restructure base

mathgenerator/funcs/__init__.py

@@ -53,6 +53,7 @@ from .cubeRootFunc import *
 from .powerRuleIntegrationFunc import *
 from .fourthAngleOfQuadriFunc import *
 from .quadraticEquation import *
+from .hcfFunc import *
 from .DiceSumProbFunc import *
 from .exponentiationFunc import *
 from .confidenceIntervalFunc import *
@@ -63,3 +64,10 @@ from .sumOfAnglesOfPolygonFunc import *
 from .dataSummaryFunc import *
 from .surfaceAreaSphere import *
 from .volumeSphereFunc import *
+from .nthFibonacciNumberFunc import *
+from .profitLossPercentFunc import *
+from .binaryToHexFunc import *
+from .multiplyComplexNumbersFunc import *
+from .geomProgrFunc import *
+from .geometricMeanFunc import *
+from .harmonicMeanFunc import *

mathgenerator/funcs/binaryToHexFunc.py

@@ -0,0 +1,11 @@
+from  .__init__ import *
+
+
+def binaryToHexFunc(max_dig=10):
+    problem = ''
+    for i in range(random.randint(1, max_dig)):
+        temp = str(random.randint(0, 1))
+        problem += temp
+
+    solution = hex(int(problem, 2))
+    return problem, solution

mathgenerator/funcs/geomProgrFunc.py

@@ -0,0 +1,15 @@
+from  .__init__ import *
+
+def geomProgrFunc(number_values=6, min_value=2, max_value=12, n_term=7, sum_term=5):
+    r=random.randint(min_value,max_value)
+    a=random.randint(min_value,max_value)
+    n_term=random.randint(number_values,number_values+5)
+    sum_term=random.randint(number_values,number_values+5)
+    GP=[]
+    for i in range(number_values):
+        GP.append(a*(r**i))
+    problem="For the given GP "+str(GP)+" ,Find the value of a,common ratio,"+str(n_term)+"th term value, sum upto "+str(sum_term)+"th term"
+    value_nth_term=a*(r**(n_term-1))
+    sum_till_nth_term=a*((r**sum_term-1)/(r-1))
+    solution="The value of a is {}, common ratio is {} , {}th term is {} , sum upto {}th term is {}".format(a,r,n_term,value_nth_term,sum_term,sum_till_nth_term)
+    return problem,solution

mathgenerator/funcs/geometricMeanFunc.py

@@ -0,0 +1,27 @@
+from  .__init__ import *
+
+
+def geometricMeanFunc(maxValue=100, maxNum=4):
+    a=random.randint(1,maxValue)
+    b=random.randint(1,maxValue)
+    c=random.randint(1,maxValue)
+    d=random.randint(1,maxValue)
+    num=random.randint(2,4)
+    if num==2:
+      product=a*b
+    elif num==3:
+      product=a*b*c
+    elif num==4:
+      product=a*b*c*d
+
+    ans=product**(1/num)
+    if num==2:
+      problem=f"Geometric mean of {num} numbers {a} and {b} = "
+      solution = f"({a}*{b})^(1/{num}) = {ans}"
+    elif num==3:
+      problem=f"Geometric mean of {num} numbers {a} , {b} and {c} = "
+      solution = f"({a}*{b}*{c})^(1/{num}) = {ans}"
+    elif num==4:
+      problem=f"Geometric mean of {num} numbers {a} , {b} , {c} , {d} = "
+      solution = f"({a}*{b}*{c}*{d})^(1/{num}) = {ans}"
+    return problem,solution

mathgenerator/funcs/harmonicMeanFunc.py

@@ -0,0 +1,28 @@
+from  .__init__ import *
+
+
+def harmonicMeanFunc(maxValue=100, maxNum=4):
+
+        a=random.randint(1,maxValue)
+        b=random.randint(1,maxValue)
+        c=random.randint(1,maxValue)
+        d=random.randint(1,maxValue)
+        num=random.randint(2,4)
+        if num==2:
+            sum=(1/a)+(1/b)
+        elif num==3:
+            sum=(1/a)+(1/b)+(1/c)
+        elif num==4:
+            sum=(1/a)+(1/b)+(1/c)+(1/d)
+
+        ans=num/sum
+        if num==2:
+            problem=f"Harmonic mean of {num} numbers {a} and {b} = "
+            solution = f" {num}/((1/{a}) + (1/{b})) = {ans}"
+        elif num==3:
+            problem=f"Harmonic mean of {num} numbers {a} , {b} and {c} = "
+            solution = f" {num}/((1/{a}) + (1/{b}) + (1/{c})) = {ans}"
+        elif num==4:
+            problem=f"Harmonic mean of {num} numbers {a} , {b} , {c} , {d} = "
+            solution = f" {num}/((1/{a}) + (1/{b}) + (1/{c}) + (1/{d})) = {ans}"
+        return problem,solution

mathgenerator/funcs/hcfFunc.py

@@ -0,0 +1,11 @@
+from  .__init__ import *
+
+def hcfFunc(maxVal=20):
+    a = random.randint(1, maxVal)
+    b = random.randint(1, maxVal)
+    x, y = a, b
+    while(y):
+        x, y = y, x % y
+    problem = f"HCF of {a} and {b} = "
+    solution = str(x)
+    return problem, solution

mathgenerator/funcs/multiplyComplexNumbersFunc.py

@@ -0,0 +1,9 @@
+from  .__init__ import *
+
+
+def multiplyComplexNumbersFunc(minRealImaginaryNum = -20, maxRealImaginaryNum = 20):
+    num1 = complex(random.randint(minRealImaginaryNum, maxRealImaginaryNum), random.randint(minRealImaginaryNum, maxRealImaginaryNum))
+    num2 = complex(random.randint(minRealImaginaryNum, maxRealImaginaryNum), random.randint(minRealImaginaryNum, maxRealImaginaryNum))
+    problem = f"{num1} * {num2} = "
+    solution = num1 * num2
+    return problem, solution

mathgenerator/funcs/nthFibonacciNumberFunc.py

@@ -0,0 +1,10 @@
+from  .__init__ import *
+
+
+def nthFibonacciNumberFunc(maxN = 100):
+    golden_ratio = (1 + math.sqrt(5))/2
+    n = random.randint(1,maxN)
+    problem = f"What is the {n}th Fibonacci number?"
+    ans = round((math.pow(golden_ratio,n) - math.pow(-golden_ratio,-n))/(math.sqrt(5)))
+    solution = f"{ans}"
+    return problem, solution

mathgenerator/funcs/profitLossPercentFunc.py

@@ -0,0 +1,14 @@
+from  .__init__ import *
+
+
+def profitLossPercentFunc(maxCP = 1000, maxSP = 1000):
+    cP = random.randint(1, maxCP)
+    sP = random.randint(1, maxSP)
+    diff = abs(sP-cP)
+    if (sP-cP >= 0):
+        profitOrLoss = "Profit"
+    else:
+        profitOrLoss = "Loss"
+    percent = diff/cP * 100
+    problem = f"{profitOrLoss} percent when CP = {cP} and SP = {sP} is: "
+    solution = percent