,y) | turtle.goto(x,y) | ||
turtle.dot(5,color) | turtle.dot(5,color) | ||
− | if __name__=="__main__": | + | if __name__ == "__main__": |
− | r=float(input("scrivi un numero (consigliato da 100 a 200): ")) | + | r = float(input("scrivi un numero (consigliato da 100 a 200): ")) |
print("guarda il risultato della funzione misteriosa") | print("guarda il risultato della funzione misteriosa") | ||
cy(r) | cy(r) |
Revision as of 15:21, 4 December 2019
Gli esercizi proposti sono programmi funzionanti.
Come svolgimento dell'esercizio si deve:
- determinare lo scopo del programma
- modificare, migliorare discutere le soluzioni proposta. Proporre soluzioni alternative dello stesso problema.
1
def dd(s):
d,m,y=s.split('.')
d,m,y=int(d),int(m),int(y)
md=[0,31,28,31,30,31,30,31,31,30,31,30,31]
if y % 4 == 0: md[2]=29
dy=d
for i in range(1,m):
dy += md[i]
return dy
if __name__=="__main__":
data=input("Dammi una data (es. 14.03.2014) ")
print("il risultato della funzione misteriosa e' ",dd(data))
2
def imin(l):
im,mn=0,l[0]
for i in range(1,len(l)):
if l[i]<mn: im,mn=i,l[i]
return im
if __name__="__main__":
l=input('dammi in input una lista di elementi (es: [1,2,3]): ')
print("l'output della funzione misteriosa e': ",imin(l))
3
def r13(s):
e=''
for c in s:
if 'A'<=c<='Z':
e+=chr(((ord(c)-ord('A'))+13)%26+ord('A'))
elif 'a'<=c<='z':
e+=chr(((ord(c)-ord('a'))+13)%26+ord('a'))
else:
e+=c
return e
if __name__=="__main__":
s=input("scrivi una semplice frase (es: 'Ciao Mondo') ")
r=r13(s)
print("il risultato della funzione misteriosa e': ",r)
print("consiglio: prova a eseguire nuovamente il programma scrivendo")
print("la frase: ",r)
4
def pf(n):
f=[]
for i in range(2,n+1):
while n % i == 0:
f.append(i)
n //= i
if n == 1:
break
return f
if __name__=="__main__":
n=int(input("dammi un numero (consigliato da 2 a 1000): "))
print("il risultato della funzione misteriosa e' ",pf(n))
5
(richiede il modulo turtle)
import turtle
import random
def cy(r):
turtle.setup(400,400)
turtle.penup()
turtle.hideturtle()
turtle.speed(0)
for i in range(1000):
x,y = random.randint(-200,200),random.randint(-200,200)
if (x*x + y*y)**0.5 < r:
color = "red"
else:
color = "blue"
turtle.goto(x,y)
turtle.dot(5,color)
if __name__ == "__main__":
r = float(input("scrivi un numero (consigliato da 100 a 200): "))
print("guarda il risultato della funzione misteriosa")
cy(r)
turtle.exitonclick()
6
(richiede il modulo turtle)
import turtle
def poly(n):
for i in range(n):
turtle.forward(50)
turtle.left(360/n)
if __name__=="__main__":
n=int(input("dammi un intero (consigliato da 3 a 12): "))
poly(n)
turtle.exitonclick()
7
Questo e' contorto. Se vi piace... iniziate a preoccuparvi: state diventando informatici ;-)
f="f={0}{1}{0};print(f.format(chr(34),f))";print(f.format(chr(34),f))
NB: non e' necessario capire questo programma, e' solo per chi si vuole cimentare in una sfida...
8
def pf(n):
f=[]
for i in range(2,n+1):
while n % i == 0:
f.append(i)
n //= i
if n == 1:
break
return f
def fgcd(a,b):
def rgcd(fa,fb):
if fa and fb:
if fa[0]==fb[0]:
return fa[:1]+rgcd(fa[1:],fb[1:])
elif fa[0]<fb[0]:
return rgcd(fa[1:],fb)
else:
return rgcd(fa,fb[1:])
else:
return []
return rgcd(pf(a),pf(b))
def flcm(a,b):
def rlcm(fa,fb):
if fa and fb:
if fa[0]==fb[0]:
return fa[:1]+rlcm(fa[1:],fb[1:])
elif fa[0]<fb[0]:
return fa[:1]+rlcm(fa[1:],fb)
else:
return fa[:1]+rlcm(fa,fb[1:])
else:
return fa if fa else fb
return rlcm(pf(a),pf(b))
def mul(l):
rv=1
for el in l:
rv *= el
return rv
def gcd(x,y):
return mul(fgcd(x,y))
def lcm(x,y):
return mul(flcm(x,y))
if __name__=="__main__":
a,b=input("Inserisci due numeri (es: 48 36): ").split()
a,b=int(a),int(b)
print("pf({})={}".format(a,pf(a)))
print("pf({})={}".format(b,pf(b)))
print("fgcd({},{})={}".format(a,b,fgcd(a,b)))
print("flcm({},{})={}".format(a,b,flcm(a,b)))
print("gcd({},{})={}".format(a,b,gcd(a,b)))
print("lcm({},{})={}".format(a,b,lcm(a,b)))
9
def div(n):
return {x for x in range(1,n+1) if n % x == 0}
#alternativa:
#def div(n):
# d=set()
# for x in range(1,n+1):
# if n % x == 0: d.add(x)
# return d
def gcd(a,b):
return max(div(a) & div(b))
def mul(n,limit):
return {x*n for x in range(1,limit//n + 1)}
#alternativa
#def mul(n,limit):
# d=set()
# for x in range(1,limit//n + 1):
# d.add(x*n)
# return d
def lcm(a,b):
return min(mul(a,a*b) & mul(b,a*b))
if __name__=="__main__":
a,b=input("Inserisci due numeri (es: 48 36): ").split()
a,b=int(a),int(b)
print("div({})={}".format(a,div(a)))
print("div({})={}".format(b,div(b)))
print("mul({},{})={}".format(a,a*b,mul(a,a*b)))
print("mul({},{})={}".format(b,a*b,mul(b,a*b)))
print("gcd({},{})={}".format(a,b,gcd(a,b)))
print("lcm({},{})={}".format(a,b,lcm(a,b)))
10
def sdiv(n):
return {x for x in range(2,n) if n % x == 0}
#alternativa:
#def sdiv(n):
# d=set()
# for x in range(2,n):
# if n % x == 0: d.add(x)
# return d
def pr(n):
return not sdiv(n)
def pdiv(n):
return {x for x in sdiv(n) if pr(x)}
#alternativa:
#def pdiv(n):
# d=set()
# for x in sdiv(n):
# if pr(x): d.add(x)
# return d
def gcd(a,b):
csdiv=pdiv(a) & pdiv(b)
r=1
for x in csdiv:
while a % (r*x) == 0 and b % (r*x) == 0:
r *= x
return r
def lcm(a,b):
return a * b // gcd(a,b)
if __name__=="__main__":
a,b=input("Inserisci due numeri (es: 48 36): ").split()
a,b=int(a),int(b)
print("pdiv({})={}".format(a,pdiv(a)))
print("pdiv({})={}".format(b,pdiv(b)))
print("gcd({},{})={}".format(a,b,gcd(a,b)))
print("lcm({},{})={}".format(a,b,lcm(a,b)))
11
def tartline(l):
l[:0]=[1]
for i in range(1,len(l)-1):
l[i] += l[i+1]
l=[]
for i in range(12):
tartline(l)
print("{:^60}".format(str(l)))
12
def sdiv(n):
return {x for x in range(2,n) if n % x == 0}
#alternativa:
#def sdiv(n):
# d=set()
# for x in range(2,n):
# if n % x == 0: d.add(x)
# return d
def pr(n):
return not sdiv(n)
N=int(input("dammi il numero massimo (es 100): "))
print("ecco i numeri ***** fino a",N,":",[n for n in range(1,N+1) if pr(n)])
13
vf=[("Nella vecchia fattoria","Quante bestie ha zio Tobia","C'e' la capra","capra","ca"),
("Attaccato a un carrettino","C'è un quadrupede piccino","L'asinel","nel","nè"),
("Tra le casse e i ferri rotti", "Dove i topi son grassotti","C'è un bel gatto","gatto","ga"),
("Tanto grasso e tanto grosso", "Sempre sporco a più non posso", "C'è il maiale","iale","ia"),
("Poi sull'argine del fosso", "Alle prese con un osso", "C'è un bel cane","cane","ca"),
("Nella stalla silenziosa", "Dopo aver mangiato a iosa", "Dorme il bue","bue","bu")]
refrain="ia ia o"
def recverse(m,n):
v1,v2,an1,an2,an3=vf[m]
if n==m:
print(v1,refrain)
print(v2,refrain)
else:
recverse(m+1,n)
print(an1,an2,an3,an3,an2)
for i in range(len(vf)):
recverse(0,i)
print(vf[0][0],refrain)
print()
14
import turtle
def hser(size, level):
if level==0:
turtle.forward(size)
else:
hser(size,level-1)
turtle.left(45)
turtle.forward(size * 2**0.5)
turtle.left(45)
hser(size,level-1)
turtle.right(90)
turtle.forward(size)
turtle.right(90)
hser(size,level-1)
turtle.left(45)
turtle.forward(size * 2**0.5)
turtle.left(45)
hser(size,level-1)
def ser(size, level):
turtle.penup()
pos=(2**(level+2)-3) * size // 2 #posizione iniziale
turtle.setpos(-pos,pos)
turtle.pendown()
hser(size,level)
turtle.right(90)
hser(size,level)
turtle.right(90)
hser(size,level)
turtle.right(90)
hser(size,level)
turtle.right(90)
turtle.speed(0)
turtle.hideturtle()
ser(2,1)
ser(2,2)
ser(2,3)
ser(2,4)
turtle.exitonclick()
15
import turtle
import colorsys
import sys
def arrowstep(level, length, angle):
if level:
arrowstep(level-1, length/2, -angle)
turtle.left(angle)
arrowstep(level-1, length/2, angle)
turtle.left(angle)
arrowstep(level-1, length/2, -angle)
else:
turtle.forward(length)
def arrow(level, length):
if level & 1:
turtle.left(60)
arrowstep(level, length, -60)
else:
arrowstep(level, length, -60)
turtle.speed(0)
turtle.hideturtle()
turtle.colormode(1)
nmax=6
width=256
xmin= -width//2
ymin= -width*(3**0.5)//4
for n in range(nmax):
turtle.penup()
turtle.setposition(xmin,ymin)
turtle.setheading(0)
turtle.pencolor(colorsys.hls_to_rgb(1.0*n/6,0.5,1))
turtle.pendown()
arrow(n,256)
turtle.exitonclick()
16
def av(l):
return sum(l)/len(l)
def rg(l):
return max(l)-min(l)
def md(l):
lx=len(l)
ls=sorted(l)
if lx%2:
return ls[lx//2]
else:
return (ls[lx//2-1]+ls[lx//2])/2
if __name__=="__main__":
l=input("dammi una lista di numeri separati da virgole (es: 1,2,3,4.4): ")
l=[float(x) for x in l.split(',')]
print("i valori trovati dalle tre funzioni sono: {:.4f} {:.4f} {:.4f}".format(av(l),rg(l),md(l)))
17
import turtle
import sys
rows,cols=4,4
buttonsize=50
topdisplay=2*buttonsize
stack=[0]
fresh=True
def num(x):
global fresh,stack
if fresh:
stack[:0]=[x]
fresh=False
else:
stack[0]=stack[0]*10+x
enter,add,sub,mul,div=0,int.__add__,int.__sub__,int.__mul__,int.__floordiv__
def op(x):
global fresh,stack
if x!=enter and len(stack)>1:
stack=[x(stack[1],stack[0])]+stack[2:]
fresh=True
def off(x):
sys.exit(0)
buttons={
(0,0):('0',num,0), (1,0):('1',num,1), (1,1):('2',num,2), (1,2):('3',num,3), (2,0):('4',num,4),
(2,1):('5',num,5), (2,2):('6',num,6), (3,0):('7',num,7), (3,1):('8',num,8), (3,2):('9',num,9),
(3,3):('+',op,add), (2,3):('-',op,sub), (1,3):('*',op,mul), (0,3):('/',op,div),
(0,2):('ent',op,enter), (0,1):('off',off,0)}
def click(x,y):
col=x//buttonsize
row=y//buttonsize
if (row,col) in buttons:
label,op,val=buttons[row,col]
op(val)
drawcalc()
def drawcalc():
def drawbutton(col,row,label):
turtle.setpos(row*buttonsize,col*buttonsize)
turtle.pendown()
for _ in range(4):
turtle.forward(buttonsize)
turtle.left(90)
turtle.penup()
turtle.setpos(row*buttonsize+buttonsize//2,col*buttonsize+buttonsize//2)
turtle.write(label,align="center")
turtle.clear()
turtle.penup()
for row,col in buttons:
drawbutton(row,col,buttons[row,col][0])
turtle.setpos(row*buttonsize*(rows-1),col*buttonsize*(cols+1))
turtle.write(str(stack[0]),align="right")
turtle.update()
turtle.screensize(cols*buttonsize+1, rows*buttonsize+topdisplay+1)
turtle.setup(cols*buttonsize+1, rows*buttonsize+topdisplay+1)
turtle.setworldcoordinates(0,0,cols*buttonsize, rows*buttonsize+topdisplay)
turtle.hideturtle()
turtle.speed(10)
turtle.tracer(0)
drawcalc()
turtle.onscreenclick(click)
turtle.listen()
turtle.mainloop()
18
import turtle
import colorsys
import time
N=6
frompin=list(range(N,0,-1))
auxpin=[]
topin=[]
def rectangle(size, level, pin):
turtle.penup()
turtle.setpos(2*N*10*pin,level*10)
turtle.setheading(0)
turtle.pendown()
turtle.fillcolor(colorsys.hls_to_rgb(1.0*(size-1)/N,0.5,1))
turtle.begin_fill()
turtle.forward(size*10)
turtle.left(90)
turtle.forward(10)
turtle.left(90)
turtle.forward(size*20)
turtle.left(90)
turtle.forward(10)
turtle.left(90)
turtle.forward(size*10)
turtle.end_fill()
def showhanoi():
turtle.clear()
lf,la,lt=map(len,(frompin,auxpin,topin))
for i in range(lf):
rectangle(frompin[i], i, -1)
for i in range(la):
rectangle(auxpin[i], i, 0)
for i in range(lt):
rectangle(topin[i], i, 1)
turtle.update()
time.sleep(0.2)
def hanoi(n,f,a,t):
if n==1:
t.append(f.pop())
showhanoi()
else:
hanoi(n-1,f,t,a)
hanoi(1,f,a,t)
hanoi(n-1,a,f,t)
turtle.hideturtle()
turtle.speed(10)
turtle.tracer(0)
showhanoi()
hanoi(N,frompin,auxpin,topin)
turtle.exitonclick()
19
#!/usr/bin/env python3
# Copyright 2014 Renzo Davoli University of Bologna - Italy
# This program is free software; you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation; either version 2 of the License, or
# (at your option) any later version.
#
# This program is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU General Public License for more details.
#
# You should have received a copy of the GNU General Public License along
# with this program; if not, write to the Free Software Foundation, Inc.,
# 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
#
import sys
class num:
def __init__(self,n):
self.val=n
class mul(num):
pass
class onemul(mul):
pass
class plus():
pass
class times():
pass
class numlanguage():
def __init__(self):
self.dict={}
def __setitem__(self,s,op):
self.dict[s]=op
for l in range(len(s)-1,0,-1):
if s[:l] in self.dict:
break
else:
self.dict[s[:l]]=None
return op
def match(self,s):
matchlen,obj=0,None
for l in range(1,len(s)+1):
if s[:l] in self.dict:
matchlen,obj=l,self.dict[s[:l]]
else:
break
return matchlen,obj
def str2num(langnum,s):
hi=mid=lo=last=0
lastop=None
while s:
if s[0] in " -\t\n":
s=s[1:]
else:
ml,obj=langnum.match(s)
if obj:
if isinstance(obj,num):
if isinstance(obj,mul):
if isinstance(obj,onemul) and lo == 0:
lo = 1
if (last <= obj.val or isinstance(lastop,times)) and not isinstance(lastop,plus):
hi,mid,lo = (hi+mid+lo)*obj.val,0,0
else:
hi,mid,lo = hi+(lo+mid)*obj.val,0,0
last=obj.val
else:
if obj.val == 100:
mid,lo = lo*obj.val if lo else obj.val,0
elif obj.val <= lo or isinstance(lastop,plus):
lo += obj.val
else:
lo = lo*obj.val if lo else obj.val
lastop=None
else:
lastop=obj
#print(s[:ml],hi,mid,lo,last,lastop)
s=s[ml:]
else:
return -1
return hi+mid+lo
def num_it():
nl=numlanguage()
nl["zero"]=num(0)
nl["uno"]=nl["un"]=nl["una"]=num(1)
nl["due"]=num(2)
nl["tre"]=num(3)
nl["quattro"]=num(4)
nl["cinque"]=num(5)
nl["sei"]=num(6)
nl["sette"]=num(7)
nl["otto"]=num(8)
nl["nove"]=num(9)
nl["dieci"]=num(10)
nl["undici"]=num(11)
nl["dodici"]=num(12)
nl["tredici"]=num(13)
nl["quattordici"]=num(14)
nl["quindici"]=num(15)
nl["sedici"]=num(16)
nl["diciassette"]=num(17)
nl["diciotto"]=num(18)
nl["diciannove"]=num(19)
nl["venti"]=nl["vent"]=num(20)
nl["trenta"]=nl["trent"]=num(30)
nl["quaranta"]=nl["quarant"]=num(40)
nl["cinquanta"]=nl["cinquant"]=num(50)
nl["sessanta"]=nl["sessant"]=num(60)
nl["settanta"]=nl["settant"]=num(70)
nl["ottanta"]=nl["ottant"]=num(80)
nl["novanta"]=nl["novant"]=num(90)
nl["cento"]=num(100)
nl["mille"]=onemul(10**3)
nl["mila"]=nl["migliaia"]=mul(10**3)
nl["milioni"]=nl["milione"]=mul(10**6)
nl["miliardi"]=nl["miliardo"]=mul(10**9)
nl["dozzine"]=nl["dozzina"]=mul(12)
nl["decine"]=mul(10)
nl["centinaia"]=mul(100)
nl["di"]=times()
nl["e"]=plus()
return nl
def num_en():
nl=numlanguage()
nl["zero"]=nl["null"]=num(0)
nl["one"]=nl["a"]=num(1)
nl["two"]=num(2)
nl["three"]=num(3)
nl["four"]=num(4)
nl["five"]=num(5)
nl["six"]=num(6)
nl["seven"]=num(7)
nl["eight"]=num(8)
nl["nine"]=num(9)
nl["ten"]=num(10)
nl["eleven"]=num(11)
nl["twelve"]=num(12)
nl["thirteen"]=num(13)
nl["fourteen"]=num(14)
nl["fifteen"]=num(15)
nl["sixteen"]=num(16)
nl["seventeen"]=num(17)
nl["eighteen"]=num(18)
nl["nineteen"]=num(19)
nl["twenty"]=num(20)
nl["thirty"]=num(30)
nl["forty"]=num(40)
nl["fifty"]=num(50)
nl["sixty"]=num(60)
nl["seventy"]=num(70)
nl["eighty"]=num(80)
nl["ninety"]=num(90)
nl["hundred"]=num(100)
nl["thousand"]=mul(10**3)
nl["million"]=mul(10**6)
nl["billion"]=mul(10**9)
nl["trillion"]=mul(10**12)
nl["dozen"]=mul(12)
nl["and"]=plus()
nl["of"]=times()
return nl
def num_fr():
nl=numlanguage()
nl["zero"]=num(0)
nl["un"]=num(1)
nl["deux"]=num(2)
nl["trois"]=num(3)
nl["quatre"]=num(4)
nl["cinq"]=num(5)
nl["six"]=num(6)
nl["sept"]=num(7)
nl["huit"]=num(8)
nl["neuf"]=num(9)
nl["dix"]=num(10)
nl["onze"]=num(11)
nl["douze"]=num(12)
nl["treize"]=num(13)
nl["quatorze"]=num(14)
nl["quinze"]=num(15)
nl["seize"]=num(16)
nl["vingt"]=num(20)
nl["trente"]=num(30)
nl["quarante"]=num(40)
nl["cinquante"]=num(50)
nl["soixante"]=num(60)
nl["cent"]=num(100)
nl["mille"]=onemul(10**3)
nl["million"]=mul(10**6)
nl["milliard"]=mul(10**9)
nl["douzaine"]=mul(12)
nl["et"]=plus()
nl["de"]=times()
return nl
def num_de():
nl=numlanguage()
nl["null"]=num(0)
nl["eins"]=nl["ein"]=num(1)
nl["zwei"]=nl["zwo"]=num(2)
nl["drei"]=num(3)
nl["vier"]=num(4)
nl["fünf"]=num(5)
nl["sechs"]=num(6)
nl["sieben"]=num(7)
nl["acht"]=num(8)
nl["neun"]=num(9)
nl["zehn"]=num(10)
nl["elf"]=num(11)
nl["zwölf"]=num(12)
nl["dreizehn"]=num(13)
nl["vierzehn"]=num(14)
nl["fünfzehn"]=num(15)
nl["sechzehn"]=num(16)
nl["siebzehn"]=num(17)
nl["achtzehn"]=num(18)
nl["neunzehn"]=num(19)
nl["zwanzig"]=num(20)
nl["dreiβig"]=num(30)
nl["dreiÃig"]=num(30)
nl["vierzig"]=num(40)
nl["fünfzig"]=num(50)
nl["sechzig"]=num(60)
nl["siebzig"]=num(70)
nl["achtzig"]=num(80)
nl["neunzig"]=num(90)
nl["hundert"]=num(100)
nl["tausend"]=mul(10**3)
nl["million"]=mul(10**6)
nl["milliard"]=mul(10**9)
nl["und"]=plus()
return nl
def num_es():
nl=numlanguage()
nl["cero"]=num(0)
nl["uno"]=num(1)
nl["dos"]=num(2)
nl["tres"]=num(3)
nl["cuatro"]=num(4)
nl["cinco"]=num(5)
nl["seis"]=num(6)
nl["siete"]=num(7)
nl["ocho"]=num(8)
nl["nueve"]=num(9)
nl["diez"]=num(10)
nl["once"]=num(11)
nl["doce"]=num(12)
nl["trece"]=num(13)
nl["catorce"]=num(14)
nl["quince"]=num(15)
nl["dieciséis"]=num(16)
nl["diecisiete"]=num(17)
nl["dieciocho"]=num(18)
nl["diecinueve"]=num(19)
nl["veinte"]=nl["veinti"]=num(20)
nl["treinta"]=num(30)
nl["cuarenta"]=num(40)
nl["cincuenta"]=num(50)
nl["sesenta"]=num(60)
nl["setenta"]=num(70)
nl["ochenta"]=num(80)
nl["noventa"]=num(90)
nl["cien"]=nl["cientos"]=num(100)
nl["quinientos"]=num(500)
nl["setecientos "]=num(700)
nl["novecientos"]=num(900)
nl["mil"]=onemul(10**3)
nl["millón"]=nl["millones"]=mul(10**6)
nl["billón"]=nl["billones"]=mul(10**12)
nl["y"]=plus()
return nl
if __name__ == "__main__":
itnum=num_it()
print("it",str2num(itnum,sys.argv[1]))
ennum=num_en()
print("en",str2num(ennum,sys.argv[1]))
frnum=num_fr()
print("fr",str2num(frnum,sys.argv[1]))
denum=num_de()
print("de",str2num(denum,sys.argv[1]))
esnum=num_es()
print("es",str2num(esnum,sys.argv[1]))
20
trace.py:
def trace(f):
f.indent = 0
def strtuple(x):
return "("+str(x[0])+")" if len(x)==1 else str(x)
def g(*x):
print('| ' * f.indent + '/-- ', f.__name__, strtuple(x), sep='')
f.indent += 1
value = f(*x)
f.indent -= 1
print('| ' * f.indent + '\-- ', 'return', repr(value))
return value
return g
def memoize(f):
cache = {}
def g(*x):
if x not in cache:
cache[x] = f(*x)
return cache[x]
return g
main.py:
#!/usr/bin/env python3
import sys
import trace
# try to uncomment the following statements:
#@trace.trace
#@trace.memoize
def fib(i):
if i<=0:
return 0
elif i==1:
return 1
else:
return fib(i-1)+fib(i-2)
if __name__=="__main__":
for i in range(int(sys.argv[1])):
print(i,fib(i))