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2025-11-28 14:35:23 +01:00 · 2020-10-19 19:33:00 +05:30
parent b1a06816dd
commit 76c8d0e560
76 changed files with 1393 additions and 0 deletions
--- a/mathgenerator/funcs/BinaryToDecimalFunc.py
+++ b/mathgenerator/funcs/BinaryToDecimalFunc.py
@@ -0,0 +1,12 @@
 from  .__init__ import *
 def BinaryToDecimalFunc(max_dig=10):
    problem = ''
    for i in range(random.randint(1, max_dig)):
        temp = str(random.randint(0, 1))
        problem += temp
    solution = int(problem, 2)
    return problem, solution
--- a/mathgenerator/funcs/DecimalToBinaryFunc.py
+++ b/mathgenerator/funcs/DecimalToBinaryFunc.py
@@ -0,0 +1,11 @@
 from .__init__ import *
 def DecimalToBinaryFunc(max_dec=99):
    a = random.randint(1, max_dec)
    b = bin(a).replace("0b", "")
    problem = "Binary of " + str(a) + "="
    solution = str(b)
    return problem, solution
--- a/mathgenerator/funcs/DiceSumProbFunc.py
+++ b/mathgenerator/funcs/DiceSumProbFunc.py
@@ -0,0 +1,25 @@
 from .__init__ import *
 def DiceSumProbFunc(maxDice=3):
    a = random.randint(1,maxDice)
    b = random.randint(a,6*a)
    count=0
    for i in [1,2,3,4,5,6]:
        if a==1:
            if i==b:
                count=count+1
        elif a==2:
            for j in [1,2,3,4,5,6]:
                if i+j==b:
                    count=count+1
        elif a==3:
            for j in [1,2,3,4,5,6]:
                for k in [1,2,3,4,5,6]:
                    if i+j+k==b:
                        count=count+1
    problem = "If {} dice are rolled at the same time, the probability of getting a sum of {} =".format(a,b)
    solution="{}/{}".format(count, 6**a)
    return problem, solution
--- a/mathgenerator/funcs/MidPointOfTwoPointFunc.py
+++ b/mathgenerator/funcs/MidPointOfTwoPointFunc.py
@@ -0,0 +1,12 @@
 from .__init__ import *
 def MidPointOfTwoPointFunc(maxValue=20):
    x1 = random.randint(-20, maxValue)
    y1 = random.randint(-20, maxValue)
    x2 = random.randint(-20, maxValue)
    y2 = random.randint(-20, maxValue)
    problem = f"({x1},{y1}),({x2},{y2})="
    solution = f"({(x1+x2)/2},{(y1+y2)/2})"
    return problem, solution
--- a/mathgenerator/funcs/init.py
+++ b/mathgenerator/funcs/init.py
@@ -0,0 +1,79 @@
 import random
 import math
 import fractions
 from .additionFunc import *
 from .subtractionFunc import *
 from .multiplicationFunc import *
 from .divisionFunc import *
 from .binaryComplement1sFunc import *
 from .moduloFunc import *
 from .squareRootFunc import *
 from .powerRuleDifferentiationFunc import *
 from .squareFunc import *
 from .gcdFunc import *
 from .lcmFunc import *
 from .basicAlgebraFunc import *
 from .logFunc import *
 from .divisionToIntFunc import *
 from .DecimalToBinaryFunc import *
 from .BinaryToDecimalFunc import *
 from .divideFractionsFunc import *
 from .multiplyIntToMatrix22 import *
 from .areaOfTriangleFunc import *
 from .isTriangleValidFunc import *
 from .MidPointOfTwoPointFunc import *
 from .factoringFunc import *
 from .thirdAngleOfTriangleFunc import *
 from .systemOfEquationsFunc import *
 from .distanceTwoPointsFunc import *
 from .pythagoreanTheoremFunc import *
 from .linearEquationsFunc import *
 from .primeFactorsFunc import *
 from .multiplyFractionsFunc import *
 from .regularPolygonAngleFunc import *
 from .combinationsFunc import *
 from .factorialFunc import *
 from .surfaceAreaCube import *
 from .volumeCube import *
 from .surfaceAreaCuboid import *
 from .volumeCuboid import *
 from .surfaceAreaCylinder import *
 from .volumeCylinder import *
 from .surfaceAreaCone import *
 from .volumeCone import *
 from .commonFactorsFunc import *
 from .intersectionOfTwoLinesFunc import *
 from .permutationFunc import *
 from .vectorCrossFunc import *
 from .compareFractionsFunc import *
 from .simpleInterestFunc import *
 from .matrixMultiplicationFunc import *
 from .cubeRootFunc import *
 from .powerRuleIntegrationFunc import *
 from .fourthAngleOfQuadriFunc import *
 from .quadraticEquation import *
 from .hcfFunc import *
 from .DiceSumProbFunc import *
 from .exponentiationFunc import *
 from .confidenceIntervalFunc import *
 from .surdsComparisonFunc import *
 from .fibonacciSeriesFunc import *
 from .basicTrigonometryFunc import *
 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 *
 from .euclidianNormFunc import *
 from .angleBtwVectorsFunc import *
 from .absoluteDifferenceFunc import *
 from .vectorDotFunc import *
 from .binary2sComplement import *
 from .matrixInversion import *
--- a/mathgenerator/funcs/absoluteDifferenceFunc.py
+++ b/mathgenerator/funcs/absoluteDifferenceFunc.py
@@ -0,0 +1,10 @@
 from  .__init__ import *
 def absoluteDifferenceFunc (maxA = 100, maxB = 100):
 	a = random.randint(-1*maxA, maxA)
 	b = random.randint(-1*maxB, maxB)
 	absDiff = abs(a-b)
 	problem = "Absolute difference between numbers " + str(a) + " and " + str(b) + " = "
 	solution = absDiff
 	return problem, solution
--- a/mathgenerator/funcs/additionFunc.py
+++ b/mathgenerator/funcs/additionFunc.py
@@ -0,0 +1,10 @@
 from  .__init__ import *
 def additionFunc(maxSum=99, maxAddend=50):
    a = random.randint(0, maxAddend)
    b = random.randint(0, min((maxSum - a), maxAddend))  # The highest value of b will be no higher than the maxsum minus the first number and no higher than the maxAddend as well
    c = a + b
    problem = str(a) + "+" + str(b) + "="
    solution = str(c)
    return problem, solution
--- a/mathgenerator/funcs/angleBtwVectorsFunc.py
+++ b/mathgenerator/funcs/angleBtwVectorsFunc.py
@@ -0,0 +1,16 @@
 from .euclidianNormFunc import euclidianNormFunc
 import math
 from .__init__ import *
 def angleBtwVectorsFunc(v1: list, v2: list):
    sum = 0
    for i in v1:
        for j in v2:
            sum += i * j
    mags = euclidianNormFunc(v1) * euclidianNormFunc(v2)
    problem = f"angle between the vectors {v1} and {v2} is:"
    solution = math.acos(sum / mags)
    # would return the answer in radians
    return problem, solution
--- a/mathgenerator/funcs/areaOfTriangleFunc.py
+++ b/mathgenerator/funcs/areaOfTriangleFunc.py
@@ -0,0 +1,14 @@
 from  .__init__ import *
 def areaOfTriangleFunc(maxA=20, maxB=20, maxC=20):
    a = random.randint(1, maxA)
    b = random.randint(1, maxB)
    c = random.randint(1, maxC)
    s = (a + b + c) / 2
    area = (s * (s - a) * (s - b) * (s - c)) ** 0.5
    problem = "Area of triangle with side lengths: " + str(a) + " " + str(b) + " " + str(c) + " = "
    solution = area
    return problem, solution
--- a/mathgenerator/funcs/basicAlgebraFunc.py
+++ b/mathgenerator/funcs/basicAlgebraFunc.py
@@ -0,0 +1,25 @@
 from  .__init__ import *
 def basicAlgebraFunc(maxVariable=10):
    a = random.randint(1, maxVariable)
    b = random.randint(1, maxVariable)
    c = random.randint(b, maxVariable)
    # calculate gcd
    def calculate_gcd(x, y):
        while(y):
            x, y = y, x % y
        return x
    i = calculate_gcd((c - b), a)
    x = f"{(c - b)//i}/{a//i}"
    if (c - b == 0):
        x = "0"
    elif a == 1 or a == i:
        x = f"{c - b}"
    problem = f"{a}x + {b} = {c}"
    solution = x
    return problem, solution
--- a/mathgenerator/funcs/basicTrigonometryFunc.py
+++ b/mathgenerator/funcs/basicTrigonometryFunc.py
@@ -0,0 +1,14 @@
 from  .__init__ import *
 def basicTrigonometryFunc(angles=[0,30,45,60,90],functions=["sin","cos","tan"]): #Handles degrees in quadrant one
    angle=random.choice(angles)
    function=random.choice(functions)
    problem=f"What is {function}({angle})?"
    expression='math.'+function+'(math.radians(angle))'
    result_fraction_map={0.0:"0",0.5:"1/2",0.71:"1/√2",0.87:"√3/2",1.0:"1",0.58:"1/√3",1.73:"√3"}
    solution=result_fraction_map[round(eval(expression),2)] if round(eval(expression),2)<=99999 else "∞"  #for handling the ∞ condition
    return problem,solution
--- a/mathgenerator/funcs/binary2sComplement.py
+++ b/mathgenerator/funcs/binary2sComplement.py
@@ -0,0 +1,26 @@
 from  .__init__ import *
 def binary2sComplementFunc(maxDigits=10):
    digits = random.randint(1, maxDigits)
    question = ''.join([str(random.randint(0, 1)) for i in range(digits)]).lstrip('0')
    answer = []
    for i in question:
        answer.append(str(int(not bool(int(i)))))
    carry = True
    j = len(answer) - 1
    while j >= 0:
        if answer[j] == '0':
            answer[j] = '1'
            carry = False
            break
        answer[j] = '0'
        j -= 1
    if j == 0 and carry == True:
        answer.insert(0, '1')
    problem = "2's complement of " + question + " ="
    solution = ''.join(answer).lstrip('0')
    return problem, solution
--- a/mathgenerator/funcs/binaryComplement1sFunc.py
+++ b/mathgenerator/funcs/binaryComplement1sFunc.py
@@ -0,0 +1,15 @@
 from  .__init__ import *
 def binaryComplement1sFunc(maxDigits=10):
    question = ''
    answer = ''
    for i in range(random.randint(1, maxDigits)):
        temp = str(random.randint(0, 1))
        question += temp
        answer += "0" if temp == "1" else "1"
    problem = question+"="
    solution = answer
    return problem, solution
--- a/mathgenerator/funcs/binaryToHexFunc.py
+++ b/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
--- a/mathgenerator/funcs/combinationsFunc.py
+++ b/mathgenerator/funcs/combinationsFunc.py
@@ -0,0 +1,19 @@
 from  .__init__ import *
 def combinationsFunc(maxlength=20):
    def factorial(a):
        d = 1
        for i in range(a):
            a = (i + 1) * d
            d = a
        return d
    a = random.randint(10, maxlength)
    b = random.randint(0, 9)
    solution = int(factorial(a) / (factorial(b) * factorial(a - b)))
    problem = "Number of combinations from {} objects picked {} at a time ".format(a, b)
    return problem, solution
--- a/mathgenerator/funcs/commonFactorsFunc.py
+++ b/mathgenerator/funcs/commonFactorsFunc.py
@@ -0,0 +1,24 @@
 from  .__init__ import *
 def commonFactorsFunc(maxVal=100):
    a = x = random.randint(1, maxVal)
    b = y = random.randint(1, maxVal)
    if (x < y):
        min = x
    else:
        min = y
    count = 0
    arr = []
    for i in range(1, min + 1):
        if (x % i == 0):
            if (y % i == 0):
                count = count + 1
                arr.append(i)
    problem = f"Common Factors of {a} and {b} = "
    solution = arr
    return problem, solution
--- a/mathgenerator/funcs/compareFractionsFunc.py
+++ b/mathgenerator/funcs/compareFractionsFunc.py
@@ -0,0 +1,26 @@
 from .__init__ import *
 def compareFractionsFunc(maxVal=10):
    a = random.randint(1, maxVal)
    b = random.randint(1, maxVal)
    c = random.randint(1, maxVal)
    d = random.randint(1, maxVal)
    while (a == b):
        b = random.randint(1, maxVal)
    while (c == d):
        d = random.randint(1, maxVal)
    first = a / b
    second = c / d
    if(first > second):
        solution = ">"
    elif(first < second):
        solution = "<"
    else:
        solution = "="
    problem = f"Which symbol represents the comparison between {a}/{b} and {c}/{d}?"
    return problem, solution
--- a/mathgenerator/funcs/confidenceIntervalFunc.py
+++ b/mathgenerator/funcs/confidenceIntervalFunc.py
@@ -0,0 +1,30 @@
 from .__init__ import *
 def confidenceIntervalFunc():
    n=random.randint(20,40)
    j=random.randint(0,3)
    lst=random.sample(range(200,300),n)
    lst_per=[80 ,90, 95, 99]
    lst_t = [1.282, 1.645, 1.960, 2.576]
    mean=0
    sd=0
    for i in lst:
        count= i + mean
        mean=count
    mean = mean/n
    for i in lst:
        x=(i-mean)**2+sd
        sd=x
    sd=sd/n
    standard_error = lst_t[j]*math.sqrt(sd/n)
    problem= 'The confidence interval for sample {} with {}% confidence is'.format([x for x in lst], lst_per[j])
    solution= '({}, {})'.format(mean+standard_error, mean-standard_error)
    return problem, solution
--- a/mathgenerator/funcs/cubeRootFunc.py
+++ b/mathgenerator/funcs/cubeRootFunc.py
@@ -0,0 +1,10 @@
 from .__init__ import *
 def cubeRootFunc(minNo=1, maxNo=1000):
    b = random.randint(minNo, maxNo)
    a = b**(1 / 3)
    problem = "cuberoot of " + str(b) + " upto 2 decimal places is:"
    solution = str(round(a, 2))
    return problem, solution
--- a/mathgenerator/funcs/dataSummaryFunc.py
+++ b/mathgenerator/funcs/dataSummaryFunc.py
@@ -0,0 +1,26 @@
 from .__init__ import *
 def dataSummaryFunc(number_values=15,minval=5,maxval=50):
    random_list=[]
    for i in range(number_values):
        n=random.randint(minval,maxval)
        random_list.append(n)
    a=sum(random_list)
    mean=a/number_values
    var=0
    for i in range(number_values):
        var+=(random_list[i]-mean)**2
    # we're printing stuff here?
    print(random_list)
    print(mean)
    print(var/number_values)
    print((var/number_values)**0.5)
    problem="Find the mean,standard deviation and variance for the data"+str(random_list)
    solution="The Mean is {} , Standard Deviation is {}, Variance is {}".format(mean,var/number_values,(var/number_values)**0.5)
    return problem,solution
--- a/mathgenerator/funcs/distanceTwoPointsFunc.py
+++ b/mathgenerator/funcs/distanceTwoPointsFunc.py
@@ -0,0 +1,14 @@
 from .__init__ import *
 def distanceTwoPointsFunc(maxValXY=20, minValXY=-20):
    point1X = random.randint(minValXY, maxValXY + 1)
    point1Y = random.randint(minValXY, maxValXY + 1)
    point2X = random.randint(minValXY, maxValXY + 1)
    point2Y = random.randint(minValXY, maxValXY + 1)
    distanceSq = (point1X - point2X) ** 2 + (point1Y - point2Y) ** 2
    solution = f"sqrt({distanceSq})"
    problem = f"Find the distance between ({point1X}, {point1Y}) and ({point2X}, {point2Y})"
    return problem, solution
--- a/mathgenerator/funcs/divideFractionsFunc.py
+++ b/mathgenerator/funcs/divideFractionsFunc.py
@@ -0,0 +1,32 @@
 from .__init__ import *
 def divideFractionsFunc(maxVal=10):
    a = random.randint(1, maxVal)
    b = random.randint(1, maxVal)
    while (a == b):
        b = random.randint(1, maxVal)
    c = random.randint(1, maxVal)
    d = random.randint(1, maxVal)
    while (c == d):
        d = random.randint(1, maxVal)
    def calculate_gcd(x, y):
        while(y):
            x, y = y, x % y
        return x
    tmp_n = a * d
    tmp_d = b * c
    gcd = calculate_gcd(tmp_n, tmp_d)
    x = f"{tmp_n//gcd}/{tmp_d//gcd}"
    if (tmp_d == 1 or tmp_d == gcd):
        x = f"{tmp_n//gcd}"
    # for equal numerator and denominators
    problem = f"({a}/{b})/({c}/{d})"
    solution = x
    return problem, solution
--- a/mathgenerator/funcs/divisionFunc.py
+++ b/mathgenerator/funcs/divisionFunc.py
@@ -0,0 +1,11 @@
 from .__init__ import *
 def divisionFunc(maxRes=99, maxDivid=99):
    a = random.randint(0, maxDivid)
    b = random.randint(0, min(maxRes, maxDivid))
    c = a / b
    problem = str(a) + "/" + str(b) + "="
    solution = str(c)
    return problem, solution
--- a/mathgenerator/funcs/divisionToIntFunc.py
+++ b/mathgenerator/funcs/divisionToIntFunc.py
@@ -0,0 +1,13 @@
 from .__init__ import *
 def divisionToIntFunc(maxA=25, maxB=25):
    a = random.randint(1, maxA)
    b = random.randint(1, maxB)
    divisor = a * b
    dividend = random.choice([a, b])
    problem = f"{divisor}/{dividend} = "
    solution = int(divisor / dividend)
    return problem, solution
--- a/mathgenerator/funcs/euclidianNormFunc.py
+++ b/mathgenerator/funcs/euclidianNormFunc.py
@@ -0,0 +1,7 @@
 from .__init__ import *
 def euclidianNormFunc(v1: list):
    problem = f"Euclidian norm or L2 norm of the vector{v1} is:"
    solution = sqrt(sum([i**2 for i in v1]))
    return problem, solution
--- a/mathgenerator/funcs/exponentiationFunc.py
+++ b/mathgenerator/funcs/exponentiationFunc.py
@@ -0,0 +1,10 @@
 from .__init__ import *
 def exponentiationFunc(maxBase = 20,maxExpo = 10):
    base = random.randint(1, maxBase)
    expo = random.randint(1, maxExpo)
    problem = f"{base}^{expo} ="
    solution = str(base ** expo)
    return problem, solution
--- a/mathgenerator/funcs/factorialFunc.py
+++ b/mathgenerator/funcs/factorialFunc.py
@@ -0,0 +1,15 @@
 from .__init__ import *
 def factorialFunc(maxInput=6):
    a = random.randint(0, maxInput)
    n = a
    problem = str(a) + "! = "
    b = 1
    while a != 1 and n > 0:
            b *= n
            n -= 1
    solution = str(b)
    return problem, solution
--- a/mathgenerator/funcs/factoringFunc.py
+++ b/mathgenerator/funcs/factoringFunc.py
@@ -0,0 +1,29 @@
 from .__init__ import *
 def factoringFunc(range_x1=10, range_x2=10):
    x1 = random.randint(-range_x1, range_x1)
    x2 = random.randint(-range_x2, range_x2)
    def intParser(z):
        if (z == 0):
            return ""
        if (z > 0):
            return "+" + str(z)
        if (z < 0):
            return "-" + str(abs(z))
    b = intParser(x1 + x2)
    c = intParser(x1 * x2)
    if b == "+1":
        b = "+"
    if b == "":
        problem = f"x^2{c}"
    else:
        problem = f"x^2{b}x{c}"
    x1 = intParser(x1)
    x2 = intParser(x2)
    solution = f"(x{x1})(x{x2})"
    return problem, solution
--- a/mathgenerator/funcs/fibonacciSeriesFunc.py
+++ b/mathgenerator/funcs/fibonacciSeriesFunc.py
@@ -0,0 +1,21 @@
 from .__init__ import *
 def fibonacciSeriesFunc(minNo=1):
    n = random.randint(minNo,20)
    def createFibList(n):
        l=[]
        for i in range(n):
            if i<2:
                l.append(i)
            else:
                val = l[i-1]+l[i-2]
                l.append(val)
        return l
    fibList=createFibList(n)
    problem = "The Fibonacci Series of the first "+str(n)+" numbers is ?"
    solution = fibList
    return problem,solution
--- a/mathgenerator/funcs/fourthAngleOfQuadriFunc.py
+++ b/mathgenerator/funcs/fourthAngleOfQuadriFunc.py
@@ -0,0 +1,14 @@
 from .__init__ import *
 def fourthAngleOfQuadriFunc(maxAngle=180):
    angle1 = random.randint(1, maxAngle)
    angle2 = random.randint(1, 240 - angle1)
    angle3 = random.randint(1, 340 - (angle1 + angle2))
    sum_ = angle1 + angle2 + angle3
    angle4 = 360 - sum_
    problem = f"Fourth angle of quadrilateral with angles {angle1} , {angle2}, {angle3} ="
    solution = angle4
    return problem, solution
--- a/mathgenerator/funcs/gcdFunc.py
+++ b/mathgenerator/funcs/gcdFunc.py
@@ -0,0 +1,12 @@
 from .__init__ import *
 def gcdFunc(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"GCD of {a} and {b} = "
    solution = str(x)
    return problem, solution
--- a/mathgenerator/funcs/geomProgrFunc.py
+++ b/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
--- a/mathgenerator/funcs/geometricMeanFunc.py
+++ b/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
--- a/mathgenerator/funcs/harmonicMeanFunc.py
+++ b/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
--- a/mathgenerator/funcs/hcfFunc.py
+++ b/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
--- a/mathgenerator/funcs/intersectionOfTwoLinesFunc.py
+++ b/mathgenerator/funcs/intersectionOfTwoLinesFunc.py
@@ -0,0 +1,62 @@
 from .__init__ import *
 def intersectionOfTwoLinesFunc(
    minM=-10, maxM=10, minB=-10, maxB=10, minDenominator=1, maxDenominator=6
 ):
    def generateEquationString(m, b):
        """
        Generates an equation given the slope and intercept.
        It handles cases where m is fractional.
        It also ensures that we don't have weird signs such as y = mx + -b.
        """
        if m[1] == 1:
            m = m[0]
        else:
            m = f"{m[0]}/{m[1]}"
        base = f"y = {m}x"
        if b > 0:
            return f"{base} + {b}"
        elif b < 0:
            return f"{base} - {b * -1}"
        else:
            return base
    def fractionToString(x):
        """
        Converts the given fractions.Fraction into a string.
        """
        if x.denominator == 1:
            x = x.numerator
        else:
            x = f"{x.numerator}/{x.denominator}"
        return x
    m1 = (random.randint(minM, maxM), random.randint(minDenominator, maxDenominator))
    m2 = (random.randint(minM, maxM), random.randint(minDenominator, maxDenominator))
    b1 = random.randint(minB, maxB)
    b2 = random.randint(minB, maxB)
    equation1 = generateEquationString(m1, b1)
    equation2 = generateEquationString(m2, b2)
    problem = "Find the point of intersection of the two lines: "
    problem += f"{equation1} and {equation2}"
    m1 = fractions.Fraction(*m1)
    m2 = fractions.Fraction(*m2)
    # if m1 == m2 then the slopes are equal
    # This can happen if both line are the same
    # Or if they are parallel
    # In either case there is no intersection
    if m1 == m2:
        solution = "No Solution"
    else:
        intersection_x = (b1 - b2) / (m2 - m1)
        intersection_y = ((m2 * b1) - (m1 * b2)) / (m2 - m1)
        solution = f"({fractionToString(intersection_x)}, {fractionToString(intersection_y)})"
    return problem, solution
--- a/mathgenerator/funcs/isTriangleValidFunc.py
+++ b/mathgenerator/funcs/isTriangleValidFunc.py
@@ -0,0 +1,19 @@
 from .__init__ import *
 def isTriangleValidFunc(maxSideLength=50):
    sideA = random.randint(1, maxSideLength)
    sideB = random.randint(1, maxSideLength)
    sideC = random.randint(1, maxSideLength)
    sideSums = [sideA + sideB, sideB + sideC, sideC + sideA]
    sides = [sideC, sideA, sideB]
    exists = True & (sides[0] < sideSums[0]) & (sides[1] < sideSums[1]) & (sides[2] < sideSums[2])
    problem = f"Does triangle with sides {sideA}, {sideB} and {sideC} exist?"
    if exists:
        solution = "Yes"
        return problem, solution
    solution = "No"
    return problem, solution
--- a/mathgenerator/funcs/lcmFunc.py
+++ b/mathgenerator/funcs/lcmFunc.py
@@ -0,0 +1,17 @@
 from .__init__ import *
 def lcmFunc(maxVal=20):
    a = random.randint(1, maxVal)
    b = random.randint(1, maxVal)
    c = a * b
    x, y = a, b
    while y:
        x, y = y, x % y
    d = c // x
    problem = f"LCM of {a} and {b} ="
    solution = str(d)
    return problem, solution
--- a/mathgenerator/funcs/linearEquationsFunc.py
+++ b/mathgenerator/funcs/linearEquationsFunc.py
@@ -0,0 +1,25 @@
 from .__init__ import *
 def linearEquationsFunc(n=2, varRange=20, coeffRange=20):
    if n > 10:
        print("[!] n cannot be greater than 10")
        return None, None
    vars = ['x', 'y', 'z', 'a', 'b', 'c', 'd', 'e', 'f', 'g'][:n]
    soln = [random.randint(-varRange, varRange) for i in range(n)]
    problem = list()
    solution = ", ".join(["{} = {}".format(vars[i], soln[i]) for i in range(n)])
    for _ in range(n):
        coeff = [random.randint(-coeffRange, coeffRange) for i in range(n)]
        res = sum([coeff[i] * soln[i] for i in range(n)])
        prob = ["{}{}".format(coeff[i], vars[i]) if coeff[i] != 0 else "" for i in range(n)]
        while "" in prob:
            prob.remove("")
        prob = " + ".join(prob) + " = " + str(res)
        problem.append(prob)
    problem = "\n".join(problem)
    return problem, solution
--- a/mathgenerator/funcs/logFunc.py
+++ b/mathgenerator/funcs/logFunc.py
@@ -0,0 +1,12 @@
 from .__init__ import *
 def logFunc(maxBase=3, maxVal=8):
    a = random.randint(1, maxVal)
    b = random.randint(2, maxBase)
    c = pow(b, a)
    problem = "log" + str(b) + "(" + str(c) + ")"
    solution = str(a)
    return problem, solution
--- a/mathgenerator/funcs/matrixInversion.py
+++ b/mathgenerator/funcs/matrixInversion.py
@@ -0,0 +1,69 @@
 from .__init__ import *
 import sympy
 def matrixInversion(SquareMatrixDimension=3, MaxMatrixElement=99, OnlyIntegerElementsInInvertedMatrix=False):
    if OnlyIntegerElementsInInvertedMatrix is True:
        isItOk = False
        Mat = list()
        while (isItOk is False):
            Mat = list()
            for i in range(0, SquareMatrixDimension):
                z = list()
                for j in range(0, SquareMatrixDimension):
                    z.append(0)
                z[i] = 1
                Mat.append(z)
            MaxAllowedMatrixElement = math.ceil(
                pow(MaxMatrixElement, 1 / (SquareMatrixDimension)))
            randomlist = random.sample(
                range(0, MaxAllowedMatrixElement + 1), SquareMatrixDimension)
            for i in range(0, SquareMatrixDimension):
                if i == SquareMatrixDimension - 1:
                    Mat[0] = [j + (k * randomlist[i])
                              for j, k in zip(Mat[0], Mat[i])]
                else:
                    Mat[i + 1] = [j + (k * randomlist[i])
                                  for j, k in zip(Mat[i + 1], Mat[i])]
            for i in range(1, SquareMatrixDimension - 1):
                Mat[i] = [sum(i)
                          for i in zip(Mat[SquareMatrixDimension - 1], Mat[i])]
            isItOk = True
            for i in Mat:
                for j in i:
                    if j > MaxMatrixElement:
                        isItOk = False
                        break
                if isItOk is False:
                    break
        random.shuffle(Mat)
        Mat = sympy.Matrix(Mat)
        Mat = sympy.Matrix.transpose(Mat)
        Mat = Mat.tolist()
        random.shuffle(Mat)
        Mat = sympy.Matrix(Mat)
        Mat = sympy.Matrix.transpose(Mat)
    else:
        randomlist = list(sympy.primerange(0, MaxMatrixElement + 1))
        plist = random.sample(randomlist, SquareMatrixDimension)
        randomlist = random.sample(
            range(0, MaxMatrixElement + 1), SquareMatrixDimension * SquareMatrixDimension)
        randomlist = list(set(randomlist) - set(plist))
        n_list = random.sample(
            randomlist, SquareMatrixDimension * (SquareMatrixDimension - 1))
        Mat = list()
        for i in range(0, SquareMatrixDimension):
            z = list()
            z.append(plist[i])
            for j in range(0, SquareMatrixDimension - 1):
                z.append(n_list[(i * SquareMatrixDimension) + j - i])
            random.shuffle(z)
            Mat.append(z)
        Mat = sympy.Matrix(Mat)
    problem = 'Inverse of Matrix ' + str(Mat) + ' is:'
    solution = str(sympy.Matrix.inv(Mat))
    return problem, solution
--- a/mathgenerator/funcs/matrixMultiplicationFunc.py
+++ b/mathgenerator/funcs/matrixMultiplicationFunc.py
@@ -0,0 +1,51 @@
 from .__init__ import *
 def matrixMultiplicationFunc(maxVal=100):
    m = random.randint(2, 10)
    n = random.randint(2, 10)
    k = random.randint(2, 10)
    # generate matrices a and b
    a = []
    for r in range(m):
        a.append([])
        for c in range(n):
            a[r].append(random.randint(-maxVal, maxVal))
    b = []
    for r in range(n):
        b.append([])
        for c in range(k):
            b[r].append(random.randint(-maxVal, maxVal))
    res = []
    a_string = matrixMultiplicationFuncHelper(a)
    b_string = matrixMultiplicationFuncHelper(b)
    for r in range(m):
        res.append([])
        for c in range(k):
            temp = 0
            for t in range(n):
                temp += a[r][t] * b[t][c]
            res[r].append(temp)
    problem = f"Multiply \n{a_string}\n and \n\n{b_string}"  # consider using a, b instead of a_string, b_string if the problem doesn't look right
    solution = matrixMultiplicationFuncHelper(res)
    return problem, solution
 def matrixMultiplicationFuncHelper(inp):
    m = len(inp)
    n = len(inp[0])
    string = "[["
    for i in range(m):
        for j in range(n):
            string += f"{inp[i][j]: 6d}"
            string += ", "if j < n-1 else ""
        string += "]\n [" if i < m-1 else ""
    string += "]]"
    return string
--- a/mathgenerator/funcs/moduloFunc.py
+++ b/mathgenerator/funcs/moduloFunc.py
@@ -0,0 +1,11 @@
 from .__init__ import *
 def moduloFunc(maxRes=99, maxModulo=99):
    a = random.randint(0, maxModulo)
    b = random.randint(0, min(maxRes, maxModulo))
    c = a % b if b != 0 else 0
    problem = str(a) + "%" + str(b) + "="
    solution = str(c)
    return problem, solution
--- a/mathgenerator/funcs/multiplicationFunc.py
+++ b/mathgenerator/funcs/multiplicationFunc.py
@@ -0,0 +1,11 @@
 from .__init__ import *
 def multiplicationFunc(maxRes=99, maxMulti=99):
    a = random.randint(0, maxMulti)
    b = random.randint(0, min(int(maxMulti / a), maxRes))
    c = a * b
    problem = str(a) + "*" + str(b) + "="
    solution = str(c)
    return problem, solution
--- a/mathgenerator/funcs/multiplyComplexNumbersFunc.py
+++ b/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
--- a/mathgenerator/funcs/multiplyFractionsFunc.py
+++ b/mathgenerator/funcs/multiplyFractionsFunc.py
@@ -0,0 +1,32 @@
 from .__init__ import *
 def multiplyFractionsFunc(maxVal=10):
    a = random.randint(1, maxVal)
    b = random.randint(1, maxVal)
    c = random.randint(1, maxVal)
    d = random.randint(1, maxVal)
    while (a == b):
        b = random.randint(1, maxVal)
    while (c == d):
        d = random.randint(1, maxVal)
    def calculate_gcd(x, y):
        while(y):
            x, y = y, x % y
        return x
    tmp_n = a * c
    tmp_d = b * d
    gcd = calculate_gcd(tmp_n, tmp_d)
    x = f"{tmp_n//gcd}/{tmp_d//gcd}"
    if (tmp_d == 1 or tmp_d == gcd):
        x = f"{tmp_n//gcd}"
    problem = f"({a}/{b})*({c}/{d})"
    solution = x
    return problem, solution
--- a/mathgenerator/funcs/multiplyIntToMatrix22.py
+++ b/mathgenerator/funcs/multiplyIntToMatrix22.py
@@ -0,0 +1,13 @@
 from .__init__ import *
 def multiplyIntToMatrix22(maxMatrixVal=10, maxRes=100):
    a = random.randint(0, maxMatrixVal)
    b = random.randint(0, maxMatrixVal)
    c = random.randint(0, maxMatrixVal)
    d = random.randint(0, maxMatrixVal)
    constant = random.randint(0, int(maxRes / max(a, b, c, d)))
    problem = f"{constant} * [[{a}, {b}], [{c}, {d}]] = "
    solution = f"[[{a*constant},{b*constant}],[{c*constant},{d*constant}]]"
    return problem, solution
--- a/mathgenerator/funcs/nthFibonacciNumberFunc.py
+++ b/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
--- a/mathgenerator/funcs/permutationFunc.py
+++ b/mathgenerator/funcs/permutationFunc.py
@@ -0,0 +1,10 @@
 from .__init__ import *
 def permutationFunc(maxlength=20):
    a = random.randint(10, maxlength)
    b = random.randint(0, 9)
    solution = int(math.factorial(a) / (math.factorial(a - b)))
    problem = "Number of Permutations from {} objects picked {} at a time =  ".format(a, b)
    return problem, solution
--- a/mathgenerator/funcs/powerRuleDifferentiationFunc.py
+++ b/mathgenerator/funcs/powerRuleDifferentiationFunc.py
@@ -0,0 +1,18 @@
 from .__init__ import *
 def powerRuleDifferentiationFunc(maxCoef=10, maxExp=10, maxTerms=5):
    numTerms = random.randint(1, maxTerms)
    problem = ""
    solution = ""
    for i in range(numTerms):
        if i > 0:
            problem += " + "
            solution += " + "
        coefficient = random.randint(1, maxCoef)
        exponent = random.randint(1, maxExp)
        problem += str(coefficient) + "x^" + str(exponent)
        solution += str(coefficient * exponent) + "x^" + str(exponent - 1)
    return problem, solution
--- a/mathgenerator/funcs/powerRuleIntegrationFunc.py
+++ b/mathgenerator/funcs/powerRuleIntegrationFunc.py
@@ -0,0 +1,20 @@
 from .__init__ import *
 def powerRuleIntegrationFunc(maxCoef=10, maxExp=10, maxTerms=5):
    numTerms = random.randint(1, maxTerms)
    problem = ""
    solution = ""
    for i in range(numTerms):
        if i > 0:
            problem += " + "
            solution += " + "
        coefficient = random.randint(1, maxCoef)
        exponent = random.randint(1, maxExp)
        problem += str(coefficient) + "x^" + str(exponent)
        solution += "(" + str(coefficient) + "/" + str(exponent) + ")x^" + str(exponent + 1)
    solution += " + c"
    return problem, solution
--- a/mathgenerator/funcs/primeFactorsFunc.py
+++ b/mathgenerator/funcs/primeFactorsFunc.py
@@ -0,0 +1,22 @@
 from .__init__ import *
 def primeFactorsFunc(minVal=1, maxVal=200):
    a = random.randint(minVal, maxVal)
    n = a
    i = 2
    factors = []
    while i * i <= n:
        if n % i:
            i += 1
        else:
            n //= i
            factors.append(i)
    if n > 1:
        factors.append(n)
    problem = f"Find prime factors of {a}"
    solution = f"{factors}"
    return problem, solution
--- a/mathgenerator/funcs/profitLossPercentFunc.py
+++ b/mathgenerator/funcs/profitLossPercentFunc.py
@@ -0,0 +1,16 @@
 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
    return problem, solution
--- a/mathgenerator/funcs/pythagoreanTheoremFunc.py
+++ b/mathgenerator/funcs/pythagoreanTheoremFunc.py
@@ -0,0 +1,11 @@
 from .__init__ import *
 def pythagoreanTheoremFunc(maxLength=20):
    a = random.randint(1, maxLength)
    b = random.randint(1, maxLength)
    c = (a**2 + b**2)**0.5
    problem = f"The hypotenuse of a right triangle given the other two lengths {a} and {b} = "
    solution = f"{c:.0f}" if c.is_integer() else f"{c:.2f}"
    return problem, solution
--- a/mathgenerator/funcs/quadraticEquation.py
+++ b/mathgenerator/funcs/quadraticEquation.py
@@ -0,0 +1,12 @@
 from .__init__ import *
 def quadraticEquation(maxVal=100):
    a = random.randint(1, maxVal)
    c = random.randint(1, maxVal)
    b = random.randint(round(math.sqrt(4 * a * c)) + 1, round(math.sqrt(4 * maxVal * maxVal)))
    problem = "Zeros of the Quadratic Equation {}x^2+{}x+{}=0".format(a, b, c)
    D = math.sqrt(b * b - 4 * a * c)
    solution = str([round((-b + D) / (2 * a), 2), round((-b - D) / (2 * a), 2)])
    return problem, solution
--- a/mathgenerator/funcs/regularPolygonAngleFunc.py
+++ b/mathgenerator/funcs/regularPolygonAngleFunc.py
@@ -0,0 +1,10 @@
 from .__init__ import *
 def regularPolygonAngleFunc(minVal=3, maxVal=20):
    sideNum = random.randint(minVal, maxVal)
    problem = f"Find the angle of a regular polygon with {sideNum} sides"
    exteriorAngle = round((360 / sideNum), 2)
    solution = 180 - exteriorAngle
    return problem, solution
--- a/mathgenerator/funcs/simpleInterestFunc.py
+++ b/mathgenerator/funcs/simpleInterestFunc.py
@@ -0,0 +1,12 @@
 from .__init__ import *
 def simpleInterestFunc(maxPrinciple=10000, maxRate=10, maxTime=10):
    a = random.randint(1000, maxPrinciple)
    b = random.randint(1, maxRate)
    c = random.randint(1, maxTime)
    d = (a * b * c) / 100
    problem = "Simple interest for a principle amount of " + str(a) + " dollars, " + str(b) + "% rate of interest and for a time period of " + str(c) + " years is = "
    solution = round(d, 2)
    return problem, solution
--- a/mathgenerator/funcs/squareFunc.py
+++ b/mathgenerator/funcs/squareFunc.py
@@ -0,0 +1,10 @@
 from .__init__ import *
 def squareFunc(maxSquareNum=20):
    a = random.randint(1, maxSquareNum)
    b = a * a
    problem = str(a) + "^2" + "="
    solution = str(b)
    return problem, solution
--- a/mathgenerator/funcs/squareRootFunc.py
+++ b/mathgenerator/funcs/squareRootFunc.py
@@ -0,0 +1,10 @@
 from .__init__ import *
 def squareRootFunc(minNo=1, maxNo=12):
    b = random.randint(minNo, maxNo)
    a = b * b
    problem = "sqrt(" + str(a) + ")="
    solution = str(b)
    return problem, solution
--- a/mathgenerator/funcs/subtractionFunc.py
+++ b/mathgenerator/funcs/subtractionFunc.py
@@ -0,0 +1,11 @@
 from .__init__ import *
 def subtractionFunc(maxMinuend=99, maxDiff=99):
    a = random.randint(0, maxMinuend)
    b = random.randint(max(0, (a - maxDiff)), a)
    c = a - b
    problem = str(a) + "-" + str(b) + "="
    solution = str(c)
    return problem, solution
--- a/mathgenerator/funcs/sumOfAnglesOfPolygonFunc.py
+++ b/mathgenerator/funcs/sumOfAnglesOfPolygonFunc.py
@@ -0,0 +1,10 @@
 from .__init__ import *
 def sumOfAnglesOfPolygonFunc(maxSides = 12):
    side = random.randint(3, maxSides)
    sum = (side - 2) * 180
    problem = f"Sum of angles of polygon with {side} sides = "
    solution = sum
    return problem, solution
--- a/mathgenerator/funcs/surdsComparisonFunc.py
+++ b/mathgenerator/funcs/surdsComparisonFunc.py
@@ -0,0 +1,17 @@
 from .__init__ import *
 def surdsComparisonFunc(maxValue = 100, maxRoot = 10):
    radicand1,radicand2 = tuple(random.sample(range(1,maxValue),2))
    degree1, degree2 = tuple(random.sample(range(1,maxRoot),2))
    problem = f"Fill in the blanks {radicand1}^(1/{degree1}) _ {radicand2}^(1/{degree2})"
    first = math.pow(radicand1, 1/degree1)
    second = math.pow(radicand2, 1/degree2)
    solution = "="
    if first > second:
        solution = ">"
    elif first < second:
        solution = "<"
    return problem, solution
--- a/mathgenerator/funcs/surfaceAreaCone.py
+++ b/mathgenerator/funcs/surfaceAreaCone.py
@@ -0,0 +1,13 @@
 from .__init__ import *
 def surfaceAreaCone(maxRadius=20, maxHeight=50, unit='m'):
    a = random.randint(1, maxHeight)
    b = random.randint(1, maxRadius)
    slopingHeight = math.sqrt(a**2 + b**2)
    problem = f"Surface area of cone with height = {a}{unit} and radius = {b}{unit} is"
    ans = int(math.pi * b * slopingHeight + math.pi * b * b)
    solution = f"{ans} {unit}^2"
    return problem, solution
--- a/mathgenerator/funcs/surfaceAreaCube.py
+++ b/mathgenerator/funcs/surfaceAreaCube.py
@@ -0,0 +1,9 @@
 from .__init__ import *
 def surfaceAreaCube(maxSide=20, unit='m'):
    a = random.randint(1, maxSide)
    problem = f"Surface area of cube with side = {a}{unit} is"
    ans = 6 * a * a
    solution = f"{ans} {unit}^2"
    return problem, solution
--- a/mathgenerator/funcs/surfaceAreaCuboid.py
+++ b/mathgenerator/funcs/surfaceAreaCuboid.py
@@ -0,0 +1,12 @@
 from .__init__ import *
 def surfaceAreaCuboid(maxSide=20, unit='m'):
    a = random.randint(1, maxSide)
    b = random.randint(1, maxSide)
    c = random.randint(1, maxSide)
    problem = f"Surface area of cuboid with sides = {a}{unit}, {b}{unit}, {c}{unit} is"
    ans = 2 * (a * b + b * c + c * a)
    solution = f"{ans} {unit}^2"
    return problem, solution
--- a/mathgenerator/funcs/surfaceAreaCylinder.py
+++ b/mathgenerator/funcs/surfaceAreaCylinder.py
@@ -0,0 +1,11 @@
 from .__init__ import *
 def surfaceAreaCylinder(maxRadius=20, maxHeight=50, unit='m'):
    a = random.randint(1, maxHeight)
    b = random.randint(1, maxRadius)
    problem = f"Surface area of cylinder with height = {a}{unit} and radius = {b}{unit} is"
    ans = int(2 * math.pi * a * b + 2 * math.pi * b * b)
    solution = f"{ans} {unit}^2"
    return problem, solution
--- a/mathgenerator/funcs/surfaceAreaSphere.py
+++ b/mathgenerator/funcs/surfaceAreaSphere.py
@@ -0,0 +1,10 @@
 from .__init__ import *
 def surfaceAreaSphere(maxSide = 20, unit = 'm'):
    r = random.randint(1, maxSide)
    problem = f"Surface area of Sphere with radius = {r}{unit} is"
    ans = 4 * math.pi * r * r
    solution = f"{ans} {unit}^2"
    return problem, solution
--- a/mathgenerator/funcs/systemOfEquationsFunc.py
+++ b/mathgenerator/funcs/systemOfEquationsFunc.py
@@ -0,0 +1,45 @@
 from .__init__ import *
 def systemOfEquationsFunc(range_x=10, range_y=10, coeff_mult_range=10):
    # Generate solution point first
    x = random.randint(-range_x, range_x)
    y = random.randint(-range_y, range_y)
    # Start from reduced echelon form (coeffs 1)
    c1 = [1, 0, x]
    c2 = [0, 1, y]
    def randNonZero():
        return random.choice([i for i in range(-coeff_mult_range, coeff_mult_range)
                              if i != 0])
    # Add random (non-zero) multiple of equations (rows) to each other
    c1_mult = randNonZero()
    c2_mult = randNonZero()
    new_c1 = [c1[i] + c1_mult * c2[i] for i in range(len(c1))]
    new_c2 = [c2[i] + c2_mult * c1[i] for i in range(len(c2))]
    # For extra randomness, now add random (non-zero) multiples of original rows
    # to themselves
    c1_mult = randNonZero()
    c2_mult = randNonZero()
    new_c1 = [new_c1[i] + c1_mult * c1[i] for i in range(len(c1))]
    new_c2 = [new_c2[i] + c2_mult * c2[i] for i in range(len(c2))]
    def coeffToFuncString(coeffs):
        # lots of edge cases for perfect formatting!
        x_sign = '-' if coeffs[0] < 0 else ''
        # No redundant 1s
        x_coeff = str(abs(coeffs[0])) if abs(coeffs[0]) != 1 else ''
        # If x coeff is 0, dont include x
        x_str = f'{x_sign}{x_coeff}x' if coeffs[0] != 0 else ''
        # if x isn't included and y is positive, dont include operator
        op = ' - ' if coeffs[1] < 0 else (' + ' if x_str != '' else '')
        # No redundant 1s
        y_coeff = abs(coeffs[1]) if abs(coeffs[1]) != 1 else ''
        # Don't include if 0, unless x is also 0 (probably never happens)
        y_str = f'{y_coeff}y' if coeffs[1] != 0 else ('' if x_str != '' else '0')
        return f'{x_str}{op}{y_str} = {coeffs[2]}'
    problem = f"{coeffToFuncString(new_c1)}, {coeffToFuncString(new_c2)}"
    solution = f"x = {x}, y = {y}"
    return problem, solution
    # Add random (non-zero) multiple of equations to each other
--- a/mathgenerator/funcs/thirdAngleOfTriangleFunc.py
+++ b/mathgenerator/funcs/thirdAngleOfTriangleFunc.py
@@ -0,0 +1,11 @@
 from .__init__ import *
 def thirdAngleOfTriangleFunc(maxAngle=89):
    angle1 = random.randint(1, maxAngle)
    angle2 = random.randint(1, maxAngle)
    angle3 = 180 - (angle1 + angle2)
    problem = f"Third angle of triangle with angles {angle1} and {angle2} = "
    solution = angle3
    return problem, solution
--- a/mathgenerator/funcs/vectorCrossFunc.py
+++ b/mathgenerator/funcs/vectorCrossFunc.py
@@ -0,0 +1,13 @@
 from .__init__ import *
 def vectorCrossFunc(minVal=-20, maxVal=20):
     a = [random.randint(minVal, maxVal) for i in range(3)]
     b = [random.randint(minVal, maxVal) for i in range(3)]
     c = [a[1] * b[2] - a[2] * b[1],
         a[2] * b[0] - a[0] * b[2],
         a[0] * b[1] - a[1] * b[0]]
     problem = str(a) + " X " + str(b) + " = "
     solution = str(c)
     return problem, solution
--- a/mathgenerator/funcs/vectorDotFunc.py
+++ b/mathgenerator/funcs/vectorDotFunc.py
@@ -0,0 +1,11 @@
 from .__init__ import *
 def vectorDotFunc(minVal=-20, maxVal=20):
     a = [random.randint(minVal, maxVal) for i in range(3)]
     b = [random.randint(minVal, maxVal) for i in range(3)]
     c = a[0] * b[0] +  a[1] * b[1] + a[2] * b[2] 
     problem = str(a) + " . " + str(b) + " = "
     solution = str(c)
     return problem, solution
--- a/mathgenerator/funcs/volumeCone.py
+++ b/mathgenerator/funcs/volumeCone.py
@@ -0,0 +1,11 @@
 from .__init__ import *
 def volumeCone(maxRadius=20, maxHeight=50, unit='m'):
    a = random.randint(1, maxHeight)
    b = random.randint(1, maxRadius)
    problem = f"Volume of cone with height = {a}{unit} and radius = {b}{unit} is"
    ans = int(math.pi * b * b * a * (1 / 3))
    solution = f"{ans} {unit}^3"
    return problem, solution
--- a/mathgenerator/funcs/volumeCube.py
+++ b/mathgenerator/funcs/volumeCube.py
@@ -0,0 +1,10 @@
 from .__init__ import *
 def volumeCube(maxSide=20, unit='m'):
    a = random.randint(1, maxSide)
    problem = f"Volume of cube with side = {a}{unit} is"
    ans = a * a * a
    solution = f"{ans} {unit}^3"
    return problem, solution
--- a/mathgenerator/funcs/volumeCuboid.py
+++ b/mathgenerator/funcs/volumeCuboid.py
@@ -0,0 +1,12 @@
 from .__init__ import *
 def volumeCuboid(maxSide=20, unit='m'):
    a = random.randint(1, maxSide)
    b = random.randint(1, maxSide)
    c = random.randint(1, maxSide)
    problem = f"Volume of cuboid with sides = {a}{unit}, {b}{unit}, {c}{unit} is"
    ans = a * b * c
    solution = f"{ans} {unit}^3"
    return problem, solution
--- a/mathgenerator/funcs/volumeCylinder.py
+++ b/mathgenerator/funcs/volumeCylinder.py
@@ -0,0 +1,11 @@
 from .__init__ import *
 def volumeCylinder(maxRadius=20, maxHeight=50, unit='m'):
    a = random.randint(1, maxHeight)
    b = random.randint(1, maxRadius)
    problem = f"Volume of cylinder with height = {a}{unit} and radius = {b}{unit} is"
    ans = int(math.pi * b * b * a)
    solution = f"{ans} {unit}^3"
    return problem, solution
--- a/mathgenerator/funcs/volumeSphereFunc.py
+++ b/mathgenerator/funcs/volumeSphereFunc.py
@@ -0,0 +1,10 @@
 from .__init__ import *
 def volumeSphereFunc(maxRadius = 100):
    r=random.randint(1,maxRadius)
    problem=f"Volume of sphere with radius {r} m = "
    ans=(4*math.pi/3)*r*r*r
    solution = f"{ans} m^3"
    return problem,solution