dt

2025-01-15 14:16:49 +01:00 · 2025-01-15 14:16:49 +01:00 · b7841fd8b1
parent 9b8a746e15
commit b7841fd8b1
13 changed files with 357 additions and 0 deletions
--- a/PYTHON/ProbeklausurWolf/A1.py
+++ b/PYTHON/ProbeklausurWolf/A1.py
@ -0,0 +1,22 @@
 import doctest
 def filter_and_scale(numbers, scale=1):
    """
    Eine Funktion um aus einer gegebenen Liste alle positiven Zahlen zu extrahieren, diese mit dem Skalierungsfaktor zu addieren und eine Liste mit den Werten zurückzugeben.
    :param numbers: Liste mit allen Zahlen
    :param scale: Skalierungsfaktor, default Wert ist 1
    :return: Array mit nur positiven skalierten Zahlen
    >>> filter_and_scale([1, -2, 3, 0, -4, 5], scale=2)
    [2, 6, 10]
    """
    returnList = []
    for elem in numbers:
        if elem > 0:
            returnList.append(elem * scale)
    return returnList
 if __name__ == "__main__":
    doctest.testmod()
--- a/PYTHON/ProbeklausurWolf/A3.py
+++ b/PYTHON/ProbeklausurWolf/A3.py
@ -0,0 +1,17 @@
 F = lambda x: x*x
 print(F(5))
 t = (1,2,3,7)
 print(type(t))
 u = list(t)
 print(type(u))
 print(u[-1])
 # for idx, x in enumerate(t):
 #     print(idx, x)
--- a/PYTHON/ProbeklausurWolf/A4.py
+++ b/PYTHON/ProbeklausurWolf/A4.py
@ -0,0 +1,22 @@
 import numpy as np
 d=np.load("npdata12.npy")
 print(d)
 print("\n\nG1")
 g1 = d[d[:, 0] == 1][:,1]
 print(g1.mean())
 print(g1.shape)
 # print(head(d))
 M = np.array([[1,2,3], [4,5,6]])
 r = M[:,[1,0,2,1]]
 # print(r)
--- a/PYTHON/ProbeklausurWolf/npdata12.npy
+++ b/PYTHON/ProbeklausurWolf/npdata12.npy
--- a/PYTHON/daten.csv
+++ b/PYTHON/daten.csv
@ -0,0 +1,11 @@
 ID;Alter;Geschlecht;Blutgruppe;Raucher;Größe;Chars
 10;1;W;6;nein;168;1
 10;17;W;6;nein;168;2
 20;5;M;0;ja;175;3
 30;24;W;1;ja;176;4
 40;22;D;2;ja;177;5
 50;23;M;3;nein;178;6
 60;6;D;4;ja;178;5
 70;23;M;5;nein;170;6
 75;6;W;6;ja;179;0
 90;23;M;7;ja;179;0
--- a/PYTHON/matplot.py
+++ b/PYTHON/matplot.py
@ -0,0 +1,28 @@
 import matplotlib.pyplot as plt
 year = [1800, 1850,  1900,  1950,  1970,  1990,  2010,  2100]
 pop =  [1.0,  1.262, 1.650, 2.519, 3.692, 5.263, 6.972, 10.85]
 values = [0,0.6,1.4,1.6,2.2,2.5,2.6,3.2,3.5,3.9,4.2,6]
 # plt.scatter(year, pop)
 # # plt.plot(year, pop)
 # plt.xlabel('Year')
 # plt.ylabel('Population')
 # plt.title('World Population')
 # plt.yticks([0, 2, 4, 6, 8, 10],
 # ['0', '2 Mrd', '4 Mrd',
 # '6 Mrd', '8 Mrd', '10 Mrd'])
 # plt.show()
 # plt.figure()
 f, ax = plt.subplots(1,2, figsize=(3,1))
 ax[0].plot(year, pop)
 ax[1].hist(values, bins=3)
 plt.tight_layout()
 plt.show()
--- a/PYTHON/nastja.py
+++ b/PYTHON/nastja.py
@ -0,0 +1,14 @@
 import numpy as np
 e = np.array([[1,2,3], [2,3,4]])
 s = "Hallo"
 for x in dir(e):
    print(x)
 print(s.lower())
--- a/PYTHON/p1.py
+++ b/PYTHON/p1.py
@ -0,0 +1,97 @@
 import numpy as np
 s = {1,2,3}
 sn = np.array(s)
 print(sn)
 print(type(sn))
 l = [1,2,3]
 ln = np.array(l)
 print(ln)
 print(type(ln))
 t = (1,2,3)
 tn = np.array(t)
 print(tn)
 print(type(tn))
 s = "Hallo"
 print(s[2:])
 print(s[:-2])
 a = [1,2,3]
 c = a 
 b = a[:]
 a[0] = 6
 print(f"A: {a}")
 print(f"B: {b}")
 print(f"C: {c}")
 print("\n")
 a = np.array([7,3,1])
 print(a)
 a += [1,2,3]
 print(a)
 print("\n")
 b = np.array([[1,2], [2,3], [4,5]])
 print(b)
 print("\n")
 inner = [[1,2,0], [0,3,4]]
 c = np.array([inner, inner])
 print(c.ndim)
 print(c.shape)
 print("\n")
 d = np.array([1,2])
 print(d)
 print(d.T)
 print("\n")
 M = np.array([[1,2,3], [2,3,4], [3,4,5]])
 N = M.copy()
 print(M)
 print("")
 print(f"Test:")
 print(M[:,1:3])
 print(M[:, [1,2,1]])
 MSpalte = M[:, 0:2]
 MZeile = M[:, [0,2,0]]
 print(f"Spalte:\n {MSpalte}")
 print(f"Zeile:\n {MZeile}")
 print("\n")
 M = np.array([[1,2,3], [2,3,4], [3,4,5]])
 MCon = M > 2
 print(f"Con:\n {MCon}")
 M[M>2]=17
 print(M)
 print("\n")
 print(N)
 print("")
 new = (N>3) & (N > 3)
 print(new)
 print((N > 2) & (N < 5))
 print("\n")
 vec1 = np.array([1,2,3])
 vec2 = np.array([2,3,4])
 print(np.matmul(vec1, vec2))
--- a/PYTHON/panda.py
+++ b/PYTHON/panda.py
@ -0,0 +1,66 @@
 import pandas as pd
 df = pd.read_csv("daten.csv",
 delimiter=";",
 na_values=["."],
 index_col="ID",
 encoding="utf-8")
 df2 = df.sort_values(["Größe", "ID"])
 # df3 = df.drop([80,90])
 # df4 = df.drop(columns=["Raucher", "Blutgruppe"])
 df3 = df2[df2["Größe"] > 175]
 # elems = df2.loc[[10], "Blutgruppe":"Größe"]
 # elems = df2.iloc[0:3, 0:2]
 # elems = df2.loc[20:80,"Geschlecht":"Raucher"]
 print(df2)
 # print("")
 # print(f"Type: {type(elems)}")
 # print(elems)
 # print(df2.index)
 # df5 = df2.set_index("Alter", append=True)
 df5 = df2.set_index(["Alter", "Geschlecht"], append=True)
 # print(df5)
 # print(df5.index)
 rowsIter = df.iterrows()
 colsIter = df.items()
 # print("Befor row loop:\n")
 # for rowLabel, row in rowsIter:
 #     print(f"Label: {type(rowLabel)}, row: {type(row)}")
 #     print(f"{rowLabel}:\n{row}\n")
 # print("Befor col loop:\n")
 # for colLabel, col in colsIter:
 #     print(f"Label: {type(colLabel)}, Col: {type(col)}")
 #     print(f"{colLabel}:\n{col}\n")
 # print("\n")
 # nextCol = next(colsIter)
 # nextColLabel = nextCol[0]
 # nextColSeries = nextCol[1]
 # print(f"Label: {nextColLabel}")
 # print(f"Series:\n{nextColSeries}")
 # seriesIter = nextColSeries.items()
 # nextElem = next(seriesIter)
 # print(nextElem)
 print(df2)
 df7 = df2.fillna(0)
 # print(df7)
 print(df)
 meanRet = df.max()
 print(type(meanRet))
 print(meanRet)
--- a/PYTHON/pandas2.py
+++ b/PYTHON/pandas2.py
@ -0,0 +1,80 @@
 import pandas as pd
 import numpy as np
 df = pd.read_csv("daten.csv",
 delimiter=";",
 na_values=["."],
 index_col="ID",
 encoding="utf-8")
 meanRet = df.max()
 # print(type(meanRet))
 # print(meanRet)
 onlyNumsDf = df[["Alter", "Größe"]]
 # print(onlyNumsDf.mean())
 df["Alter2"] = df["Alter"] * 2
 # print(df)
 onlyAlter = df["Alter"]
 alterMean = onlyAlter.max()
 # print(type(alterMean))
 # print(alterMean)
 charMap = {
    0: "",
    1: "A",
    2: "M",
    3: "O",
    4: "G",
    5: "U",
    6: "S",
 }
 def intToChar(col):
    retString = ""
    for num in col:
        char = charMap.get(num, " ")
        retString += char
    return retString
 def timesTwo(num):
    return num*2
 charNums = df[["Alter", "Chars"]]
 print(charNums)
 print("")
 def map_numbers_to_string(column):
    return "".join(charMap[num] for num in column)
 print(charNums.apply(intToChar, axis=0))
 print("")
 print(charNums.apply(timesTwo, axis=0))
 # print(charNums.apply(intToChar))
 print("")
 alterSeries = df[["Alter"]]
 print(alterSeries.apply(np.sum, axis=0))
 print(df)
 raucherGeschlechtDf = df.loc[10:70 ,["Raucher","Geschlecht"]]
 geschlechtGrößeDf = df.loc[50:90, ["Geschlecht", "Größe"]]
 alterBlutgruppeDf = df.loc[50:90 ,["Alter", "Blutgruppe"]]
 print("\nRaucher Geschlecht: ")
 print(raucherGeschlechtDf)
 print("\nGeschlecht Größe: ")
 print(geschlechtGrößeDf)
 # print("\nMerge: ")
 # res = raucherGeschlechtDf.merge(geschlechtGrößeDf, on="Geschlecht")
 print("\nGroup: ")
 res = raucherGeschlechtDf.groupby(geschlechtGrößeDf, by="Geschlecht")
 print(res)
--- a/ZIG/Zahlenraten.zig
+++ b/ZIG/Zahlenraten.zig
--- a/ZIG/u1.zig
+++ b/ZIG/u1.zig
--- a/ZIG/u2Vector.zig
+++ b/ZIG/u2Vector.zig